JP3653256B2 - Hybrid energy system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a hybrid energy system, and more particularly to an energy system that can be operated efficiently by docking a solar system and a cogeneration system that are conventionally operated independently.
[0002]
[Prior art]
Hospitals, hotels, and the like consume large amounts of heat energy and electric energy, but there are a solar system that uses solar heat and a cogeneration system that uses a private generator as a facility for securing an energy source. FIG. 7 is a flowchart of a conventional solar system hot water supply / cooling / heating system. As main components, a solar heat collector 1, a heat storage tank 2, a hot water supply heat exchanger 3, a hot water tank 4, an auxiliary boiler 5, a cold / hot water generator 6, There are a cooling tower 7 and a heat exchanger 8 for heating. Although not shown in the drawings, in addition to the above, a heat collecting pump, a heat source pump, a cold / hot water pump, a cooling water pump, an automatic control device for controlling driving of each device, and a control panel are provided.
[0003]
According to such a solar system, the energy collected by the solar heat collector 1 is stored in the heat storage tank 2, and the hot water supply 9 is performed through the hot water supply heat exchanger 3 and the hot water storage tank 4. The auxiliary boiler 5 is operated as necessary. Further, the cold / hot water generator 6 and the cooling tower 7 are driven by the heat stored in the heat storage tank 2, and the cooling / heating 10 is performed via the heating heat exchanger 8. At this time, heat energy is exchanged between the heat storage tank 2 and the heat exchanger 8 for heating.
[0004]
FIG. 8 is a flow chart of a conventional cogeneration system hot water supply / cooling system including a private heat generator 12, a heat exchanger 11 for recovering waste heat, an absorption chiller 13, a cooling tower 7, a hot water tank 4, and an auxiliary boiler 5. ing. The private generator 12 includes a diesel engine, a gas engine, and a turbine as a power source, and the private generator 12 includes a waste heat recovery device (heat exchanger, waste gas boiler). It also has a grid connection board and a DC power board that control the drive of each device.
[0005]
According to such a cogeneration system, the power generated by operating the private generator 12 is preferentially supplied to the building, and the waste heat is recovered by the waste heat recovery device incorporated in the private generator 12 to generate heat. It is exchanged and supplied to the absorption refrigeration machine 13, the cooling tower 7 is driven to perform air conditioning 10, and heat exchange is further performed between the waste heat recovery heat exchanger 11 and the hot water tank 4, and the auxiliary boiler 5. The hot water supply 9 is performed under the drive of the above, and it is devised that the efficient hot water supply 9 and the air conditioning 10 are performed by transmitting excess heat energy between the devices.
[0006]
[Problems to be solved by the invention]
Heating of the hot water storage tank 4 for hot water supply in the conventional solar system is often performed at the same level as the heating from the heat recovered heat storage tank 2 and the auxiliary boiler 5, and the hot water storage tank due to circulation heat dissipation loss. Since the heating at the time of the temperature drop of 4 is often relied on the auxiliary boiler 5, there is a problem that a large energy saving effect is not obtained. Further, after the collected energy is stored in the heat storage tank 2, the two heat supply sources used for the hot water supply 9 and the air conditioning 10 correspond to the two demand loads of the hot water supply 9 and the air conditioning 10 via the heat storage tank 2. Therefore, it is difficult to control the system to cope with a rapid temperature change, and it is difficult to cause operational troubles.
[0007]
The pumps for transport power of the above solar system and cogeneration system operate constantly regardless of load fluctuations, so a large energy saving effect cannot be expected, and the temperature change range of the heat storage tank 2 is large when a large amount of hot water is supplied. In addition to the difficulty of causing problems such as freezer locks and solar heat shocks when using solar cooling, there is a problem that heat collection is reduced due to the amount of heat collected when the weather is cloudy and rainy. is there.
[0008]
When connecting to a power company via a cogeneration system, it is necessary to purchase a considerable amount of electricity even when the load is less than the generator capacity. This often increases the operating rate of the generator and causes the generator to stop. There are some drawbacks, such as inability to recover heat, and there is a drawback that facilities using a conventional solar system and cogeneration system cannot be adapted to small and medium buildings.
[0009]
On the other hand, FIG. 9 is a conventional example in which a solar system and a cogeneration system are used together, and mainly shows a piping diagram around the heat collection circuit of the heat storage tank 2. That is, by arranging a heat collection pump 2 d between the solar heat collector 1 and the heat storage tank 2, and connecting the private power generator 12, the waste heat recovery heat exchanger 11, and the absorption refrigeration machine 13 to the heat storage tank 2. A system using both the heat storage tank 2 and the private generator 12 has been obtained. However, in this example, since the inside of the heat storage tank 2 is of a single tank type, the hot water of the outlet pipe and the return pipe of the heat collecting circuit (SH) and the waste heat recovery circuit (MH) are mixed in the tank to supply hot water and air conditioning. There is a problem that the hot water temperature on the outgoing pipe side of each circuit becomes unstable depending on the load condition.
[0010]
In particular, the solar system and the cogeneration system have been independent from each other, and since the control conditions and transport power when using both systems are completely different, the operability and interlock are related to each other. However, there is a problem that various inconsistencies occur during use and a failure or the like is likely to occur. Furthermore, since both systems require a solar control panel, a cogeneration panel, an air conditioning panel, a power panel and the like separately, there is a problem that the cost of the system itself increases.
[0011]
Therefore, the present invention solves the above-described problems, docks the solar system and the coordination system, and controls the inverter in accordance with the load so as to variably adjust the flow rates of the cooling water and the cold / hot water, thereby reducing the load at the time of low load. By reducing the transport power, increasing the energy saving effect, increasing the relevance of each device and combining the control panel into one, enabling efficient operation, and unifying operation display, trouble display, alarm, etc. The objective is to provide a hybrid energy system that can reduce costs.
[0012]
[Means for Solving the Problems]
In order to achieve the above object, the present invention provides a solar heat collector, a heat storage tank, a hot water heat exchanger, a hot water tank, an auxiliary boiler, a waste heat recovery heat exchanger, a private generator, an absorption refrigeration machine, a cooling tower. , Heating heat exchanger and system interconnection panel, DC power supply panel integrated to control the drive of each device, heat energy collected by solar heat collector is stored in heat storage tank, hot water supply Along with the operation of the heat source pump and the hot water supply pump, hot water is supplied through the hot water heat exchanger and hot water storage tank, and further, the heating heat source pump is operated to supply heat energy to the heating heat exchanger, The cooling tower is driven to heat and cool, and the private generator is operated to supply power to the building through the cupicle and distribution board, and the waste heat discharged from the private generator is also used for heat exchange for waste heat recovery. Heat exchange between the storage unit and the heat storage tank The excess heat energy is collected in the heat storage tank and used again for hot water supply and cooling / heating. The variable flow rate of cooling water and cold / warm water during operation is variable by inverter-controlling the conveyance power pump according to the load. Adjusting to reduce the conveyance power at low load, the hot water storage tank is heated from the heat storage tank where heat is recovered, and the auxiliary boiler is operated only when the heating is insufficient. The hybrid energy system is a basic means.
[0016]
According to such a hybrid energy system, the heat energy collected by the solar heat collector is stored in the heat storage tank, hot water is supplied via the hot water supply heat exchanger and the hot water storage tank, and the heat energy is supplied to the heating heat exchanger. The absorption chiller and the cooling tower are driven to cool and heat the unit, and at the same time, the private power generator is operated to supply power to the building via the cupicle and the distribution board, and then discharge from the private power generator. Waste heat is recovered as extra heat energy in the heat storage tank by operating the waste heat recovery pump. The variable flow rate of cooling water and cold / hot water during system operation is controlled by the inverter for the conveyance power pump according to the load, so that the conveyance power can be reduced at low loads and the hot water storage tank is heated. Heating from the tank is used as a priority circuit, and the auxiliary boiler is operated only when the heating is insufficient, and the energy saving effect is enhanced.
[0017]
The temperature inside the heat storage tank is divided into three tanks: a high-temperature tank, an intermediate rectification tank, and a low-temperature tank, so that the temperature of the hot water on the outgoing pipe side is stable regardless of the heat load, and it is on the outlet side The temperature range of the hot water in the hot bath is kept below a certain range, and troubles due to sudden temperature changes are prevented. In addition, since the grid connection panel and DC power panel for controlling the drive of each device are integrated into one, the installation space is reduced, and the operation display, trouble display, alarm, etc. are unified, and operability is achieved. And the interlock can be prevented.
[0018]
In the present invention, solar heat that is natural energy and waste heat generated from private power generation equipment can be heat-exchanged and stored in a heat storage tank, and can be used for hot water supply and cooling and heating, particularly by docking the two systems, Since it is possible to recover heat using the waste heat of the generator even in rainy weather, it is possible to adopt a usage form such as heat recovery from the collector even when the generator is stopped, so each system is installed independently The effect that the width of the heat recovery efficiency becomes wider than that in the case of the above is obtained.
[0019]
DETAILED DESCRIPTION OF THE INVENTION
An embodiment of a hybrid energy system according to the present invention will be described below with the same reference numerals assigned to the same components as those of the conventional configuration, based on the drawings. The hybrid energy system defined in the present invention refers to “solar system” + “cogeneration system” + “inverter control”.
[0020]
As described above, in hospitals and hotels, etc., both heat energy and electric energy are consumed in large quantities, but in the present invention, a solar system using solar heat as an energy source facility and a cogeneration system with high overall energy efficiency are docked. Comprehensive energy-saving equipment has been realized by adding inverter control to reduce transport power.
[0021]
FIG. 1 is a flow chart of hot water supply and cooling by a hybrid energy system to which the present invention is applied. First, main components will be described. 1 is a solar heat collector, 2 is a heat storage tank, 3 is a heat exchanger for hot water supply, 4 is A hot water storage tank, 5 is an auxiliary boiler, 11 is a heat exchanger for recovering waste heat, 12 is a generator for private use, 13 is an absorption refrigerator, 7 is a cooling tower, and 8 is a heat exchanger for heating. The power source of the private generator 12 is a diesel engine, a gas engine, and a turbine. The private generator 12 includes a waste heat recovery device (heat exchanger, waste gas boiler). Moreover, in order to control the drive of each apparatus, the system interconnection board and DC power supply board put together are provided.
[0022]
FIG. 2 is a piping diagram showing the hybrid energy system more specifically . A heating heat source pump 14 is disposed between the heat storage tank 2 and the heat exchanger 8 for heating, and the heat storage tank 2 and the hot water supply. A hot water supply heat source pump 15 is disposed between the heat exchanger 3 and the waste heat recovery pump 16 is disposed between the heat storage tank 2 and the waste heat recovery heat exchanger 11. 2d is a heat collecting pump, and 21 is an oil service tank of the auxiliary boiler 5. A hot water supply heat source pump 17 is provided between the hot water storage tank 4 and the hot water supply heat exchanger 3, and a hot water supply pump 18 is provided between the hot water storage tank 4 and the auxiliary boiler 5. Reference numeral 19 denotes a cold / hot water pipe (return), 20 denotes a cold / hot water pipe (outward), 22 denotes hot water supply (outward) , and 23 denotes hot water supply (return) .
[0023]
FIG. 3 shows a piping diagram around the heat collection circuit of the heat storage tank 2 mainly of the hybrid energy system. The heat storage tank 2 is provided with an internal partition plate and is divided into three tanks, a high temperature tank 2a, an intermediate rectification tank 2b, and a low temperature tank 2c. Thermometers 24 and 25 and three-way valves 26 and 27 are provided on the return pipe side of each circuit. Is provided to control the temperature of the heat storage tank 2.
[0024]
According to such a hybrid energy system, the heat energy collected by the solar heat collector 1 is stored in the heat storage tank 2 by the operation of the heat collection pump 2d, and is used for hot water supply with the operation of the hot water supply heat source pump 15 and the hot water supply pump 18. Hot water supply (outward) 22 and hot water supply (return) 23 are performed through the heat exchanger 3 and the hot water storage tank 4 . The warming of the hot water storage tank 4 uses the heating from the heat storage tank 2 that has recovered heat as a priority circuit, and the auxiliary boiler 5 is operated only when the heating is insufficient . In addition, the heating heat source pump 14 is operated to supply heat energy to the heating heat exchanger 8 and the absorption refrigerator 13 and the cooling tower 7 are driven, so that the cold / hot water pipe 19 and the cold / hot water pipe ) Cold / hot water is supplied to 20 and air conditioning is performed. If the private generator 12 is driven, the waste heat recovery pump 16 is operated to exchange heat between the waste heat recovery heat exchanger 11 and the heat storage tank 2, and excess heat energy is recovered in the heat storage tank 2. It is used again for hot water supply and air conditioning by a series of actions.
[0025]
The variable flow rate of cooling water and cold / hot water during operation is controlled by inverter control. Conventionally, a constant flow of cooling water is operated even when the load is low.In this system, by adjusting the flow rate of cooling water and cold / hot water by inverter control of the conveyance power pump according to the load, The pump is designed to reduce the conveyance power at low load of a pump such as a cold / hot water pump or a cooling water pump that has a long operation time and a large output. Further, by changing the pipe tapping position of the hot water storage tank 4 for hot water supply, the warming of the hot water storage tank 4 becomes a priority circuit with the heating from the heat storage tank 2 where heat is recovered, and the auxiliary boiler is used only when the heating is insufficient. 5 is operated, and the heating by the circulation heat dissipation loss is also the heating by heat recovery, so the energy saving effect is enhanced.
[0026]
Moreover, since the inside of the heat storage tank 2 is a temperature regulating tank type partitioned into three tanks, a high temperature tank 2a, an intermediate rectification tank 2b, and a low temperature tank 2c, the inflow from the high temperature tank 2a to the low temperature tank 2c is automatically distributed. Regardless of the heat load, the temperature of the hot water on the outgoing pipe side of each circuit is stabilized, and the temperature of the hot water in the hot bath 2a on the hot water outlet side can be kept below a certain width and also due to a sudden temperature change Trouble can be prevented. In particular, in the case where the heat storage tank 2 is of a single tank type as in the prior art, the temperature of the hot water supply and the air conditioning heat source with different temperature conditions is likely to be uneven, and the control is unstable. By using the provided temperature regulating tank type, it is possible to improve the effective heat utilization and stabilize the automatic control.
[0027]
In addition, the system interconnection panel and DC power panel for controlling the drive of each device are integrated into one, so the installation space can be reduced and the operation display, trouble display, alarm, etc. are unified, By maintaining the relevance of each device, the operability can be improved and the interlock can be prevented.
[0028]
An example in which the hybrid energy system according to the present invention is applied to an actual hospital will be described below. Hospital structures RC structures, floor space on the ground 5 story is 9,184.2M ^2, high temperature solar vacuum tube type heat collector (2.92m ² / base × 92 units = 268.64m ²⁾ High efficiency type was adopted. The heat insulation thickness of the heat storage tank 2 was 100 mm, and SUS444 was used. The jacket recovery heat amount of the cogeneration system is 418.6 MJ / H, the recovery heat amount of the waste gas boiler is 439.5 MJ / H), the power generation amount of the private generator 12 is 255 kW, and the overall efficiency is 73.9%. The cogeneration system uses a diesel engine generator to supply 255KW and heat 858MJ, and aims to drastically increase operating efficiency and operating rate through commercial interconnection and a single operation detector.
[0029]
A high-efficiency energy-saving system for the primary energy source facility that combines inverter control with a cogeneration system and a solar system was completed, and air conditioning was used for heating using the heat recovered from the cogeneration system and solar thermal energy, and absorption type It is used as a heat source for the refrigerator 13 and is also used for cooling after heat exchange. Further, it is also used for hot water supply via the hot water tank 4 by the heat recovered by the cogeneration system and solar thermal energy. In particular, the conveyance power of the cold / hot water pump 28, the cooling water pump 29, etc. can be greatly reduced by inverter control.
[0030]
The rooftops of existing hospitals are often empty spaces, but the installation of the solar heat collector 1 with a small load on the building and the cogeneration system with a small facility space are the heat storage tank 2 and hot water tank 4 In addition, there are many common points among other peripheral devices such as various heat exchangers, absorption chiller / heaters, etc., especially for existing hospitals where the rooftop with good solar radiation conditions is vacant, and is an optimal system for energy sources. It is effective for securing. Application to welfare facilities other than hospitals and other facilities is also possible.
[0031]
FIG. 4 is a block diagram comparing the facilities of the cogeneration system before the introduction of the system shown by A and the hybrid energy system after the introduction of the invention shown by B. The solid line shows the thermal piping system, and the broken line shows the electrical system Shows the wiring. In the facilities after the introduction of the present invention, new construction is shown by double frames in addition to the existing facilities shown by ordinary frames.
[0032]
In a general system before the introduction of this system, electric energy from the electric power company 30 is supplied to the cooling tower 7 and the cooling water pump 29, the absorption chiller / heater 34, the air-cooled heat pump chiller 33 through the cupicle 31 and the distribution board 32, The cold / hot water pump 28 is operated to perform the air conditioning 10 and 10, the hot water supply 9 is performed by the operation of the auxiliary boiler 5, and the illumination 36 and other power 37 are obtained from the distribution board 32. On the other hand, in the hybrid energy system after the introduction of the present invention, the power energy of the private generator 12 is used preferentially, and when there is a shortage of power, power is purchased from the power company 30 to obtain the lighting 36 and other power 37. , The cooling tower 7, the cooling water pump 29, the absorption chiller / heater 34, the absorption refrigeration machine 13, the thermal energy generated by operating the chilling / hot water pump 28, the solar heat collector 1, the private generator 12, and the waste gas Heat energy stored in the heat storage tank 2 by the action of the boiler 38 is heat-exchanged by the heat exchanger 8 for heating and cooling 10 and 10 through the header 39, and the hot water heater 40 and the auxiliary boiler 5 are installed. The heat energy generated by working and the heat source energy stored in the heat storage tank 2 is heat-exchanged by the heat exchanger 3 for hot water supply via the hot water tank 4 Perform hot water supply 9,9, furthermore, cold water pump 28, by cooling water pump 29 to inverter control, and corresponds to the variable flow of cold and hot water and cooling water.
[0033]
Furthermore, the operation of the private generator 12 is detected by the single operation detection device 41 and the power supplied from the electric power company is adjusted by the grid connection 42. A normal cogeneration system is connected to a power company in a commercial connection, but the installation of the isolated operation detection device 41 enables independent operation and high-efficiency operation by the private generator 12 at low load, and private power generation. The operating rate and machine efficiency of the machine 12 can be greatly improved.
[0034]
5 and 6 are graphs showing the heat medium inlet temperature characteristics, and FIG. 5 is a graph showing the heat medium inlet temperature (° C.) and the refrigerating capacity under the condition that the inlet temperature of the cooling water is 31 ° C. and the outlet temperature is 7 ° C. 6) and FIG. 6 shows the relationship between the heating medium inlet temperature (° C.) and C.O.P (coefficient of performance in the case of single use of the hot water tank of the absorption chiller / heater). In FIG. 5, the operating temperature range is 70 ° C. to 95 ° C.
[0035]
In general, the heat recovery temperature of the private generator 12 is often about 75 ° C. to 85 ° C. However, in the case of cooling with low temperature water of 75 ° C. to 85 ° C., C.O.P is 0.5,85 at 75 ° C. It is about 0.67 at ℃, and in this hybrid system, the heat source water at the time of cooling is 88 ℃ ~ by adding heat collection by the vacuum tube type solar heat collector with high heat collecting efficiency to the recovered heat of the private generator 12 It became possible to reach 95 ° C, C.O.P was 0.7 or higher at 88 ° C, and it was confirmed that the refrigerating capacity was improved by 25% or more together with the energy saving effect by improving C.O.P.
[0036]
【The invention's effect】
As described above in detail, according to the present invention, the heat energy collected by the solar heat collector and the heat energy recovered from the waste heat generated by operating the private generator are used for hot water supply from the heat storage tank. Hot water is supplied through heat exchangers and hot water storage tanks, as well as heat exchangers and boilers for heating, cooling and heating through cooling towers and absorption chillers, and variable flow rates of cooling water and cold / hot water during system operation. The inverter control can reduce the conveyance power at the time of low load. Furthermore, warming of the hot water storage tank is not performed at the same level as the heating from the heat-recovered heat storage tank and the auxiliary boiler. Since the temperature can be determined without relying on an auxiliary boiler, the energy saving effect can be enhanced.
[0038]
In the present invention, the system interconnection panel, DC power panel, etc. for controlling the drive of each device are combined into one, so the installation space is reduced and the operation display, trouble display, alarm, etc. are unified. Operability is improved and interlock can be prevented. Furthermore, by docking the two systems, solar heat, which is natural energy, and waste heat generated from private power generation facilities can be used for hot water supply and air conditioning, and heat can be recovered using waste heat from the generator even in rainy weather. In addition, since heat can be recovered from the heat collector even when the generator is stopped, the range of heat recovery efficiency can be expanded compared to the case where each system is installed alone.
[0039]
In addition, since an independent operation detection device can be installed in a private generator and the power supplied from the electric power company can be adjusted according to the operation status detected by the individual operation detection device, the load is less than the generator capacity. There is no need for electricity purchase, and it can be adapted to not only large hospitals but also small and medium buildings by enabling independent operation and high-efficiency operation with a private generator, improving the operating rate and mechanical efficiency.
[0040]
Therefore, according to the present invention, the solar system and the coordination system are docked to store solar heat energy in the heat storage tank, hot water is supplied by operating the hot water source pump and the hot water pump, and further to the heat exchanger for heating. To cool the air by driving the absorption chiller and the cooling tower, and exchange the waste heat discharged from the private generator between the heat exchanger for waste heat recovery and the heat storage tank to obtain excess heat energy. In addition to collecting in the heat storage tank, the variable flow rate of cooling water and cold / warm water during operation is controlled by inverter control of the conveyance power pump according to the load, thereby reducing the conveyance power at low loads. , to enable an efficient operation to increase the relevance of each of the devices by which is adapted to operate an auxiliary boiler only when the heating was insufficient, operation indicator, Reconfigurable display, unified also alarm or the like can provide a hybrid energy system that achieves cost reduction.
[Brief description of the drawings]
FIG. 1 is a flow chart of hot water supply / cooling / heating by a hybrid energy system to which the present invention is applied.
FIG. 2 is a piping diagram more specifically showing the system according to the present invention .
FIG. 3 is a piping diagram around the heat collection circuit of the heat storage tank of the system.
FIG. 4 is a block diagram comparing a general system (hot water supply / cooling / heating / electric equipment) before the introduction of the present system and a hybrid energy system facility after the introduction of the present invention.
FIG. 5 is a graph showing the relationship between cooling medium heating medium inlet temperature (° C.) and refrigeration capacity (%).
FIG. 6 is a graph showing the relationship between cooling medium heating medium inlet temperature (° C.) and C.O.P.
FIG. 7 is a flowchart of a conventional solar system hot water supply / cooling / heating system.
FIG. 8 is a flowchart of a conventional cogeneration system hot water supply / cooling / heating system.
FIG. 9 is a piping diagram around a heat collecting circuit of a heat storage tank in a conventional example using both a solar system and a cogeneration system.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Solar heat collector 2 ... Heat storage tank 2a ... High temperature tank 2b ... Intermediate rectification tank 2c ... Low temperature tank 2d ... Heat collection pump 3 ... Heat exchanger for hot water supply 4 ... Hot water tank 5 ... Auxiliary boiler 6 ... Cold / hot water generator 7 ... Cooling tower 8 ... Heat exchanger for heating 9 ... Hot water supply 10 ... Air conditioning and heating 11 ... Heat exchanger for waste heat recovery 12 ... Private generator 13 ... Absorption refrigerator 14 ... Heating heat source pump 15 ... Hot water supply heat source pump 16 ... Waste heat Recovery pump 17 ... Hot water supply heat source pump 18 ... Hot water supply pump 19 ... Cold / hot water piping (return)
20 ... Cold / hot water piping (out)
21 ... Oil service tank 22 ... Hot water supply (outward)
23 ... Hot water supply (recovery)
24, 25 ... Thermometer 26, 27 ... Three-way valve 28 ... Cold / hot water pump 29 ... Cooling water pump 30 ... Electric power company 31 ... Cupicle 32 ... Distribution board 33 ... Air-cooled heat pump chiller 34 ... Absorption chiller / heater 35 ... Oil tank 36 ... Illumination 37 ... Other power 38 ... Waste gas boiler 39 ... Header 40 ... Hot water heater 41 ... Single operation detection device 42 ... Grid connection

Claims (1)

Solar heat collector, heat storage tank, hot water supply heat exchanger, hot water storage tank, auxiliary boiler, waste heat recovery heat exchanger, private generator, absorption refrigerator, cooling tower, heating heat exchanger and driving of each device In order to control the system, it is equipped with a single grid connection panel and a DC power supply panel. The thermal energy collected by the solar heat collector is stored in the heat storage tank, and the hot water supply pump and hot water pump are operated as the hot water pump is operated. Hot water is supplied through a heat exchanger and hot water storage tank, and heat energy is supplied to the heat exchanger for heating by operating a heating heat source pump, and air conditioning is performed by driving an absorption chiller and a cooling tower. By operating the generator, power is supplied to the building via the cupicle and distribution board, and the waste heat discharged from the private generator is exchanged between the waste heat recovery heat exchanger and the heat storage tank. Collect excess heat energy in the heat storage tank Te, utilized again hot water, heating and cooling, variable flow of cooling water and the cold water at the time of operation, and variably adjusting the flow rate by the inverter controls the conveyance power for the pump in accordance with the load of the conveying power of the low load A hybrid energy system characterized by reducing the temperature and heating the hot water storage tank with priority from the heat recovered heat storage tank and operating the auxiliary boiler only when the heating is insufficient .

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