JP7639866B2 - Hot water production system - Google Patents

Description

The present invention relates to a hot water production system.

Manufacturing factories that produce food and beverages, as well as automobile, metal product, and machinery and equipment, consume large amounts of hot water and heat in the production process. In recent years, many factories have been working toward "decarbonization," moving away from fossil fuels, with the aim of reducing emissions of CO2, a greenhouse gas. As a result, as shown in Patent Document 1, electric heat pumps are increasingly being used as water heating devices in hot water production systems.

JP 2012-229828 A

Electric heat pumps are heat source devices that are extremely effective in reducing _CO2 emissions, but they have the disadvantage that the equipment cost per heat output is about 10 times higher than that of combustion boilers. In addition, electric heat pumps have the disadvantage that they have a lower instantaneous power when outputting heat than combustion boilers, and that it takes a long time to obtain hot water at the desired temperature after starting up in cold mode. In order to promote the introduction of heat pumps, it is necessary to build a system that can compensate for these disadvantages.
In recent years, the Virtual Power Plant (VPP) system has been attracting attention as a mechanism for adjusting the balance between power supply and demand. In the VPP system, it is desired that the consumer side performs demand adjustment (demand response: DR) in a planned manner according to the demands of the power market. Demand response includes "downward DR" that suppresses power consumption, and "upward DR" that promotes power consumption. In order to promote the introduction of heat pumps and have consumers participate in the VPP system, it is also necessary to build a system that can respond to these DRs.

The present invention was made in consideration of the above problems, and aims to provide a hot water production system that can optimally heat water depending on whether or not power demand adjustment is implemented while compensating for the shortcomings of electric heat pumps.

(1) The present invention is a hot water production system for warming water used in load equipment in a business establishment, comprising a first heating device for heating the water by an electric heat pump, a second heating device for heating the water by a combustion boiler, a heating mode selection means for selecting one of a plurality of heating modes including at least a first heating mode and a third heating mode depending on whether or not power demand adjustment is implemented, and a control means for controlling the operation of the first heating device and the second heating device depending on the heating mode selected by the heating mode selection means, wherein the load equipment generates a demand for hot water by directly using the heated water, the heating mode selection means selects the first heating mode when power demand adjustment is not implemented, and selects the third heating mode when power demand adjustment is implemented to promote power consumption more than when the first heating mode is selected, and the control means controls a hot water tank attached to the load equipment. The hot water production system detects the hot water demand of the load equipment based on the water level or the flow rate of makeup water, and operates the first heating device and the second heating device according to the detected hot water demand. In the first heating mode, the first heating device is a base load device and the second heating device is a peak load device, and switching is performed between the independent operation of the first heating device and the coordinated operation of the first heating device and the second heating device, thereby allowing the hot water supply to follow changes in the hot water demand of the load equipment. In the third heating mode, the first heating device is a base load device and a peak load device, and the first heating device is independently operated, and the electric heat pump is controlled so that the heat output of the first heating device in the third heating mode is greater than the heat output of the first heating device in the first heating mode, thereby allowing the hot water supply to follow changes in the hot water demand of the load equipment.

(2) The present invention also relates to a hot water production system for warming water used in load equipment in a business establishment, comprising: a first heating device for heating the water by an electric heat pump; a second heating device for heating the water by a combustion boiler; a heating mode selection means for selecting one of a plurality of heating modes including at least a first heating mode and a third heating mode depending on whether or not power demand adjustment is being implemented; and a control means for controlling the operation of the first heating device and the second heating device depending on the heating mode selected by the heating mode selection means, wherein the load equipment generates a demand for hot water by directly using the heated water, the heating mode selection means selects the first heating mode when power demand adjustment is not being implemented, and selects the third heating mode when power demand adjustment is being implemented to promote power consumption more than when the first heating mode is selected, and the control means detects the hot water demand of the load equipment based on the water level of a hot water tank attached to the load equipment or the flow rate of make-up water, and controls the operation of the detected hot water. The hot water production system operates the first heating device and the second heating device according to demand, and in the first heating mode, the first heating device is a base load device and the second heating device is a peak load device, and switches between the independent operation of the first heating device and the cooperative operation of the first heating device and the second heating device, thereby allowing the hot water supply to follow changes in the hot water demand of the load equipment; and in the third heating mode, the first heating device is a base load device and the second heating device is a peak load device, and switches between the independent operation of the first heating device and the cooperative operation of the first heating device and the second heating device, and in the cooperative operation of the third heating mode, the electric heat pump and the combustion boiler are controlled so that the output ratio of the first heating device to the total heat output of the first heating device and the second heating device is greater than the output ratio of the first heating device in the cooperative operation of the first heating mode, thereby allowing the hot water supply to follow changes in the hot water demand of the load equipment.

(3) The present invention also relates to a hot water production system for warming water used in load equipment within a business establishment, comprising: a first heating device for heating the water by an electric heat pump; a second heating device for heating the water by a combustion boiler; a heating mode selection means for selecting one of a plurality of heating modes including at least a first heating mode and a third heating mode depending on whether or not power demand adjustment is being implemented; and a control means for controlling the operation of the first heating device and the second heating device depending on the heating mode selected by the heating mode selection means, wherein the load equipment generates a demand for hot water by indirectly using the warmed water, the heating mode selection means selects the first heating mode when power demand adjustment is not being implemented, and selects the third heating mode when power demand adjustment is being implemented to promote power consumption more than when the first heating mode is selected, and the control means controls the return temperature of the hot water in a hot water loop system formed for the load equipment, Alternatively, the hot water production system detects the hot water demand of the load equipment based on the difference between the supply temperature and the return temperature of the hot water in the hot water loop system, and operates the first heating device and the second heating device according to the detected hot water demand. In the first heating mode, the first heating device is operated as a base load device and the second heating device is operated as a peak load device, and switching is performed between the independent operation of the first heating device and the cooperative operation of the first heating device and the second heating device is performed, thereby allowing the hot water supply to follow the change in the hot water demand of the load equipment. In the third heating mode, the first heating device is operated as a base load device and a peak load device, and the electric heat pump is controlled so that the heat output of the first heating device in the third heating mode is greater than the heat output of the first heating device in the first heating mode, thereby allowing the hot water supply to follow the change in the hot water demand of the load equipment.

(4) The present invention also relates to a hot water production system for heating water used in load equipment in a business establishment, comprising a first heating device for heating the water by an electric heat pump, a second heating device for heating the water by a combustion boiler, a heating mode selection means for selecting one of a plurality of heating modes including at least a first heating mode and a third heating mode depending on whether or not power demand adjustment is being implemented, and a control means for controlling the operation of the first heating device and the second heating device depending on the heating mode selected by the heating mode selection means, wherein the load equipment generates a demand for hot water by indirectly using the heated water, the heating mode selection means selects the first heating mode when power demand adjustment is not being implemented, and selects the third heating mode when power demand adjustment is being implemented to promote power consumption more than when the first heating mode is selected, and the control means determines the hot water demand of the load equipment by the return temperature of the hot water in a hot water loop system formed for the load equipment, or the difference between the supply temperature and the return temperature of the hot water in the hot water loop system. The hot water production system detects the demand for hot water, and operates the first heating device and the second heating device in response to the detected demand for hot water. In the first heating mode, the first heating device is a base load device and the second heating device is a peak load device, and switching is performed between the independent operation of the first heating device and the cooperative operation of the first heating device and the second heating device, thereby allowing the supply of hot water to follow changes in the demand for hot water of the load equipment. In the third heating mode, the first heating device is a base load device and the second heating device is a peak load device, and switching is performed between the independent operation of the first heating device and the cooperative operation of the first heating device and the second heating device, and in the cooperative operation of the third heating mode, the electric heat pump and the combustion boiler are controlled so that the output ratio of the first heating device to the total heat output of the first heating device and the second heating device is greater than the output ratio of the first heating device in the cooperative operation of the first heating mode, thereby allowing the supply of hot water to follow changes in the demand for hot water of the load equipment.

(5) In addition, in any of the hot water production systems (1) to (4) above, the control means may detect the heat output of the first heating device based on the outlet hot water temperature during operation of the first heating device, and in the first heating mode, switch between independent operation of the first heating device and coordinated operation of the first heating device and the second heating device depending on the heat output of the first heating device.

(6) In addition, in any of the hot water production systems (1) to (4) above, a steam boiler may be used as the combustion boiler constituting the second heating device, and the water may be heated by direct or indirect heat exchange between the steam and the water.

(7) In addition, in any of the hot water production systems (1) to (4) above, the combustion boiler may use a fuel selected from hydrogen, ammonia, biomethane, and bioethanol.

The present invention provides a hot water production system that can compensate for the shortcomings of electric heat pumps and perform optimal water heating depending on whether or not power demand adjustment is implemented.

1 is a diagram showing a schematic configuration of a hot water producing system according to a first embodiment of the present invention; FIG. 10 is a diagram showing a schematic configuration of a hot water producing system according to a second embodiment of the present invention. FIG. 13 is a diagram showing a schematic configuration of a hot water producing system according to a third embodiment of the present invention. FIG. 13 is a diagram showing a schematic configuration of a hot water producing system according to a fourth embodiment of the present invention. FIG. 13 is a diagram showing a schematic configuration of a hot water producing system according to a fifth embodiment of the present invention. FIG. 13 is a diagram showing a schematic configuration of a hot water producing system according to a sixth embodiment of the present invention. FIG. 13 is a diagram showing a schematic configuration of a hot water producing system according to a seventh embodiment of the present invention. FIG. 13 is a diagram showing a schematic configuration of a hot water producing system according to an eighth embodiment of the present invention. FIG. 13 is a diagram showing a schematic configuration of a hot water producing system according to a ninth embodiment of the present invention. FIG. 23 is a diagram showing a schematic configuration of a hot water producing system according to a tenth embodiment of the present invention. FIG. 23 is a diagram showing a schematic configuration of a hot water producing system according to an eleventh embodiment of the present invention. FIG. 23 is a diagram showing a schematic configuration of a hot water producing system according to a twelfth embodiment of the present invention.

First Embodiment
Hereinafter, a first embodiment of a hot water producing system 1 of the present invention will be described with reference to the drawings. In this specification, the term "line" is a general term for a line, such as a flow path, a pathway, or a pipe, through which a fluid can flow.

Figure 1 is a diagram showing a schematic configuration of a hot water production system 1 according to the first embodiment. The hot water production system 1 includes a first heating device 10 that heats the water W1 using an electric heat pump 11, a second heating device 20 that heats the water W1 using a combustion boiler 21, and a control unit 100. The hot water production system 1 of this embodiment further includes a hot water tank 30, a water distribution line L10, and a water return line L20. The hot water production system 1 heats the water W1 used in the load equipment 200 within the business premises.

Here, the business establishment refers to an individual location where the production of goods or the provision of services is carried out as a business, such as a factory, a commercial facility, a medical institution, a welfare facility, an accommodation facility, or a research facility. The service water W1 refers to water used in the production of goods or the provision of services. In the case where the business establishment is a factory, the load equipment 200 refers to production equipment (equipment directly involved in the production of goods), such as a food or beverage manufacturing factory or an automobile, metal product, or machine tool manufacturing factory. The heated service water W1 is used directly as cleaning water, etc., and is also used indirectly as heat transfer water. An example of the load equipment 200 other than the production equipment of a factory is a steam boiler device (heat source equipment involved in the operation of the production equipment), and a part of the heated service water W1 is used as boiler feed water.
The load equipment 200 in this embodiment indirectly uses the heated service water W1 as heat transfer water (i.e., heat output).

<Hot water tank>
The hot water tank 30 stores the hot water W1 as stored water. In this embodiment, the hot water tank 30 is an open tank. The hot water tank 30 is equipped with a water level sensor 31. When the water level sensor 31 detects a decrease in water level in the hot water tank 30 due to natural evaporation, makeup water W0 is supplied into the hot water tank 30 through the makeup water line L00. A temperature sensor (not shown) is provided in the hot water tank 30, and the temperature of the stored water in the hot water tank 30 is detected as the heat storage temperature TC of the hot water tank 30.

<Various lines>
In this embodiment, a water distribution line L10, which is a hot water supply pipe, is laid from the hot water tank 30 to the load equipment 200, and a hot water return line L20, which is a hot water return pipe, is laid from the load equipment 200 to the hot water tank 30. This forms a circulation line of a hot water loop system.

The water distribution line L10 is a line for supplying the hot water W1 in the hot water tank 30 to the load equipment 200. A supply pump 50 is provided on the water distribution line L10.

The water return line L20 is a line for returning the water W1 from the load equipment 200 to the hot water tank 30. The water return line L20 branches from a branch point P into a first heated target line L21 and a second heated target line L22.

The first heating target line L21 is provided with a first sub-heat exchanger 12 of the first heating device 10 described below. The water W1 flowing through the first heating target line L21 is heated by the first sub-heat exchanger 12. A water valve 51 is provided in the first heating target line L21.

The second heating target line L22 is provided with a second sub-heat exchanger 22 of the second heating device 20 described below. The water W1 flowing through the second heating target line L22 is heated by the second sub-heat exchanger 22. A water passage valve 52 is provided in the second heating target line L22.

A temperature sensor 40 is provided upstream of the branch point P of the water return line L20. The temperature sensor 40 detects the return temperature Tr of the hot water flowing through the water return line L20 upstream of the branch point P of the water return line.

<First Heating Device>
The first heating device 10 has an electric heat pump 11 (abbreviation: HP), a first sub-heat exchanger 12, a first sub-circulation pump 13, and a first sub-circulation line LS1.

The first sub-circulation line LS1 connects the first sub-heat exchanger 12 and the condenser of the heat pump 11. The heat medium R1 circulating through the first sub-circulation line LS1 may be water. In particular, for hot water supply applications, it is preferable that the heat medium R1 be water in order to prevent the refrigerant from being mixed into the water W1 when the condenser breaks down.

The heat pump 11 heats the heat medium R1 circulating through the first sub-circulation line LS1. The heat pump 11 may be either an air heat source type or a water heat source type (groundwater, waste hot water, etc.). It may also be a heat pump chiller capable of simultaneously extracting hot and cold water.

The first sub-heat exchanger 12 exchanges heat between the water W1 flowing through the first heating target line L21 and the heat medium R1 flowing through the first sub-circulation line LS1 to heat the water W1. The first sub-heat exchanger 12 is disposed in the first heating target line L21 (including the return water line from the load equipment in each embodiment, the circulation line to the hot water tank, and the water supply line from the water supply equipment). A temperature sensor (not shown) is provided downstream of the first sub-heat exchanger 12 in the first heating target line L21, and the temperature of the hot water flowing through the first heating target line L21 after passing through the first sub-heat exchanger 12 is detected as the outlet temperature TA of the first sub-heat exchanger 12. In addition, a temperature sensor (not shown) is provided upstream of the first sub-heat exchanger 12 in the first heating target line L21, and the temperature of the hot water flowing through the first heating target line L21 before passing through the first sub-heat exchanger 12 is detected as the inlet temperature TA0 of the first sub-heat exchanger 12. The inlet/outlet temperature difference of the first sub-heat exchanger 12 is detected from the difference between this inlet temperature TA0 and the outlet temperature TA.

The first sub-circulation pump 13 is provided in the first sub-circulation line LS1. The first sub-circulation pump 13 circulates the heat medium R1 flowing through the first sub-circulation line LS1.

The first heating device 10 may be configured such that the first heating target line L21 is directly connected to the condenser of the heat pump 11. In this case, the first sub-heat exchanger 12 and the first sub-circulation line LS1 can be omitted.

<Second Heating Device>
The second heating device 20 has a combustion boiler 21, a second sub-heat exchanger 22, a second sub-circulation pump 23, and a second sub-circulation line LS2.

The second sub-circulation line LS2 connects the second sub-heat exchanger 22 to the hot water boiler body of the combustion boiler 21. The heat medium R2 circulating through the second sub-circulation line LS2 may be water.

The combustion boiler 21 heats the heat medium R2 circulating through the second sub-circulation line LS2. The combustion boiler 21 may be a boiler that uses a fuel selected from hydrocarbons, hydrogen, and ammonia. The combustion boiler 21 may be either a hot water boiler (abbreviation: BH) or a steam boiler (abbreviation: BS). In this embodiment, the hot water boiler 21 is used as the combustion boiler. The hot water boiler 21 includes a vacuum type hot water heater and a non-pressure type hot water heater.

The second sub-heat exchanger 22 exchanges heat between the water W1 flowing through the second heating target line L22 and the heat medium R2 flowing through the second sub-circulation line LS2 to heat the water W1. The second sub-heat exchanger 22 is disposed in the second heating target line L22 (including the return water line from the load equipment, the circulation line to the hot water tank, and the water supply line from the water supply equipment in each embodiment). A temperature sensor (not shown) is provided downstream of the second sub-heat exchanger 22 in the second heating target line L22, and the temperature of the hot water flowing through the second heating target line L22 after passing through the second sub-heat exchanger 22 is detected as the outlet temperature TB of the second sub-heat exchanger 22. In addition, a temperature sensor (not shown) is provided upstream of the second sub-heat exchanger 22 in the second heating target line L22, and the temperature of the hot water flowing through the second heating target line L22 before passing through the second sub-heat exchanger 22 is detected as the inlet temperature TB0 of the second sub-heat exchanger 22. The inlet/outlet temperature difference of the second sub-heat exchanger 22 is detected from the difference between this inlet temperature TB0 and the outlet temperature TB.

The second sub-circulation pump 23 is provided in the second sub-circulation line LS2. The second sub-circulation pump 23 circulates the heat medium R2 flowing through the second sub-circulation line LS2.

The second heating device 20 may be a device that heats the water W1 by exchanging heat between the steam generated in the combustion boiler 21 and the water W1. For example, the second heating device 20 may be configured such that a second sub-heat exchanger 22 is disposed in the second heating target line L22 (including the return water line from the load equipment in each embodiment, the circulation line with the hot water tank, and the water supply line from the water supply equipment), and a steam line extending from the steam boiler via a steam header is connected to the second sub-heat exchanger 22. A steam supply valve (proportional control valve) is provided in the steam line.

In this way, the combustion boiler 21 constituting the second heating device 20 can be a steam boiler as well as a hot water boiler. When a steam boiler is used as the heat source, the steam and the water are indirectly or directly heat exchanged to heat the water. For example, when using steam with an absolute pressure of 0.3 MPa to 2 MPa generated by a small once-through steam boiler, the saturation temperature reaches 150 to 215°C, so that the heating operation time can be shortened even when producing hot water at 80 to 90°C. As a result, the increase in _CO2 emissions is suppressed.

The hot water production system 1 may further include a third heating device that heats the boiler feed water using a heat recovery electric heat pump. A third heating device incorporating a heat recovery electric heat pump that uses waste hot water or the like as a heat source is installed to heat the boiler feed water of the steam boiler. This makes it possible to significantly reduce _CO2 emissions from the combustion boiler when using steam energy in the third heating mode.

The second heating device 20 may be a device that heats the water stored in the hot water tank 30, as shown in other embodiments described below. In this case, the heating means of the second heating device 20 may be any of (A) a steam injection pipe (direct heating) installed inside the hot water tank 30, (B) a steam heater 25 (indirect heating) installed inside the hot water tank 30, and (C) a steam heat exchanger (indirect heating by water circulation) installed outside the hot water tank 30.

As described above, the hot water production system 1 of this embodiment has a return water line L20 as a heating target line that supplies water to the hot water tank 30, and the first heating device 10 and the second heating device 20 heat the water W1 flowing through the heating target line. In addition, the heating target line is branched, and the first heating device 10 and the second heating device 20 are arranged in parallel.

<Control Unit>
The control unit 100 includes a heating mode selection unit 110 as a heating mode selection means, an operation control unit 120 as a control means, and a storage unit 130 .

The control unit 100 may be a server. The control unit 100 is composed of a plurality of functional blocks as described above, but the functional blocks do not necessarily need to be physically separated, and one CPU may realize the functions of a plurality of functional blocks. The control unit 100 may be arranged in two or more locations, taking into consideration the arrangement of the controlled parts, etc. One functional block may be divided into two or more locations and controlled in a distributed manner. The storage unit is composed of a recording medium such as a ROM (Read Only Memory), a HDD (Hard Disk Drive), a SSD (Solid State Drive), or a removable memory card. Examples of recording media include non-transitory tangible media. The control unit 100 is composed of an arithmetic processor such as a CPU (Central Processing Unit), a DSP (Digital Signal Processor), and an FPGA (Field-Programmable Gate Array). The various functions of the control unit 100 are realized, for example, by executing a program (application) stored in the storage unit. The program (application) may be provided via a network, or may be provided recorded on a computer-readable storage medium such as a CD-ROM (Compact Disc Read Only Memory) or a DVD (Digital Versatile Disc). Each function of the control unit 100 may be realized by a combination of hardware and software, or may be realized only by hardware (electronic circuits).

The heating mode selection unit 110 selects one heating mode from among a plurality of heating modes depending on whether or not power demand adjustment is performed. The plurality of heating modes include a first heating mode, a second heating mode, and a third heating mode. The heating mode selection unit 110 selects the first heating mode when power demand adjustment is not performed, selects the second heating mode when power demand adjustment is performed to suppress power consumption, and selects the third heating mode when power demand adjustment is performed to promote power consumption. The heating mode selection unit 110 selects one mode from among a plurality of heating modes based on input information from outside. The input information from outside is, for example, information on the activation of an up-down DR provided by a resource aggregator (a business operator that directly enters into a VPP service contract with a consumer to control resources) or the like.

The second heating mode may have multiple types of heating modes, such as the second heating mode A and the second heating mode B. The hot water production system 1 may be configured to be able to execute only the second heating mode A as the second heating mode, or to execute only the second heating mode B, or to selectively execute either one of them. The third heating mode may have multiple types of heating modes, such as the third heating mode A and the third heating mode B. The hot water production system 1 may be configured to be able to execute only the third heating mode A as the third heating mode, or to execute only the third heating mode B, or to selectively execute either one of them.

In addition, if the system is configured to be able to selectively execute either the second heating mode A or the second heating mode B, when executing the second heating mode, the system may switch between the second heating mode A and the second heating mode B as needed depending on the operating hours of the business establishment and the required amount of power adjustment. Furthermore, the system may transition to the second heating mode B during execution of the second heating mode A. The same applies to the system configured to be able to selectively execute either the third heating mode A or the third heating mode B.

The operation control unit 120 controls the operation of the first heating device 10 and the second heating device 20 according to the heating mode selected by the heating mode selection unit 110. In controlling the operation of the first heating device 10 and the second heating device 20, the operation control unit 120 controls various devices constituting the hot water production system 1, such as the refrigerant compressor of the heat pump 11, the water valve 51 of the first sub-heat exchanger 12, the burner of the hot water boiler 21, the water valve 52 of the second sub-heat exchanger 22, the first sub-circulation pump 13, and the second sub-circulation pump 23.

The operation control unit 120, for example, acquires information on the return temperature Tr detected by the temperature sensor 40, the outlet temperature TA of the first sub-heat exchanger 12, and the outlet temperature TB of the second sub-heat exchanger 22, and controls the operation of the first heating device 10 and the second heating device 20 based on this information. The operation control unit 120 may compare the return temperature Tr detected by the temperature sensor 40 with a plurality of set temperatures and control the operation of the first heating device 10 and the second heating device 20. The operation control unit 120 may compare the return temperature Tr detected by the temperature sensor 40 with three set temperatures T1>T2>T3, for example, and control the operation of the first heating device 10 and the second heating device 20. Each set temperature may be set based on input information from the outside. Also, each set temperature may be stored in the memory unit 130 of the control unit 100.

<<Control of First Heating Mode>>
As described above, the first heating mode is selected by the heating mode selection unit 110 when power demand adjustment is not performed. In the first heating mode, the operation control unit 120 switches between the independent operation of the first heating device 10 and the cooperative operation of the first heating device 10 and the second heating device 20 according to the hot water demand in the load equipment 200, the heat demand in the load equipment 200, or the heat output of the first heating device 10. In this embodiment, the operation control unit 120 controls the operation of the first heating device 10 and the second heating device 20 according to the heat demand in the load equipment 200. For example, the return temperature Tr of the hot water from the load equipment 200 side in the hot water loop system is an index indicating the heat demand of the load equipment 200. The lower the return temperature Tr, the greater the heat demand.

The following describes an example of control by the operation control unit 120 in the first heating mode.

[1] The set temperatures are, for example, T1 = 70°C (return temperature at zero load, i.e., equivalent to the target hot water temperature), T2 = 60°C (equivalent to the return temperature at the average base load), and T3 = 50°C (equivalent to the return temperature at the average peak load). However, the numerical examples of each set temperature do not take into account heat loss associated with hot water circulation.

[2] The water valve 51 of the first sub-heat exchanger 12 is always open to return hot water from the load equipment 200 to the hot water tank 30. The water valve 52 of the second sub-heat exchanger 22 is opened when the second heating device 20 starts operating and closed when the operation ends.

[3] When the return temperature Tr becomes equal to or higher than the set temperature T1 (Tr≧70°C), the operation of the first heating device 10 is terminated. Specifically, the refrigerant compressor of the heat pump 11 is stopped, and the first sub-circulation pump 13 is stopped.

[4] When the return temperature Tr becomes lower than the set temperature T2 (Tr<60° C.), the operation of the first heating device 10 is started. Specifically, the first sub-circulation pump 13 is driven, and the refrigerant compressor of the heat pump 11 is driven.
During independent operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a first target temperature (e.g., 70°C).

[5] When the return temperature Tr becomes equal to or higher than the set temperature T2 (Tr ≧ 60°C), the operation of the second heating device 20 is terminated. Specifically, the burner of the hot water boiler 21 is stopped, and the second sub-circulation pump 23 is stopped.

[6] When the return temperature Tr becomes lower than the set temperature T3 (Tr<50° C.), the second heating device 20 starts operating. Specifically, the second sub-circulation pump 23 is driven and the burner of the hot water boiler 21 is operated.
During the coordinated operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to the first target temperature (e.g., 70° C.). Also, during the coordinated operation of the second heating device 20, the combustion amount of the burner of the hot water boiler 21 is adjusted so that the outlet temperature TB of the second sub-heat exchanger 22 converges to the first target temperature (e.g., 70° C.).

<<Control of second heating mode A>>
As described above, the second heating mode is selected by the heating mode selection unit 110 when power demand adjustment is performed to suppress power consumption. In the second heating mode A, the operation control unit 120 executes an independent operation of the second heating device 20 in response to the hot water demand in the load equipment 200 or the heat demand in the load equipment 200. In this embodiment, the operation control unit 120 executes an independent operation of the second heating device 20 in response to the heat demand in the load equipment 200.

The following describes an example of control by the operation control unit 120 in the second heating mode A.

[1] In the second heating mode A, the target temperature for hot water supply is increased to increase the amount of heat stored in the system. To this end, the set temperature T1 is changed from 70°C to 90°C, and the set temperature T2 is changed from 60°C to 70°C. In this heating mode, there is no coordinated operation with the first heating device 10.

[2] The water valve 52 of the second sub-heat exchanger 22 is always open to return hot water from the load equipment 200 to the hot water tank 30. The water valve 51 of the first sub-heat exchanger 12 is closed.

[3] When the return temperature Tr becomes equal to or higher than the set temperature T1 (Tr ≧ 90°C), the operation of the second heating device 20 is terminated. Specifically, the burner of the hot water boiler 21 is stopped, and the second sub-circulation pump 23 is stopped.

[4] When the return temperature Tr becomes lower than the set temperature T2 (Tr<70° C.), the second heating device 20 starts operating. Specifically, the second sub-circulation pump 23 is driven and the burner of the hot water boiler 21 is operated.
During the independent operation of the second heating device 20, the combustion amount of the burner of the hot water boiler 21 is adjusted so that the outlet temperature TB of the second sub-heat exchanger 22 converges to a second target temperature (e.g., 90° C.). By making the heat storage temperature TC of the hot water tank 30 higher than in the first heating mode, the independent operation that promotes fuel consumption of the second heating device 20 is continued, while also satisfying the peak demand of the load equipment 200.

In this way, it is preferable that the operation control unit 120 controls the combustion boiler 21 so that the heat output of the second heating device 20 in the second heating mode is greater than the heat output of the second heating device 20 in the first heating mode.

<<Control of third heating mode A>>
As described above, the third heating mode is selected by the heating mode selection unit 110 when power demand adjustment is performed to promote power consumption. In the third heating mode A, the operation control unit 120 executes an independent operation of the first heating device 10 in response to the hot water demand in the load equipment 200 or the heat demand in the load equipment 200. In this embodiment, the operation control unit 120 executes an independent operation of the first heating device 10 in response to the heat demand in the load equipment 200.

The following describes an example of control by the operation control unit 120 in the third heating mode A.

[1] In the third heating mode A, the target temperature for hot water supply is increased to increase the amount of heat stored in the system. To this end, the set temperature T1 is changed from 70°C to 90°C, and the set temperature T2 is changed from 60°C to 70°C. In this heating mode, there is no coordinated operation with the second heating device 20.

[2] The water valve 51 of the first sub-heat exchanger 12 is always open to return hot water from the load equipment 200 to the hot water tank 30. The water valve 52 of the second sub-heat exchanger 22 is closed.

[3] When the return temperature Tr becomes equal to or higher than the set temperature T1 (Tr ≧ 90°C), the operation of the first heating device 10 is terminated. Specifically, the refrigerant compressor of the heat pump 11 is stopped, and the first sub-circulation pump 13 is stopped.

[4] When the return temperature Tr becomes lower than the set temperature T2 (Tr<70° C.), the operation of the first heating device 10 is started. Specifically, the first sub-circulation pump 13 is driven, and the refrigerant compressor of the heat pump 11 is driven.
During the independent operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a second target temperature (e.g., 90° C.). By making the heat storage temperature TC of the hot water tank 30 higher than in the first heating mode, the independent operation that promotes the power consumption of the first heating device 10 is continued while also satisfying the peak demand of the load equipment 200.

In this way, it is preferable that the operation control unit 120 controls the electric heat pump 11 so that the heat output of the first heating device 10 in the third heating mode is greater than the heat output of the first heating device 10 in the first heating mode.

<<Control of second heating mode B>>
As described above, the second heating mode is selected by the heating mode selection unit 110 when power demand adjustment is performed to suppress power consumption. In the second heating mode B, the operation control unit 120 switches between the independent operation of the second heating device 20 and the cooperative operation of the second heating device 20 and the first heating device 10 according to the hot water demand in the load equipment 200 or the heat demand in the load equipment 200, and controls the electric heat pump 11 and the combustion boiler 21 in the cooperative operation of the second heating mode B so that the output ratio of the second heating device 20 to the total heat output of the first heating device 10 and the second heating device 20 is greater than the output ratio of the second heating device 20 in the cooperative operation of the first heating mode. In this embodiment, the operation control unit 120 performs such control according to the heat demand in the load equipment 200.

The following describes an example of control by the operation control unit 120 in the second heating mode B.

[1] The set temperatures T1 to T3 are the same as those in the first heating mode.

[2] The water valve 52 of the second sub-heat exchanger 22 is always open to return hot water from the load equipment 200 to the hot water tank 30. The water valve 51 of the first sub-heat exchanger 12 is opened when the first heating device 10 starts operating and closed when the operation ends.

[3] When the return temperature Tr becomes equal to or higher than the set temperature T1 (Tr ≧ 70°C), the operation of the second heating device 20 is terminated. Specifically, the burner of the hot water boiler 21 is stopped, and the second sub-circulation pump 23 is stopped.

[4] When the return temperature Tr becomes lower than the set temperature T2 (Tr<60° C.), the second heating device 20 starts operating. Specifically, the second sub-circulation pump 23 is driven and the burner of the hot water boiler 21 is operated.
During independent operation of the second heating device 20, the combustion amount of the burner of the hot water boiler 21 is adjusted so that the outlet temperature TB of the second sub-heat exchanger 22 converges to the first target temperature (e.g., 70°C).

[5] When the return temperature Tr becomes equal to or higher than the set temperature T2 (Tr ≧ 60°C), the operation of the first heating device 10 is terminated. Specifically, the refrigerant compressor of the heat pump 11 is stopped, and the first sub-circulation pump 13 is stopped.

[6] When the return temperature Tr becomes lower than the set temperature T3 (Tr<50° C.), the operation of the first heating device 10 is started. Specifically, the first sub-circulation pump 13 is driven, and the refrigerant compressor of the heat pump 11 is driven.
During the cooperative operation of the second heating device 20, the combustion amount of the burner of the hot water boiler 21 is adjusted so that the outlet temperature TB of the second sub-heat exchanger 22 converges to a second target temperature (e.g., 80°C). Also, during the cooperative operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a third target temperature (e.g., 60°C). By raising the outlet temperature of the second heating device 20 (i.e., raising the output ratio) and lowering the outlet temperature of the first heating device 10 (i.e., lowering the output ratio) more than in the first heating mode, it is possible to suppress the power consumption of the first heating device 10 while performing the cooperative operation.

<<Control of third heating mode B>>
As described above, the third heating mode is selected by the heating mode selection unit 110 when implementing power demand adjustment to promote power consumption. In the third heating mode B, the operation control unit 120 switches between the independent operation of the first heating device 10 and the cooperative operation of the first heating device 10 and the second heating device 20 according to the hot water demand in the load equipment 200 or the heat demand in the load equipment 200, and controls the electric heat pump 11 and the combustion boiler 21 in the cooperative operation of the third heating mode B so that the output ratio of the first heating device 10 to the total heat output of the first heating device 10 and the second heating device 20 is greater than the output ratio of the first heating device 10 in the cooperative operation of the first heating mode. In this embodiment, the operation control unit 120 executes such control according to the heat demand in the load equipment 200.

The following describes an example of control by the operation control unit 120 in the third heating mode B.

[1] The set temperatures T1 to T3 are the same as those in the first heating mode.

[2] The water valve 52 of the first sub-heat exchanger 12 is always open to return hot water from the load equipment 200 to the hot water tank 30. The water valve 52 of the second sub-heat exchanger 22 is opened when the second heating device 20 starts operating and closed when the operation ends.

[3] When the return temperature Tr becomes equal to or higher than the set temperature T1 (Tr≧70°C), the operation of the first heating device 10 is terminated. Specifically, the refrigerant compressor of the heat pump 11 is stopped, and the first sub-circulation pump 13 is stopped.

[4] When the return temperature Tr becomes lower than the set temperature T2 (Tr<60° C.), the operation of the first heating device 10 is started. Specifically, the first sub-circulation pump 13 is driven, and the refrigerant compressor of the heat pump 11 is driven.
During independent operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a first target temperature (e.g., 70°C).

[5] When the return temperature Tr becomes equal to or higher than the set temperature T2 (Tr ≧ 60°C), the operation of the second heating device 20 is terminated. Specifically, the burner of the hot water boiler 21 is stopped, and the second sub-circulation pump 23 is stopped.

[6] When the return temperature Tr becomes lower than the set temperature T3 (Tr<50° C.), the second heating device 20 starts operating. Specifically, the second sub-circulation pump 23 is driven and the burner of the hot water boiler 21 is operated.
During the cooperative operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a second target temperature (e.g., 80°C). Also, during the cooperative operation of the second heating device 20, the combustion amount of the burner of the hot water boiler 21 is adjusted so that the outlet temperature TB of the second sub-heat exchanger 22 converges to a third target temperature (e.g., 60°C). By raising the outlet temperature of the first heating device 10 (i.e., raising the output ratio) and lowering the outlet temperature of the second heating device 20 (i.e., lowering the output ratio) more than in the first heating mode, it is possible to promote power consumption of the first heating device 10 while performing the cooperative operation.

<Indicators of hot water demand, heat demand, and heat output>
In the above control example, the operation control unit 120 controls the operation of the first heating device 10 and the second heating device 20 in accordance with the return temperature Tr as the heat demand of the load equipment 200. However, the operation control unit 120 can control the operation of the first heating device 10 and the second heating device 20 in accordance with the hot water demand of the load equipment 200, the hot heat demand of the load equipment 200, or the heat output of the first heating device 10. Below, (1) an index indicating the hot water demand of the load equipment 200, (2) an index indicating the hot heat demand of the load equipment 200, and (3) an index indicating the heat output of the first heating device 10 will be described.

(1) Indicators of hot water demand for the load equipment 200 include the water level of the stored water (= amount of hot water stored/amount of remaining hot water) in a system with a hot water tank 30, and the make-up water flow rate (= hot water consumption flow rate) in a system without a hot water tank 30. The lower the amount of hot water stored or the higher the water supply flow rate, the greater the hot water demand (= a greater amount of make-up water supplied per hour). When cooperative operation in the first heating mode is selected, if the hot water demand for the load equipment 200 increases, the amount of hot water supplied per hour to the load equipment 200 is increased by heating the amount of make-up water that cannot be heated by the first heating device 10 with the second heating device 20.

(2) An index showing the heat demand of the load equipment 200 is the return temperature Tr of the hot water from the load equipment 200 side in the hot water loop system. The lower the return temperature Tr, the greater the heat demand. The index can also be the difference between the supply temperature and the return temperature. The greater the temperature difference, the greater the heat demand. When the first heating mode cooperative operation is selected, if the heat demand of the load equipment 200 increases, and if the outlet temperature of the first heating device 10 or the heat storage temperature TC of the hot water tank 30 does not meet the required temperature of the load equipment 200, the temperature is raised to the required temperature by heating with the second heating device 20.

(3) The outlet hot water temperature (service water outlet temperature) during operation is an index showing the thermal output of the first heating device 10. When the outlet hot water temperature of the first heating device 10 is low, the second heating device 20 is operated in coordination with the first heating device 10, and the combustion energy is used to back up the heating. Here, the case where the outlet hot water temperature of the first heating device 10 is low refers to, for example, the following cases.
(a) When the target hot water outlet temperature cannot be obtained even if the output of the refrigerant compressor is increased due to a decrease in the temperature of the heat source air of the heat pump 11 (low temperature outside air, such as in winter) or a decrease in the temperature of the heat source water (low temperature waste hot water, such as at the start of operation).
(b) When the target hot water outlet temperature cannot be obtained even if the output of the refrigerant compressor is increased due to a decrease in the temperature of the water supply from the water supply equipment (low-temperature water supply, such as in winter) or a decrease in the temperature of the return hot water from the load equipment 200 (low-temperature circulating water, such as at the start of operation).
(c) When a heat pump that simultaneously outputs hot and cold water is used and the hot water temperature falls due to control to maintain the cold water temperature at a target temperature.
(d) A case where the target temperature is lowered due to a decrease in the heating capacity of the heat pump 11 (mainly due to a decrease in the heat source temperature or the inlet temperature).

Second Embodiment
Next, a second embodiment will be described. Fig. 2 is a diagram showing a schematic configuration of a hot water production system 1 in this embodiment. In this embodiment, the same components as those in the first embodiment are denoted by the same reference numerals, and the description thereof may be omitted.
The load equipment 200 in this embodiment indirectly uses the heated service water W1 as heat transfer water (i.e., heat output).

As shown in FIG. 2, the return water line L20 of the hot water production system 1 of this embodiment is connected to the hot water tank 30 without branching. The first heating device 10 and the second heating device 20 of the hot water production system 1 of this embodiment are arranged in series in the return water line L20, which is the line to be heated, and heat the water W1 flowing through the return water line L20.

The first sub-heat exchanger 12 of the first heating device 10 is disposed in the water return line L20, which is the line to be heated. The first sub-heat exchanger 12 exchanges heat between the water W1 flowing through the water return line L20 and the heat medium R1 flowing through the first sub-circulation line LS1, and heats the water W1 flowing through the water return line L20.

The second sub-heat exchanger 22 of the second heating device 20 is disposed in the water return line L20, which is the line to be heated. The second sub-heat exchanger 22 exchanges heat between the water W1 flowing through the water return line L20 and the heat medium R2 flowing through the second sub-circulation line LS2, and heats the water W1 flowing through the water return line L20.

A temperature sensor 40 that detects the return temperature Tr is provided upstream of the position where the first sub-heat exchanger 12 and the second sub-heat exchanger 22 are located in the water return line L20.

As described above, in this embodiment, the first sub-heat exchanger 12 of the first heating device 10 and the second sub-heat exchanger 22 of the second heating device 20 are arranged in sequence in the water return line L20 to heat the circulating water.

Below, we explain examples of control of each heating mode by the operation control unit 120 in this embodiment.

<<Control of First Heating Mode>>
As described above, when power demand adjustment is not performed, the first heating mode is selected by the heating mode selection unit 110. Hereinafter, an example of control by the operation control unit 120 in the first heating mode will be described.

[1] The set temperatures are, for example, T1 = 70°C (return temperature at zero load, i.e., equivalent to the target hot water temperature), T2 = 60°C (equivalent to the return temperature at the average base load), and T3 = 50°C (equivalent to the return temperature at the average peak load). However, the numerical examples of each set temperature do not take into account heat loss associated with hot water circulation.

[2] When the return temperature Tr becomes equal to or higher than the set temperature T1 (Tr ≧ 70°C), the operation of the first heating device 10 is terminated. Specifically, the refrigerant compressor of the heat pump 11 is stopped, and the first sub-circulation pump 13 is stopped.

[3] When the return temperature Tr becomes lower than the set temperature T2 (Tr<60° C.), the operation of the first heating device 10 is started. Specifically, the first sub-circulation pump 13 is driven, and the refrigerant compressor of the heat pump 11 is driven.
During independent operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a first target temperature (e.g., 70°C).

[4] When the return temperature Tr becomes equal to or higher than the set temperature T2 (Tr ≧ 60°C), the operation of the second heating device 20 is terminated. Specifically, the burner of the hot water boiler 21 is stopped, and the second sub-circulation pump 23 is stopped.

[5] When the return temperature Tr becomes lower than the set temperature T3 (Tr<50° C.), the second heating device 20 starts operating. Specifically, the second sub-circulation pump 23 is driven and the burner of the hot water boiler 21 is operated.
During the coordinated operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the inlet/outlet temperature difference of the first sub-heat exchanger 12 converges to a first target temperature difference (e.g., 10° C.). Also, during the coordinated operation of the second heating device 20, the combustion amount of the burner of the hot water boiler 21 is adjusted so that the outlet temperature TB of the second sub-heat exchanger 22 converges to a first target temperature (e.g., 70° C.).

<<Control of second heating mode A>>
As described above, the second heating mode is selected by the heating mode selection unit 110 when power demand adjustment for suppressing power consumption is performed. Hereinafter, an example of control by the operation control unit 120 in the second heating mode A will be described.

[1] In the second heating mode A, the target temperature for hot water supply is increased to increase the amount of heat stored in the system. For this reason, only the set temperature T1 is changed from 70°C to 90°C. In this heating mode, there is no coordinated operation with the first heating device 10.

[2] When the return temperature Tr becomes equal to or higher than the set temperature T1 (Tr ≧ 90°C), the operation of the second heating device 20 is terminated. Specifically, the burner of the hot water boiler 21 is stopped, and the second sub-circulation pump 23 is stopped.

[3] When the return temperature Tr becomes lower than the set temperature T2 (Tr<60° C.), the second heating device 20 starts operating. Specifically, the second sub-circulation pump 23 is driven and the burner of the hot water boiler 21 is operated.
During the independent operation of the second heating device 20, the combustion amount of the burner of the hot water boiler 21 is adjusted so that the outlet temperature TB of the second sub-heat exchanger 22 converges to a second target temperature (e.g., 90° C.). By making the heat storage temperature TC of the hot water tank 30 higher than in the first heating mode, the independent operation that promotes fuel consumption of the second heating device 20 is continued, while also satisfying the peak demand of the load equipment 200.

<<Control of third heating mode A>>
As described above, the third heating mode is selected by the heating mode selection unit 110 when power demand adjustment for promoting power consumption is performed. Hereinafter, an example of control by the operation control unit 120 in the third heating mode A will be described.

[1] In the third heating mode A, the target temperature for hot water supply is increased to increase the amount of heat stored in the system. For this reason, only the set temperature T1 is changed from 70°C to 90°C. In this heating mode, there is no coordinated operation with the second heating device 20.

[2] When the return temperature Tr becomes equal to or higher than the set temperature T1 (Tr ≧ 90°C), the operation of the first heating device 10 is terminated. Specifically, the refrigerant compressor of the heat pump 11 is stopped, and the first sub-circulation pump 13 is stopped.

[3] When the return temperature Tr becomes lower than the set temperature T2 (Tr<60° C.), the operation of the first heating device 10 is started. Specifically, the first sub-circulation pump 13 is driven, and the refrigerant compressor of the heat pump 11 is driven.
During the independent operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a second target temperature (e.g., 90° C.). By making the heat storage temperature TC of the hot water tank 30 higher than in the first heating mode, the independent operation that promotes the power consumption of the first heating device 10 is continued while also satisfying the peak demand of the load equipment 200.

<<Control of second heating mode B>>
As described above, the second heating mode is selected by the heating mode selection unit 110 when power demand adjustment for suppressing power consumption is performed. Hereinafter, an example of control by the operation control unit 120 in the second heating mode B will be described.

[1] The set temperatures T1 to T3 are the same as those in the first heating mode.

[2] When the return temperature Tr becomes equal to or higher than the set temperature T1 (Tr ≧ 70°C), the operation of the second heating device 20 is terminated. Specifically, the burner of the hot water boiler 21 is stopped, and the second sub-circulation pump 23 is stopped.

[3] When the return temperature Tr becomes lower than the set temperature T2 (Tr<60° C.), the second heating device 20 starts operating. Specifically, the second sub-circulation pump 23 is driven and the burner of the hot water boiler 21 is operated.
During independent operation of the second heating device 20, the combustion amount of the burner of the hot water boiler 21 is adjusted so that the outlet temperature TB of the second sub-heat exchanger 22 converges to the first target temperature (e.g., 70°C).

[4] When the return temperature Tr becomes equal to or higher than the set temperature T2 (Tr ≧ 60°C), the operation of the first heating device 10 is terminated. Specifically, the refrigerant compressor of the heat pump 11 is stopped, and the first sub-circulation pump 13 is stopped.

[5] When the return temperature Tr becomes lower than the set temperature T3 (Tr<50° C.), the operation of the first heating device 10 is started. Specifically, the first sub-circulation pump 13 is driven, and the refrigerant compressor of the heat pump 11 is driven.
During the cooperative operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the inlet/outlet temperature difference of the first sub-heat exchanger 12 converges to a second target temperature difference (e.g., 5°C). Also, during the cooperative operation of the second heating device 20, the combustion amount of the burner of the hot water boiler 21 is adjusted so that the outlet temperature TB of the second sub-heat exchanger 22 converges to a first target temperature (e.g., 70°C). By lowering the inlet/outlet temperature difference of the first heating device 10 (i.e., lowering the output ratio) more than in the first heating mode, it is possible to suppress power consumption while performing cooperative operation with the second heating device 20.

<<Control of third heating mode B>>
As described above, the third heating mode is selected by the heating mode selection unit 110 when power demand adjustment for promoting power consumption is performed. Hereinafter, an example of control by the operation control unit 120 in the third heating mode B will be described.

[1] The set temperatures T1 to T3 are the same as those in the first heating mode.

[2] When the return temperature Tr becomes equal to or higher than the set temperature T1 (Tr ≧ 70°C), the operation of the first heating device 10 is terminated. Specifically, the refrigerant compressor of the heat pump 11 is stopped, and the first sub-circulation pump 13 is stopped.

[3] When the return temperature Tr becomes lower than the set temperature T2 (Tr<60° C.), the operation of the first heating device 10 is started. Specifically, the first sub-circulation pump 13 is driven, and the refrigerant compressor of the heat pump 11 is driven.
During independent operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a first target temperature (e.g., 70°C).

[4] When the return temperature Tr becomes equal to or higher than the set temperature T2 (Tr ≧ 60°C), the operation of the second heating device 20 is terminated. Specifically, the burner of the hot water boiler 21 is stopped, and the second sub-circulation pump 23 is stopped.

[5] When the return temperature Tr becomes lower than the set temperature T3 (T5<50° C.), the second heating device 20 starts operating. Specifically, the second sub-circulation pump 23 is driven and the burner of the hot water boiler 21 is operated.
During the cooperative operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a third target temperature difference (e.g., 15°C). Also, during the cooperative operation of the second heating device 20, the combustion amount of the burner of the hot water boiler 21 is adjusted so that the outlet temperature TB of the second sub-heat exchanger 22 converges to a second target temperature (e.g., 70°C). By increasing the inlet/outlet temperature difference of the first heating device 10 more than in the first heating mode (i.e., increasing the output ratio), it is possible to promote power consumption while performing cooperative operation with the second heating device 20.

Third Embodiment
Next, a third embodiment will be described. Fig. 3 is a diagram showing a schematic configuration of a hot water production system 1 in this embodiment. In this embodiment, the same components as those in the first embodiment are denoted by the same reference numerals, and the description thereof may be omitted.
The load equipment 200 in this embodiment indirectly uses the heated service water W1 as heat transfer water (i.e., heat output).

As shown in FIG. 3, the first heating device 10 and the second heating device 20 are not arranged in the water return line L20 of the hot water production system 1 of this embodiment. The water return line L20 is not branched, but is directly connected to the hot water tank 30. The hot water production system 1 of this embodiment includes a circulation line L30 as a heating target line that circulates the water stored in the hot water tank 30. The first heating device 10 and the second heating device 20 heat the water W1 as circulating water flowing through the circulation line L30.

The circulation line L30 is a line for circulating the hot water W1 in the hot water tank 30. The circulation line L30 branches into a first circulation line L31 and a second circulation line L32 from a branch point P, and then merges.

The first sub-heat exchanger 12 of the first heating device 10 is arranged in the first circulation line L31. A first circulation pump 53 is provided in the first circulation line L31.

The second sub-heat exchanger 22 of the second heating device 20 is arranged in the second circulation line L32. A second circulation pump 54 is provided in the second circulation line L32.

The first sub-heat exchanger 12 exchanges heat between the water W1 flowing through the first circulation line L31 and the heat medium R1 flowing through the first sub-circulation line LS1, and heats the water W1 flowing through the first circulation line L31.

The second sub-heat exchanger 22 exchanges heat between the water W1 flowing through the second circulation line L32 and the heat medium R2 flowing through the second sub-circulation line LS2, and heats the water W1 flowing through the second circulation line L32.

The return water line L20 is provided with a temperature sensor 40 that detects the return temperature Tr.

As described above, in this embodiment, the first sub-heat exchanger 12 and the first circulation pump 53 of the first heating device 10 are arranged in the first circulation line L31 connected to the hot water tank 30 to heat the circulating water. Also, the second sub-heat exchanger 22 and the second circulation pump 54 of the second heating device 20 are arranged in the second circulation line L32 connected to the hot water tank 30 to heat the circulating water.

Below, we explain examples of control of each heating mode by the operation control unit 120 in this embodiment.

<<Control of First Heating Mode>>
As described above, when power demand adjustment is not performed, the first heating mode is selected by the heating mode selection unit 110. Hereinafter, an example of control by the operation control unit 120 in the first heating mode will be described.

[1] The set temperatures are, for example, T1 = 70°C (return temperature at zero load, i.e., equivalent to the target hot water temperature), T2 = 60°C (equivalent to the return temperature at the average base load), and T3 = 50°C (equivalent to the return temperature at the average peak load). However, the numerical examples of each set temperature do not take into account heat loss associated with hot water circulation.

[2] When the return temperature Tr becomes equal to or higher than the set temperature T1 (Tr≧70°C), the operation of the first heating device 10 is terminated. Specifically, the refrigerant compressor of the heat pump 11 is stopped, the first sub-circulation pump 13 is stopped, and the first circulation pump is stopped.

[3] When the return temperature Tr becomes lower than the set temperature T2 (Tr<60° C.), the operation of the first heating device 10 is started. Specifically, the first circulation pump is driven, the first sub-circulation pump 13 is driven, and the refrigerant compressor of the heat pump 11 is driven.
During independent operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a first target temperature (e.g., 70°C).

[4] When the return temperature Tr becomes equal to or higher than the set temperature T2 (Tr ≧ 60°C), the operation of the second heating device 20 is terminated. Specifically, the burner of the hot water boiler 21 is stopped, the second sub-circulation pump 23 is stopped, and the second circulation pump is stopped.

[5] When the return temperature Tr becomes lower than the set temperature T3 (Tr<50° C.), the second heating device 20 starts operating. Specifically, the second circulation pump is driven, the second sub-circulation pump 23 is driven, and the burner of the hot water boiler 21 is operated.
During the coordinated operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to the first target temperature (e.g., 70° C.). Also, during the coordinated operation of the second heating device 20, the combustion amount of the burner of the hot water boiler 21 is adjusted so that the outlet temperature TB of the second sub-heat exchanger 22 converges to the first target temperature (e.g., 70° C.).

<<Control of second heating mode A>>
As described above, the second heating mode is selected by the heating mode selection unit 110 when power demand adjustment for suppressing power consumption is performed. Hereinafter, an example of control by the operation control unit 120 in the second heating mode A will be described.

[1] In the second heating mode A, the target temperature for hot water supply is increased to increase the amount of heat stored in the system. To this end, the set temperature T1 is changed from 70°C to 90°C, and the set temperature T2 is changed from 60°C to 70°C. In this heating mode, there is no coordinated operation with the first heating device 10.

[2] When the return temperature Tr becomes equal to or higher than the set temperature T1 (Tr ≧ 90°C), the operation of the second heating device 20 is terminated. Specifically, the burner of the hot water boiler 21 is stopped, the second sub-circulation pump 23 is stopped, and the second circulation pump is stopped.

[3] When the return temperature Tr becomes lower than the set temperature T2 (Tr<70° C.), the second heating device 20 starts operating. Specifically, the second circulation pump is driven, the second sub-circulation pump 23 is driven, and the burner of the hot water boiler 21 is operated.
During the independent operation of the second heating device 20, the combustion amount of the burner of the hot water boiler 21 is adjusted so that the outlet temperature TB of the second sub-heat exchanger 22 converges to a second target temperature (e.g., 90° C.). By making the heat storage temperature TC of the hot water tank 30 higher than in the first heating mode, the independent operation that promotes fuel consumption of the second heating device 20 is continued, while also satisfying the peak demand of the load equipment 200.

<<Control of third heating mode A>>
As described above, the third heating mode is selected by the heating mode selection unit 110 when power demand adjustment for promoting power consumption is performed. Hereinafter, an example of control by the operation control unit 120 in the third heating mode A will be described.

[1] In the third heating mode A, the target temperature for hot water supply is increased to increase the amount of heat stored in the system. To this end, the set temperature T1 is changed from 70°C to 90°C, and the set temperature T2 is changed from 60°C to 70°C. In this heating mode, there is no coordinated operation with the second heating device 20.

[2] When the return temperature Tr becomes equal to or higher than the set temperature T1 (Tr ≧ 90°C), the operation of the first heating device 10 is terminated. Specifically, the refrigerant compressor of the heat pump 11 is stopped, the first sub-circulation pump 13 is stopped, and the first circulation pump is stopped.

[3] When the return temperature Tr becomes lower than the set temperature T2 (Tr<70° C.), the operation of the first heating device 10 is started. Specifically, the first circulation pump is driven, the first sub-circulation pump 13 is driven, and the refrigerant compressor of the heat pump 11 is driven.
During the independent operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a second target temperature (e.g., 90° C.). By making the heat storage temperature TC of the hot water tank 30 higher than in the first heating mode, the independent operation that promotes the power consumption of the first heating device 10 is continued while also satisfying the peak demand of the load equipment 200.

<<Control of second heating mode B>>
As described above, the second heating mode is selected by the heating mode selection unit 110 when power demand adjustment for suppressing power consumption is performed. Hereinafter, an example of control by the operation control unit 120 in the second heating mode B will be described.

[1] The set temperatures T1 to T3 are the same as those in the first heating mode.

[2] When the return temperature Tr becomes equal to or higher than the set temperature T1 (Tr ≧ 70°C), the operation of the second heating device 20 is terminated. Specifically, the burner of the hot water boiler 21 is stopped, the second sub-circulation pump 23 is stopped, and the second circulation pump is stopped.

[3] When the return temperature Tr becomes lower than the set temperature T2 (Tr<60° C.), the second heating device 20 starts operating. Specifically, the second circulation pump is driven, the second sub-circulation pump 23 is driven, and the burner of the hot water boiler 21 is operated.
During independent operation of the second heating device 20, the combustion amount of the burner of the hot water boiler 21 is adjusted so that the outlet temperature TB of the second sub-heat exchanger 22 converges to the first target temperature (e.g., 70°C).

[4] When the return temperature Tr becomes equal to or higher than the set temperature T2 (Tr≧60°C), the operation of the first heating device 10 is terminated. Specifically, the refrigerant compressor of the heat pump 11 is stopped, the first sub-circulation pump 13 is stopped, and the first circulation pump is stopped.

[5] When the return temperature Tr becomes lower than the set temperature T3 (Tr<50° C.), the operation of the first heating device 10 is started. Specifically, the first circulation pump is driven, the first sub-circulation pump 13 is driven, and the refrigerant compressor of the heat pump 11 is driven.
During the cooperative operation of the second heating device 20, the combustion amount of the burner of the hot water boiler 21 is adjusted so that the outlet temperature TB of the second sub-heat exchanger 22 converges to a second target temperature (e.g., 80°C). Also, during the cooperative operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a third target temperature (e.g., 60°C). By raising the outlet temperature of the second heating device 20 (i.e., raising the output ratio) and lowering the outlet temperature of the first heating device 10 (i.e., lowering the output ratio) more than in the first heating mode, it is possible to suppress the power consumption of the first heating device 10 while performing the cooperative operation.

<<Control of third heating mode B>>
As described above, the third heating mode is selected by the heating mode selection unit 110 when power demand adjustment for promoting power consumption is performed. Hereinafter, an example of control by the operation control unit 120 in the third heating mode B will be described.

[1] The set temperatures T1 to T3 are the same as those in the first heating mode.

[2] When the return temperature Tr becomes equal to or higher than the set temperature T1 (Tr≧70°C), the operation of the first heating device 10 is terminated. Specifically, the refrigerant compressor of the heat pump 11 is stopped, the first sub-circulation pump 13 is stopped, and the first circulation pump is stopped.

[3] When the return temperature Tr becomes lower than the set temperature T2 (Tr<60° C.), the operation of the first heating device 10 is started. Specifically, the first circulation pump is driven, the first sub-circulation pump 13 is driven, and the refrigerant compressor of the heat pump 11 is driven.
During independent operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a first target temperature (e.g., 70°C).

[4] When the return temperature Tr becomes equal to or higher than the set temperature T2 (Tr ≧ 60°C), the operation of the second heating device 20 is terminated. Specifically, the burner of the hot water boiler 21 is stopped, the second sub-circulation pump 23 is stopped, and the second circulation pump is stopped.

[5] When the return temperature Tr becomes lower than the set temperature T3 (Tr<50° C.), the second heating device 20 starts operating. Specifically, the second circulation pump is driven, the second sub-circulation pump 23 is driven, and the burner of the hot water boiler 21 is operated.
During the cooperative operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a second target temperature (e.g., 80°C). Also, during the cooperative operation of the second heating device 20, the combustion amount of the burner of the hot water boiler 21 is adjusted so that the outlet temperature TB of the second sub-heat exchanger 22 converges to a third target temperature (e.g., 60°C). By raising the outlet temperature of the first heating device 10 (i.e., raising the output ratio) and lowering the outlet temperature of the second heating device 20 (i.e., lowering the output ratio) more than in the first heating mode, it is possible to promote power consumption of the first heating device 10 while performing the cooperative operation.

Fourth Embodiment
Next, a fourth embodiment will be described. Fig. 4 is a diagram showing a schematic configuration of a hot water production system 1 in this embodiment. In this embodiment, the same components as those in the first embodiment are denoted by the same reference numerals, and the description thereof may be omitted.
The load equipment 200 in this embodiment indirectly uses the heated service water W1 as heat transfer water (i.e., heat output).

As shown in FIG. 4, the return water line L20 of the hot water production system 1 of this embodiment is not branched and is connected to the hot water tank 30. The first heating device 10 heats the water W1 flowing through the return water line L20 as the line to be heated. The second heating device 20 heats the water W1 as the stored water in the hot water tank 30.

The first sub-heat exchanger 12 of the first heating device 10 is disposed in the water return line L20, which is the line to be heated. The first sub-heat exchanger 12 exchanges heat between the water W1 flowing through the water return line L20 and the heat medium R1 flowing through the first sub-circulation line LS1, and heats the water W1 flowing through the water return line L20.

The second heating device 20 includes a steam boiler (not shown), a steam heater 25, a steam supply valve 26, and a steam line.

The steam line L40 supplies steam S from the steam boiler to the steam heater 25. After heat exchange in the steam heater 25, the steam S is discharged from the steam heater 25 through the steam line L40.

The steam heater 25 is installed inside the hot water tank 30. The steam heater 25 exchanges heat between the water W1 stored in the hot water tank 30 and the steam S flowing through the steam line L40, thereby heating the stored water.

The steam supply valve 26 controls the flow state of the steam S flowing through the steam line L40. It is preferable that the steam supply valve 26 is a proportional control valve whose opening degree can be adjusted.

A temperature sensor 40 that detects the return temperature Tr is provided upstream of the position where the first sub-heat exchanger 12 is located in the water return line L20.

As described above, in this embodiment, the first sub-heat exchanger 12 of the first heating device 10 is arranged in the water return line L20 to heat the circulating water as the water W1. The steam heater 25 of the second heating device 20 is arranged in the hot water tank 30 to heat the stored water as the water W1. The steam heater 25 (steam heat exchanger) is supplied with steam S generated in the steam boiler via the steam supply valve 26.

Below, we explain examples of control of each heating mode by the operation control unit 120 in this embodiment.

<<Control of 1 heating mode>>
As described above, when power demand adjustment is not performed, the first heating mode is selected by the heating mode selection unit 110. Hereinafter, an example of control by the operation control unit 120 in the first heating mode will be described.

[1] The set temperatures are, for example, T1 = 70°C (return temperature at zero load, i.e., equivalent to the target hot water temperature), T2 = 60°C (equivalent to the return temperature at the average base load), and T3 = 50°C (equivalent to the return temperature at the average peak load). However, the numerical examples of each set temperature do not take into account heat loss associated with hot water circulation.

[2] When the return temperature Tr becomes equal to or higher than the set temperature T1 (Tr ≧ 70°C), the operation of the first heating device 10 is terminated. Specifically, the refrigerant compressor of the heat pump 11 is stopped, and the first sub-circulation pump 13 is stopped.

[3] When the return temperature Tr becomes lower than the set temperature T2 (Tr<60° C.), the operation of the first heating device 10 is started. Specifically, the first sub-circulation pump 13 is driven, and the refrigerant compressor of the heat pump 11 is driven.
During independent operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a first target temperature (e.g., 70°C).

[4] When the return temperature Tr becomes equal to or higher than the set temperature T2 (Tr ≧ 60°C), the operation of the second heating device 20 is terminated. Specifically, the steam supply valve 26 is closed and the steam heater 25 is stopped.

[5] When the return temperature Tr becomes lower than the set temperature T3 (Tr<50° C.), the second heating device 20 starts operating. Specifically, the steam supply valve 26 is opened to operate the steam heater 25.
During the coordinated operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the inlet/outlet temperature difference of the first sub-heat exchanger 12 converges to a first target temperature difference (e.g., 10° C.). Also, during the coordinated operation of the second heating device 20, the opening of the steam supply valve 26 is adjusted so that the heat storage temperature TC of the hot water tank 30 converges to a first target temperature (e.g., 70° C.).

<<Control of second heating mode A>>
As described above, the second heating mode is selected by the heating mode selection unit 110 when power demand adjustment for suppressing power consumption is performed. Hereinafter, an example of control by the operation control unit 120 in the second heating mode A will be described.

[1] In the second heating mode A, the target temperature for hot water supply is increased to increase the amount of heat stored in the system. For this reason, only the set temperature T1 is changed from 70°C to 90°C. In this heating mode, there is no coordinated operation with the first heating device 10.

[2] When the return temperature Tr becomes equal to or higher than the set temperature T1 (Tr ≧ 90°C), the operation of the second heating device 20 is terminated. Specifically, the steam supply valve 26 is closed and the steam heater 25 is stopped.

[3] When the return temperature Tr becomes lower than the set temperature T2 (Tr<60° C.), the second heating device 20 starts operating. Specifically, the steam supply valve 26 is opened to operate the steam heater 25.
During the independent operation of the second heating device 20, the opening degree of the steam supply valve 26 of the steam heater 25 is adjusted so that the heat storage temperature TC of the hot water tank 30 converges to a second target temperature (e.g., 90° C.). By making the heat storage temperature TC of the hot water tank 30 higher than in the first heating mode, the independent operation that promotes fuel consumption of the second heating device 20 is continued while also satisfying the peak demand of the load equipment 200.

<<Control of third heating mode A>>
As described above, the third heating mode is selected by the heating mode selection unit 110 when power demand adjustment for promoting power consumption is performed. Hereinafter, an example of control by the operation control unit 120 in the third heating mode A will be described.

[1] In the third heating mode A, the target temperature for hot water supply is increased to increase the amount of heat stored in the system. For this reason, only the set temperature T1 is changed from 70°C to 90°C. In this heating mode, there is no coordinated operation with the second heating device 20.

[2] When the return temperature Tr becomes equal to or higher than the set temperature T1 (Tr ≧ 90°C), the operation of the first heating device 10 is terminated. Specifically, the refrigerant compressor of the heat pump 11 is stopped, and the first sub-circulation pump 13 is stopped.

[3] When the return temperature Tr becomes lower than the set temperature T2 (Tr<60° C.), the operation of the first heating device 10 is started. Specifically, the first sub-circulation pump 13 is driven, and the refrigerant compressor of the heat pump 11 is driven.
During the independent operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a second target temperature (e.g., 90° C.). By making the heat storage temperature TC of the hot water tank 30 higher than in the first heating mode, the independent operation that promotes the power consumption of the first heating device 10 is continued while also satisfying the peak demand of the load equipment 200.

<<Control of second heating mode B>>
As described above, the second heating mode is selected by the heating mode selection unit 110 when power demand adjustment for suppressing power consumption is performed. Hereinafter, an example of control by the operation control unit 120 in the second heating mode B will be described.

[1] The set temperatures T1 to T3 are the same as those in the first heating mode.

[2] When the return temperature Tr becomes equal to or higher than the set temperature T1 (Tr ≧ 70°C), the operation of the second heating device 20 is terminated. Specifically, the steam supply valve 26 is closed and the steam heater 25 is stopped.

[3] When the return temperature Tr becomes lower than the set temperature T2 (Tr<60° C.), the second heating device 20 starts operating. Specifically, the steam supply valve 26 is opened to operate the steam heater 25.
During the independent operation of the second heating device 20, the opening of the steam supply valve 26 of the steam heater 25 is adjusted so that the heat storage temperature TC of the hot water tank 30 converges to the first target temperature (e.g., 70°C).

[4] When the return temperature Tr becomes equal to or higher than the set temperature T2 (Tr ≧ 60°C), the operation of the first heating device 10 is terminated. Specifically, the refrigerant compressor of the heat pump 11 is stopped, and the first sub-circulation pump 13 is stopped.

[5] When the return temperature Tr becomes lower than the set temperature T3 (Tr<50° C.), the operation of the first heating device 10 is started. Specifically, the first sub-circulation pump 13 is driven, and the refrigerant compressor of the heat pump 11 is driven.
During the cooperative operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the inlet/outlet temperature difference of the first sub-heat exchanger 12 converges to a second target temperature difference (e.g., 5° C.). Also, during the cooperative operation of the second heating device 20, the opening degree of the steam supply valve 26 of the steam heater 25 is adjusted so that the heat storage temperature TC of the hot water tank 30 converges to a first target temperature (e.g., 70° C.). By lowering the inlet/outlet temperature difference of the first heating device 10 (i.e., lowering the output ratio) more than in the first heating mode, it is possible to suppress power consumption while performing cooperative operation with the second heating device 20.

<<Control of third heating mode B>>
As described above, the third heating mode is selected by the heating mode selection unit 110 when power demand adjustment for promoting power consumption is performed. Hereinafter, an example of control by the operation control unit 120 in the third heating mode B will be described.

[1] The set temperatures T1 to T3 are the same as those in the first heating mode.

[2] When the return temperature Tr becomes equal to or higher than the set temperature T1 (Tr ≧ 70°C), the operation of the first heating device 10 is terminated. Specifically, the refrigerant compressor of the heat pump 11 is stopped, and the first sub-circulation pump 13 is stopped.

[3] When the return temperature Tr becomes lower than the set temperature T2 (Tr<60° C.), the operation of the first heating device 10 is started. Specifically, the first sub-circulation pump 13 is driven, and the refrigerant compressor of the heat pump 11 is driven.
During independent operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a first target temperature (e.g., 70°C).

[4] When the return temperature Tr becomes equal to or higher than the set temperature T2 (Tr ≧ 60°C), the operation of the second heating device 20 is terminated. Specifically, the steam supply valve 26 is closed and the steam heater 25 is stopped.

[5] When the return temperature Tr becomes lower than the set temperature T3 (Tr<50° C.), the second heating device 20 starts operating. Specifically, the steam supply valve 26 is opened to operate the steam heater 25.
During the cooperative operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a third target temperature difference (e.g., 15°C). Also, during the cooperative operation of the second heating device 20, the opening degree of the steam supply valve 26 of the steam heater 25 is adjusted so that the heat storage temperature TC of the hot water tank 30 converges to a second target temperature (e.g., 70°C). By increasing the inlet/outlet temperature difference of the first heating device 10 more than in the first heating mode (i.e., increasing the output ratio), it is possible to promote power consumption while performing cooperative operation with the second heating device 20.

Fifth Embodiment
Next, a fifth embodiment will be described. Fig. 5 is a diagram showing a schematic configuration of a hot water production system 1 in this embodiment. In this embodiment, the same components as those in the fourth embodiment are denoted by the same reference numerals, and the description thereof may be omitted.
The load equipment 200 in this embodiment indirectly uses the heated service water W1 as heat transfer water (i.e., heat output).

As shown in FIG. 5, the first heating device 10 is not disposed in the return water line L20 of the hot water production system 1 of this embodiment. The hot water production system 1 of this embodiment includes a first circulation line L31 as a heating target line that circulates the water stored in the hot water tank 30. The first heating device 10 heats the water W1 as circulating water flowing through the first circulation line L31. The second heating device 20 heats the water W1 as stored water in the hot water tank 30, as in the fourth embodiment.

The first circulation line L31 is a line for circulating the hot water W1 in the hot water tank 30.

The first sub-heat exchanger 12 of the first heating device 10 is arranged in the first circulation line L31. A first circulation pump 53 is provided in the first circulation line L31.

The first sub-heat exchanger 12 exchanges heat between the water W1 flowing through the first circulation line L31 and the heat medium R1 flowing through the first sub-circulation line LS1, and heats the water W1 flowing through the first circulation line L31.

The return water line L20 is provided with a temperature sensor 40 that detects the return temperature Tr.

As described above, in this embodiment, the first sub-heat exchanger 12 of the first heating device 10 and the first circulation pump 53 are arranged in the first circulation line L31 connected to the hot water tank 30 to heat the water W1 as circulating water. In addition, the steam heater 25 of the second heating device 20 is arranged in the hot water tank 30 to heat the stored water as the water W1. Steam S generated in the steam boiler is supplied to the steam heater 25 (steam heat exchanger) via the steam supply valve 26.

Below, we explain examples of control of each heating mode by the operation control unit 120 in this embodiment.

<<Control of First Heating Mode>>
As described above, when power demand adjustment is not performed, the first heating mode is selected by the heating mode selection unit 110. Hereinafter, an example of control by the operation control unit 120 in the first heating mode will be described.

[1] The set temperatures are, for example, T1 = 70°C (return temperature at zero load, i.e., equivalent to the target hot water temperature), T2 = 60°C (equivalent to the return temperature at the average base load), and T3 = 50°C (equivalent to the return temperature at the average peak load). However, the numerical examples of each set temperature do not take into account heat loss associated with hot water circulation.

[2] When the return temperature Tr becomes equal to or higher than the set temperature T1 (Tr≧70°C), the operation of the first heating device 10 is terminated. Specifically, the refrigerant compressor of the heat pump 11 is stopped, the first sub-circulation pump 13 is stopped, and the first circulation pump is stopped.

[3] When the return temperature Tr becomes lower than the set temperature T2 (Tr<60° C.), the operation of the first heating device 10 is started. Specifically, the first circulation pump is driven, the first sub-circulation pump 13 is driven, and the refrigerant compressor of the heat pump 11 is driven.
During independent operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a first target temperature (e.g., 70°C).

[4] When the return temperature Tr becomes equal to or higher than the set temperature T2 (Tr ≧ 60°C), the operation of the second heating device 20 is terminated. Specifically, the steam supply valve 26 is closed and the steam heater 25 is stopped.

[5] When the return temperature Tr becomes lower than the set temperature T3 (Tr<50° C.), the second heating device 20 starts operating. Specifically, the steam supply valve 26 is opened to operate the steam heater 25.
During the coordinated operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the inlet/outlet temperature difference of the first sub-heat exchanger 12 converges to a first target temperature difference (e.g., 10° C.). Also, during the coordinated operation of the second heating device 20, the opening of the steam supply valve 26 is adjusted so that the heat storage temperature TC of the hot water tank 30 converges to a first target temperature (e.g., 70° C.).

<<Control of second heating mode A>>
As described above, the second heating mode is selected by the heating mode selection unit 110 when power demand adjustment for suppressing power consumption is performed. Hereinafter, an example of control by the operation control unit 120 in the second heating mode A will be described.

[1] In the second heating mode A, the target temperature for hot water supply is increased to increase the amount of heat stored in the system. For this reason, only the set temperature T1 is changed from 70°C to 90°C. In this heating mode, there is no coordinated operation with the first heating device 10.

[2] When the return temperature Tr becomes equal to or higher than the set temperature T1 (Tr ≧ 90°C), the operation of the second heating device 20 is terminated. Specifically, the steam supply valve 26 is closed and the steam heater 25 is stopped.

[3] When the return temperature Tr becomes lower than the set temperature T2 (Tr<60° C.), the second heating device 20 starts operating. Specifically, the steam supply valve 26 is opened to operate the steam heater 25.
During the independent operation of the second heating device 20, the opening degree of the steam supply valve 26 of the steam heater 25 is adjusted so that the heat storage temperature TC of the hot water tank 30 converges to a second target temperature (e.g., 90° C.). By making the heat storage temperature TC of the hot water tank 30 higher than in the first heating mode, the independent operation that promotes fuel consumption of the second heating device 20 is continued while also satisfying the peak demand of the load equipment 200.

<<Control of third heating mode A>>
As described above, the third heating mode is selected by the heating mode selection unit 110 when power demand adjustment for promoting power consumption is performed. Hereinafter, an example of control by the operation control unit 120 in the third heating mode A will be described.

[1] In the third heating mode A, the target temperature for hot water supply is increased to increase the amount of heat stored in the system. For this reason, only the set temperature T1 is changed from 70°C to 90°C. In this heating mode, there is no coordinated operation with the second heating device 20.

[2] When the return temperature Tr becomes equal to or higher than the set temperature T1 (Tr ≧ 90°C), the operation of the first heating device 10 is terminated. Specifically, the refrigerant compressor of the heat pump 11 is stopped, the first sub-circulation pump 13 is stopped, and the first circulation pump is stopped.

[3] When the return temperature Tr becomes lower than the set temperature T2 (Tr<60° C.), the operation of the first heating device 10 is started. Specifically, the first circulation pump is driven, the first sub-circulation pump 13 is driven, and the refrigerant compressor of the heat pump 11 is driven.
During the independent operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a second target temperature (e.g., 90° C.). By making the heat storage temperature TC of the hot water tank 30 higher than in the first heating mode, the independent operation that promotes the power consumption of the first heating device 10 is continued while also satisfying the peak demand of the load equipment 200.

<<Control of second heating mode B>>
As described above, the second heating mode is selected by the heating mode selection unit 110 when power demand adjustment for suppressing power consumption is performed. Hereinafter, an example of control by the operation control unit 120 in the second heating mode B will be described.

[1] The set temperatures T1 to T3 are the same as those in the first heating mode.

[2] When the return temperature Tr becomes equal to or higher than the set temperature T1 (Tr ≧ 70°C), the operation of the second heating device 20 is terminated. Specifically, the steam supply valve 26 is closed and the steam heater 25 is stopped.

[3] When the return temperature Tr becomes lower than the set temperature T2 (Tr<60° C.), the second heating device 20 starts operating. Specifically, the steam supply valve 26 is opened to operate the steam heater 25.
During the independent operation of the second heating device 20, the opening of the steam supply valve 26 of the steam heater 25 is adjusted so that the heat storage temperature TC of the hot water tank 30 converges to the first target temperature (e.g., 70°C).

[4] When the return temperature Tr becomes equal to or higher than the set temperature T2 (Tr≧60°C), the operation of the first heating device 10 is terminated. Specifically, the refrigerant compressor of the heat pump 11 is stopped, the first sub-circulation pump 13 is stopped, and the first circulation pump is stopped.

[5] When the return temperature Tr becomes lower than the set temperature T3 (Tr<50° C.), the operation of the first heating device 10 is started. Specifically, the first circulation pump is driven, the first sub-circulation pump 13 is driven, and the refrigerant compressor of the heat pump 11 is driven.
During the coordinated operation of the first heating device 10 and the second heating device 20, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the inlet/outlet temperature difference of the first sub-heat exchanger 12 converges to a second target temperature difference (e.g., 5°C). Also, the opening degree of the steam supply valve 26 of the steam heater 25 is adjusted so that the heat storage temperature TC of the hot water tank 30 converges to a first target temperature (e.g., 70°C). By lowering the inlet/outlet temperature difference of the first heating device 10 (i.e., lowering the output ratio) more than in the first heating mode, it is possible to suppress power consumption while performing coordinated operation with the second heating device 20.

<<Control of third heating mode B>>
As described above, the third heating mode is selected by the heating mode selection unit 110 when power demand adjustment for promoting power consumption is performed. Hereinafter, an example of control by the operation control unit 120 in the third heating mode B will be described.

[1] The set temperatures T1 to T3 are the same as those in the first heating mode.

[2] When the return temperature Tr becomes equal to or higher than the set temperature T1 (Tr≧70°C), the operation of the first heating device 10 is terminated. Specifically, the refrigerant compressor of the heat pump 11 is stopped, the first sub-circulation pump 13 is stopped, and the first circulation pump is stopped.

[3] When the return temperature Tr becomes lower than the set temperature T2 (Tr<60° C.), the operation of the first heating device 10 is started. Specifically, the first circulation pump is driven, the first sub-circulation pump 13 is driven, and the refrigerant compressor of the heat pump 11 is driven.
During independent operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a first target temperature (e.g., 70°C).

[4] When the return temperature Tr becomes equal to or higher than the set temperature T2 (Tr ≧ 60°C), the operation of the second heating device 20 is terminated. Specifically, the steam supply valve 26 is closed and the steam heater 25 is stopped.

[5] When the return temperature Tr becomes lower than the set temperature T3 (Tr<50° C.), the second heating device 20 starts operating. Specifically, the steam supply valve 26 is opened to operate the steam heater 25.
During the cooperative operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a third target temperature difference (e.g., 15°C). Also, during the cooperative operation of the second heating device 20, the opening degree of the steam supply valve 26 of the steam heater 25 is adjusted so that the heat storage temperature TC of the hot water tank 30 converges to a second target temperature (e.g., 70°C). By increasing the inlet/outlet temperature difference of the first heating device 10 more than in the first heating mode (i.e., increasing the output ratio), it is possible to promote power consumption while performing cooperative operation with the second heating device 20.

Sixth Embodiment
Next, a sixth embodiment will be described. Fig. 6 is a diagram showing a schematic configuration of a hot water production system 1 in this embodiment. In this embodiment, the same components as those in the fourth embodiment are denoted by the same reference numerals, and the description thereof may be omitted.
The load equipment 200 in this embodiment indirectly uses the heated service water W1 as heat transfer water (i.e., heat output).

As shown in FIG. 6, the water return line L20 of the hot water production system 1 of this embodiment branches midway, and multiple first heating devices 10 are arranged in parallel. The multiple first heating devices 10 arranged in parallel heat the water W1 flowing through the water return line L20. In this embodiment, the first heating device group as the first heating device 10 is composed of a first unit 10A, a second unit 10B, and a third unit 10C. The second heating device 20 heats the water W1 stored in the hot water tank 30, as in the fourth embodiment.

The water return line L20 branches into a plurality of first heating target lines L21A, L21B, and L21C downstream of the branch point P. First heating devices 10A, 10B, and 10C are arranged in the plurality of first heating target lines L21A, 21B, and 21C, respectively.

The first heating device group is made up of a plurality of first heating devices 10A, 10B, and 10C, each of which has the same configuration as the first heating device 10 of the first embodiment. In FIG. 6, only the first sub-heat exchanger 12 of the first heating devices 10B and 10C is shown, and other configurations are omitted from the illustration. The first heating devices 10A, 10B, and 10C each heat the water W1 flowing through the first heating target lines L21A, L21B, and L21C.

When controlling the number of units in the first heating device group (increasing or decreasing the number of operating units), water valves 51A, 51B, and 51C are provided on the first heating target lines L21A, 21B, and 21C, respectively. When controlling the first heating device group collectively (without increasing or decreasing the number of operating units), it is not necessary to provide water valves 51A, 51B, and 51C.

As in the fourth embodiment, the second heating device 20 uses a steam heater 25 to heat the water W1 stored in the hot water tank 30. Steam S from the steam boiler is supplied to the steam heater 25 through a steam line L40.

The combustion boiler constituting the second heating device 20 may be a hot water boiler instead of a steam boiler. When replaced with a hot water boiler, the second heating device 20 may be installed after the first heating device group, for example as shown in FIG. 2, and the heat output may be adjusted according to the amount of combustion of the burner.

A temperature sensor 40 is provided upstream of the branch point P of the water return line L20. The temperature sensor 40 detects the return temperature Tr of the hot water flowing through the water return line L20 upstream of the branch point P of the water return line.

As described above, in this embodiment, the water return line L20 is branched midway and the first sub-heat exchangers 12 of multiple first heating devices 10A, 10B, and 10C are connected in parallel.

Below, an example of control of each heating mode by the operation control unit 120 in this embodiment will be described. The collective control of the first heating device group involves starting and stopping operation of all the devices at the same time, and the control of each heating mode is similar to that of the fourth embodiment. The control of the number of devices in the first heating device group follows the control explanation for each heating mode below. The control of the number of devices in the first heating device group is, for example, by comparing the return temperature Tr of the hot water flowing through the water return line L20 with five set temperatures T1>T2>T3>T4>T5, and increasing or decreasing the number of devices in operation.

<<Control of First Heating Mode: Control of the Number of First Heating Devices>>
As described above, when power demand adjustment is not performed, the first heating mode is selected by the heating mode selection unit 110. Hereinafter, an example of control by the operation control unit 120 in the first heating mode will be described.

[1] The set temperatures are, for example, T1 = 70°C (return temperature at zero load, i.e., equivalent to the target hot water temperature), T2 = 66°C, T3 = 63°C, T4 = 60°C (respectively equivalent to return temperatures within the fluctuation range of the average base load), and T5 = 50°C (equivalent to return temperature at the average peak load). However, the numerical examples of each set temperature do not take into account heat loss associated with hot water circulation.

[2] When the return temperature Tr becomes equal to or higher than the set temperature T1 (Tr≧70°C), the operation of the first heating device 10A (No. 1) is terminated. When the return temperature Tr becomes lower than the set temperature T2 (Tr<66°C), the operation of the first heating device 10A (No. 1) is started. When the return temperature Tr becomes equal to or higher than the set temperature T2 (Tr≧66°C), the operation of the first heating device 10B (No. 2) is terminated. When the return temperature Tr becomes lower than the set temperature T3 (Tr<63°C), the operation of the first heating device 10B (No. 2) is started. When the return temperature Tr becomes equal to or higher than the set temperature T3 (Tr≧63°C), the operation of the first heating device 10C (No. 3) is terminated. When the return temperature Tr becomes lower than the set temperature T4 (Tr<60°C), the operation of the first heating device 10C (No. 3) is started.
During independent operation of the first heating device 10 (i.e., any one of units 1 to 3 is operating), the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a first target temperature (e.g., 70°C).

[3] When the return temperature Tr becomes equal to or higher than the set temperature T2 (Tr ≧ 60°C), the operation of the second heating device 20 is terminated. Specifically, the steam supply valve 26 is closed and the steam heater 25 is stopped.

[4] When the return temperature Tr becomes lower than the set temperature T3 (Tr<50° C.), the second heating device 20 starts operating. Specifically, the steam supply valve 26 is opened to operate the steam heater 25.
During the coordinated operation of the first heating device 10 (i.e., all of the first to third units are operating), the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the inlet/outlet temperature difference of the first sub-heat exchanger 12 converges to a first target temperature difference (e.g., 10°C). Also, during the coordinated operation of the second heating device 20, the opening of the steam supply valve 26 of the steam heater 25 is adjusted so that the heat storage temperature TC of the hot water tank 30 converges to a first target temperature (e.g., 70°C).

<<Control of second heating mode A>>
As described above, the second heating mode is selected by the heating mode selection unit 110 when power demand adjustment for suppressing power consumption is performed. Hereinafter, an example of control by the operation control unit 120 in the second heating mode A will be described.

[1] In the second heating mode A, the target temperature for hot water supply is increased to increase the amount of heat stored in the system. For this reason, only the set temperature T1 is changed from 70°C to 90°C. In this heating mode, there is no coordinated operation with the first heating device 10.

[2] When the return temperature Tr becomes equal to or higher than the set temperature T1 (Tr ≧ 90°C), the operation of the second heating device 20 is terminated. Specifically, the steam supply valve 26 is closed and the steam heater 25 is stopped.

[3] When the return temperature Tr becomes lower than the set temperature T2 (Tr<60° C.), the second heating device 20 starts operating. Specifically, the steam supply valve 26 is opened to operate the steam heater 25.
During the independent operation of the second heating device 20, the opening degree of the steam supply valve 26 of the steam heater 25 is adjusted so that the heat storage temperature TC of the hot water tank 30 converges to a second target temperature (e.g., 90° C.). By making the heat storage temperature TC of the hot water tank 30 higher than in the first heating mode, the independent operation that promotes fuel consumption of the second heating device 20 is continued while also satisfying the peak demand of the load equipment 200.

<<Control of Third Heating Mode A: Control of the Number of Units in the First Heating Device Group>>
As described above, the third heating mode is selected by the heating mode selection unit 110 when power demand adjustment for promoting power consumption is performed. Hereinafter, an example of control by the operation control unit 120 in the third heating mode A will be described.

[1] In the third heating mode A, in order to increase the target temperature for hot water supply and increase the amount of heat stored in the system, the set temperature T1 is changed from 70°C to 90°C, the set temperature T2 is changed from 66°C to 80°C, and the set temperature T3 is changed from 63°C to 70°C. In this heating mode, there is no coordinated operation with the second heating device 20.

[2] When the return temperature Tr becomes equal to or higher than the set temperature T1 (Tr≧90°C), the operation of the first heating device 10A (unit 1) is terminated. When the return temperature Tr becomes lower than the set temperature T2 (Tr<80°C), the operation of the first heating device 10A (unit 1) is started. When the return temperature Tr becomes equal to or higher than the set temperature T2 (Tr≧80°C), the operation of the first heating device 10B (unit 2) is terminated. When the return temperature Tr becomes lower than the set temperature T3 (Tr<70°C), the operation of the first heating device 10B (unit 2) is started. When the return temperature Tr becomes equal to or higher than the set temperature T3 (Tr≧70°C), the operation of the first heating device 10C (unit 3) is terminated. When the return temperature Tr becomes lower than the set temperature T4 (Tr<60°C), the operation of the first heating device 10C (unit 3) is started.
During independent operation of the first heating device 10 (i.e., any one of the first to third units is in operation), the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a second target temperature (e.g., 90°C). By making the heat storage temperature TC of the hot water tank 30 higher than in the first heating mode, the peak demand of the load equipment 200 is satisfied while continuing independent operation that promotes power consumption of the first heating device 10.

<<Control of second heating mode B: Control of the number of first heating device group>>
As described above, the second heating mode is selected by the heating mode selection unit 110 when power demand adjustment for suppressing power consumption is performed. Hereinafter, an example of control by the operation control unit 120 in the second heating mode B will be described.

[1] The set temperatures T1 to T5 are the same as those in the first heating mode.

[2] When the return temperature Tr becomes equal to or higher than the set temperature T1 (Tr ≧ 70°C), the operation of the second heating device 20 is terminated. Specifically, the steam supply valve 26 is closed and the steam heater 25 is stopped.

[3] When the return temperature Tr becomes less than the set temperature T2 (Tr < 60°C), the second heating device 20 starts operating. Specifically, the steam supply valve 26 is opened to operate the steam heater 25. During independent operation of the second heating device 20, the opening of the steam supply valve 26 of the steam heater 25 is adjusted so that the heat storage temperature TC of the hot water tank 30 converges to the first target temperature (e.g., 70°C).

[4] When the return temperature Tr becomes equal to or higher than the set temperature T1 (Tr≧70°C), the operation of the first heating device 10A (No. 1) is terminated. When the return temperature Tr becomes lower than the set temperature T2 (Tr<66°C), the operation of the first heating device 10A (No. 1) is started. When the return temperature Tr becomes equal to or higher than the set temperature T2 (Tr≧66°C), the operation of the first heating device 10B (No. 2) is terminated. When the return temperature Tr becomes lower than the set temperature T3 (Tr<63°C), the operation of the first heating device 10B (No. 2) is started. When the return temperature Tr becomes equal to or higher than the set temperature T3 (Tr≧63°C), the operation of the first heating device 10C (No. 3) is terminated. When the return temperature Tr becomes lower than the set temperature T4 (Tr<60°C), the operation of the first heating device 10C (No. 3) is started.
During the coordinated operation of the first heating device 10 (i.e., all of the first to third units are in operation), the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the inlet/outlet temperature difference of the first sub-heat exchanger 12 converges to a second target temperature difference (e.g., 5°C). Also, during the coordinated operation of the second heating device 20, the opening degree of the steam supply valve 26 of the steam heater 25 is adjusted so that the heat storage temperature TC of the hot water tank 30 converges to a first target temperature (e.g., 70°C). By lowering the inlet/outlet temperature difference of the first heating device 10 compared to the first heating mode (i.e., lowering the output ratio), it is possible to suppress power consumption while performing coordinated operation with the second heating device 20.

<<Control of Third Heating Mode B: Control of the Number of Units in the First Heating Device Group>>
As described above, the third heating mode is selected by the heating mode selection unit 110 when power demand adjustment for promoting power consumption is performed. Hereinafter, an example of control by the operation control unit 120 in the third heating mode B will be described.

[1] The set temperatures T1 to T5 are the same as those in the first heating mode.

[2] When the return temperature Tr becomes equal to or higher than the set temperature T1 (Tr≧70°C), the operation of the first heating device 10A (No. 1) is terminated. When the return temperature Tr becomes lower than the set temperature T2 (Tr<66°C), the operation of the first heating device 10A (No. 1) is started. When the return temperature Tr becomes equal to or higher than the set temperature T2 (Tr≧66°C), the operation of the first heating device 10B (No. 2) is terminated. When the return temperature Tr becomes lower than the set temperature T3 (Tr<63°C), the operation of the first heating device 10B (No. 2) is started. When the return temperature Tr becomes equal to or higher than the set temperature T3 (Tr≧63°C), the operation of the first heating device 10C (No. 3) is terminated. When the return temperature Tr becomes lower than the set temperature T4 (Tr<60°C), the operation of the first heating device 10C (No. 3) is started.
During independent operation of the first heating device 10 (i.e., any one of units 1 to 3 is operating), the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a first target temperature (e.g., 70°C).

[3] When the return temperature Tr becomes equal to or higher than the set temperature T2 (Tr ≧ 60°C), the operation of the second heating device 20 is terminated. Specifically, the steam supply valve 26 is closed and the steam heater 25 is stopped.

[4] When the return temperature Tr becomes lower than the set temperature T3 (T5<50° C.), the second heating device 20 starts operating. Specifically, the steam supply valve 26 is opened to operate the steam heater 25.
During the coordinated operation of the first heating device 10 (i.e., all of the first to third units are in operation), the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a third target temperature difference (e.g., 15°C). Also, during the coordinated operation of the second heating device 20, the opening of the steam supply valve 26 of the steam heater 25 is adjusted so that the heat storage temperature TC of the hot water tank 30 converges to a second target temperature (e.g., 70°C). By increasing the inlet/outlet temperature difference of the first heating device 10 more than in the first heating mode (i.e., increasing the output ratio), it is possible to promote power consumption while performing coordinated operation with the second heating device 20.

Seventh Embodiment
Next, a seventh embodiment will be described. Fig. 7 is a diagram showing a schematic configuration of a hot water production system 1 in this embodiment. In this embodiment, the same components as those in the first embodiment are denoted by the same reference numerals, and the description thereof may be omitted.

As shown in FIG. 7, the hot water production system 1 of this embodiment has a water supply line L50 from the water supply equipment. The first heating device 10 and the second heating device 20 heat the service water W1 as the supply water flowing through the water supply line L50. The hot water production systems 1 of the first to sixth embodiments described above mainly supply heat to the load equipment 200 by water circulation (i.e., hot heat output in the load equipment 200), but the hot water production system 1 of this embodiment mainly supplies hot water to the load equipment 200 by one-way circulation (i.e., hot water output in the load equipment 200).

The hot water tank 30 in this embodiment is an open tank. The hot water tank 30 is equipped with a water level sensor 31. The water level sensor 31 detects the water level in the hot water tank 30 and compares it with, for example, three set water levels L1>L2>L3. When the water level sensor 31 detects a decrease in water level due to hot water consumption, make-up water from the water supply equipment is supplied as water W1 through the water supply line L50.

A water distribution line L10, which is a hot water supply pipe, is laid from the hot water tank 30 to the load equipment 200 (single-pipe hot water supply). In addition, a water return line L20, which is a return pipe for excess hot water, may be laid from the load equipment 200 to the hot water tank 30 (circulating hot water supply).

The water supply line L50 is a line for supplying make-up water from the water supply equipment as water W1 to the hot water tank 30. The water supply line L50 branches from a branch point P into a first water supply line L51 and a second water supply line L52.

The first sub-heat exchanger 12 of the first heating device 10 is arranged in the first water supply line L51. In the case of circulating hot water supply, a water passage valve 51 is provided in the first water supply line L51.

The second sub-heat exchanger 22 of the second heating device 20 is arranged in the second water supply line L52. In the case of circulating hot water supply, a water passage valve 52 is provided in the second water supply line L52.

Two water supply pumps 55A, 55B are installed in parallel on the water supply line L50 upstream of the branch point P of the water supply line L50. The rotation speed (driving frequency) of each water supply pump 55A, 55B is constant, and the water supply flow rate is adjusted in two stages by switching between driving and stopping each water supply pump 55A, 55B depending on the detected water level of the hot water tank 30. When only the first water supply pump 55A is driven, water is supplied at a first flow rate, and when both the first water supply pump 55A and the second water supply pump 55B are driven, water is supplied at a second flow rate (> first flow rate).

The first sub-heat exchanger 12 of the first heating device 10 is disposed in the first water supply line L51, which is the line to be heated. The first sub-heat exchanger 12 exchanges heat between the water W1 flowing through the first water supply line L51 and the heat medium R1 flowing through the first sub-circulation line LS1, and heats the water W1 flowing through the first water supply line L51.

The second sub-heat exchanger 22 of the second heating device 20 is disposed in the second water supply line L52, which is the line to be heated. The second sub-heat exchanger 22 exchanges heat between the water W1 flowing through the second water supply line L52 and the heat medium R2 flowing through the second sub-circulation line LS2, and heats the water W1 flowing through the second water supply line L52.

As described above, the hot water production system 1 of this embodiment has a water supply line L50 as a heating target line that supplies water to the hot water tank 30, and the first heating device 10 and the second heating device 20 heat the water W1 flowing through the heating target line. In addition, the heating target line is branched, and the first heating device 10 and the second heating device 20 are arranged in parallel.

Below, we explain examples of control of each heating mode by the operation control unit 120 in this embodiment.

<<Control of First Heating Mode>>
As described above, the first heating mode is selected by the heating mode selection unit 110 when power demand adjustment is not performed. In this embodiment, in the first heating mode, the operation control unit 120 controls the operation of the first heating device 10 and the second heating device 20 according to the hot water demand in the load equipment 200. An example of an index indicating the hot water demand of the load equipment 200 is the water level (= stored hot water amount/remaining hot water amount) of the stored water in the hot water tank 30. A smaller amount of stored hot water indicates a larger hot water demand (= a larger amount of makeup water supplied per hour).

The following describes an example of control by the operation control unit 120 in the first heating mode.

[1] In the case of circulating hot water supply, the water flow valve 51 of the first sub-heat exchanger 12 is always open to return hot water from the load equipment 200 to the hot water tank 30. The water flow valve 52 of the second sub-heat exchanger 22 is opened when the second heating device 20 starts operating and closed when the operation ends.

[2] When the detected water level reaches or exceeds the set water level L1, water supply at the first flow rate and operation of the first heating device 10 are terminated. Specifically, the refrigerant compressor of the heat pump 11 is stopped, the first sub-circulation pump 13 is stopped, and the first water supply pump 55A is stopped.

[3] When the detected water level falls below the set water level L2, start supplying water at the first flow rate and operating the first heating device 10. Specifically, drive the first water supply pump 55A, drive the first sub-circulation pump 13, and drive the refrigerant compressor of the heat pump 11.
During independent operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a first target temperature (e.g., 70°C).

[4] When the detected water level reaches or exceeds the set water level L2, the water supply at the second flow rate and the operation of the second heating device 20 are terminated. Specifically, the burner of the hot water boiler 21 is stopped, the second sub-circulation pump 23 is stopped, and the second water supply pump 55B is stopped. The first water supply pump 55A continues to operate.

[5] When the detected water level falls below the set water level L3, start supplying water at the second flow rate and operating the second heating device 20. Specifically, drive the second feedwater pump 55B, drive the second sub-circulation pump 23, and operate the burner of the hot water boiler 21. The first feedwater pump 55A continues to be driven.
During the coordinated operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to the first target temperature (e.g., 70° C.). Also, during the coordinated operation of the second heating device 20, the combustion amount of the burner of the hot water boiler 21 is adjusted so that the outlet temperature TB of the second sub-heat exchanger 22 converges to the first target temperature (e.g., 70° C.).

<<Control of second heating mode A>>
As described above, the second heating mode is selected by the heating mode selection unit 110 when power demand adjustment for suppressing power consumption is performed. In this embodiment, in the second heating mode A, the operation control unit 120 executes an independent operation of the second heating device 20 in response to the hot water demand in the load equipment 200.

The following describes an example of control by the operation control unit 120 in the second heating mode A.

[1] In the second heating mode A, the target temperature of the hot water supply is increased to increase the amount of heat stored in the system. In this heating mode, there is no coordinated operation with the first heating device 10.

[2] In the case of circulating hot water supply, the water valve 52 of the second sub-heat exchanger 22 is always open to return hot water from the load equipment 200 to the hot water tank 30. The water valve 51 of the first sub-heat exchanger 12 is closed.

[3] When the detected water level reaches or exceeds the set water level L1, the water supply at the first flow rate and the operation of the second heating device 20 are terminated. Specifically, the burner of the hot water boiler 21 is stopped, the second sub-circulation pump 23 is stopped, and the first water supply pump 55A is stopped.

[4] When the detected water level falls below the set water level L2, start supplying water at the first flow rate and operating the second heating device 20. Specifically, drive the first feedwater pump 55A, drive the second sub-circulation pump 23, and operate the burner of the hot water boiler 21.
During independent operation of the second heating device 20, the combustion amount of the burner of the hot water boiler 21 is adjusted so that the outlet temperature TB of the second sub-heat exchanger 22 converges to a second target temperature (e.g., 90°C). By setting the heat storage temperature TC of the hot water tank 30 higher than in the first heating mode, the peak demand of the load equipment 200 is also satisfied while continuing independent operation that promotes fuel consumption of the second heating device 20. Since the load equipment 200 mixes high-temperature water and room-temperature water to adjust the temperature to an appropriate level, a higher heat storage temperature TC allows more hot water at the required temperature to be taken out.

<<Control of third heating mode A>>
As described above, the third heating mode is selected by the heating mode selection unit 110 when power demand adjustment for promoting power consumption is performed. In this embodiment, in the third heating mode A, the operation control unit 120 executes independent operation of the first heating device in response to the hot water demand in the load equipment 200.

The following describes an example of control by the operation control unit 120 in the third heating mode A.

[1] In the third heating mode A, the target temperature of the hot water supply is increased to increase the amount of heat stored in the system. In this heating mode, there is no coordinated operation with the second heating device 20.

[2] In the case of circulating hot water supply, the water valve 51 of the first sub-heat exchanger 12 is always open to return hot water from the load equipment 200 to the hot water tank 30. The water valve 52 of the second sub-heat exchanger 22 is closed.

[3] When the detected water level reaches or exceeds the set water level L1, water supply at the first flow rate and operation of the first heating device 10 are terminated. Specifically, the refrigerant compressor of the heat pump 11 is stopped, the first sub-circulation pump 13 is stopped, and the first water supply pump 55A is stopped.

[4] When the detected water level falls below the set water level L2, start supplying water at the first flow rate and operating the first heating device 10. Specifically, drive the first water supply pump 55A, drive the first sub-circulation pump 13, and drive the refrigerant compressor of the heat pump 11.
During independent operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a second target temperature (e.g., 90° C.). By setting the heat storage temperature TC of the hot water tank 30 higher than in the first heating mode, the peak demand of the load equipment 200 is satisfied while continuing independent operation that promotes power consumption of the first heating device 10. Since the load equipment 200 mixes high-temperature water and room-temperature water to adjust the temperature to an appropriate level, a higher heat storage temperature TC allows more hot water at the required temperature to be extracted.

<<Control of second heating mode B>>
As described above, the second heating mode is selected by the heating mode selection unit 110 when power demand adjustment is performed to suppress power consumption. In this embodiment, in the second heating mode B, the operation control unit 120 switches between the independent operation of the second heating device 20 and the cooperative operation of the second heating device 20 and the first heating device 10 according to the hot water demand in the load equipment 200, and controls the electric heat pump 11 and the combustion boiler 21 in the cooperative operation of the second heating mode B so that the output ratio of the second heating device 20 to the total heat output of the first heating device 10 and the second heating device 20 is greater than the output ratio of the second heating device 20 in the cooperative operation of the first heating mode.

The following describes an example of control by the operation control unit 120 in the second heating mode B.

[1] The water valve 52 of the second sub-heat exchanger 22 is always open to return hot water from the load equipment 200 to the hot water tank 30. The water valve 51 of the first sub-heat exchanger 12 is opened when the first heating device 10 starts operating and closed when the operation ends.

[2] When the detected water level reaches or exceeds the set water level L1, the water supply at the first flow rate and the operation of the second heating device 20 are terminated. Specifically, the burner of the hot water boiler 21 is stopped, the second sub-circulation pump 23 is stopped, and the first water supply pump 55A is stopped.

[3] When the detected water level falls below the set water level L2, start supplying water at the first flow rate and operating the second heating device 20. Specifically, drive the first feedwater pump 55A, drive the second sub-circulation pump 23, and operate the burner of the hot water boiler 21.
During independent operation of the second heating device 20, the combustion amount of the burner of the hot water boiler 21 is adjusted so that the outlet temperature TB of the second sub-heat exchanger 22 converges to the first target temperature (e.g., 70°C).

[4] When the detected water level reaches or exceeds the set water level L2, water supply at the second flow rate and operation of the first heating device 10 are terminated. Specifically, the refrigerant compressor of the heat pump 11 is stopped, the first sub-circulation pump 13 is stopped, and the second water supply pump 55B is stopped. The first water supply pump 55A continues to operate.

[5] When the detected water level falls below the set water level L3, start supplying water at the second flow rate and operating the first heating device 10. Specifically, drive the second water supply pump 55B, drive the first sub-circulation pump 13, and drive the refrigerant compressor of the heat pump 11. The first water supply pump 55A continues to operate.
During the cooperative operation of the second heating device 20, the combustion amount of the burner of the hot water boiler 21 is adjusted so that the outlet temperature TB of the second sub-heat exchanger 22 converges to a second target temperature (e.g., 80°C). Also, during the cooperative operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a third target temperature (e.g., 60°C). By raising the outlet temperature of the second heating device 20 (i.e., raising the output ratio) and lowering the outlet temperature of the first heating device 10 (i.e., lowering the output ratio) more than in the first heating mode, it is possible to suppress the power consumption of the first heating device 10 while performing the cooperative operation.

<<Control of third heating mode B>>
As described above, the third heating mode is selected by the heating mode selection unit 110 when power demand adjustment is performed to promote power consumption. In this embodiment, in the third heating mode B, the operation control unit 120 switches between the independent operation of the first heating device 10 and the cooperative operation of the first heating device 10 and the second heating device 20 according to the hot water demand in the load equipment 200, and controls the electric heat pump 11 and the combustion boiler 21 in the cooperative operation of the third heating mode B so that the output ratio of the first heating device 10 to the total heat output of the first heating device 10 and the second heating device 20 is greater than the output ratio of the first heating device 10 in the cooperative operation of the first heating mode.

The following describes an example of control by the operation control unit 120 in the third heating mode B.

[1] The water valve 51 of the first sub-heat exchanger 12 is always open to return hot water from the load equipment 200 to the hot water tank 30. The water valve 52 of the second sub-heat exchanger 22 is opened when the second heating device 20 starts operating and closed when the operation ends.

[2] When the detected water level reaches or exceeds the set water level L1, water supply at the first flow rate and operation of the first heating device 10 are terminated. Specifically, the refrigerant compressor of the heat pump 11 is stopped, the first sub-circulation pump 13 is stopped, and the first water supply pump 55A is stopped.

[3] When the detected water level falls below the set water level L2, start supplying water at the first flow rate and operating the first heating device 10. Specifically, drive the first water supply pump 55A, drive the first sub-circulation pump 13, and drive the refrigerant compressor of the heat pump 11.
During independent operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a first target temperature (e.g., 70°C).

[4] When the detected water level reaches or exceeds the set water level L2, the water supply at the second flow rate and the operation of the second heating device 20 are terminated. Specifically, the burner of the hot water boiler 21 is stopped, the second sub-circulation pump 23 is stopped, and the second water supply pump 55B is stopped. The first water supply pump 55A continues to operate.

[5] When the detected water level falls below the set water level L3, start supplying water at the second flow rate and operating the second heating device 20. Specifically, drive the second feedwater pump 55B, drive the second sub-circulation pump 23, and operate the burner of the hot water boiler 21. The first feedwater pump 55A continues to be driven.
During the cooperative operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a second target temperature (e.g., 80°C). Also, during the cooperative operation of the second heating device 20, the combustion amount of the burner of the hot water boiler 21 is adjusted so that the outlet temperature TB of the second sub-heat exchanger 22 converges to a third target temperature (e.g., 60°C). By raising the outlet temperature of the first heating device 10 (i.e., raising the output ratio) and lowering the outlet temperature of the second heating device 20 (i.e., lowering the output ratio) more than in the first heating mode, it is possible to promote power consumption of the first heating device 10 while performing the cooperative operation.

Eighth embodiment
Next, an eighth embodiment will be described. Fig. 8 is a diagram showing a schematic configuration of a hot water production system 1 in this embodiment. In this embodiment, the same components as those in the seventh embodiment are denoted by the same reference numerals, and the description thereof may be omitted.
The load equipment 200 in this embodiment directly uses the heated water W1 as cleaning water or the like (i.e., outputs heated water).

As shown in FIG. 8, the water supply line L50 of the hot water production system 1 of this embodiment is connected to the hot water tank 30 without branching. The first heating device 10 and the second heating device 20 of the hot water production system 1 of this embodiment are arranged in series in the water supply line L50 as the line to be heated, and heat the water W1 flowing through the water supply line L50. Here, the configuration in which the first heating device 10 and the second heating device 20 are arranged in series in the line to be heated (water supply line L50) is the same as in the second embodiment, so a description will be omitted. In the case of circulating hot water supply, a water passage valve is provided in the branch line.

Below, we explain examples of control of each heating mode by the operation control unit 120 in this embodiment.

<<Control of First Heating Mode>>
As described above, when power demand adjustment is not performed, the first heating mode is selected by the heating mode selection unit 110. Hereinafter, an example of control by the operation control unit 120 in the first heating mode will be described.

[1] When the detected water level reaches or exceeds the set water level L1, water supply at the first flow rate and operation of the first heating device 10 are terminated. Specifically, the refrigerant compressor of the heat pump 11 is stopped, the first sub-circulation pump 13 is stopped, and the first water supply pump 55A is stopped.

[2] When the detected water level falls below the set water level L2, start supplying water at the first flow rate and operating the first heating device 10. Specifically, drive the first water supply pump 55A, drive the first sub-circulation pump 13, and drive the refrigerant compressor of the heat pump 11.
During independent operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a first target temperature (e.g., 70°C).

[3] When the detected water level reaches or exceeds the set water level L2, water supply at the second flow rate and operation of the second heating device 20 are terminated. Specifically, the burner of the hot water boiler 21 is stopped, the second sub-circulation pump 23 is stopped, and the second water supply pump 55B is stopped. The first water supply pump 55A continues to operate.

[4] When the detected water level falls below the set water level L3, start supplying water at the second flow rate and operating the second heating device 20. Specifically, drive the second feedwater pump 55B, drive the second sub-circulation pump 23, and operate the burner of the hot water boiler 21. The first feedwater pump 55A continues to be driven.
During the coordinated operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the inlet/outlet temperature difference of the first sub-heat exchanger 12 converges to a first target temperature difference (e.g., 30° C.). Also, during the coordinated operation of the second heating device 20, the combustion amount of the burner of the hot water boiler 21 is adjusted so that the outlet temperature TB of the second sub-heat exchanger 22 converges to a first target temperature (e.g., 70° C.).

<<Control of second heating mode A>>
As described above, the second heating mode is selected by the heating mode selection unit 110 when power demand adjustment for suppressing power consumption is performed. Hereinafter, an example of control by the operation control unit 120 in the second heating mode A will be described.

[1] In the second heating mode A, the target temperature of the hot water supply is increased to increase the amount of heat stored in the system. In this heating mode, there is no coordinated operation with the first heating device 10.

[2] When the detected water level reaches or exceeds the set water level L1, the water supply at the first flow rate and the operation of the second heating device 20 are terminated. Specifically, the burner of the hot water boiler 21 is stopped, the second sub-circulation pump 23 is stopped, and the first water supply pump 55A is stopped.

[3] When the detected water level falls below the set water level L2, start supplying water at the first flow rate and operating the second heating device 20. Specifically, drive the first feedwater pump 55A, drive the second sub-circulation pump 23, and operate the burner of the hot water boiler 21.
During independent operation of the second heating device 20, the combustion amount of the burner of the hot water boiler 21 is adjusted so that the outlet temperature TB of the second sub-heat exchanger 22 converges to a second target temperature (e.g., 90°C). By setting the heat storage temperature TC of the hot water tank 30 higher than in the first heating mode, the peak demand of the load equipment 200 is also satisfied while continuing independent operation that promotes fuel consumption of the second heating device 20. Since the load equipment 200 mixes high-temperature water and room-temperature water to adjust the temperature to an appropriate level, a higher heat storage temperature TC allows more hot water at the required temperature to be taken out.

<<Control of third heating mode A>>
As described above, the third heating mode is selected by the heating mode selection unit 110 when power demand adjustment for promoting power consumption is performed. Hereinafter, an example of control by the operation control unit 120 in the third heating mode A will be described.

[1] In the third heating mode A, the target temperature of the hot water supply is increased to increase the amount of heat stored in the system. In this heating mode, there is no coordinated operation with the second heating device 20.

[2] When the detected water level reaches or exceeds the set water level L1, water supply at the first flow rate and operation of the first heating device 10 are terminated. Specifically, the refrigerant compressor of the heat pump 11 is stopped, the first sub-circulation pump 13 is stopped, and the first water supply pump 55A is stopped.

[3] When the detected water level falls below the set water level L2, start supplying water at the first flow rate and operating the first heating device 10. Specifically, drive the first water supply pump 55A, drive the first sub-circulation pump 13, and drive the refrigerant compressor of the heat pump 11.
During independent operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a second target temperature (e.g., 90° C.). By setting the heat storage temperature TC of the hot water tank 30 higher than in the first heating mode, the peak demand of the load equipment 200 is satisfied while continuing independent operation that promotes power consumption of the first heating device 10. Since the load equipment 200 mixes high-temperature water and room-temperature water to adjust the temperature to an appropriate level, a higher heat storage temperature TC allows more hot water at the required temperature to be extracted.

<<Control of second heating mode B>>
As described above, the second heating mode is selected by the heating mode selection unit 110 when power demand adjustment for suppressing power consumption is performed. Hereinafter, an example of control by the operation control unit 120 in the second heating mode B will be described.

[1] When the detected water level reaches or exceeds the set water level L1, the water supply at the first flow rate and the operation of the second heating device 20 are terminated. Specifically, the burner of the hot water boiler 21 is stopped, the second sub-circulation pump 23 is stopped, and the first water supply pump 55A is stopped.

[2] When the detected water level falls below the set water level L2, start supplying water at the first flow rate and operating the second heating device 20. Specifically, drive the first feedwater pump 55A, drive the second sub-circulation pump 23, and operate the burner of the hot water boiler 21.
During independent operation of the second heating device 20, the combustion amount of the burner of the hot water boiler 21 is adjusted so that the outlet temperature TB of the second sub-heat exchanger 22 converges to the first target temperature (e.g., 70°C).

[3] When the detected water level reaches or exceeds the set water level L2, water supply at the second flow rate and operation of the first heating device 10 are terminated. Specifically, the refrigerant compressor of the heat pump 11 is stopped, the first sub-circulation pump 13 is stopped, and the second water supply pump 55B is stopped. The first water supply pump 55A continues to operate.

[4] When the detected water level falls below the set water level L3, start supplying water at the second flow rate and operating the first heating device 10. Specifically, drive the second water supply pump 55B, drive the first sub-circulation pump 13, and drive the refrigerant compressor of the heat pump 11. The first water supply pump 55A continues to operate.
During the cooperative operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the inlet/outlet temperature difference of the first sub-heat exchanger 12 converges to a second target temperature difference (e.g., 25° C.). Also, during the cooperative operation of the second heating device 20, the combustion amount of the burner of the hot water boiler 21 is adjusted so that the outlet temperature TB of the second sub-heat exchanger 22 converges to a first target temperature (e.g., 70° C.). By lowering the inlet/outlet temperature difference of the first heating device 10 (i.e., lowering the output ratio) more than in the first heating mode, it is possible to suppress power consumption while performing cooperative operation with the second heating device 20.

<<Control of third heating mode B>>
As described above, the third heating mode is selected by the heating mode selection unit 110 when power demand adjustment for promoting power consumption is performed. Hereinafter, an example of control by the operation control unit 120 in the third heating mode B will be described.

[1] When the detected water level reaches or exceeds the set water level L1, water supply at the first flow rate and operation of the first heating device 10 are terminated. Specifically, the refrigerant compressor of the heat pump 11 is stopped, the first sub-circulation pump 13 is stopped, and the 21st water supply pump is stopped.

[2] When the detected water level falls below the set water level L2, start supplying water at the first flow rate and operating the first heating device 10. Specifically, drive the first water supply pump 55A, drive the first sub-circulation pump 13, and drive the refrigerant compressor of the heat pump 11.
During independent operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a first target temperature (e.g., 70°C).

[3] When the detected water level reaches or exceeds the set water level L2, water supply at the second flow rate and operation of the second heating device 20 are terminated. Specifically, the burner of the hot water boiler 21 is stopped, the second sub-circulation pump 23 is stopped, and the second water supply pump 55B is stopped. The first water supply pump 55A continues to operate.

[4] When the detected water level falls below the set water level L3, start supplying water at the second flow rate and operating the second heating device 20. Specifically, drive the second feedwater pump 55B, drive the second sub-circulation pump 23, and operate the burner of the hot water boiler 21. The first feedwater pump 55A continues to be driven.
During the cooperative operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a third target temperature difference (e.g., 35° C.). Moreover, during the cooperative operation of the second heating device 20, the combustion amount of the burner of the hot water boiler 21 is adjusted so that the outlet temperature TB of the second sub-heat exchanger 22 converges to a second target temperature (e.g., 70° C.). By increasing the inlet/outlet temperature difference of the first heating device 10 more than in the first heating mode (i.e., increasing the output ratio), it is possible to promote power consumption while performing cooperative operation with the second heating device 20.

Ninth embodiment
Next, a ninth embodiment will be described. Fig. 9 is a diagram showing a schematic configuration of a hot water production system 1 in this embodiment. In this embodiment, the same components as those in the seventh embodiment are denoted by the same reference numerals, and the description thereof may be omitted.
The load equipment 200 in this embodiment directly uses the heated water W1 as cleaning water or the like (i.e., outputs heated water).

As shown in FIG. 9, the first heating device 10 and the second heating device 20 are not arranged in the water supply line L50 of the hot water production system 1 of this embodiment. The water supply line L50 is not branched and is directly connected to the hot water tank 30. The hot water production system 1 of this embodiment includes a circulation line L30 as a heating target line that circulates the stored water in the hot water tank 30. The first heating device 10 and the second heating device 20 heat the water W1 as circulating water flowing through the circulation line L30. Here, the configuration in which the first heating device 10 and the second heating device 20 are arranged in parallel in the circulation line L30 is the same as in the third embodiment, so a description thereof will be omitted.

Below, we explain examples of control of each heating mode by the operation control unit 120 in this embodiment.

<<Control of First Heating Mode>>
As described above, when power demand adjustment is not performed, the first heating mode is selected by the heating mode selection unit 110. Hereinafter, an example of control by the operation control unit 120 in the first heating mode will be described.

[1] When the detected water level reaches or exceeds the set water level L1, water supply at the first flow rate and operation of the first heating device 10 are terminated. Specifically, the refrigerant compressor of the heat pump 11 is stopped, the first sub-circulation pump 13 is stopped, the first circulation pump is stopped, and the first water supply pump 55A is stopped.

[2] When the detected water level falls below the set water level L2, start supplying water at the first flow rate and operating the first heating device 10. Specifically, drive the first water supply pump 55A, drive the first circulation pump, drive the first sub-circulation pump 13, and drive the refrigerant compressor of the heat pump 11.
During independent operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a first target temperature (e.g., 70°C).

[3] When the detected water level reaches or exceeds the set water level L2, water supply at the second flow rate and operation of the second heating device 20 are terminated. Specifically, the burner of the hot water boiler 21 is stopped, the second sub-circulation pump 23 is stopped, the second circulation pump is stopped, and the second feedwater pump 55B is stopped. The first feedwater pump 55A continues to operate.

[4] When the detected water level falls below the set water level L3, start supplying water at the second flow rate and operating the second heating device 20. Specifically, drive the second feedwater pump 55B, drive the second circulation pump, drive the second sub-circulation pump 23, and operate the burner of the hot water boiler 21. The first feedwater pump 55A continues to be driven.
During the coordinated operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to the first target temperature (e.g., 70° C.). Also, during the coordinated operation of the second heating device 20, the combustion amount of the burner of the hot water boiler 21 is adjusted so that the outlet temperature TB of the second sub-heat exchanger 22 converges to the first target temperature (e.g., 70° C.).

<<Control of second heating mode A>>
As described above, the second heating mode is selected by the heating mode selection unit 110 when power demand adjustment for suppressing power consumption is performed. Hereinafter, an example of control by the operation control unit 120 in the second heating mode A will be described.

[1] In the second heating mode A, the target temperature of the hot water supply is increased to increase the amount of heat stored in the system. In this heating mode, there is no coordinated operation with the first heating device 10.

[2] When the detected water level reaches or exceeds the set water level L1, the water supply at the first flow rate and the operation of the second heating device 20 are terminated. Specifically, the burner of the hot water boiler 21 is stopped, the second sub-circulation pump 23 is stopped, the second circulation pump is stopped, and the first water supply pump 55A is stopped.

[3] When the detected water level falls below the set water level L2, start supplying water at the first flow rate and operating the second heating device 20. Specifically, drive the first feedwater pump 55A, drive the second circulation pump, drive the second sub-circulation pump 23, and operate the burner of the hot water boiler 21.
During independent operation of the second heating device 20, the combustion amount of the burner of the hot water boiler 21 is adjusted so that the outlet temperature TB of the second sub-heat exchanger 22 converges to a second target temperature (e.g., 90°C). By setting the heat storage temperature TC of the hot water tank 30 higher than in the first heating mode, the peak demand of the load equipment 200 is also satisfied while continuing independent operation that promotes fuel consumption of the second heating device 20. Since the load equipment 200 mixes high-temperature water and room-temperature water to adjust the temperature to an appropriate level, a higher heat storage temperature TC allows more hot water at the required temperature to be taken out.

<<Control of third heating mode A>>
As described above, the third heating mode is selected by the heating mode selection unit 110 when power demand adjustment for promoting power consumption is performed. Hereinafter, an example of control by the operation control unit 120 in the third heating mode A will be described.

[1] In the third heating mode A, the target temperature of the hot water supply is increased to increase the amount of heat stored in the system. In this heating mode, there is no coordinated operation with the second heating device 20.

[2] When the detected water level reaches or exceeds the set water level L1, water supply at the first flow rate and operation of the first heating device 10 are terminated. Specifically, the refrigerant compressor of the heat pump 11 is stopped, the first sub-circulation pump 13 is stopped, the first circulation pump is stopped, and the first water supply pump 55A is stopped.

[3] When the detected water level falls below the set water level L2, start supplying water at the first flow rate and operating the first heating device 10. Specifically, drive the first water supply pump 55A, drive the first circulation pump, drive the first sub-circulation pump 13, and drive the refrigerant compressor of the heat pump 11.
During independent operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a second target temperature (e.g., 90° C.). By setting the heat storage temperature TC of the hot water tank 30 higher than in the first heating mode, the peak demand of the load equipment 200 is satisfied while continuing independent operation that promotes power consumption of the first heating device 10. Since the load equipment 200 mixes high-temperature water and room-temperature water to adjust the temperature to an appropriate level, a higher heat storage temperature TC allows more hot water at the required temperature to be extracted.

<<Control of second heating mode B>>
As described above, the second heating mode is selected by the heating mode selection unit 110 when power demand adjustment for suppressing power consumption is performed. Hereinafter, an example of control by the operation control unit 120 in the second heating mode B will be described.

[1] When the detected water level reaches or exceeds the set water level L1, water supply at the first flow rate and operation of the second heating device 20 are terminated. Specifically, the burner of the hot water boiler 21 is stopped, the second sub-circulation pump 23 is stopped, the second circulation pump is stopped, and the first water supply pump 55A is stopped.

[2] When the detected water level falls below the set water level L2, start supplying water at the first flow rate and operating the second heating device 20. Specifically, drive the first feedwater pump 55A, drive the second circulation pump, drive the second sub-circulation pump 23, and operate the burner of the hot water boiler 21.
During independent operation of the second heating device 20, the combustion amount of the burner of the hot water boiler 21 is adjusted so that the outlet temperature TB of the second sub-heat exchanger 22 converges to the first target temperature (e.g., 70°C).

[3] When the detected water level reaches or exceeds the set water level L2, water supply at the second flow rate and operation of the first heating device 10 are terminated. Specifically, the refrigerant compressor of the heat pump 11 is stopped, the first sub-circulation pump 13 is stopped, the first circulation pump is stopped, and the second water supply pump 55B is stopped. The first water supply pump 55A continues to operate.

[4] When the detected water level falls below the set water level L3, start supplying water at the second flow rate and operating the first heating device 10. Specifically, drive the second water supply pump 55B, drive the first circulation pump, drive the first sub-circulation pump 13, and drive the refrigerant compressor of the heat pump 11. The first water supply pump 55A continues to operate.
During the cooperative operation of the second heating device 20, the combustion amount of the burner of the hot water boiler 21 is adjusted so that the outlet temperature TB of the second sub-heat exchanger 22 converges to a second target temperature (e.g., 80°C). Also, during the cooperative operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a third target temperature (e.g., 60°C). By raising the outlet temperature of the second heating device 20 (i.e., raising the output ratio) and lowering the outlet temperature of the first heating device 10 (i.e., lowering the output ratio) more than in the first heating mode, it is possible to suppress the power consumption of the first heating device 10 while performing the cooperative operation.

<<Control of third heating mode B>>
As described above, the third heating mode is selected by the heating mode selection unit 110 when power demand adjustment for promoting power consumption is performed. Hereinafter, an example of control by the operation control unit 120 in the third heating mode B will be described.

[1] When the detected water level reaches or exceeds the set water level L1, water supply at the first flow rate and operation of the first heating device 10 are terminated. Specifically, the refrigerant compressor of the heat pump 11 is stopped, the first sub-circulation pump 13 is stopped, the first circulation pump is stopped, and the first water supply pump 55A is stopped.

[2] When the detected water level falls below the set water level L2, start supplying water at the first flow rate and operating the first heating device 10. Specifically, drive the first water supply pump 55A, drive the first circulation pump, drive the first sub-circulation pump 13, and drive the refrigerant compressor of the heat pump 11.
During independent operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a first target temperature (e.g., 70°C).

[3] When the detected water level reaches or exceeds the set water level L2, water supply at the second flow rate and operation of the second heating device 20 are terminated. Specifically, the burner of the hot water boiler 21 is stopped, the second sub-circulation pump 23 is stopped, the second circulation pump is stopped, and the second feedwater pump 55B is stopped. The first feedwater pump 55A continues to operate.

[4] When the detected water level falls below the set water level L3, start supplying water at the second flow rate and operating the second heating device 20. Specifically, drive the second feedwater pump 55B, drive the second circulation pump, drive the second sub-circulation pump 23, and operate the burner of the hot water boiler 21. The first feedwater pump 55A continues to be driven.
During the cooperative operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a second target temperature (e.g., 80°C). Also, during the cooperative operation of the second heating device 20, the combustion amount of the burner of the hot water boiler 21 is adjusted so that the outlet temperature TB of the second sub-heat exchanger 22 converges to a third target temperature (e.g., 60°C). By raising the outlet temperature of the first heating device 10 (i.e., raising the output ratio) and lowering the outlet temperature of the second heating device 20 (i.e., lowering the output ratio) more than in the first heating mode, it is possible to promote power consumption of the first heating device 10 while performing the cooperative operation.

Tenth embodiment
Next, a tenth embodiment will be described. Fig. 10 is a diagram showing a schematic configuration of a hot water production system 1 in this embodiment. In this embodiment, the same components as those in the seventh embodiment are denoted by the same reference numerals, and the description thereof may be omitted.
The load equipment 200 in this embodiment directly uses the heated water W1 as cleaning water or the like (i.e., outputs heated water).

As shown in FIG. 10, the water supply line L50 of the hot water production system 1 of this embodiment is not branched and is connected to the hot water tank 30. The first heating device 10 heats the water W1 flowing through the water supply line L50 as the line to be heated. The second heating device 20 heats the water W1 as stored water in the hot water tank 30. Here, the configuration in which the first heating device 10 heats the water W1 flowing through the line to be heated (water supply line L50) and the configuration in which the second heating device 20 heats the water W1 as stored water in the hot water tank are the same as those in the fourth embodiment, and therefore will not be described.

Below, we explain examples of control of each heating mode by the operation control unit 120 in this embodiment.

<<Control of First Heating Mode>>
As described above, when power demand adjustment is not performed, the first heating mode is selected by the heating mode selection unit 110. Hereinafter, an example of control by the operation control unit 120 in the first heating mode will be described.

[1] When the detected water level reaches or exceeds the set water level L1, water supply at the first flow rate and operation of the first heating device 10 are terminated. Specifically, the refrigerant compressor of the heat pump 11 is stopped, the first sub-circulation pump 13 is stopped, and the first water supply pump 55A is stopped.

[2] When the detected water level falls below the set water level L2, start supplying water at the first flow rate and operating the first heating device 10. Specifically, drive the first water supply pump 55A, drive the first sub-circulation pump 13, and drive the refrigerant compressor of the heat pump 11.
During independent operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a first target temperature (e.g., 70°C).

[3] When the detected water level reaches or exceeds the set water level L2, water supply at the second flow rate and operation of the second heating device 20 are terminated. Specifically, the steam supply valve 26 is closed to stop the steam heater 25, and the second water supply pump 55B is stopped. The first water supply pump 55A continues to operate.

[4] When the detected water level falls below the set water level L3, start supplying water at the second flow rate and operating the second heating device 20. Specifically, drive the second feedwater pump 55B and open the steam supply valve 26 to operate the steam heater 25. The first feedwater pump 55A continues to be driven.
During the coordinated operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the inlet/outlet temperature difference of the first sub-heat exchanger 12 converges to a first target temperature difference (e.g., 30° C.). Also, during the coordinated operation of the second heating device 20, the opening of the steam supply valve 26 is adjusted so that the heat storage temperature TC of the hot water tank 30 converges to a first target temperature (e.g., 70° C.).

<<Control of second heating mode A>>
As described above, the second heating mode is selected by the heating mode selection unit 110 when power demand adjustment for suppressing power consumption is performed. Hereinafter, an example of control by the operation control unit 120 in the second heating mode A will be described.

[1] In the second heating mode A, the target temperature of the hot water supply is increased to increase the amount of heat stored in the system. In this heating mode, there is no coordinated operation with the first heating device 10.

[2] When the detected water level reaches or exceeds the set water level L1, the water supply at the first flow rate and the operation of the second heating device 20 are terminated. Specifically, the steam supply valve 26 is closed to stop the steam heater 25, and the first water supply pump 55A is stopped.

[3] When the detected water level falls below the set water level L2, start supplying water at the first flow rate and operating the second heating device 20. Specifically, drive the first feedwater pump 55A and open the steam supply valve 26 to operate the steam heater 25.
During the independent operation of the second heating device 20, the opening of the steam supply valve 26 of the steam heater 25 is adjusted so that the heat storage temperature TC of the hot water tank 30 converges to a second target temperature (e.g., 90°C). By making the heat storage temperature TC of the hot water tank 30 higher than in the first heating mode, the peak demand of the load equipment 200 is satisfied while continuing the independent operation that promotes fuel consumption of the second heating device 20. Since the load equipment 200 mixes high-temperature water and room-temperature water to adjust the temperature to an appropriate level, a higher heat storage temperature TC allows more hot water at the required temperature to be taken out.

<<Control of third heating mode A>>
As described above, the third heating mode is selected by the heating mode selection unit 110 when power demand adjustment for promoting power consumption is performed. Hereinafter, an example of control by the operation control unit 120 in the third heating mode A will be described.

[1] In the third heating mode A, the target temperature of the hot water supply is increased to increase the amount of heat stored in the system. In this heating mode, there is no coordinated operation with the second heating device 20.

[2] When the detected water level reaches or exceeds the set water level L1, water supply at the first flow rate and operation of the first heating device 10 are terminated. Specifically, the refrigerant compressor of the heat pump 11 is stopped, the first sub-circulation pump 13 is stopped, and the first water supply pump 55A is stopped.

[3] When the detected water level falls below the set water level L2, start supplying water at the first flow rate and operating the first heating device 10. Specifically, drive the first water supply pump 55A, drive the first sub-circulation pump 13, and drive the refrigerant compressor of the heat pump 11.
During independent operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a second target temperature (e.g., 90° C.). By setting the heat storage temperature TC of the hot water tank 30 higher than in the first heating mode, the peak demand of the load equipment 200 is satisfied while continuing independent operation that promotes power consumption of the first heating device 10. Since the load equipment 200 mixes high-temperature water and room-temperature water to adjust the temperature to an appropriate level, a higher heat storage temperature TC allows more hot water at the required temperature to be extracted.

<<Control of second heating mode B>>
As described above, the second heating mode is selected by the heating mode selection unit 110 when power demand adjustment for suppressing power consumption is performed. Hereinafter, an example of control by the operation control unit 120 in the second heating mode B will be described.

[1] When the detected water level reaches or exceeds the set water level L1, the water supply at the first flow rate and the operation of the second heating device 20 are terminated. Specifically, the steam supply valve 26 is closed to stop the steam heater 25, and the first water supply pump 55A is stopped.

[2] When the detected water level falls below the set water level L2, start supplying water at the first flow rate and operating the second heating device 20. Specifically, drive the first feedwater pump 55A and open the steam supply valve 26 to operate the steam heater 25.
During independent operation of the second heating device 20, the opening of the steam supply valve 26 of the steam heater 25 is adjusted so that the outlet temperature TB of the second sub-heat exchanger 22 converges to the first target temperature (e.g., 70°C).

[3] When the detected water level reaches or exceeds the set water level L2, water supply at the second flow rate and operation of the first heating device 10 are terminated. Specifically, the refrigerant compressor of the heat pump 11 is stopped, the first sub-circulation pump 13 is stopped, and the second water supply pump 55B is stopped. The first water supply pump 55A continues to operate.

[4] When the detected water level falls below the set water level L3, start supplying water at the second flow rate and operating the first heating device 10. Specifically, drive the second water supply pump 55B, drive the first sub-circulation pump 13, and drive the refrigerant compressor of the heat pump 11. The first water supply pump 55A continues to operate.
During the cooperative operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the inlet/outlet temperature difference of the first sub-heat exchanger 12 converges to a second target temperature difference (e.g., 25° C.). Also, during the cooperative operation of the second heating device 20, the opening degree of the steam supply valve 26 of the steam heater 25 is adjusted so that the heat storage temperature TC of the hot water tank 30 converges to a first target temperature (e.g., 70° C.). By lowering the inlet/outlet temperature difference of the first heating device 10 (i.e., lowering the output ratio) more than in the first heating mode, it is possible to suppress power consumption while performing cooperative operation with the second heating device 20.

<<Control of third heating mode B>>
As described above, the third heating mode is selected by the heating mode selection unit 110 when power demand adjustment for promoting power consumption is performed. Hereinafter, an example of control by the operation control unit 120 in the third heating mode B will be described.

[1] When the detected water level reaches or exceeds the set water level L1, water supply at the first flow rate and operation of the first heating device 10 are terminated. Specifically, the refrigerant compressor of the heat pump 11 is stopped, the first sub-circulation pump 13 is stopped, and the 21st water supply pump is stopped.

[2] When the detected water level falls below the set water level L2, start supplying water at the first flow rate and operating the first heating device 10. Specifically, drive the first water supply pump 55A, drive the first sub-circulation pump 13, and drive the refrigerant compressor of the heat pump 11.
During independent operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a first target temperature (e.g., 70°C).

[3] When the detected water level reaches or exceeds the set water level L2, water supply at the second flow rate and operation of the second heating device 20 are terminated. Specifically, the steam supply valve 26 is closed to stop the steam heater 25, and the second water supply pump 55B is stopped. The first water supply pump 55A continues to operate.

[4] When the detected water level falls below the set water level L3, start supplying water at the second flow rate and operating the second heating device 20. Specifically, drive the second feedwater pump 55B and open the steam supply valve 26 to operate the steam heater 25. The first feedwater pump 55A continues to be driven.
During the cooperative operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a third target temperature difference (e.g., 35° C.). Moreover, during the cooperative operation of the second heating device 20, the combustion amount of the burner of the hot water boiler 21 is adjusted so that the outlet temperature TB of the second sub-heat exchanger 22 converges to a second target temperature (e.g., 70° C.). By increasing the inlet/outlet temperature difference of the first heating device 10 more than in the first heating mode (i.e., increasing the output ratio), it is possible to promote power consumption while performing cooperative operation with the second heating device 20.

Eleventh Embodiment
Next, an eleventh embodiment will be described. Fig. 11 is a diagram showing a schematic configuration of a hot water producing system 1 in this embodiment. In this embodiment, the same components as those in the tenth embodiment are given the same reference numerals, and the description thereof may be omitted. The load equipment 200 in this embodiment directly uses the heated water W1 as washing water or the like (i.e., hot water output).

As shown in FIG. 11, the first heating device 10 is not disposed in the water supply line L50 of the hot water production system 1 of this embodiment. The hot water production system 1 of this embodiment includes a first circulation line L31 as a heating target line for circulating the stored water in the hot water tank 30. The first heating device 10 heats the water W1 as circulating water flowing through the first circulation line L31. The second heating device 20 heats the water W1 as stored water in the hot water tank 30, as in the tenth embodiment. Here, the configuration in which the first heating device 10 heats the water W1 as circulating water flowing through the first circulation line L31 is the same as in the fifth embodiment, and therefore will not be described.

Below, we explain examples of control of each heating mode by the operation control unit 120 in this embodiment.

<<Control of First Heating Mode>>
As described above, when power demand adjustment is not performed, the first heating mode is selected by the heating mode selection unit 110. Hereinafter, an example of control by the operation control unit 120 in the first heating mode will be described.

[1] When the detected water level reaches or exceeds the set water level L1, water supply at the first flow rate and operation of the first heating device 10 are terminated. Specifically, the refrigerant compressor of the heat pump 11 is stopped, the first sub-circulation pump 13 is stopped, the first circulation pump is stopped, and the first water supply pump 55A is stopped.

[2] When the detected water level falls below the set water level L2, start supplying water at the first flow rate and operating the first heating device 10. Specifically, drive the first water supply pump 55A, drive the first circulation pump, drive the first sub-circulation pump 13, and drive the refrigerant compressor of the heat pump 11.
During independent operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a first target temperature (e.g., 70°C).

[3] When the detected water level reaches or exceeds the set water level L2, water supply at the second flow rate and operation of the second heating device 20 are terminated. Specifically, the steam supply valve 26 is closed to stop the steam heater 25, and the second water supply pump 55B is stopped. The first water supply pump 55A continues to operate.

[4] When the detected water level falls below the set water level L3, start supplying water at the second flow rate and operating the second heating device 20. Specifically, drive the second feedwater pump 55B and open the steam supply valve 26 to operate the steam heater 25. The first feedwater pump 55A continues to be driven.
During the coordinated operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to the first target temperature (e.g., 70° C.). Also, during the coordinated operation of the second heating device 20, the opening degree of the steam supply valve 26 is adjusted so that the heat storage temperature TC of the hot water tank 30 converges to the first target temperature (e.g., 70° C.).

<<Control of second heating mode A>>
As described above, the second heating mode is selected by the heating mode selection unit 110 when power demand adjustment for suppressing power consumption is performed. Hereinafter, an example of control by the operation control unit 120 in the second heating mode A will be described.

[1] In the second heating mode A, the target temperature of the hot water supply is increased to increase the amount of heat stored in the system. In this heating mode, there is no coordinated operation with the first heating device 10.

[2] When the detected water level reaches or exceeds the set water level L1, the water supply at the first flow rate and the operation of the second heating device 20 are terminated. Specifically, the steam supply valve 26 is closed to stop the steam heater 25, and the first water supply pump 55A is stopped.

[3] When the detected water level falls below the set water level L2, start supplying water at the first flow rate and operating the second heating device 20. Specifically, drive the first feedwater pump 55A and open the steam supply valve 26 to operate the steam heater 25.
During the independent operation of the second heating device 20, the opening of the steam supply valve 26 of the steam heater 25 is adjusted so that the heat storage temperature TC of the hot water tank 30 converges to a second target temperature (e.g., 90°C). By making the heat storage temperature TC of the hot water tank 30 higher than in the first heating mode, the peak demand of the load equipment 200 is satisfied while continuing the independent operation that promotes fuel consumption of the second heating device 20. Since the load equipment 200 mixes high-temperature water and room-temperature water to adjust the temperature to an appropriate level, a higher heat storage temperature TC allows more hot water at the required temperature to be taken out.

<<Control of third heating mode A>>
As described above, the third heating mode is selected by the heating mode selection unit 110 when power demand adjustment for promoting power consumption is performed. Hereinafter, an example of control by the operation control unit 120 in the third heating mode A will be described.

[1] In the third heating mode A, the target temperature of the hot water supply is increased to increase the amount of heat stored in the system. In this heating mode, there is no coordinated operation with the second heating device 20.

[2] When the detected water level reaches or exceeds the set water level L1, water supply at the first flow rate and operation of the first heating device 10 are terminated. Specifically, the refrigerant compressor of the heat pump 11 is stopped, the first sub-circulation pump 13 is stopped, the first circulation pump is stopped, and the first water supply pump 55A is stopped.

[3] When the detected water level falls below the set water level L2, start supplying water at the first flow rate and operating the first heating device 10. Specifically, drive the first water supply pump 55A, drive the first circulation pump, drive the first sub-circulation pump 13, and drive the refrigerant compressor of the heat pump 11.
During independent operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a second target temperature (e.g., 90° C.). By setting the heat storage temperature TC of the hot water tank 30 higher than in the first heating mode, the peak demand of the load equipment 200 is satisfied while continuing independent operation that promotes power consumption of the first heating device 10. Since the load equipment 200 mixes high-temperature water and room-temperature water to adjust the temperature to an appropriate level, a higher heat storage temperature TC allows more hot water at the required temperature to be extracted.

<<Control of second heating mode B>>
As described above, the second heating mode is selected by the heating mode selection unit 110 when power demand adjustment for suppressing power consumption is performed. Hereinafter, an example of control by the operation control unit 120 in the second heating mode B will be described.

[1] When the detected water level reaches or exceeds the set water level L1, the water supply at the first flow rate and the operation of the second heating device 20 are terminated. Specifically, the steam supply valve 26 is closed to stop the steam heater 25, and the first water supply pump 55A is stopped.

[2] When the detected water level falls below the set water level L2, start supplying water at the first flow rate and operating the second heating device 20. Specifically, drive the first feedwater pump 55A and open the steam supply valve 26 to operate the steam heater 25.
During the independent operation of the second heating device 20, the opening of the steam supply valve 26 of the steam heater 25 is adjusted so that the heat storage temperature TC of the hot water tank 30 converges to the first target temperature (e.g., 70°C).

[3] When the detected water level reaches or exceeds the set water level L2, water supply at the second flow rate and operation of the first heating device 10 are terminated. Specifically, the refrigerant compressor of the heat pump 11 is stopped, the first sub-circulation pump 13 is stopped, the first circulation pump is stopped, and the second water supply pump 55B is stopped. The first water supply pump 55A continues to operate.

[4] When the detected water level falls below the set water level L3, start supplying water at the second flow rate and operating the first heating device 10. Specifically, drive the second water supply pump 55B, drive the first circulation pump, drive the first sub-circulation pump 13, and drive the refrigerant compressor of the heat pump 11. The first water supply pump 55A continues to operate.
During the cooperative operation of the second heating device 20, the opening of the steam supply valve 26 of the steam heater 25 is adjusted so that the heat storage temperature TC of the hot water tank 30 converges to a second target temperature (e.g., 80°C). Also, during the cooperative operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a third target temperature (e.g., 60°C). By raising the heat storage temperature TC by the second heating device 20 (i.e., increasing the output ratio) and lowering the outlet temperature of the first heating device 10 (i.e., decreasing the output ratio) more than in the first heating mode, it is possible to suppress the power consumption of the first heating device 10 while performing the cooperative operation.

<<Control of third heating mode B>>
As described above, the third heating mode is selected by the heating mode selection unit 110 when power demand adjustment for promoting power consumption is performed. Hereinafter, an example of control by the operation control unit 120 in the third heating mode B will be described.

[1] When the detected water level reaches or exceeds the set water level L1, water supply at the first flow rate and operation of the first heating device 10 are terminated. Specifically, the refrigerant compressor of the heat pump 11 is stopped, the first sub-circulation pump 13 is stopped, the first circulation pump is stopped, and the first water supply pump 55A is stopped.

[2] When the detected water level falls below the set water level L2, start supplying water at the first flow rate and operating the first heating device 10. Specifically, drive the first water supply pump 55A, drive the first circulation pump, drive the first sub-circulation pump 13, and drive the refrigerant compressor of the heat pump 11.
During independent operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a first target temperature (e.g., 70°C).

[3] When the detected water level reaches or exceeds the set water level L2, water supply at the second flow rate and operation of the second heating device 20 are terminated. Specifically, the steam supply valve 26 is closed to stop the steam heater 25, and the second water supply pump 55B is stopped. The first water supply pump 55A continues to operate.

[4] When the detected water level falls below the set water level L3, start supplying water at the second flow rate and operating the second heating device 20. Specifically, drive the second feedwater pump 55B and open the steam supply valve 26 to operate the steam heater 25. The first feedwater pump 55A continues to be driven.
During the cooperative operation of the first heating device 10, the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a second target temperature (e.g., 80°C). Also, during the cooperative operation of the second heating device 20, the combustion amount of the burner of the hot water boiler 21 is adjusted so that the outlet temperature TB of the second sub-heat exchanger 22 converges to a third target temperature (e.g., 60°C). By raising the outlet temperature of the first heating device 10 (i.e., increasing the output ratio) and lowering the heat storage temperature TC by the second heating device 20 (i.e., decreasing the output ratio) more than in the first heating mode, it is possible to promote power consumption of the first heating device 10 while performing the cooperative operation.

Twelfth Embodiment
Next, a twelfth embodiment will be described. Fig. 12 is a diagram showing a schematic configuration of a hot water production system 1 in this embodiment. In this embodiment, the same components as those in the tenth embodiment are denoted by the same reference numerals, and the description thereof may be omitted.
The load equipment 200 in this embodiment directly uses the heated water W1 as cleaning water or the like (i.e., outputs heated water).

As shown in FIG. 12, the water supply line L50 of the hot water production system 1 of this embodiment is branched on the way, and multiple first heating devices 10 are arranged in parallel. The multiple first heating devices 10 arranged in parallel heat the water W1 flowing through the water supply line L50. In this embodiment, the first heating device group as the first heating device 10 is composed of the first unit 10A, the second unit 10B, and the third unit 10C. The second heating device 20 heats the water W1 as the stored water in the hot water tank 30, as in the tenth embodiment. Here, the configuration in which the multiple first heating devices 10 arranged in parallel heat the water W1 flowing through the heating target line (water supply line L50) is the same as in the sixth embodiment, so the description will be omitted. A water supply pump 55 whose rotation speed (drive frequency) can be inverter-controlled is installed in the water supply line L50. The water supply pump 55 supplies water at a first flow rate < second flow rate < third flow rate < fourth flow rate under inverter control. A flow meter 56 may be installed in the water supply line L50 to detect the flow rate through the water supply line L50.

The collective control of the first heating device group involves starting and stopping operation of all the devices at the same time, and the control of each heating mode conforms to the tenth embodiment. The control of the number of devices in the first heating device group follows the control explanation for each heating mode below. For example, the water level in the hot water tank 30 is detected and compared with the five set water levels "L1>L2>L3>L4>L5", and the water supply flow rate is adjusted in four stages. The control of the number of devices in the first heating device group increases or decreases the number of operating devices depending on the detected water level (i.e., the water supply flow rate).

Below, we explain examples of control of each heating mode by the operation control unit 120 in this embodiment.

<<Control of First Heating Mode: Control of the Number of First Heating Devices>>
As described above, when power demand adjustment is not performed, the first heating mode is selected by the heating mode selection unit 110. Hereinafter, an example of control by the operation control unit 120 in the first heating mode will be described.

[1] When the detected water level is equal to or higher than the set water level L1, the operation of the first heating device 10A (unit 1) is terminated and the feedwater pump is stopped. When the detected water level is lower than the set water level L2, the feedwater pump is driven at the first flow rate and the operation of the first heating device 10A (unit 1) is started. When the detected water level is equal to or higher than the set water level L2, the operation of the first heating device 10B (unit 2) is terminated and the feedwater pump is shifted from the second flow rate to the first flow rate. When the detected water level is lower than the set water level L3, the feedwater pump is shifted from the first flow rate to the second flow rate and the operation of the first heating device 10B (unit 2) is started. When the detected water level is equal to or higher than the set water level L3, the operation of the first heating device 10C (unit 3) is terminated and the feedwater pump is shifted from the third flow rate to the second flow rate. When the detected water level falls below the set water level L4, the feedwater pump is shifted from the second flow rate to the third flow rate, and operation of the first heating device 10C (Unit No. 3) is started.
During independent operation of the first heating device 10 (i.e., any one of units 1 to 3 is operating), the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a first target temperature (e.g., 70°C).

[2] When the detected water level is equal to or higher than the set water level L4, the operation of the second heating device 20 is terminated (the steam supply valve 26 is closed and the steam heater 25 is stopped) and the feedwater pump is shifted from the fourth flow rate to the third flow rate. When the detected water level is lower than the set water level L5, the feedwater pump is shifted from the third flow rate to the fourth flow rate and the operation of the second heating device 20 is started (the steam supply valve 26 is opened and the steam heater 25 is operated).
During the coordinated operation of the first heating device 10 (i.e., all of the first to third units are operating), the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the inlet/outlet temperature difference of the first sub-heat exchanger 12 converges to a first target temperature difference (e.g., 30°C). Also, during the coordinated operation of the second heating device 20, the opening of the steam supply valve 26 is adjusted so that the heat storage temperature TC of the hot water tank 30 converges to a first target temperature (e.g., 70°C).

<<Control of second heating mode A>>
As described above, the second heating mode is selected by the heating mode selection unit 110 when power demand adjustment for suppressing power consumption is performed. Hereinafter, an example of control by the operation control unit 120 in the second heating mode A will be described.

[1] In the second heating mode A, the target temperature of the hot water supply is increased to increase the amount of heat stored in the system. In this heating mode, there is no coordinated operation with the first heating device 10.

[2] When the detected water level is equal to or higher than the set water level L1, the operation of the second heating device 20 is terminated (the steam supply valve 26 is closed and the steam heater 25 is stopped). When the detected water level is lower than the set water level L4, the water supply pump is driven at the third flow rate and the operation of the second heating device 20 is started (the steam supply valve 26 is opened and the steam heater 25 is operated).
During the independent operation of the second heating device 20, the opening of the steam supply valve 26 of the steam heater 25 is adjusted so that the heat storage temperature TC of the hot water tank 30 converges to a second target temperature (e.g., 90°C). By making the heat storage temperature TC of the hot water tank 30 higher than in the first heating mode, the peak demand of the load equipment 200 is satisfied while continuing the independent operation that promotes fuel consumption of the second heating device 20. Since the load equipment 200 mixes high-temperature water and room-temperature water to adjust the temperature to an appropriate level, a higher heat storage temperature TC allows more hot water at the required temperature to be taken out.

<<Control of Third Heating Mode A: Control of the Number of Units in the First Heating Device Group>>
As described above, the third heating mode is selected by the heating mode selection unit 110 when power demand adjustment for promoting power consumption is performed. Hereinafter, an example of control by the operation control unit 120 in the third heating mode A will be described.

[1] In the third heating mode A, the target temperature of the hot water supply is increased to increase the amount of heat stored in the system. In this heating mode, there is no coordinated operation with the second heating device 20.

[2] When the detected water level is equal to or higher than the set water level L1, the operation of the first heating device 10A (unit 1) is terminated and the feedwater pump is stopped. When the detected water level is lower than the set water level L2, the feedwater pump is driven at the first flow rate and the operation of the first heating device 10A (unit 1) is started. When the detected water level is equal to or higher than the set water level L2, the operation of the first heating device 10B (unit 2) is terminated and the feedwater pump is shifted from the second flow rate to the first flow rate. When the detected water level is lower than the set water level L3, the feedwater pump is shifted from the first flow rate to the second flow rate and the operation of the first heating device 10B (unit 2) is started. When the detected water level is equal to or higher than the set water level L3, the operation of the first heating device 10C (unit 3) is terminated and the feedwater pump is shifted from the third flow rate to the second flow rate. When the detected water level falls below the set water level L4, the feedwater pump is shifted from the second flow rate to the third flow rate, and operation of the first heating device 10C (Unit No. 3) is started.
During independent operation of the first heating device 10 (i.e., any one of the first to third units is in operation), the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a second target temperature (e.g., 90°C). By setting the heat storage temperature TC of the hot water tank 30 higher than in the first heating mode, the peak demand of the load equipment 200 is satisfied while continuing independent operation that promotes power consumption of the first heating device 10. Since the load equipment 200 mixes high-temperature water and room-temperature water to adjust the temperature to an appropriate level, a higher heat storage temperature TC allows more hot water at the required temperature to be extracted.

<<Control of second heating mode B: Control of the number of first heating device group>>
As described above, the second heating mode is selected by the heating mode selection unit 110 when power demand adjustment for suppressing power consumption is performed. Hereinafter, an example of control by the operation control unit 120 in the second heating mode B will be described.

[1] When the detected water level is equal to or higher than the set water level L1, the operation of the second heating device 20 is terminated (the steam supply valve 26 is closed and the steam heater 25 is stopped) and the feedwater pump is stopped. When the detected water level is lower than the set water level L2, the feedwater pump is driven at the first flow rate and the operation of the second heating device 20 is started (the steam supply valve 26 is opened and the steam heater 25 is operated).
During independent operation of the second heating device 20, the opening of the steam supply valve 26 of the steam heater 25 is adjusted so that the outlet temperature TB of the second sub-heat exchanger 22 converges to the first target temperature (e.g., 70°C).

[2] When the detected water level is equal to or higher than the set water level L2, the operation of the first heating device 10A (unit 1) is terminated, and the feedwater pump is shifted from the second flow rate to the first flow rate. When the detected water level is lower than the set water level L3, the feedwater pump is shifted from the first flow rate to the second flow rate, and the operation of the first heating device 10A (unit 1) is started. When the detected water level is equal to or higher than the set water level L3, the operation of the first heating device 10B (unit 2) is terminated, and the feedwater pump is shifted from the third flow rate to the second flow rate. When the detected water level is lower than the set water level L4, the feedwater pump is shifted from the second flow rate to the third flow rate, and the operation of the first heating device 10B (unit 2) is started. When the detected water level is equal to or higher than the set water level L4, the operation of the first heating device 10C (unit 3) is terminated, and the feedwater pump is shifted from the fourth flow rate to the third flow rate. When the detected water level falls below the set water level L5, the feedwater pump is shifted from the third flow rate to the fourth flow rate, and operation of the first heating device 10C (Unit No. 3) is started.
During cooperative operation of the first heating device 10 (i.e., any one of the first to third units is operating), the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the inlet/outlet temperature difference of the first sub-heat exchanger 12 converges to a second target temperature difference (e.g., 25°C). Also, during cooperative operation of the second heating device 20, the opening degree of the steam supply valve 26 of the steam heater 25 is adjusted so that the heat storage temperature TC of the hot water tank 30 converges to a first target temperature (e.g., 70°C). By lowering the inlet/outlet temperature difference of the first heating device 10 compared to the first heating mode (i.e., lowering the output ratio), it is possible to suppress power consumption while performing cooperative operation with the second heating device 20.

<<Control of Third Heating Mode B: Control of the Number of Units in the First Heating Device Group>>
As described above, the third heating mode is selected by the heating mode selection unit 110 when power demand adjustment for promoting power consumption is performed. Hereinafter, an example of control by the operation control unit 120 in the third heating mode B will be described.

[1] When the detected water level is equal to or higher than the set water level L1, the operation of the first heating device 10A (unit 1) is terminated and the feedwater pump is stopped. When the detected water level is lower than the set water level L2, the feedwater pump is driven at the first flow rate and the operation of the first heating device 10A (unit 1) is started. When the detected water level is equal to or higher than the set water level L2, the operation of the first heating device 10B (unit 2) is terminated and the feedwater pump is shifted from the second flow rate to the first flow rate. When the detected water level is lower than the set water level L3, the feedwater pump is shifted from the first flow rate to the second flow rate and the operation of the first heating device 10B (unit 2) is started. When the detected water level is equal to or higher than the set water level L3, the operation of the first heating device 10C (unit 3) is terminated and the feedwater pump is shifted from the third flow rate to the second flow rate. When the detected water level falls below the set water level L4, the feedwater pump is shifted from the second flow rate to the third flow rate, and operation of the first heating device 10C (Unit No. 3) is started.
During independent operation of the first heating device 10 (i.e., any one of units 1 to 3 is operating), the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a first target temperature (e.g., 70°C).

[2] When the detected water level is equal to or higher than the set water level L4, the feedwater pump is shifted from the fourth flow rate to the third flow rate, and the operation of the second heating device 20 is terminated (the steam supply valve 26 is closed and the steam heater 25 is stopped). When the detected water level is lower than the set water level L3, the feedwater pump is shifted from the third flow rate to the fourth flow rate, and the operation of the second heating device 20 is started (the steam supply valve 26 is opened and the steam heater 25 is operated).
During coordinated operation of the first heating device 10 (i.e., all of units 1 to 3 are in operation), the rotation speed of the refrigerant compressor of the heat pump 11 is adjusted so that the outlet temperature TA of the first sub-heat exchanger 12 converges to a third target temperature difference (e.g., 35°C). Also, during coordinated operation of the second heating device 20, the combustion amount of the burner of the hot water boiler 21 is adjusted so that the outlet temperature TB of the second sub-heat exchanger 22 converges to a second target temperature (e.g., 70°C). By increasing the inlet/outlet temperature difference of the first heating device 10 more than in the first heating mode (i.e., increasing the output ratio), it is possible to promote power consumption while performing coordinated operation with the second heating device 20.

The hot water production system 1 according to the embodiment described above provides the following advantages:

(1) The hot water production system 1 is a hot water production system that heats water used in a load facility 200 in a business establishment, and includes a first heating device 10 that heats the water using an electric heat pump 11, a second heating device 20 that heats the water using a combustion boiler 21, a heating mode selection means 110 (heating mode selection unit 110) that selects one of a plurality of heating modes depending on whether or not power demand adjustment is performed, and a control means 120 (operation control unit 120) that controls the operation of the first heating device 10 and the second heating device 20 depending on the heating mode selected by the heating mode selection means 110. This makes it possible to provide a hot water production system 1 that can perform optimal water heating depending on whether or not power demand adjustment is performed while compensating for the shortcomings of an electric heat pump.

The system is configured to combine a first heating device 10 using an electric heat pump 11 with a second heating device 20 using a combustion boiler 21 (hot water boiler or steam boiler) and operate in one of a number of heating modes. By selecting the optimal heating mode depending on the power supply situation of the retail electricity supplier, VPP supplier, private power generation facility, etc., hot water can be produced stably.
Furthermore, the combustion boiler 21 has a larger heating capacity by combustion energy and a higher instantaneous heat output than the electric heat pump 11. Therefore, in the heating mode in which the first heating device 10 and the second heating device 20 are used in combination, it is possible to supply heat by taking advantage of the advantages of the electric heat pump 11 and the combustion boiler 21.

(2) In the hot water production system 1 of (1), the multiple heating modes include a first heating mode, a second heating mode A, and a third heating mode A, and the heating mode selection means 110 selects the first heating mode when power demand adjustment is not performed, selects the second heating mode A when power demand adjustment is performed to suppress power consumption, and selects the third heating mode A when power demand adjustment is performed to promote power consumption, and the control means 120 selects the first heating mode based on the hot water demand in the load equipment 200, the load Depending on the heat demand in the equipment 200 or the heat output of the first heating device 10, the first heating device 10 is operated independently, and the first heating device 10 and the second heating device 20 are operated in a coordinated manner. In the second heating mode A, the second heating device 20 is operated independently depending on the hot water demand in the load equipment 200 or the hot water demand in the load equipment 200. In the third heating mode A, the first heating device 10 is operated independently depending on the hot water demand in the load equipment 200 or the hot water demand in the load equipment 200.

In the first heating mode, hot water is produced by switching between independent operation of the first heating device 10 and cooperative operation (joint operation) of the first heating device 10 and the second heating device 20. During periods when electricity rates are set appropriately, the first heating device 10 is operated as a base load device and the second heating device 20 is operated as a peak load device, thereby improving the responsiveness of heat supply to changes in demand in the load equipment 200 and simultaneously minimizing running costs and _CO2 emissions.
In the second heating mode A, the second heating device 20 is operated alone to produce hot water. During periods of increased electricity rates, the second heating device 20 is operated as a base load device and a peak load device to limit power consumption by utilizing combustion energy, thereby allowing a temporary increase in _CO2 emissions while reducing running costs.
In the third heating mode A, the first heating device 10 is operated alone to produce hot water. During periods of reduced electricity rates, the first heating device 10 is operated as a base load device and a peak load device, and fuel consumption is limited by utilizing electric energy, thereby reducing running costs and _CO2 emissions at the same time.

(3) In the hot water production system 1 of (1), the multiple heating modes include a first heating mode, a second heating mode B, and a third heating mode B, and the heating mode selection means 110 selects the first heating mode when power demand adjustment is not performed, selects the second heating mode B when power demand adjustment is performed to suppress power consumption, and selects the third heating mode B when power demand adjustment is performed to promote power consumption, and the control means 120 switches between independent operation of the first heating device 10 and cooperative operation of the first heating device 10 and the second heating device 20 in accordance with the hot water demand in the load equipment 200, the heat demand in the load equipment 200, or the heat output of the first heating device 10 in the first heating mode, and switches between independent operation of the second heating device 20 and cooperative operation of the second heating device 20 and the first heating device 1 in accordance with the hot water demand in the load equipment 200 or the heat demand in the load equipment 200 in the second heating mode B. 0 cooperative operation, and in the cooperative operation of the second heating mode B, the electric heat pump 11 and the combustion boiler 21 are controlled so that the output ratio of the second heating device 20 to the total heat output of the first heating device 10 and the second heating device 20 is greater than the output ratio of the second heating device 20 in the cooperative operation of the first heating mode. In the third heating mode B, the first heating device 10 is switched between independent operation and the cooperative operation of the first heating device 10 and the second heating device 20 in accordance with the hot water demand in the load equipment 200 or the heat demand in the load equipment 200, and in the cooperative operation of the third heating mode B, the electric heat pump 11 and the combustion boiler 21 are controlled so that the output ratio of the first heating device 10 to the total heat output of the first heating device 10 and the second heating device 20 is greater than the output ratio of the first heating device 10 in the cooperative operation of the first heating mode.

In the first heating mode, hot water is produced by switching between independent operation of the first heating device 10 and cooperative operation (joint operation) of the first heating device 10 and the second heating device 20. During periods when electricity rates are set appropriately, the first heating device 10 is operated as a base load device and the second heating device 20 is operated as a peak load device, thereby improving the responsiveness of heat supply to changes in demand in the load equipment 200 and simultaneously minimizing running costs and _CO2 emissions.
In the second heating mode B, hot water is produced by switching between the independent operation of the second heating device 20 and the cooperative operation of the second heating device 20 and the first heating device 10. During the period of increasing electricity rates, the second heating device 20 is operated as a base load device and the first heating device 10 is operated as a peak load device, and the power consumption is limited by utilizing combustion energy, thereby allowing a temporary increase in _CO2 emissions and reducing running costs. In addition, in the cooperative operation of the second heating mode B, the output ratio of the second heating device 20, which is a base load device, is operated at a higher rate than in the first heating mode, and most of the heat is supplied by the combustion boiler 21 to the peak demand of the load equipment 200. On the other hand, the electric heat pump 11 is operated to supplement only a portion of the heat to the peak demand, so that the power consumption of the system can be minimized.
In the third heating mode B, hot water is produced by switching between independent operation of the first heating device 10 and cooperative operation of the first heating device 10 and the second heating device 20. During the period of lowering the price setting of electricity rates, the first heating device 10 is operated as a base load device and the second heating device 20 is operated as a peak load device, and fuel consumption is limited by utilizing electric energy, thereby reducing running costs and _CO2 emissions at the same time. In addition, in the cooperative operation of the third heating mode B, the output ratio of the first heating device 10, which is a base load device, is operated at a higher rate than in the first heating mode, and most of the heat is supplied by the electric heat pump 11 to the peak demand of the load equipment 200. On the other hand, the combustion boiler 21 is operated to supplement only a portion of the heat to the peak demand, so that the power consumption of the system can be maximized.

(4) In the hot water production system 1 of (1), the multiple heating modes include a first heating mode, a second heating mode B, and a third heating mode A, and the heating mode selection means 110 selects the first heating mode when power demand adjustment is not performed, selects the second heating mode B when power demand adjustment is performed to suppress power consumption, and selects the third heating mode A when power demand adjustment is performed to promote power consumption, and the control means 120 switches between independent operation of the first heating device 10 and cooperative operation of the first heating device 10 and the second heating device 20 in accordance with the hot water demand in the load equipment 200, the heat demand in the load equipment 200, or the heat output of the first heating device 10 in the first heating mode. In the second heating mode B, the second heating device 20 is operated independently and the second heating device 20 and the first heating device 10 are operated in cooperation with each other in response to the hot water demand in the load equipment 200 or the heat demand in the load equipment 200. In the cooperation operation in the second heating mode B, the electric heat pump 11 and the combustion boiler 21 are controlled so that the output ratio of the second heating device 20 to the total heat output of the first heating device 10 and the second heating device 20 is greater than the output ratio of the second heating device 20 in the cooperation operation in the first heating mode. In the third heating mode A, the first heating device 10 is operated independently in response to the hot water demand in the load equipment 200 or the heat demand in the load equipment 200.

In the first heating mode, hot water is produced by switching between independent operation of the first heating device 10 and cooperative operation (joint operation) of the first heating device 10 and the second heating device 20. During periods when electricity rates are set appropriately, the first heating device 10 is operated as a base load device and the second heating device 20 is operated as a peak load device, thereby improving the responsiveness of heat supply to changes in demand in the load equipment 200 and simultaneously minimizing running costs and _CO2 emissions.
In the second heating mode B, hot water is produced by switching between the independent operation of the second heating device 20 and the cooperative operation of the second heating device 20 and the first heating device 10. During the period of increasing electricity rates, the second heating device 20 is operated as a base load device and the first heating device 10 is operated as a peak load device, and the power consumption is limited by utilizing combustion energy, thereby allowing a temporary increase in CO2 emissions and reducing running costs. In addition, in the cooperative operation of the second heating mode B, the output ratio of the second heating device 20, which is a base load device, is increased compared to the first heating mode, and most of the heat is supplied by the combustion boiler 21 to the peak demand of the load equipment 200. On the other hand, the electric heat pump 11 is operated to supplement only a portion of the heat to the peak demand, so that the power consumption of the system can be minimized.
In the third heating mode A, the first heating device 10 is operated alone to produce hot water. During periods of reduced electricity rates, the first heating device 10 is operated as a base load device and a peak load device, and fuel consumption is limited by utilizing electric energy, thereby reducing running costs and _CO2 emissions at the same time.

(5) In the hot water production system 1 of (1), the multiple heating modes include a first heating mode, a second heating mode A, and a third heating mode B, and the heating mode selection means 110 selects the first heating mode when power demand adjustment is not performed, selects the second heating mode A when power demand adjustment is performed to suppress power consumption, and selects the third heating mode B when power demand adjustment is performed to promote power consumption, and the control means 120 switches between independent operation of the first heating device 10 and cooperative operation of the first heating device 10 and the second heating device 20 in accordance with the hot water demand in the load equipment 200, the heat demand in the load equipment 200, or the heat output of the first heating device 10 in the first heating mode. In the second heating mode A, the second heating device 20 is operated independently in response to the hot water demand in the load equipment 200 or the heat demand in the load equipment 200, and in the third heating mode B, the first heating device 10 is operated independently and the first heating device 10 and the second heating device 20 are switched between cooperative operation in response to the hot water demand in the load equipment 200 or the heat demand in the load equipment 200, and in the cooperative operation of the third heating mode B, the electric heat pump 11 and the combustion boiler 21 are controlled so that the output ratio of the first heating device 10 to the total heat output of the first heating device 10 and the second heating device 20 is greater than the output ratio of the first heating device 10 in the cooperative operation of the first heating mode.

In the first heating mode, hot water is produced by switching between independent operation of the first heating device 10 and cooperative operation (joint operation) of the first heating device 10 and the second heating device 20. During periods when electricity rates are set appropriately, the first heating device 10 is operated as a base load device and the second heating device 20 is operated as a peak load device, thereby improving the responsiveness of heat supply to changes in demand in the load equipment 200 and simultaneously minimizing running costs and _CO2 emissions.
In the second heating mode A, the second heating device 20 is operated alone to produce hot water. During periods of increased electricity rates, the second heating device 20 is operated as a base load device and a peak load device to limit power consumption by utilizing combustion energy, thereby allowing a temporary increase in _CO2 emissions while reducing running costs.
In the third heating mode B, hot water is produced by switching between independent operation of the first heating device 10 and cooperative operation of the first heating device 10 and the second heating device 20. During the period of lowering the price setting of electricity rates, the first heating device 10 is operated as a base load device and the second heating device 20 is operated as a peak load device, and fuel consumption is limited by utilizing electric energy, thereby reducing running costs and CO2 emissions at the same time. In addition, in the cooperative operation of the third heating mode B, the output ratio of the first heating device 10, which is a base load device, is operated at a higher rate than in the first heating mode, and most of the heat is supplied by the electric heat pump 11 to the peak demand of the load equipment 200. On the other hand, the combustion boiler 21 is operated to supplement only a portion of the heat to the peak demand, so that the power consumption of the system can be maximized.

(6) In the hot water production system 1 of (2) or (5), the control means 120 controls the combustion boiler 21 so that the heat output of the second heating device 20 in the second heating mode A is greater than the heat output of the second heating device 20 in the first heating mode.

In the cooperative operation of the first heating mode, the combustion boiler 21 is operated at a predetermined output point to produce hot water at about 50 to 70°C. On the other hand, in the independent operation of the second heating mode A, in order to prioritize the consumption of fuel instead of electricity, the combustion boiler 21 is operated at a higher output point to produce hot water at about 80 to 90°C. By actively converting fuel that can be purchased stably from the market into high-temperature thermal energy and storing it in the hot water tank 30, even in the independent operation of the second heating device 20, it is possible to flexibly and stably respond not only to the base demand of the load equipment 200 but also to peak demand. When using high-temperature water in the load equipment 200, hot water of the required temperature can be obtained by mixing the high-temperature water with room-temperature water or by heat exchanging the high-temperature water with room-temperature water.

(7) In the hot water production system 1 of (2) or (4), the control means 120 controls the electric heat pump 11 so that the heat output of the first heating device 10 in the third heating mode A is greater than the heat output of the first heating device 10 in the first heating mode.

In the independent and cooperative operation of the first heating mode, the electric heat pump 11 is driven at a predetermined output point to produce hot water at about 50 to 70°C. On the other hand, in the third heating mode A, in order to consume surplus electricity generated by the power supply source, the electric heat pump 11 is driven at a higher output point to produce hot water at about 80 to 90°C. By actively converting surplus electricity on the market into high-temperature thermal energy and storing it in the hot water tank 30, even in the independent operation of the first heating device 10, it is possible to flexibly and stably respond to not only the base demand of the load equipment 200 but also peak demand. When using high-temperature water in the load equipment 200, hot water of the required temperature can be obtained by mixing the high-temperature water with room-temperature water or by heat exchanging the high-temperature water with room-temperature water.

(8) In the hot water production system 1 of (1), the second heating device 20 heats the water by exchanging heat between the steam generated in the combustion boiler 21 and the water.

The combustion boiler 21 constituting the second heating device 20 can be a hot water boiler or a steam boiler. When a steam boiler is used as the heat source, the steam and the water are indirectly or directly heat exchanged to heat the water. For example, when using steam with an absolute pressure of 0.3 MPa to 2 MPa generated by a small once-through steam boiler, the saturation temperature reaches 150 to 215°C, so that the heating operation time can be shortened even when producing hot water at 80 to 90°C. As a result, the increase in _CO2 emissions is suppressed.

(9) In the hot water production system 1 of (1), the combustion boiler 21 uses a fuel selected from hydrocarbons, hydrogen, and ammonia.

Hydrocarbon gases mainly composed of methane (city gas 13A, biogas, etc.), hydrocarbon gases mainly composed of propane, hydrogen gas, and ammonia gas can be used as gas fuels for the combustion boiler 21. In addition, as oil fuels for the combustion boiler 21, kerosene, light oil, heavy oil containing hydrocarbons, as well as bioethanol with adjusted moisture content can also be used.
When hydrogen gas or ammonia gas is used, there is an advantage that a decarbonized system that takes environmental conservation into consideration can be constructed since no _CO2 is generated by combustion. When biomethane or bioethanol is used, a carbon-neutral system can be constructed, although _CO2 is generated by combustion.

The above describes a preferred embodiment of the hot water production system of the present invention, but the present invention is not limited to the above-mentioned embodiment and can be modified as appropriate. The present invention also includes a combination of two or more of the individual configurations of the above-mentioned embodiments.

1 Hot water production system 10 First heating device 11 Heat pump 12 First sub-heat exchanger 20 Second heating device 21 Combustion boiler (hot water boiler)
22 Second sub-heat exchanger 30 Hot water tank 31 Water level sensor 40 Temperature sensor 100 Control unit 110 Heating mode selection unit (heating mode selection means)
120 Operation control unit (control means)
200 Load equipment L10 Water distribution line L20 Water return line L21 First heating target line L22 Second heating target line L30 Circulation line L31 First circulation line L32 Second circulation line L50 Water supply line L51 First water supply line L52 Second water supply line

Claims (7)

A hot water production system that heats water used in load equipment within a business establishment,
a first heating device that heats water by an electric heat pump;
A second heating device that heats the water by a combustion boiler;
a heating mode selection means for selecting one of a plurality of heating modes including at least a first heating mode and a third heating mode depending on whether or not power demand adjustment is being performed;
a control means for controlling operation of the first heating device and the second heating device in accordance with the heating mode selected by the heating mode selection means,
The load facility generates a demand for hot water by directly using heated water,
The heating mode selection means includes:
When power demand regulation is not performed, the first heating mode is selected;
Selecting the third heating mode when implementing power demand adjustment that promotes power consumption more than when the first heating mode is selected;
The control means
Detecting a demand for hot water of the load equipment based on a water level of a hot water tank attached to the load equipment or a flow rate of makeup water, and operating the first heating device and the second heating device in response to the detected demand for hot water;
In the first heating mode, the first heating device is a base load device and the second heating device is a peak load device, and switching is performed between an independent operation of the first heating device and a coordinated operation of the first heating device and the second heating device, thereby making the hot water supply follow the change in the hot water demand of the load equipment;
In the third heating mode, the first heating device is operated independently as a base load device and a peak load device, and the electric heat pump is controlled so that the heat output of the first heating device in the third heating mode is greater than the heat output of the first heating device in the first heating mode, thereby allowing the hot water supply to follow changes in hot water demand of the load equipment.
Hot water production system. A hot water production system that heats water used in load equipment within a business establishment,
a first heating device that heats water by an electric heat pump;
A second heating device that heats the water by a combustion boiler;
a heating mode selection means for selecting one of a plurality of heating modes including at least a first heating mode and a third heating mode depending on whether or not power demand adjustment is being performed;
a control means for controlling operation of the first heating device and the second heating device in accordance with the heating mode selected by the heating mode selection means,
The load facility generates a demand for hot water by directly using heated water,
The heating mode selection means includes:
When power demand regulation is not performed, the first heating mode is selected;
Selecting the third heating mode when implementing power demand adjustment that promotes power consumption more than when the first heating mode is selected;
The control means
Detecting a demand for hot water of the load equipment based on a water level of a hot water tank attached to the load equipment or a flow rate of makeup water, and operating the first heating device and the second heating device in response to the detected demand for hot water;
In the first heating mode, the first heating device is a base load device and the second heating device is a peak load device, and switching is performed between an independent operation of the first heating device and a coordinated operation of the first heating device and the second heating device, thereby making the hot water supply follow the change in the hot water demand of the load equipment;
In the third heating mode, the first heating device is a base load device and the second heating device is a peak load device, and switching is performed between an independent operation of the first heating device and a coordinated operation of the first heating device and the second heating device, and in the coordinated operation of the third heating mode, the electric heat pump and the combustion boiler are controlled so that the output ratio of the first heating device to the total heat output of the first heating device and the second heating device is greater than the output ratio of the first heating device in the coordinated operation of the first heating mode, thereby allowing the hot water supply to follow changes in hot water demand of the load equipment.
Hot water production system. A hot water production system that heats water used in load equipment within a business establishment,
a first heating device that heats water by an electric heat pump;
A second heating device that heats the water by a combustion boiler;
a heating mode selection means for selecting one of a plurality of heating modes including at least a first heating mode and a third heating mode depending on whether or not power demand adjustment is being performed;
a control means for controlling operation of the first heating device and the second heating device in accordance with the heating mode selected by the heating mode selection means,
The load equipment generates heat demand by indirectly using heated water,
The heating mode selection means includes:
When power demand regulation is not performed, the first heating mode is selected;
Selecting the third heating mode when implementing power demand adjustment that promotes power consumption more than when the first heating mode is selected;
The control means
Detecting the heat demand of the load equipment based on the return temperature of the hot water in a hot water loop system formed for the load equipment or the difference between the supply temperature and the return temperature of the hot water in the hot water loop system, and operating the first heating device and the second heating device in response to the detected heat demand;
In the first heating mode, the first heating device is a base load device and the second heating device is a peak load device, and the first heating device is operated independently, and the first heating device and the second heating device are operated in a coordinated manner. In this manner, the heat supply is made to follow the change in the heat demand of the load equipment.
In the third heating mode, the first heating device is operated independently as a base load device and a peak load device, and the electric heat pump is controlled so that the heat output of the first heating device in the third heating mode is greater than the heat output of the first heating device in the first heating mode, thereby making the heat supply follow the change in the heat demand of the load equipment.
Hot water production system. A hot water production system that heats water used in load equipment within a business establishment,
a first heating device that heats water by an electric heat pump;
A second heating device that heats the water by a combustion boiler;
a heating mode selection means for selecting one of a plurality of heating modes including at least a first heating mode and a third heating mode depending on whether or not power demand adjustment is being performed;
a control means for controlling operation of the first heating device and the second heating device in accordance with the heating mode selected by the heating mode selection means,
The load equipment generates heat demand by indirectly using heated water,
The heating mode selection means includes:
When power demand regulation is not performed, the first heating mode is selected;
Selecting the third heating mode when implementing power demand adjustment that promotes power consumption more than when the first heating mode is selected;
The control means
Detecting the heat demand of the load equipment based on the return temperature of the hot water in a hot water loop system formed for the load equipment or the difference between the supply temperature and the return temperature of the hot water in the hot water loop system, and operating the first heating device and the second heating device in response to the detected heat demand;
In the first heating mode, the first heating device is a base load device and the second heating device is a peak load device, and the first heating device is operated independently, and the first heating device and the second heating device are operated in a coordinated manner. In this manner, the heat supply is made to follow the change in the heat demand of the load equipment.
In the third heating mode, the first heating device is a base load device and the second heating device is a peak load device, and switching is performed between an independent operation of the first heating device and a coordinated operation of the first heating device and the second heating device, and in the coordinated operation of the third heating mode, the electric heat pump and the combustion boiler are controlled so that the output ratio of the first heating device to the total heat output of the first heating device and the second heating device is greater than the output ratio of the first heating device in the coordinated operation of the first heating mode, thereby allowing the supply of hot heat to follow changes in the hot heat demand of the load equipment.
Hot water production system. The control means
Detecting a heat output of the first heating device based on a temperature of hot water discharged from the first heating device during operation;
In the first heating mode, switching between an independent operation of the first heating device and a coordinated operation of the first heating device and the second heating device is performed according to a heat output of the first heating device.
The hot water producing system according to any one of claims 1 to 4. A steam boiler is used as the combustion boiler constituting the second heating device, and the water is heated by direct or indirect heat exchange between the steam and the water.
The hot water producing system according to any one of claims 1 to 4. The combustion boiler uses a fuel selected from hydrogen, ammonia, biomethane, and bioethanol.
The hot water producing system according to any one of claims 1 to 4.

Images