JP7508386B2 - Hybrid hot water heating system - Google Patents

Description

This invention relates to a hybrid hot water heating system having a refrigerant circulation circuit with a compressor and a hot water circulation circuit with a gas heater.

In this type of heating system, as described in Patent Document 1, a heat exchanger that exchanges heat with a refrigerant circulation circuit equipped with a compressor and a heat exchanger that exchanges heat with a hot water circulation circuit through which hot water heated by a gas heater flows have been provided in a load side circuit equipped with a load terminal, and the system has been configured to be able to receive heat from both the refrigerant side and the hot water side.

JP 2020-159663 A

For example, when used in cold regions, if heating operation is not performed for a long period of time during the harsh winter, snow accumulation may cause freezing in the refrigerant circulation circuit (particularly the air heat exchanger). The above conventional system did not take such freezing into consideration, and no method for defrosting the ice was disclosed.

In order to solve the above problems, in a first aspect of the present invention, a gas heater, a first heat source side heat exchanger that receives heat from the gas heater, and a first load side heat exchanger are connected by hot water piping to form a hot water circulation circuit, a compressor, a second heat source side heat exchanger that can exchange heat with outside air, a pressure reducing means, and a second load side heat exchanger are connected by refrigerant piping to form a refrigerant circulation circuit, the first load side heat exchanger, the second load side heat exchanger, and at least one load terminal are connected by circulating liquid piping so that the second load side heat exchanger is disposed in series upstream of the first load side heat exchanger to form a load side circuit, and a control means is provided to control at least the compressor and the gas heater. In this hybrid hot water heating system, the system has an operation means that can execute a defrosting command when freezing occurs in the refrigerant circulation circuit, and when the defrosting command is issued via the operation means, the control means communicates an inlet side of the second heat source side heat exchanger that functions as a condenser with a discharge side of the compressor. and a de-icing operation is performed in which heat received by the refrigerant in the second load side heat exchanger is supplied to the second heat source side heat exchanger by connecting an outlet side of the second heat source side heat exchanger functioning as a condenser to an inlet side of the second load side heat exchanger whose outlet side is connected to the suction side of the compressor, and the compressor is controlled to start compressing the refrigerant in the refrigerant piping and the gas heater is controlled to start heating the hot water in the hot water piping, and the control means has a first mode in which, when a predetermined temperature index is within a first range during the de-icing operation, the control means controls the gas heater and the compressor to heat the hot water in the hot water piping and compress the refrigerant in the refrigerant piping, and a second mode in which, when the temperature index is within a second range that is higher than the first range, the control means controls the compressor to compress the refrigerant in the refrigerant piping without heating the hot water in the hot water piping .

In addition, in claim 2 , the load side circuit further has a forward temperature detection means for detecting a circulating fluid temperature in the circulating fluid piping flowing out from the second load side heat exchanger or the first load side heat exchanger, and the control means switches to either the first mode or the second mode depending on whether the circulating fluid temperature detected by the forward temperature detection means as the temperature indicator is within the first range or the second range.

In a third aspect of the present invention , the first range is a temperature range in which condensation occurs in the load side circuit, and the second range is a temperature range in which condensation does not occur in the load side circuit.

In addition, in claim 4 , the control means terminates operation of the compressor and the gas heater when a predetermined first operation termination condition is satisfied in the operating state of the compressor and the gas heater in the first mode, and terminates operation of the compressor when a predetermined second operation termination condition is satisfied in the operating state of the compressor in the second mode.

In addition, in claim 5 , the control means forcibly stops operation of the compressor and the gas heater when a predetermined operation stop condition is satisfied in the operating state of the compressor and the gas heater in the first mode.

In addition, in claim 6 , the control means controls the opening degree of the pressure reduction means to a first opening degree in the first mode, and controls the opening degree of the pressure reduction means to a second opening degree larger than the first opening degree in the second mode.

According to claim 1 of this invention, a load side circuit capable of supplying circulating fluid to a load terminal and a refrigerant circulation circuit capable of exchanging heat with outside air are provided, and heating operation can be performed via the load terminal by heating the circulating fluid using heat absorption from the outside air. That is, in the refrigerant circulation circuit, the refrigerant that has exchanged heat with the outside air in the second heat source side heat exchanger and evaporated and absorbed heat is guided to the compressor and compressed to a high temperature and high pressure, and then guided to the second load side heat exchanger where it condenses while releasing heat. As a result, the circulating fluid in the load side circuit is heated, and the heated circulating fluid is guided to the load terminal for heating.

For example, in the harsh winter, freezing may occur in the refrigerant circulation circuit (for example, the second heat source side heat exchanger that exchanges heat with the outside air) due to the effects of wind and snow. In the present invention, in response to this, when a defrosting command is issued, defrosting operation is performed. That is, in the refrigerant circulation circuit, the refrigerant that exchanges heat with the load side circuit in the second load side heat exchanger functioning as an evaporator and evaporates and receives heat is introduced to the compressor and compressed to a high temperature and high pressure, and then introduced to the second heat source side heat exchanger functioning as a condenser where it condenses while releasing heat. The heat released at this time can melt the ice that has formed as described above.

During the defrosting operation, the second heat source heat exchanger dissipates heat by receiving heat from the load circuit in the second load heat exchanger, but there is a limit to the heat that can be obtained from the load circuit. In addition, when freezing occurs, it is assumed that a state in which heating operation is not performed has continued for a long period of time, and the temperature of the circulating fluid in the load circuit is originally relatively low. As a result, if left as is, the second heat source heat exchanger will not be able to dissipate heat sufficiently, and defrosting may become difficult.

In the present invention, during the defrosting operation, the control means controls the gas heater to start heating the hot water in the hot water pipe. This allows the first load heat exchanger to dissipate heat from the hot water to the load circuit, increasing the amount of heat received by the load circuit in the first load heat exchanger and raising the temperature of the circulating liquid circulating in the load circuit. As a result, the amount of heat received by the refrigerant from the load circuit in the second load heat exchanger is increased, allowing sufficient heat to be dissipated in the second heat source heat exchanger, ensuring reliable defrosting.

In addition, when performing the defrosting operation as described above, depending on the temperature environment, it may be possible to melt the ice only by receiving heat from the refrigerant circulation circuit from the load side circuit, without heating the hot water with the gas heater. In such a case, starting heating with the gas heater will lead to an unnecessary increase in running costs. Therefore, in claim 1 of the present invention, the control means has two control modes: a first mode in which both the compressor of the refrigerant circulation circuit compresses the refrigerant and the gas heater heats it, and a second mode in which only the compressor compresses the refrigerant without heating the gas heater. Then, when the temperature index is within a first range on the low temperature side, control is performed in the first mode, while when the temperature index is within a second range on the high temperature side, control is performed in the second mode. This makes it possible to reduce running costs by avoiding heating with the gas heater as much as possible in a relatively high temperature environment.

According to claim 2 , the temperature of the circulating fluid flowing out from the second load side heat exchanger or the first load side heat exchanger (so-called forward temperature) is used as the temperature index. When the circulating fluid temperature detected by the forward temperature detection means is within a second range on the high temperature side, it is deemed that heating by the gas heater is not necessarily required, and control is performed in the second mode. On the other hand, when the detected circulating fluid temperature is within a first range on the low temperature side, it is deemed that heating by the gas heater is required, and control is performed in the first mode. This makes it possible to reliably prevent heating by the gas heater from being performed in a high temperature environment.

According to claim 3 , a first range and a second range are set depending on whether condensation occurs in the load side circuit. As a result, when the temperature index is within the first range where condensation may occur, heating is performed by the gas heater in the first mode, whereas when the temperature index is within the second range where condensation does not occur, heating by the gas heater is not performed in the second mode. In this way, by not performing heating by the gas heater as much as possible until the very last moment when condensation occurs, it is possible to reliably reduce running costs.

According to claim 4 , when a first operation end condition is satisfied during operation in a first mode in which the compressor compresses the refrigerant and the gas heater heats the refrigerant, the operation of the compressor and the gas heater is terminated. Similarly, when a second operation end condition is satisfied during operation in a second mode in which the compressor only compresses the refrigerant, the operation of the compressor is terminated. This makes it possible to reliably terminate operation in response to the melting of the ice.

According to claim 5 , when the compressor and the gas heater are operating in the first mode and a predetermined operation stop condition is satisfied, their operation is forcibly stopped. This makes it possible to avoid further wasteful operation in cases where the ice does not melt even after a certain amount of ice-melting operation due to a malfunction in any part of the system or an abnormal amount of ice has formed.

According to claim 6 , the pressure reducing means is narrowed to a smaller opening in the first mode in which heating is performed by the gas heater than in the second mode in which heating is not performed by the gas heater. This increases the discharge temperature of the refrigerant from the compressor in the first mode, thereby increasing the amount of heat dissipation and enabling quick defrosting.

An overall circuit configuration diagram of a hybrid hot water heating system according to an embodiment of the present invention. A diagram explaining the operation of a heat pump during heating only operation Diagram explaining operation during gas-only heating operation Diagram explaining operation during heat pump/gas heating operation Functional diagram of heat pump control device Functional diagram of heat exchange unit control device Functional diagram of boiler control device Diagram explaining operation during defrosting operation (heat pump/gas) Diagram explaining operation during defrosting operation (heat pump only) FIG. 1 is a flowchart showing a control procedure executed by the heat exchange unit control device, the heat pump control device, and the boiler control device in cooperation with each other during defrosting operation.

One embodiment of the present invention will be described below with reference to Figures 1 to 10.

This embodiment is an embodiment in which the present invention is applied to a combined heat source type hybrid hot water heating system.

<Overall circuit configuration>
The overall circuit configuration of the hybrid hot water heating system 1 of this embodiment is shown in Fig. 1. As shown in Fig. 1, the hybrid hot water heating system 1 includes a heat exchange unit 4A, a gas heating water heater unit 4B, and a heat pump unit 5. The hybrid hot water heating system 1 includes a terminal circulation circuit 30 as a load side circuit for circulating a circulating liquid L (e.g., water or antifreeze) to a heat exchange terminal 36 (corresponding to a load terminal), a hot water circulation circuit 40 provided in the heat exchange unit 4A and the gas heating water heater unit 4B and capable of heating the circulating liquid L on the heat exchange terminal 36 side by using a heat source by gas heating, and a refrigerant circulation circuit 50 provided in the heat pump unit 5 and capable of heating or cooling the circulating liquid L on the heat exchange terminal 36 side by using an air heat source.

<Hot water circulation circuit>
The hot water circulation circuit 40 includes a variable output gas heater (a combustion heater that heats with combustion gas of gas or liquid fuel, a so-called burner) 43, a first heat exchanger 41 as the first load side heat exchanger, a heating heat exchanger 45 as the first heat source side heat exchanger, and a hot water circulation pump 44, all connected in a ring shape by hot water piping 42.

The first heat exchanger 41 is, for example, a plate-type heat exchanger. This plate-type heat exchanger is made up of a plurality of heat transfer plates stacked together, with refrigerant flow paths for circulating hot water C1 (e.g., water or antifreeze; see Figures 3, 4, 8, etc.) and fluid flow paths for circulating the circulating liquid L alternately formed on either side of each heat transfer plate.

The heating heat exchanger 45 receives heat from the gas heater 43 to heat the hot water in the hot water pipe 42. At this time, a hot water heat exchanger 46 is provided so as to be able to receive heat from the gas heater 43, just like the heating heat exchanger 45. City water is supplied from the outside to the water pipe 47 provided in the hot water heat exchanger 46, and the hot water heated by the heat received from the gas heater 43 is supplied to a hot water tap 48 connected to the water pipe 47. In other words, the gas heater 43, the heating heat exchanger 45, and the hot water heat exchanger 46 constitute a so-called boiler.

The temperature of the hot water C1 discharged from the gas heater 43 is detected by the boiler feed temperature sensor 42a, and the detection result is input to the boiler control device 63. A remote control 60 is also connected to the boiler control device 63, and the heating capacity of the gas heater 43 can be adjusted by manually operating the remote control 60.

<Refrigerant Circulation Circuit>
The refrigerant circulation circuit 50 includes a variable capacity compressor 53, a second heat exchanger 51 as a second load-side heat exchanger, an expansion valve 54 as a pressure reducing means, and an air heat exchanger 55 as a second heat source-side heat exchanger configured to be able to exchange heat with outside air, which are connected in a ring shape by refrigerant piping 52. The refrigerant piping 52 is provided with a four-way valve 58 as a switching valve that switches the flow direction of the refrigerant C2 (see Figures 2, 4, 8, 9, etc. described later) in the refrigerant circulation circuit 50. The air heat exchanger 55 is also provided with a blower fan 56.

The second heat exchanger 51 is, as described above, for example a plate-type heat exchanger, in which the refrigerant flow path for the refrigerant C2 and the fluid flow path for the circulating liquid L are alternately formed on each heat transfer plate.

The temperature of the refrigerant C2 discharged from the compressor 53 is detected by the refrigerant discharge temperature sensor 52a. Similarly, the temperature of the refrigerant C2 on the low pressure side (when heating) or high pressure side (when cooling) is detected by the refrigerant temperature sensor 52b installed in the refrigerant piping 52 from the expansion valve 54 to the air heat exchanger 55. Furthermore, the temperature of the outside air is detected by, for example, an outside air temperature sensor 57 installed in the air heat exchanger 55 or in its vicinity. The detection results of the refrigerant discharge temperature sensor 52a, the refrigerant temperature sensor 52b, and the outside air temperature sensor 57 are input to the heat pump control device 62. A remote control 60 is also connected to the heat pump control device 62 so that the capacity of the refrigerant circulation circuit 50 can be adjusted by manually operating the remote control 60 (details will be described later).

The refrigerant C2 in the refrigerant circulation circuit 50 can be any refrigerant, such as an HFC refrigerant such as R410A or R32, or a carbon dioxide refrigerant.

<Terminal circulation circuit>
In the terminal circulation circuit 30, the first heat exchanger 41, the second heat exchanger 51, and at least one heat exchange terminal 36 are connected in a ring shape in order from the upstream side by the load pipe 31 as a circulating fluid pipe. Examples of the heat exchange terminal 36 include a floor heating panel, a heating panel, a hot/cold water panel, a radiator, a fan coil, and a panel convector. In the illustrated example, one floor heating panel is connected. The load pipe 31 is provided with a circulating fluid circulation pump 32 that circulates the circulating fluid L in the terminal circulation circuit 30, and a pressure adjustment tank (not shown) that stores the circulating fluid L and adjusts the pressure of the terminal circulation circuit 30. The heat exchange terminal 36 can be operated by a terminal remote control (not shown). Although one heat exchange terminal 36 is provided in FIG. 1, two or more heat exchange terminals may be provided, and the number and specifications are not particularly limited.

At this time, in the terminal circulation circuit 30, the first heat exchanger 41 and the second heat exchanger 51 are connected in series, and as described above, the second heat exchanger 51 is arranged upstream of the first heat exchanger 41 with respect to the flow of the circulating liquid L circulating in the terminal circulation circuit 30. In other words, the hybrid hot water heating system 1 is a combined heat source heat pump device in which the first heat exchanger 41 of the hot water circulation circuit 40, which can heat the circulating liquid L on the heat exchange terminal 36 side by using a heat source by gas heating, and the second heat exchanger 51 of the refrigerant circulation circuit 50, which uses an air heat source to heat or cool the circulating liquid L on the heat exchange terminal 36 side, are connected in series to the terminal circulation circuit 30.

The load pipe 31 is provided with a return temperature sensor 34 that detects the temperature of the circulating fluid L flowing from the heat exchange terminal 36 into the second heat exchanger 51, a second forward temperature sensor 35 that detects the temperature of the circulating fluid L flowing from the second heat exchanger 51 to the first heat exchanger 41 side, and a first forward temperature sensor 33 that detects the temperature of the circulating fluid L flowing from the first heat exchanger 41 to the heat exchange terminal 36 side. The detection result of the first forward temperature sensor 33 is input to the heat exchange unit control device 61. The detection results of the return temperature sensor 34 and the second forward temperature sensor 35 are input to the heat pump control device 62. The heat pump control device 62 receives an operation signal from the operation unit 70, which will be described later.

The heat pump control device 62, the heat exchange unit control device 61, and the boiler control device 63 are connected to each other so that they can transmit and receive information, and can share the detection results of each sensor input as described above with each other.

<Heating operation>
Here, the hybrid hot water heating system 1 can selectively function as a heating device performing a heating operation or as a cooling device performing a cooling operation by switching the four-way valve 58. In particular, in the case of heating operation, three types of heating operation can be selectively performed: a heating operation in which the circulating liquid L is heated only by using the air heat source via the refrigerant circulation circuit 50 (hereinafter, appropriately, referred to as "HP only heating operation"), a heating operation in which the circulating liquid L is heated only by using the heat source by gas heating via the hot water circulation circuit 40 (hereinafter, appropriately, referred to as "gas only heating operation"), and a heating operation in which the circulating liquid L is heated by both the air heat source via the refrigerant circulation circuit 50 and the heat source by gas heating via the hot water circulation circuit 40 (hereinafter, appropriately, referred to as "HP/gas heating operation").

<HP independent heating operation>
FIG. 2 shows the state during HP-only heating operation. In order to prevent the illustration from becoming complicated, various signal lines shown in FIG. 1 are omitted. During HP-only heating operation shown in FIG. 2, the four-way valve 58 is switched in the refrigerant circulation circuit 50 as shown in the figure, so that the refrigerant C2 discharged from the compressor 53 flows through the second heat exchanger 51, the expansion valve 54, and the air heat exchanger 55 in this order, and then a flow path is formed that returns to the compressor 53. As a result, the refrigerant C2 in a gas state sucked at a low temperature and low pressure is compressed by the compressor 53 to become a high-temperature and high-pressure gas, and then exchanges heat with the circulating liquid L flowing through the terminal circulation circuit 30 in the second heat exchanger 51 that functions as a condenser, heating the circulating liquid L and changing it into a high-pressure liquid. The refrigerant C2 that has become liquid in this way is reduced in pressure in the expansion valve 54, becoming a low-pressure liquid that is easy to evaporate, and in the air heat exchanger 55, which functions as an evaporator, it exchanges heat with the air sent by the operation of the blower fan 56, evaporates and turns into gas, absorbing heat, and then returns to the compressor 53 as a low-temperature, low-pressure gas.

At this time, in the terminal circulation circuit 30, the circulating liquid L flowing into the second heat exchanger 51 by the circulating liquid circulation pump 32 receives heat in the second heat exchanger 51, which functions as an evaporator, by exchanging heat with the outside air in the air heat exchanger 55 and exchanging heat with the refrigerant C2 heated as described above. The circulating liquid L thus heated is then supplied to the heat exchange terminal 36 to heat the conditioned space.

In the above, heating operation has been described as an example, but if a terminal capable of cooling is used as the heat exchange terminal 36, the four-way valve 58 can be switched to form a flow path that causes the refrigerant C2 discharged from the compressor 53 to flow through the air heat exchanger 55, the expansion valve 54, and the second heat exchanger 51 in that order, and then return it to the compressor 53, thereby allowing cooling operation to be performed (detailed description omitted).

<Gas only heating operation>
Fig. 3 shows the state during gas-only heating operation. As described above, various signal lines shown in Fig. 1 are omitted. During gas-only heating operation shown in Fig. 3, hot water C1 flowed into the heating heat exchanger 45 by the hot water circulation pump 44 is heated by the thermal power of the gas heater 43 in the heating heat exchanger 45 and becomes high temperature. After that, the hot water C1, which has become high temperature, exchanges heat with the circulating liquid L flowing through the terminal circulation circuit 30 in the first heat exchanger 41 to heat the circulating liquid L and lower its temperature, and then returns to the heating heat exchanger 45 again.

At this time, in the terminal circulation circuit 30, the circulating fluid L flowing into the first heat exchanger 41 by the circulating fluid circulation pump 32 receives heat in the first heat exchanger 41 through heat exchange with the hot water C1 heated as described above by the gas heater 43. The circulating fluid L thus heated is then supplied to the heat exchange terminal 36 to heat the conditioned space.

<HP/Gas heating operation>
Fig. 4 shows the state during HP/gas heating operation. As described above, the various signal lines shown in Fig. 1 are omitted. During HP/gas heating operation shown in Fig. 4, both the heating of the refrigerant C2 by the air heat exchanger 55 in the refrigerant circulation circuit 50 described with reference to Fig. 2 and the heating of the hot water C1 by the gas heater 43 in the hot water circulation circuit 40 described with reference to Fig. 3 are performed.

In the terminal circulation circuit 30, the circulating liquid L flowing into the second heat exchanger 51 by the circulating liquid circulation pump 32 receives heat by exchanging heat with the refrigerant C2 heated as described above in the second heat exchanger 51, and then flows into the first heat exchanger 41. The circulating liquid L flowing into the first heat exchanger 41 receives further heat by exchanging heat with the hot water C1 heated as described above. The circulating liquid L heated by the air heat source and the gas heating heat source in this way is then supplied to the heat exchange terminal 36, where it heats the conditioned space.

<Functional configuration of the control device>
Next, the heat exchange unit control device 61, the boiler control device 63, and the heat pump control device 62 in this embodiment will be described. Although detailed illustrations are omitted, the heat exchange unit control device 61, the boiler control device 63, and the heat pump control device 62 each include a storage unit for storing various data and programs, and a control unit for performing calculation and control processing. The functional configurations of the heat exchange unit control device 61, the boiler control device 63, and the heat pump control device 62 will be described with reference to Figures 5, 6, and 7. Note that in the following Figures 5, 6, and 7, the signal transmission and reception between the heat exchange unit control device 61, the boiler control device 63, and the heat pump control device 62, which can transmit and receive signals to and from each other as described above, and the signal transmission and reception via each control device are appropriately omitted, and the signals that are substantially input and output to each control unit described later are shown.

<Heat pump control device>
As shown in FIG. 5, the heat pump control device 62 functionally comprises a compressor control section 62A, an expansion valve control section 62B, a pump control section 62C, a fan control section 62D, and a four-way valve control section 62E.

The compressor control unit 62A controls the rotation speed of the compressor 53, for example, in response to the temperature of the circulating fluid L detected by the return temperature sensor 34 and the second forward temperature sensor 35. In this particular example, the compressor control unit 62A controls the rotation speed of the compressor 53 so that the temperature of the circulating fluid L detected by the second forward temperature sensor 35 becomes a desired target temperature corresponding to, for example, the operation of the remote control 60.

The expansion valve control unit 62B controls the valve opening degree of the expansion valve 54 according to the temperature of the refrigerant C2 detected by the refrigerant discharge temperature sensor 52a. In this particular example, the expansion valve control unit 62B controls the valve opening degree of the expansion valve 54 so that the temperature of the refrigerant C2 detected by the refrigerant discharge temperature sensor 52a becomes a control target temperature corresponding to, for example, the operation of the remote control 60.

The pump control unit 62C controls the rotation speed of the circulating fluid circulation pump 32, for example, depending on the desired target temperature of the circulating fluid L and the type of operation.

The fan control unit 62D controls the rotation speed of the blower fan 56 according to the outside air temperature detected by the outside air temperature sensor 57.

The four-way valve control unit 62E receives an operation instruction from the remote control 60 (a control signal instructing whether to start or stop the heating operation, the cold air operation, etc.) and an operation ON/OFF signal from the heat exchange unit control device 61. The four-way valve control unit 62E determines in what operating mode the refrigerant circulation circuit 50 will actually be operated in response to the operation instruction, and outputs corresponding operating information to the compressor control unit 62A, the expansion valve control unit 62B, the pump control unit 62C, the fan control unit 62D, and the heat exchange unit control device 61. The operating information also includes operating information on whether or not to perform the defrosting operation described below based on the operation of the operation unit 70 as an operating means. The four-way valve control unit 62E also outputs a control signal corresponding to the determined operating mode to the four-way valve 58, switching the four-way valve 58.

Note that each of the above control units 62A to 62E also receives an operation signal from the operation unit 70, which will be described later.

<Heat exchange unit control device>
As shown in FIG. 6, the heat exchange unit control device 61 functionally comprises an operation control section 61A, a heating control section 61B, and a pump control section 61C.

The operation control unit 61A judges whether the gas heater 43 of the hot water circulation circuit 40 is operated or not operated, specifically, whether the gas heater 43 of the hot water circulation circuit 40 is operated together with the compressor 53 of the refrigerant circulation circuit 50 (the above-mentioned HP/gas heating operation) or whether the gas heater 43 of the hot water circulation circuit 40 is operated (with the compressor 53 of the refrigerant circulation circuit 50 not operating) (the above-mentioned gas only heating operation) based on, for example, the temperature of the outside air detected by the outside air temperature sensor 57, the temperature of the circulating liquid L from the first heat exchanger 41 detected by the first forward temperature sensor 33, and the above-mentioned operation information input from the heat pump control unit 62. Then, based on the judgment result, it outputs an operation ON signal corresponding to the case of operation or an operation OFF signal corresponding to the case of not operating to the heat pump control unit 62 and the boiler control unit 63.

The heating control unit 61B outputs a heating control signal to the boiler control device 63 to control the output of the gas heater 43 based on the temperature of the circulating liquid L from the first heat exchanger 41 detected by the first temperature sensor 33.

The pump control unit 61C outputs a rotation control signal to the boiler control device 63 to control the rotation speed of the hot water circulation pump 44, for example, depending on the desired target temperature of the circulating liquid L and the type of operation.

<Boiler control device>
As shown in Figure 7, the boiler control device 63 controls the rotation speed of the hot water circulation pump 44 and the output of the gas heater 43 based on, for example, a heating control signal from the heating control unit 61B, a rotation control signal from the pump control unit 61C, and the delivery temperature of the hot water C1 detected by the boiler delivery temperature sensor 42a.

<Occurrence of icing>
In the hybrid hot water heating system 1 having the above basic configuration and operation, for example, if the heating operation is not performed for a long period of time during a severe winter, or if wind and snow blow for a long period of time even during heating operation, freezing may occur in the refrigerant circulation circuit 50 (particularly the air heat exchanger 55) due to snow accumulation and snow accretion. In this embodiment, in response to this, the operator manually operates the operation unit 70 to issue a defrosting instruction, and a predetermined defrosting operation is performed. The operation unit 70 is provided in a housing of an outdoor unit (not shown) that incorporates, for example, the air heat exchanger 55, the blower fan 56, the compressor 53, the expansion valve 54, etc. In this case, the operation unit 70 is configured to be operable, for example, when the outer wall part of the housing that is screwed is removed and the inside is exposed, without being normally operated. In other words, the operation unit 70 cannot be normally operated by a user, and can be operated only by an operator who can remove the outer wall part by releasing the above-mentioned screwing.

<Ice melting operation>
FIG. 8 shows the state during the defrosting operation. As shown in FIG. 8, in the refrigerant circulation circuit 50, the four-way valve 58 is switched as shown in the figure, so that the inlet side of the air heat exchanger 55 is connected to the discharge side of the compressor 53, and the outlet side of the air heat exchanger 55 is connected to the inlet side of the second heat exchanger 51, the outlet side of which is connected to the suction side of the compressor 53. That is, a flow path is formed in which the refrigerant C2 discharged from the compressor 53 flows through the air heat exchanger 55, the expansion valve 54, and the second heat exchanger 51 in this order, and then returns to the compressor 53. At this time, as described later, the opening of the expansion valve 54 is appropriately narrowed to a smaller opening than full opening (see S45 in FIG. 10). The refrigerant C2 in a gaseous state sucked in at a low temperature and low pressure is compressed by the compressor 53 to become a high temperature and high pressure gas, and then changes to a high pressure liquid in the air heat exchanger 55, which functions as a condenser, while releasing heat to the frozen air heat exchanger 55. The heat generated at this time melts the frozen refrigerant. The liquefied refrigerant C2 is decompressed in the expansion valve 54 to become a low-pressure liquid that is easy to evaporate, and then evaporates by heat exchange with the circulating liquid L flowing through the terminal circulation circuit 30 in the second heat exchanger 51 that functions as an evaporator, and then returns to the compressor 53 again as a low-temperature, low-pressure gas.

In the hot water circulation circuit 40, as in the above-mentioned HP/gas only operation or gas only operation, the hot water C1 flowing into the heating heat exchanger 45 by the hot water circulation pump 44 is heated by the thermal power of the gas heater 43 in the heating heat exchanger 45 and becomes high temperature. After that, the hot water C1, which has become high temperature, exchanges heat with the circulating liquid L flowing through the terminal circulation circuit 30 in the first heat exchanger 41 to heat the circulating liquid L and lower its temperature, and then returns to the heating heat exchanger 45 again.

At this time, in the terminal circulation circuit 30, the circulating liquid L flowing into the second heat exchanger 51 by the circulating liquid pump 32 exchanges heat with the refrigerant C2, which is a low-pressure liquid as described above, in the second heat exchanger 51, dissipates heat to the refrigerant C2, and then flows into the first heat exchanger 41. The circulating liquid L flowing into the first heat exchanger 41 exchanges heat with the heated hot water C1 as described above, and is heated. The circulating liquid L thus heated by the heat source by gas heating flows again into the second heat exchanger 51 via the heat exchange terminal 36 and dissipates heat to the refrigerant C2. As described above, the amount of heat dissipated from the second heat exchanger 51 to the refrigerant C2 can be increased by dissipating heat from the hot water C1, which has become hot due to the heating of the gas heater 43, to the circulating liquid L in the first heat exchanger 41.

When performing the defrosting operation to melt the ice in the refrigerant circulation circuit 50 as described above, depending on the temperature environment, it may be possible to melt the ice only by receiving heat from the terminal circulation circuit 30 in the refrigerant circulation circuit 50 (without heating the hot water C1 by the gas heater 43). In this embodiment, in such a case, the defrosting operation shown in FIG. 9 is performed without heating by the gas heater 43. In other words, the defrosting operation in this case is a defrosting operation only on the refrigerant circulation circuit 50 side (indicated as "HP only" in FIG. 9, and correspondingly, in the above-mentioned FIG. 8, it is indicated as "HP and gas"). As shown in the figure, the heating of the hot water C1 by the gas heater 43 and the operation of the hot water circulation pump 44 are not performed, and the operation mode is otherwise the same as that of the above-mentioned FIG. 8.

<Control procedure>
FIG. 10 shows a control procedure executed by the heat exchange unit controller 61, the heat pump controller 62, and the boiler controller 63 in cooperation with each other to realize the defrosting operation described above using FIGS.

In FIG. 10, first, in S5, it is determined whether or not an instruction to start defrosting operation has been given by manual operation of the operator via the operation unit 70. If an instruction to start defrosting operation has been given, the determination is Yes, and the process proceeds to S10.

In S10, the heat pump control device 62 starts the compressor 53 at a predetermined cycle for the defrosting operation and starts the circulating liquid circulation pump 32 at a predetermined rotation speed, and then in S15, the heat pump control device 62 controls the opening of the expansion valve 54 to be fully open. The fully open opening in this case is an example of the second opening. This starts the defrosting operation by the refrigerant circulation circuit 50 side alone as shown in FIG. 9. At that time, by controlling the opening of the expansion valve 54 to be fully open as described above, the refrigerant circulation circuit 50 is prevented from excessively acquiring heat on the terminal circulation circuit 30 side, and the temperature of the circulating liquid L can be prevented from dropping excessively. As a result, it is possible to prevent condensation from occurring in the heat exchange terminal 36 while performing defrosting. Then, the process proceeds to S20.

In S20, the system is put into a standby state until a predetermined time (two minutes in this example) has elapsed since the state of S15 above. Once two minutes have elapsed, a Yes judgment is made and the system moves to S25. The purpose of this standby period is to correctly measure the temperature of the circulating fluid L in the terminal circulation circuit 30 in S25, which will be described later. In other words, if the measurement were performed immediately without waiting for the predetermined time to elapse, there is a risk that the temperature would be strongly influenced not by the temperature of the circulating fluid L, but by the temperature of the structure itself in the outdoor unit or the temperature of the internal atmosphere. By waiting for the predetermined time to elapse before performing the measurement, the circulation of the circulating fluid L in the terminal circulation circuit 30 during that time allows the temperature of the circulating fluid L in the terminal circulation circuit 30 at the beginning of the defrosting operation to be correctly measured.

In S25, it is determined whether the temperature detected by the second forward temperature sensor 35 at the beginning of the defrosting operation, that is, the forward temperature of the circulating liquid L flowing from the second heat exchanger 51 to the first heat exchanger 41 side, is equal to or higher than a predetermined temperature (7°C in this example). This predetermined temperature is the temperature that is the boundary between whether condensation occurs in the terminal circulation circuit 30 and the heat exchange terminal 36 when defrosting operation is performed on the refrigerant circulation circuit 50 side alone as described above. In other words, the predetermined temperature is a temperature that has been found, by appropriate experiments conducted in advance taking into account the indoor relative humidity in winter (e.g., 30 to 60% RH) in a typical house, or by analysis and simulation using an appropriate method, that if the forward temperature is equal to or higher than the predetermined temperature, condensation does not occur in the terminal circulation circuit 30 and the heat exchange terminal 36, and that if the forward temperature is lower than the predetermined temperature, condensation occurs in the terminal circulation circuit 30 and the heat exchange terminal 36.

The forward temperature of the circulating fluid L at this time is an example of a predetermined temperature index, and the second forward temperature sensor 35 is an example of a forward temperature detection means. Note that instead of the forward temperature of the circulating fluid L from the second heat exchanger 51 detected by the second forward temperature sensor 35, the forward temperature of the circulating fluid L from the first heat exchanger 41 detected by the first forward temperature sensor 33 may be used. In this case, the forward temperature is an example of a predetermined temperature index, and the first forward temperature sensor 33 is an example of a forward temperature detection means.

If the temperature of the circulating liquid L from the second heat exchanger 51 is equal to or higher than 7°C in S25, the answer is Yes, it is determined that the ice can be melted only by the heat received by the refrigerant circulation circuit 50 from the terminal circulation circuit 30, and the process proceeds to S30.

In S30, it is determined whether a predetermined end condition for the defrosting operation is satisfied. The defrosting end condition is, for example, that the temperature of the refrigerant C2 flowing out of the air heat exchanger 55 detected by the refrigerant temperature sensor 52b is equal to or higher than a predetermined value (e.g., 8°C) for a certain period of time (e.g., about 60 seconds). In this case, this condition is an example of a second operation end condition. While the defrosting end condition is not satisfied, S30 is determined as No, and the process returns to S25 and the same process is repeated. In other words, until the defrosting process condition in S30 is satisfied, defrosting is performed only by operation on the refrigerant circulation circuit 50 side by starting the compressor 53 in S10. This process corresponds to the second mode, and the temperature range of 7°C or higher in the above example corresponds to the second range. When the defrosting process condition is satisfied, S30 is determined as Yes, and the process proceeds to S35.

In S35, the compressor 53 and the circulating liquid circulation pump 32 that were started in S10 are stopped by the heat pump control device 62, and this flow ends.

On the other hand, if the temperature of the circulating liquid L at the outgoing temperature is less than the predetermined temperature (7°C in the above example) in S25, the result is No, it is deemed that the ice cannot be melted by heat received only from the terminal circulation circuit 30 to the refrigerant circulation circuit 50, and heating by the gas heater 43 is necessary, and the process proceeds to S40.

In S40, the gas heater 43 is started by the heat exchange unit control device 61 and the boiler control device 63, and maximum output operation is started. This starts the de-icing operation in cooperation with the refrigerant circulation circuit 50 side and the hot water circulation circuit 40 shown in FIG. 8. This process corresponds to the first mode, and the temperature range below 7°C in the above example corresponds to the first range. At this time, condensation in the gas heating hot water heater unit 4B is prevented by maximizing the output of the gas heater 43.

Then, in S45, the heat pump control device 62 controls the opening of the expansion valve 54 to an opening slightly smaller than the fully open position described above, for example, to about 3/4 of the previous opening. This increases the discharge temperature of the refrigerant C2. The opening at this time is an example of the first opening.

Then, in S50, the system goes into standby mode until a predetermined time has elapsed since the state of S45 (which may be the same 2 minutes as above, or a different time than the above), and once the predetermined time has elapsed, the system makes a Yes determination and transitions to S55.

In S55, as in S25, it is determined whether the temperature of the circulating fluid L from the second heat exchanger 51 detected by the second forward temperature sensor 35 is equal to or higher than a predetermined temperature (7°C in this example). If the temperature of the circulating fluid L is less than the predetermined temperature due to heat received from the hot water C1 heated by the gas heater 43, a No determination is made, and until 15 minutes have elapsed since the No determination, S75 is determined as No and the process returns to S55, and the same procedure is repeated. If the temperature of the circulating fluid L becomes equal to or higher than the predetermined temperature during this repetition, S55 is determined as Yes and the process moves to S60.

In S60, as in S30, it is determined whether the end condition of the defrosting operation is satisfied. In the above example, the defrosting end condition is, for example, that the temperature of the refrigerant C2 from the air heat exchanger 55 detected by the refrigerant temperature sensor 52b is, for example, 8°C or higher for about 60 seconds. In this case, this condition is an example of the first operation end condition. While the defrosting end condition is not satisfied, S60 is determined as No, and the process returns to S55 and the same process is repeated. In other words, the defrosting operation by the cooperation of the refrigerant circulation circuit 50 and the hot water circulation circuit 40 is continued until the defrosting process condition in S60 is satisfied. When the defrosting process condition is satisfied, S60 is determined as Yes, and the process proceeds to S65.

In S65, the compressor 53 and the circulating liquid circulation pump 32 started in S10 are stopped by the heat pump control device 62, and then in S70, the gas heater 43 started in S40 is stopped by the heat exchange unit control device 61 and the boiler control device 63, and this flow ends.

As described above, if S55 is judged as No while the temperature of the circulating fluid L from the second heat exchanger 51 detected by the second forward temperature sensor 35 remains below 7°C and 15 minutes have elapsed while S55 → S75 → S55 are repeated, S75 is judged as Yes and the process moves to S80.

In S80, it is deemed pointless to continue operation any further due to, for example, a malfunction in any part of the system or an unusual amount of freezing. As a result, the compressor 53 and gas heater 43 are forcibly stopped by the heat pump control device 62, the heat exchange unit control device 61, and the boiler control device 63, and this flow ends. Note that at this time, an example of a predetermined operation stop condition is that the outgoing temperature of the circulating liquid L from the second heat exchanger 51 remains at or above 7°C for 15 minutes.

The heat exchange unit control device 61, the heat pump control device 62, and the boiler control device 63, which execute the steps shown in FIG. 10 described above, correspond to examples of control means.

Effects of the embodiment
As described above, the hybrid hot water heating system 1 of this embodiment includes the terminal circulation circuit 30 capable of supplying the circulating liquid L to the heat exchange terminal 36 and the refrigerant circulation circuit 50 capable of exchanging heat with the outside air, and can perform a heating operation via the heat exchange terminal 36 by warming the circulating liquid L using heat absorption from the outside air. That is, in the refrigerant circulation circuit 50, the refrigerant C2 that has been evaporated and absorbed heat by heat exchange with the outside air in the air heat exchanger 55 is guided to the compressor 53 and compressed to a high temperature and high pressure, and then guided to the second heat exchanger 51 and condensed while releasing heat. As a result, the circulating liquid L in the terminal circulation circuit 30 is warmed, and the heated circulating liquid L is guided to the heat exchange terminal 36 to perform heating.

For example, in the harsh winter, when the heating operation is not performed for a long period of time, or when wind and snow blow for a long period of time even during heating operation, freezing may occur due to snow accumulation or snow accretion in the refrigerant circulation circuit 50 (particularly the air heat exchanger 55 and its surroundings). In this embodiment, in response to this, when a defrosting command is given by manually operating the operation unit 70, the defrosting operation is performed. That is, as shown in FIG. 8, in the refrigerant circulation circuit 50, the refrigerant C2 that has been evaporated and received heat by heat exchange with the terminal circulation circuit 30 in the second heat exchanger 51 functioning as an evaporator is introduced to the compressor 53 and compressed to a high temperature and high pressure, and then introduced to the air heat exchanger 55 functioning as a condenser where it condenses while releasing heat. The heat released at this time can melt the ice that has occurred as described above.

During the defrosting operation, the second heat exchanger 51 receives heat from the terminal circulation circuit 30 and dissipates heat in the air heat exchanger 55, but the amount of heat that can be obtained from the terminal circulation circuit 30 is limited. In addition, when freezing occurs, as described above, the state in which heating operation is not performed has continued for a long period of time, and the temperature of the circulating fluid L in the terminal circulation circuit 30 is originally relatively low. As a result, heat received from the terminal circulation circuit 30 to the refrigerant circulation circuit 50 alone cannot dissipate sufficient heat in the air heat exchanger 55, and defrosting may become difficult.

In this embodiment, during the defrosting operation, as shown in FIG. 8, the gas heater 43 is controlled to start heating the hot water C1 in the hot water pipe 42. As a result, the hot water C1, which has become hot, is radiated heat to the terminal circulation circuit 30 by the first heat exchanger 41, thereby increasing the amount of heat radiated from the second heat exchanger 51 as described above, and defrosting in the refrigerant circulation circuit 50 can be performed reliably.

In particular, in this embodiment, when performing the defrosting operation as described above, depending on the temperature environment, it may be possible to melt the ice only by receiving heat from the refrigerant circulation circuit 50 from the terminal circulation circuit 30 without heating the hot water by the gas heater 43. In such a case, starting heating by the gas heater 43 leads to an unnecessary increase in running costs. Therefore, in this embodiment, there are two control modes: a first mode (see FIG. 8) in which both the compression of the refrigerant by the compressor 53 of the refrigerant circulation circuit 50 and the heating by the gas heater 43 are performed, and a second mode (see FIG. 9) in which only the compression of the refrigerant by the compressor 53 is performed without heating by the gas heater 43. When the temperature environment is within the first range on the relatively low temperature side (in the above example, the forward temperature of the circulating liquid L flowing out to the first heat exchanger 41 side is less than 7° C.), control is performed in the first mode, while when the temperature environment is within the second range on the relatively high temperature side (in the above example, the forward temperature of the circulating liquid L flowing out to the first heat exchanger 41 side is 7° C. or more), control is performed in the second mode.
This makes it possible to avoid heating by the gas heater 43 as much as possible in a relatively high temperature environment, thereby reducing running costs.

In particular, in this embodiment, the temperature (forward temperature) of the circulating fluid L flowing out from the second heat exchanger 51 or the first heat exchanger 41 is used as the temperature index. When the temperature of the circulating fluid L detected by the second forward temperature sensor 35 or the first forward temperature sensor 33 is within the second range on the high temperature side (7°C or higher in the above example), heating by the gas heater 43 is deemed not necessarily necessary, and control is performed in the second mode. On the other hand, when the detected temperature of the circulating fluid L is within the first range on the low temperature side (less than 7°C in the above example), heating by the gas heater 43 is deemed necessary, and control is performed in the first mode. This makes it possible to reliably prevent heating by the gas heater 43 from being performed in a high temperature environment.

In particular, in this embodiment, a first range and a second range are set depending on whether condensation occurs in the terminal circulation circuit 30. As a result, when the temperature index is within the first range where condensation may occur (in the above example, the forward temperature of the circulating liquid L flowing out to the first heat exchanger 41 side is less than 7°C), heating is performed by the gas heater 43 in the first mode, whereas when the temperature index is within the second range where condensation does not occur (in the above example, the forward temperature of the circulating liquid L flowing out to the first heat exchanger 41 side is 7°C or higher), heating by the gas heater 43 is not performed in the second mode. In this way, by not performing heating by the gas heater 43 as much as possible until condensation occurs, it is possible to reliably reduce running costs.

In particular, in this embodiment, when the first operation end condition (in the above example, the state in which the delivery temperature of refrigerant C2 detected by refrigerant temperature sensor 52b is 8°C or higher continues for about 60 seconds) is satisfied during operation in the first mode in which the compressor 53 compresses the refrigerant and the gas heater 43 heats it, the operation of the compressor 53 and the gas heater 43 is terminated. Similarly, when the second operation end condition (the same as the first operation end condition in the above example) is satisfied during operation in the second mode in which only the compressor 53 compresses the refrigerant, the operation of the compressor 53 is terminated. This makes it possible to reliably terminate operation in response to the melting of the ice.

In particular, in this embodiment, when the compressor 53 and the gas heater 43 are operating in the first mode, if a predetermined operation stop condition (in the above example, the temperature of the circulating liquid L from the second heat exchanger 51 is 7°C or higher for 15 minutes) is met, their operation is forcibly stopped. This makes it possible to avoid further unnecessary operation in cases where the ice does not melt even after a certain amount of defrosting operation due to a malfunction in any part of the system or an abnormal amount of ice has formed.

In particular, in this embodiment, the expansion valve 54 is narrowed to a smaller opening in the first mode in which heating is performed by the gas heater 43 than in the second mode in which heating is not performed by the gas heater 43. As a result, in the first mode, the discharge temperature of the refrigerant C2 from the compressor 53 is increased, thereby increasing the amount of heat dissipation and achieving rapid defrosting.

<Modification>
In the above, an example has been described in which the second heat exchanger 51 is disposed upstream of the first heat exchanger 41 with respect to the flow of the circulating circulating fluid L in the terminal circulation circuit 30, but the present invention is not limited to this, and the first heat exchanger 41 may be disposed upstream of the second heat exchanger 51. Furthermore, the first heat exchanger 41 and the second heat exchanger 51 may be connected in parallel in the terminal circulation circuit 30.

In the above, the rotation speed of the compressor 53 is controlled according to the forward temperature of the circulating fluid L detected by the second forward temperature sensor 35 on the outlet side (outlet side) of the second heat exchanger 51, that is, so-called forward temperature control is performed, but this is not limited to this. The rotation speed of the compressor 53 may be controlled according to the forward temperature of the circulating fluid L detected by the return temperature sensor 34 on the inlet side (inlet side) of the second heat exchanger 51, that is, so-called return temperature control may be performed.

In addition, in the above embodiment, a case where one heat exchange terminal is connected is described as an example, but this is not limited to this. In other words, a configuration in which two or more heat exchange terminals are connected may also be used.

In addition, in step S40 of FIG. 10, the gas heater 43 is operated at maximum output, but this is not limited to the above example. For example, the boiler control device 63 (or the heat exchange unit control device 61) may control the output so that the temperature of the hot water C1 detected by the boiler inlet temperature sensor 42a becomes a target temperature for a predetermined defrosting operation, or may stop operation when the temperature exceeds a predetermined defrosting upper limit temperature and resume operation when the temperature falls below a predetermined defrosting lower limit temperature.

In addition, the flowchart shown in FIG. 10 does not limit the present invention to the steps shown in the flow chart, and steps may be added or deleted or the order may be changed without departing from the spirit and technical concept of the invention.

In addition to the above, the methods according to the above embodiments and their variations may be used in combination as appropriate.

Although we will not provide examples, the present invention can be implemented with various modifications without departing from the spirit of the invention.

1 Hybrid hot water heating system 30 Terminal circulation circuit (load side circuit)
31 Load piping (circulating fluid piping)
32 Circulating fluid circulating pump 34 Return temperature sensor 35 Second forward temperature sensor (forward temperature detection means)
36 Heat exchange terminal (load terminal)
40 Hot water circulation circuit 41 First heat exchanger (first load side heat exchanger)
42 Hot water piping 43 Gas heater 45 Heating heat exchanger (first heat source side heat exchanger)
50 Refrigerant circulation circuit 51 Second heat exchanger (second load side heat exchanger)
52 Refrigerant piping 53 Compressor 54 Expansion valve (pressure reducing means)
55 Air heat exchanger (second heat source side heat exchanger)
61 Heat exchange unit control device (control means)
62 Heat pump control device (control means)
63 Boiler control device (control means)
70 Operation unit (operation means)
C1 Hot water C2 Refrigerant L Circulating fluid

Claims (6)

a gas heater, a first heat source side heat exchanger that receives heat from the gas heater, and a first load side heat exchanger are connected by hot water piping to form a hot water circulation circuit;
a compressor, a second heat source side heat exchanger capable of exchanging heat with outside air, a pressure reducing means, and a second load side heat exchanger are connected by a refrigerant pipe to form a refrigerant circulation circuit;
the first load side heat exchanger, the second load side heat exchanger, and at least one load terminal are connected by a circulating fluid pipe so that the second load side heat exchanger is disposed in series on the upstream side of the first load side heat exchanger, thereby forming a load side circuit;
In a hybrid hot water heating system provided with a control means for controlling at least the compressor and the gas heater,
An operation means for issuing an instruction to melt ice when ice forms in the refrigerant circulation circuit is provided,
The control means
When the thawing instruction is given via the operation means,
an inlet side of the second heat source side heat exchanger functioning as a condenser is connected to the discharge side of the compressor, and an outlet side of the second heat source side heat exchanger functioning as a condenser is connected to an inlet side of the second load side heat exchanger functioning as an evaporator whose outlet side is connected to the suction side of the compressor, thereby supplying heat received by the refrigerant in the second load side heat exchanger to the second heat source side heat exchanger, controlling the compressor to start compressing the refrigerant in the refrigerant piping, and controlling the gas heater to start heating the hot water in the hot water piping ;
and,
The control means, during the defrosting operation,
a first mode in which, when a predetermined temperature index is within a first range, the gas heater and the compressor are controlled to heat the hot water in the hot water pipe and compress the refrigerant in the refrigerant pipe;
a second mode in which, when the temperature index is within a second range that is higher than the first range, the compressor is controlled to compress the refrigerant in the refrigerant pipe without heating the hot water in the hot water pipe;
A hybrid hot water heating system comprising : the load side circuit further includes a forward temperature detection means for detecting a temperature of the circulating fluid in the circulating fluid pipe flowing out from the second load side heat exchanger or the first load side heat exchanger,
The control means
2. The hybrid hot water heating system according to claim 1, characterized in that the system switches to either the first mode or the second mode depending on whether the circulating fluid temperature detected by the supply temperature detection means as the temperature indicator is within the first range or the second range. the first range is a temperature range in which condensation occurs in the load side circuit,
3. The hybrid hot water heating system according to claim 1, wherein the second range is a temperature range in which no condensation occurs in the load side circuit. The control means
When a predetermined first operation end condition is satisfied in the operating state of the compressor and the gas heater in the first mode, the operation of the compressor and the gas heater is ended,
4. The hybrid hot water heating system according to claim 1, wherein the operation of the compressor is terminated when a predetermined second operation termination condition is satisfied during the operation of the compressor in the second mode. The control means
A hybrid hot water heating system as described in any one of claims 1 to 4, characterized in that when a predetermined operation stop condition is satisfied in the operating state of the compressor and the gas heater in the first mode, the operation of the compressor and the gas heater is forcibly stopped. The control means
In the first mode, the opening degree of the pressure reducing means is controlled to a first opening degree,
6. The hybrid hot water heating system according to claim 1, wherein in the second mode, an opening degree of the pressure reducing means is controlled to a second opening degree larger than the first opening degree.

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