JP6712510B2 - Hot water supply system - Google Patents

Description

The technique disclosed in this specification relates to a hot water supply system.

The system disclosed in Patent Document 1 is a power storage device that stores power generated by a solar power generation device and power from a commercial power supply, and a device that can operate using the power stored in the power storage device. Is equipped with. The device that operates with the power of the power storage device is, for example, a water heater that boils water. A commercial power supply that supplies electric power to a power storage device generates power by consuming primary energy. For example, commercial power sources generate electricity by consuming coal at thermal power plants.

JP, 2007-295680, A

In recent years, it has been required to reduce the primary energy consumption in consideration of the environment. Therefore, the present specification provides a technique capable of reducing the primary energy consumption when boiling water.

The hot water supply system disclosed in the present specification includes a power storage device that stores power generated by consuming primary energy in a power supply source and power generated by a solar power generation device. Further, the hot water supply system includes a tank for storing water, a heat pump for boiling water stored in the tank using electric power stored in a power storage device, a gas heating device for heating water by burning gas, and a control unit. And a device. The control device calculates the amount of electricity stored by the power supply source out of the amount of electricity stored in the electricity storage device based on the power supplied from the power supply source to the electricity storage device, and calculates the amount of electricity stored by the power supply source and the amount of electricity stored in the tank by the heat pump. Based on the power consumption of the heat pump when boiling water, calculate the amount of power consumed by the power supply source out of the power consumption of the heat pump, and based on the calculated power consumption, consume it at the power supply source. The heat pump that uses the electric power stored in the power storage device based on the calculated primary energy consumption and the calculated amount of primary energy consumption and the amount of heat required to boil the water stored in the tank The first primary energy consumption efficiency when boiling water in the tank is calculated by, and the calculated first primary energy consumption efficiency and the second primary energy consumption efficiency when heating water by gas combustion. When the first primary energy consumption efficiency is higher than the second primary energy consumption efficiency, the operation of boiling up the water in the tank by the heat pump using the electric power stored in the power storage device is permitted.

According to such a configuration, when boiling water, the first primary energy consumption efficiency is calculated according to a predetermined procedure based on the electric power supplied from the power supply source to the power storage device. When the first primary energy consumption efficiency is higher than the second primary energy consumption efficiency, the heat pump can boil the water in the tank. Therefore, water can be boiled in a state where the primary energy consumption efficiency is relatively high. As a result, the primary energy consumption for boiling water can be reduced.

The figure which shows typically the structure of the hot water supply system 1 which concerns on an Example. The figure which shows typically the structure of the water heater 2 which concerns on an Example. The flowchart which shows the control processing in the hot water supply system 1 which concerns on an Example.

The main features of the embodiments described below are listed. The technical elements described below are technical elements that are independent of each other, and exhibit technical usefulness alone or in various combinations, and are not limited to the combinations described in the claims at the time of filing. Absent.

(Feature 1) The control device may compare the first primary energy consumption efficiency and the second primary energy consumption efficiency at a predetermined boiling time.

According to such a configuration, it is possible to determine whether or not the boiling can be executed by the heat pump according to the predetermined boiling time.

(Example)
FIG. 1 shows the configuration of a hot water supply system 1 according to this embodiment. As illustrated in FIG. 1, the hot water supply system 1 includes a solar power generation device 114, a generator 113 (an example of a power supply source), a power storage device 116, a water heater 2, and a power management device 192 (an example of a control device). ) Is provided.

The solar power generation device 114 is a device that generates power by receiving sunlight. The solar power generation device 114 is connected to the power storage device 116 via the power conditioner 118. The electric power generated by the solar power generation device 114 is stored in the power storage device 116.

The generator 113 is a device that generates power by consuming primary energy. The generator 113 uses, for example, gasoline as a fuel to generate electricity. The generator 113 is connected to the power storage device 116 via the power conditioner 118. The electric power generated by the generator 113 is stored in the power storage device 116.

The power conditioner 118 is connected to the commercial power supply 110 (another example of a power supply source). Further, the power conditioner 118 is connected to the water heater 2. The commercial power source 110 generates power by consuming primary energy. For example, the commercial power source 110 generates electricity by consuming coal at a thermal power plant. The commercial power supply 110 is connected to the power storage device 116 via the power conditioner 118. The electric power generated by the commercial power supply 110 is stored in the power storage device 116. The power conditioner 118 can convert AC power from the commercial power supply 110 into DC power and supply the DC power to the power storage device 116. Power conditioner 118 can convert direct-current power from power storage device 116 into alternating-current power and supply it to water heater 2.

The power storage device 116 is a device that stores the electric power supplied via the power conditioner 118. The power storage device 116 can store the power supplied from the solar power generation device 114, the power supplied from the generator 113, and the power supplied from the commercial power supply 110. Further, power storage device 116 can supply the stored power to water heater 2 via power conditioner 118.

The power management apparatus 192 is, for example, a HEMS (Home Energy Management System) controller. The power management apparatus 192 can be connected to an external network. The power management apparatus 192 is connected to the power conditioner 118 and the water heater 2 and can send and receive various information. Power management device 192 can control the operation of power conditioner 118 and water heater 2. The power management device 192 can monitor the power supplied from the solar power generation device 114 to the power storage device 116 via the power conditioner 118. Further, the power management apparatus 192 can monitor the power supplied from the generator 113 to the power storage device 116 via the power conditioner 118. Furthermore, the power management apparatus 192 can monitor the power supplied from the commercial power supply 110 to the power storage device 116 via the power conditioner 118. Further, the power management apparatus 192 can monitor the amount of power stored in the power storage apparatus 116.

Next, the configuration of the water heater 2 will be described. FIG. 2 shows the configuration of the water heater 2 according to this embodiment. As shown in FIG. 2, the water heater 2 includes a hot water supply system 104, a heat pump system 106, and a control device 100.

The heat pump system 106 includes a heat pump 50 and a heat exchanger 58. The heat pump 50 includes a refrigerant circulation path 52 for circulating a refrigerant (for example, R32), a heat exchanger (evaporator) 54, a fan 56, a compressor 62, and an expansion valve 60. The refrigerant circulation path 52 passes through the inside of the heat exchanger 58. Further, the heat exchanger 54, the compressor 62, and the expansion valve 60 are installed in the refrigerant circulation path 52. The operation of the heat pump 50 having the above configuration will be described. The operation of the compressor 62 causes the refrigerant in the refrigerant circulation path 52 to be pressurized by the compressor 62 and become a high-temperature high-pressure gas phase state. The refrigerant that has been pressurized by the compressor 62 and is in the high temperature and high pressure gas phase state is sent to the heat exchanger 58, is cooled by heat exchange with the water in the tank water circulation path 20, is condensed, and becomes the liquid phase state. .. The refrigerant cooled in the heat exchanger 58 and in the liquid phase state is sent to the expansion valve 60 and decompressed in the expansion valve 60 to be in the low temperature and low pressure liquid phase state. The low-temperature low-pressure liquid-phase refrigerant is heated and evaporated in the heat exchanger 54 by heat exchange with the outside air blown by the fan 56, and becomes a gas-phase state. The refrigerant in the gas phase is returned to the compressor 62 and is pressurized again. Therefore, by operating the heat pump 50, the high temperature and high pressure refrigerant can be sent into the refrigerant circulation path 52 passing through the heat exchanger 58.

The hot water supply system 104 includes a tank 10, a tank water circulation path 20, a tap water introduction path 24, a supply path 36, and a burner heating device 81 (an example of a gas heating device).

The tank 10 stores hot water heated by the heat pump 50. The tank 10 is a closed type, and the outside is covered with a heat insulating material. Water is stored in the tank 10 until it is full. The thermistors 12, 14, 16 and 18 are attached to the tank 10 at substantially equal intervals in the height direction of the tank 10. Each thermistor 12, 14, 16, 18 measures the temperature of the water at its mounting position.

The tank water circulation path 20 has an upstream end connected to a lower portion of the tank 10 and a downstream end connected to an upper portion of the tank 10. A circulation pump 22 is interposed in the tank water circulation passage 20. The circulation pump 22 sends the water in the tank water circulation passage 20 from the upstream side to the downstream side. Further, as described above, the tank water circulation path 20 passes through the heat exchanger 58. Therefore, when the heat pump 50 is operated, the water in the tank water circulation path 20 is heated by the heat exchanger 58. Therefore, when the circulation pump 22 and the heat pump 50 are operated, the water in the lower part of the tank 10 is sent to the heat exchanger 58 and heated, and the heated water is returned to the upper part of the tank 10. The tank water circulation path 20 is a water path for storing heat in the tank 10.

The tap water introduction passage 24 has an upstream end connected to the tap water supply source 32. The downstream side of the tap water introduction passage 24 branches into a first introduction passage 24a and a second introduction passage 24b. The downstream end of the first introduction path 24a is connected to the lower portion of the tank 10. The downstream end of the second introduction path 24b is connected in the middle of the supply path 36. A mixing valve 36a for adjusting the ratio of the flow rate of water flowing through the first introduction passage 24a (that is, the supply passage 36) and the flow rate of water flowing through the second introduction passage 24b is arranged at the connection portion. A check valve 26 is provided in the first introduction path 24a. A check valve 28 and a water amount sensor 30 are provided in the second introduction path 24b. The water amount sensor 30 detects the flow rate of tap water flowing in the second introduction path 24b.

The upstream end of the supply path 36 is connected to the upper portion of the tank 10. As described above, the second introduction passage 24b of the tap water introduction passage 24 is connected in the middle of the supply passage 36. A water amount sensor 34 is provided in the supply passage 36 on the upstream side of the connection portion with the second introduction passage 24b. The water amount sensor 34 detects the flow rate of water flowing from the tank 10 into the supply passage 36. A burner heating device 81 is provided in the supply passage 36 on the downstream side of the connection portion with the second introduction passage 24b. The burner heating device 81 heats the water in the supply passage 36. The downstream end of the supply path 36 is connected to the hot water tap 38. The supply passage 36 is provided with a bypass passage 36b that is a passage that bypasses the burner heating device 81. Further, a bypass control valve 36c for adjusting the opening degree of the bypass passage 36b is interposed in the bypass passage 36b.

The control device 100 is electrically connected to the hot water supply system 104 and the heat pump system 106, and controls the operation of each component. The control device 100 is electrically connected to the power management device 192, and can control the operation of each component based on the information transmitted/received to/from the power management device 192.

(Operation of the water heater)
Next, the operation of the water heater 2 of this embodiment will be described. The water heater 2 can perform a boiling operation and a hot water supply operation. Hereinafter, each operation will be described.

(Boiling operation)
The boiling operation is an operation of heating the water in the tank 10 with the heat generated by the heat pump 50. When execution of the boiling operation is instructed by the control device 100, the heat pump 50 starts operating and the circulation pump 22 rotates.

When the heat pump 50 operates, the high-temperature and high-pressure gas-phase refrigerant is sent into the refrigerant circulation path 52 passing through the heat exchanger 58. When the circulation pump 22 rotates, the water in the tank 10 circulates in the tank water circulation passage 20. That is, when the water existing in the lower part of the tank 10 is introduced into the tank water circulation passage 20 and the introduced water passes through the heat exchanger 58, it is heated by the heat of the refrigerant in the refrigerant circulation passage 52 and heated. Water is returned to the top of the tank 10. As a result, high temperature water is stored in the tank 10. A high-temperature water layer is formed on the upper portion of the tank 10, and a low-temperature water layer is formed on the lower portion.

(Hot water operation)
The hot water supply operation is an operation of supplying the water in the tank 10 to the hot water tap 38. The hot water supply operation can be executed even during the above boiling operation. When the hot water tap 38 is opened, the control device 100 opens the mixing valve 36a. Then, due to the water pressure from the tap water supply source 32, tap water flows into the lower portion of the tank 10 from the tap water introduction passage 24 (first introduction passage 24a). At the same time, the hot water in the upper part of the tank 10 is supplied to the hot water tap 38 via the supply path 36.

When the temperature of the water supplied from the tank 10 to the supply passage 36 (that is, the temperature detected by the thermistor 12) is higher than the hot water supply set temperature, the control device 100 adjusts the mixing valve 36a to set the second introduction passage. Tap water is introduced into the supply path 36 from 24b. Therefore, the water supplied from the tank 10 and the tap water supplied from the second introduction path 24b are mixed in the supply path 36. The control device 100 adjusts the opening ratio of the mixing valve 36a so that the temperature of the water supplied to the hot water tap 38 matches the hot water set temperature. On the other hand, control device 100 operates burner heating device 81 when the temperature of the water supplied from tank 10 to supply path 36 is lower than the hot water supply set temperature. Therefore, the water passing through the supply passage 36 is heated by the burner heating device 81. The heated water is mixed with water from the bypass passage 36b whose opening is adjusted by the bypass control valve 36c, and is supplied to the hot water supply stopper 38. The control device 100 controls the output of the burner heating device 81 so that the temperature of the water supplied to the hot water tap 38 matches the hot water supply set temperature.

As described above, in the water heater 2 of the hot water supply system 1, the water is heated by the heat pump 50 during the boiling operation. Also, the water may be heated by the burner heating device 81 during the hot water supply operation. The heat pump 50 heats water using the electric power stored in the power storage device 116. Electric power is supplied to the power storage device 116 from the solar power generation device 114, the commercial power supply 110, and the generator 113. The solar power generation device 114 does not consume primary energy because it generates power using natural energy (sunlight). On the other hand, the commercial power supply 110 and the generator 113 consume primary energy. Further, the burner heating device 81 consumes primary energy because it heats water by burning gas.

When boiling water, the primary energy consumption of the hot water supply system 1 can be reduced by considering the primary energy consumption of the heat pump 50 and the primary energy consumption of the burner heating device 81. Therefore, the hot water supply system 1 executes the following control processing.

FIG. 3 shows a control process in the hot water supply system 1. As illustrated in FIG. 3, in S11, the power management apparatus 192 measures the power p1 [kW] supplied from the solar power generation apparatus 114 to the power storage apparatus 116. The electric power supplied from the solar power generation device 114 to the power storage device 116 is electric power generated by natural energy (sunlight). This electric power is the electric power generated without consuming the primary energy.

In subsequent S12, power management device 192 measures electric power p2 [kW] supplied from commercial power supply 110 to power storage device 116. Electric power supplied from the commercial power source 110 to the power storage device 116 is, for example, electric power generated by consuming coal. This electric power is the electric power generated by consuming the primary energy.

In subsequent S13, power management device 192 measures power p3 [kW] supplied from power generator 113 to power storage device 116. Electric power supplied from power generator 113 to power storage device 116 is, for example, electric power generated by consuming gasoline. This electric power is the electric power generated by consuming the primary energy.

In subsequent S14, power management device 192 measures the amount B [kWh] of electricity stored in electricity storage device 116. In the power storage device 116, electric power generated without consuming the primary energy (electric power from the solar power generation device 114) and electric power generated by consuming the primary energy (electric power from the commercial power supply 110 and the generator 113). ) Is stored.

In subsequent S15, the power management apparatus 192 calculates a stored power amount C [kWh] of the stored power amount B [kWh] of the power storage device 116 by the power p2 supplied from the commercial power supply 110 to the power storage device 116. Power management device 192 calculates an integrated value by integrating power p2 supplied from commercial power supply 110 to power storage device 116 over a predetermined time. The integrated value of the electric power p2 corresponds to the amount C [kWh] of electricity stored by the commercial power source 110.

In subsequent S16, the power management apparatus 192 calculates the amount D [kWh] of electricity stored in the electricity storage device 116 by the power p3 supplied from the generator 113 to the electricity storage device 116, out of the amount B [kWh] of electricity storage. Power management device 192 calculates an integrated value by integrating power p3 supplied from power generator 113 to power storage device 116 over a predetermined time. The integrated value of the electric power p3 corresponds to the amount D [kWh] of electricity stored by the generator 113.

In subsequent S17, the power management apparatus 192 calculates the amount of heat Q [kWh] required to boil the water in the tank 10. For example, the capacity of the tank 10 is M [L (liter)]. Further, it is assumed that the total amount of water (M[L]) in the tank 10 is I° C. (for example, 20° C.). Further, it is assumed that the total amount of water (M[L]) in the tank 10 is boiled to H° C. (for example, 40° C.). In this case, the amount of heat Q [kWh] required to boil the water in the tank 10=capacity M×(H° C.−I° C.).

In subsequent S18, when the power management apparatus 192 heats the water in the tank 10 by the heat pump 50 based on the heat quantity Q [kWh] calculated in S17 and the energy consumption efficiency COP _HP of the heat pump 50, the heat pump 50 The power consumption R [kWh] to be consumed is calculated. Specifically, the power consumption amount R[kWh] of the heat pump 50=heat amount Q/COP _HP . The energy consumption efficiency COP _HP of the heat pump 50 is a value calculated in advance for each product.

In subsequent S19, when the power management apparatus 192 uses the power stored in the power storage apparatus 116 to boil the water in the tank 10 by the heat pump 50, the power consumption amount R [kWh] The power consumption amount J [kWh] borne by the power supply 110 is calculated. The power management apparatus 192 calculates the power consumption amount J [kWh] borne by the commercial power supply 110 based on the ratio of the stored power quantity C [kWh] from the commercial power supply 110 to the power storage quantity B [kWh] of the power storage device 116. Specifically, the power consumption amount J [kWh] borne by the commercial power source 110=the power consumption amount R of the heat pump 50×the storage amount C/the storage amount B.

In subsequent S20, when the power management apparatus 192 uses the power stored in the power storage apparatus 116 to boil the water in the tank 10 by the heat pump 50, the power management apparatus 192 generates power among the power consumption R [kWh] of the heat pump 50. The power consumption amount K [kWh] borne by the machine 113 is calculated. The power management apparatus 192 calculates the power consumption amount K [kWh] that the commercial power supply 110 bears based on the ratio of the storage amount D [kWh] of the power generator 113 to the storage amount B [kWh] of the power storage device 116. Specifically, the power consumption amount K [kWh] borne by the generator 113=the power consumption amount R of the heat pump 50×the storage amount D/the storage amount B.

In subsequent S21, the power management apparatus 192 calculates the primary energy consumption amount E [kWh] consumed by the commercial power source 110. The power management apparatus 192 calculates the primary energy consumption amount E [kWh] by the commercial power source 110 based on the power consumption amount J [kWh] that the commercial power source 110 bears. The power management apparatus 192 calculates the primary energy consumption E [kWh] using the power generation efficiency a [%] of the commercial power source 110 and the power storage efficiency c [%] of the power storage apparatus 116. Specifically, the primary energy consumption amount E [kWh]=power consumption amount J/(power generation efficiency a/100)/(storage efficiency c/100). The power generation efficiency a [%] at the commercial power source 110 is, for example, the efficiency when power is generated at a thermal power plant, and is 40% as an example. The power storage efficiency c [%] of the power storage device 116 is the efficiency at the time of charging/discharging, and is 70% as an example.

In subsequent S22, the power management apparatus 192 calculates the primary energy consumption amount F [kWh] consumed by the generator 113. The power management apparatus 192 calculates the primary energy consumption amount F [kWh] by the generator 113 based on the power consumption amount K [kWh] that the generator 113 bears. The power management apparatus 192 calculates the primary energy consumption amount F [kWh] using the power generation efficiency b [%] in the power generator 113 and the power storage efficiency c [%] in the power storage device 116. Specifically, the primary energy consumption amount F [kWh]=power consumption amount K/(power generation efficiency b/100)/(storage efficiency c/100). The power generation efficiency b [%] of the power generator 113 is the efficiency when power is generated by the power generator 113, and is 60% as an example.

In subsequent S23, the power management apparatus 192 calculates the total G [kWh] of the primary energy consumption E [kWh] of the commercial power source 110 and the primary energy consumption F [kWh] of the generator 113. That is, total primary energy consumption G [kWh]=primary energy consumption E+primary energy consumption F.

In subsequent S24, the power management apparatus 192 calculates the first primary energy consumption efficiency COP1 when the water in the tank 10 is boiled by the heat pump 50. The power management apparatus 192 calculates the first primary energy consumption efficiency COP1 based on the total primary energy consumption G [kWh] and the heat quantity Q [kWh] calculated in S17. Specifically, the first primary energy consumption efficiency COP1=heat amount Q/total primary energy consumption amount G.

In subsequent S25, the power management apparatus 192 compares the first primary energy consumption efficiency COP1 described above with the second primary energy consumption efficiency COP2 when the water is heated by the burner heating apparatus 81. The second primary energy consumption efficiency COP2 is a COP when water is heated by combustion of gas, and is a value calculated in advance depending on the product of the water heater 2 used. When the first primary energy consumption efficiency COP1 is higher than the second primary energy consumption efficiency COP2, the power management apparatus 192 determines Yes in S25 and proceeds to S26. On the other hand, when the first primary energy consumption efficiency COP1 is less than or equal to the second primary energy consumption efficiency COP2, the power management apparatus 192 determines No in S25, skips S26, and ends the process.

In S26, the power management apparatus 192 permits the boiling operation. Thereby, the water in the tank 10 can be boiled up by the heat pump 50. When the controller 100 gives an instruction to execute the boiling operation, the heat pump 50 operates.

The configuration and operation of the hot water supply system 1 have been described above. As is clear from the above description, hot water supply system 1 includes power storage device 116. Power storage device 116 stores the power generated by consuming the primary energy in commercial power supply 110 and generator 113, and the power generated by solar power generation device 114. The hot water supply system 1 also includes a tank 10 for storing water, and a heat pump 50 for boiling up the water stored in the tank 10. The heat pump 50 operates using the electric power stored in the power storage device 116. The hot water supply system 1 also includes a burner heating device 81 that heats water by burning gas and a power management device 192. Based on the electric power p2, p3 supplied from the commercial power supply 110 and the power generator 113 to the power storage device 116, the power management device 192 uses the power storage amounts D of the power storage device 116 to store the power storage amounts C, D by the commercial power supply 110 and the power generator 113. To calculate. In addition, the power management apparatus 192 calculates, based on the calculated power storage amounts C and D by the commercial power source 110 and the generator 113, and the power consumption amount R of the heat pump 50 when the water in the tank 10 is boiled by the heat pump 50. Of the power consumption R of the heat pump 50, the power consumptions J and K borne by the commercial power supply 110 and the generator 113 are calculated. Then, the power management apparatus 192 calculates the primary energy consumption amounts E and F consumed by the commercial power source 110 and the generator 113 based on the calculated power consumption amount. That is, the power management apparatus 192 calculates the total primary energy consumption G of the power supply sources that consume the primary energy. In addition, the power management apparatus 192 calculates the power stored in the power storage apparatus 116 based on the calculated total primary energy consumption G and the amount of heat Q required to boil the water stored in the tank 10. The first primary energy consumption efficiency COP1 when the water in the tank 10 is boiled by the heat pump 50 is calculated. Then, the power management apparatus 192 compares the calculated first primary energy consumption efficiency COP1 with the second primary energy consumption efficiency COP2 when water is heated by gas combustion, and compares the first primary energy consumption efficiency COP2. When COP1 is higher than the second primary energy consumption efficiency COP2, the heat pump 50 allows the operation of boiling the water in the tank 10 using the electric power stored in the power storage device 116.

With this configuration, when the first primary energy consumption efficiency COP1 is higher than the second primary energy consumption efficiency COP2, the heat pump 50 can boil the water in the tank 10. Therefore, water can be boiled in a state where the primary energy consumption efficiency is relatively high. As a result, the primary energy consumption for boiling water can be reduced.

On the other hand, when the first primary energy consumption efficiency COP1 is equal to or lower than the second primary energy consumption efficiency COP2, the heat pump 50 cannot boil the water in the tank 10. Therefore, the temperature of the water in the tank 10 does not rise. In this case, the burner heating device 81 heats water during the hot water supply operation, but since the second primary energy consumption efficiency COP2 is equal to or higher than the first primary energy consumption efficiency COP1, the primary energy consumption efficiency is compared. The water can be heated at an extremely high temperature. That is, the water can be heated by the burner heating device 81 when the second primary energy consumption efficiency COP2 when heating water by gas combustion is relatively high. This can reduce the primary energy consumption when heating water.

Although one embodiment has been described above, the specific mode is not limited to the above embodiment. For example, the timing at which the power management apparatus 192 compares the first primary energy consumption efficiency COP1 and the second primary energy consumption efficiency COP2 is not particularly limited. The power management apparatus 192 may compare the first primary energy consumption efficiency COP1 and the second primary energy consumption efficiency COP2 at a predetermined boiling time. For example, the first primary energy consumption efficiency COP1 and the second primary energy consumption efficiency COP2 at the daytime boiling time and the nighttime boiling time may be compared. During the daytime, since the amount of electric power generated by natural energy (sunlight) increases, the first primary energy consumption efficiency COP1 increases. On the other hand, at night, since the amount of electric power generated by natural energy (sunlight) increases, the first primary energy consumption efficiency COP1 decreases. According to such a configuration, the power management apparatus 192 makes a comparison at a predetermined boiling time, so that the comparison can be made periodically. Further, it is possible to determine whether or not the boiling can be executed by the heat pump 50 according to the predetermined boiling time.

Specific examples of the present invention have been described above in detail, but these are merely examples and do not limit the scope of the claims. The technology described in the claims includes various modifications and changes of the specific examples illustrated above. The technical elements described in the present specification or the drawings exert technical utility alone or in various combinations, and are not limited to the combinations described in the claims at the time of filing. Further, the technique illustrated in the present specification or the drawings can achieve a plurality of purposes at the same time, and achieving the one purpose among them has technical utility.

1: Hot water supply system 2: Hot water supply device 10: Tank 12: Thermistor 14: Thermistor 16: Thermistor 18: Thermistor 20: Tank water circulation passage 22: Circulation pump 24: Tap water introduction passage 24a: First introduction passage 24b: Second introduction passage 26: Check valve 28: Check valve 30: Water quantity sensor 32: Tap water supply source 34: Water quantity sensor 36: Supply path 36a: Mixing valve 36b: Bypass path 36c: Bypass control valve 38: Hot water tap 50: Heat pump 52: Refrigerant circulation path 54: Heat exchanger 56: Fan 58: Heat exchanger 60: Expansion valve 62: Compressor 81: Burner heating device 100: Control device 104: Hot water supply system 106: Heat pump system 110: Commercial power supply 113: Generator 114 : Solar power generation device 116: Power storage device 118: Power conditioner 192: Power management device

Claims (2)

A power storage device that stores the power generated by consuming the primary energy in the power supply source and the power generated by the solar power generation device,
A tank to store water,
A heat pump for boiling water stored in the tank using electric power stored in the power storage device;
A gas heating device that heats water by burning gas,
And a control device,
The control device calculates an amount of electricity stored by the power supply source among the amounts of electricity stored in the electricity storage device based on electric power supplied from the power supply source to the electricity storage device, and calculates the amount of electricity stored by the power supply source. , Based on the power consumption of the heat pump when boiling the water in the tank by the heat pump, to calculate the power consumption of the power supply source of the power consumption of the heat pump, the calculated consumption Based on the amount of electric power, the amount of primary energy consumed by the power supply source is calculated, based on the calculated amount of primary energy consumed and the amount of heat required to boil the water in the tank, the storage of electricity. The first primary energy consumption efficiency in the case of boiling the water in the tank by the heat pump using the electric power stored in the device is calculated, and the calculated first primary energy consumption efficiency and the water by gas combustion are calculated. When the first primary energy consumption efficiency is higher than the second primary energy consumption efficiency, the electric power stored in the electric storage device is used to A hot water supply system that allows operation of boiling water in the tank by a heat pump. The hot water supply system according to claim 1, wherein the control device compares the first primary energy consumption efficiency and the second primary energy consumption efficiency at a predetermined boiling time.

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