JP5798880B2 - Heat pump water heater - Google Patents

Description

  The present invention relates to a heat pump water heater.

  2. Description of the Related Art Heat pump water heaters having a boiling function for driving a heat pump cycle using midnight power or the like to heat low temperature water and store hot water at a desired temperature in a tank are known.

  Such a heat pump water heater generally stores hot water at a desired temperature in a tank mainly at night using midnight power, and uses the hot water stored at night in the daytime.

  In this way, heat pump water heaters store hot water at night and use the hot water stored at night during the day, so the heat pump cycle that operates to boil hot water basically does not perform the operation to boil hot water during the day. The time during which the operation is stopped becomes longer.

  On the other hand, heat pump water heaters are broadly divided into functions that boil hot water and functions that use hot water such as adjusting the temperature of stored hot water to discharge water, and installing and maintaining the product. Considering this, the heat pump side unit with the function to boil hot water and the tank side unit with the function to store hot water and use the stored hot water are configured as separate units. It is widely used to perform operation control by sharing information on each unit by communication connection.

  In such a heat pump water heater, since the time during which the heat pump side unit is stopped becomes long, there is a problem that power (standby power) during the operation stop of the heat pump side unit is wasted.

  In order to cope with this problem, a method is proposed in which a tank-side controller arranged in the tank-side unit controls an energization breaker that supplies and cuts off the operating power supplied to the heat pump unit (see, for example, Patent Document 1). Has been.

Japanese Patent No. 3618807

  The heat pump water heater has a path through which hot water circulates between the tank side unit and the heat pump side unit, and this water path is always sealed with hot water, so that in the environment where the outside air temperature is low, the remaining water in the heat pump side unit In addition, residual water in the water path pipe connecting the tank side unit and the heat pump side unit may freeze.

  In the hot water supply apparatus described in Patent Document 1, the outside air temperature is detected and stored during the boiling operation, and after the operation power of the heat pump side unit is cut off after the operation is stopped, the temporary temperature is temporarily stored based on the stored outside air temperature. By determining the interval for energizing the heat pump side unit and temporarily energizing it, the sensor information on the heat pump side is communicated to the controller on the tank unit side, and freezing of the equipment is prevented based on this communication information. I am driving.

However, in the hot water supply device described in Patent Document 1, even when temporary communication is performed to acquire sensor information of the heat pump side unit, the drive circuit that drives the compressor and the like is energized.
The electric power consumed in the meantime increases, and the heat pump side unit controller resumes energization from the state where the electric power is cut off. Therefore, the heat pump side unit controller usually needs to perform a series of start-up controls. There is a problem that the heat pump side unit controller takes time to communicate and output each sensor information and consumes electric power.

  Furthermore, in the case of providing a circuit breaker that is independent of the energization of the drive circuit for driving the compressor of the heat pump side unit and the energization of the heat pump side unit controller, the electricity for connecting the tank side unit and the heat pump side unit Wiring increased, resulting in reduced workability and increased equipment costs.

  An object of the present invention is to provide a water heater controller that reduces power consumption during operation standby and also reduces power consumption when information is communicated between a tank side unit and a heat pump side unit.

The present invention includes a heat pump cycle in which a compressor for compressing a refrigerant, a refrigerant flow path of a liquid-refrigerant heat exchanger, a pressure reducing valve, and an evaporator are connected in an annular shape through a refrigerant pipe, and the liquid-refrigerant heat exchange A tank for storing the liquid to be heated heated by the vessel, a pump for flowing the liquid to be heated to the liquid- refrigerant heat exchanger, a fan for blowing air to exchange heat between the air and the refrigerant in the evaporator, Based on sensor outputs from various sensors connected to a compressor driving circuit for driving the compressor at a variable speed, a fan driving circuit for driving the fan at a variable speed , and the circulation pump, And a heat pump unit controller for controlling the compressor drive circuit and performing a boiling operation for storing the heated liquid at a target boiling temperature in a tank, the compressor drive circuit, and the fan drive circuit A load power circuit breaker switching the supply or interruption of operating power to, arranged in the tank unit side, and a tank unit side controller communicates with the heat pump unit side controller, wherein the heat pump cycle, the compressor drive A heat pump water heater in which a circuit, the fan drive circuit, and the heat pump unit side controller are arranged on a heat pump unit side , wherein the heat pump unit side controller is connected in communication with the tank unit side controller, and the heat pump A main controller that inputs sensor outputs from each sensor of the cycle, controls the pressure reducing valve and the circulation pump, and calculates a target frequency of the compressor and a target frequency of the fan;
The compressor is connected to the main controller for variable speed control so that the compressor has a target frequency calculated by the main controller, and the fan can be set to a target frequency calculated by the main controller. The main controller controls the load power circuit breaker based on the state of the heat pump water heater during operation standby, and communicates from the tank unit side controller during operation standby . The operation is stopped based on the obtained tank status on the tank unit side .

  ADVANTAGE OF THE INVENTION According to this invention, the hot water supply which can suppress the power consumption required for the information communication of a tank unit side controller and a heat pump unit side controller small, reducing the power consumption (standby power) of a boiling state by a boiling operation. A machine control device can be provided.

1 is a block diagram of a water heater control device showing an embodiment of the present invention. It is a system configuration | structure figure of the heat pump water heater which concerns on an Example. 1 is a block diagram of a water heater control device showing an embodiment of the present invention. It is a control flowchart of the water heater control apparatus which concerns on an Example.

  Embodiments of the present invention will be described below with reference to the drawings.

  FIG. 1 is a block diagram showing an example of the hot water supply controller of the present embodiment. FIG. 2 shows a system configuration diagram of the heat pump water heater of the water heater controller. FIG. 3 is a block diagram showing another embodiment of the hot water supply controller, and FIG. 4 shows a control flow diagram of the hot water controller.

  The hot water supply controller includes a heat pump cycle in which an evaporator 7 provided with a compressor 4, a refrigerant flow path of a water-refrigerant heat exchanger 5, a pressure reducing valve 6, and a fan 8 is annularly connected by refrigerant piping, and hot water for hot water supply A hot water storage tank 9 for storing water and a hot water flow path of the water-refrigerant heat exchanger 5 are connected by a connecting pipe 3, and a hot water circuit having a circulation pump 10 in the middle, and a compressor drive for driving the compressor 4. A circuit 111, a fan motor 113 that rotates the fan 8, a fan motor drive circuit 112 that drives the fan motor 113, a heat pump unit side controller 18, and a load power breaker 108 are provided.

  Further, in FIG. 1, the heat pump unit side controller 18 includes a main controller 105, a sub-controller 110 connected to the main controller 105 by communication wiring 107, and a main controller that supplies operating power to the main controller 105. An operating power supply unit 104, and a load power supply unit 109 that supplies operating power to the compressor driving circuit 111, the fan motor driving circuit 112, and the sub-controller 110 are provided.

  The heat pump unit 1 includes an outside air temperature Ta detector 17 that detects the ambient temperature of the heat pump unit 1, an incoming water temperature Twi detector 15 that detects an incoming water temperature of the water to the water-refrigerant heat exchanger 5, and the water A hot water temperature Two detecting unit 16 for detecting the temperature of hot water discharged from the refrigerant heat exchanger 5, and the main controller 105 mounted on the heat pump unit side controller 18 includes the outside air temperature Ta Temperature signals detected by the detection unit 17, the incoming water temperature Twi detection unit 15, and the tapping temperature Two detection unit 16 are input.

  On the other hand, the tank unit side controller 19 mounted on the tank unit 2 includes a tank unit controller 102 connected to the main controller 105 mounted on the heat pump unit side controller 18, and the tank unit controller 102 includes The temperature signals detected by the tank temperature detectors 20a to 20e are input.

  A heat pump water heater provided with the water heater controller includes a heat pump unit 1 in which a refrigeration cycle including a water-refrigerant heat exchanger 5 shown on the left side of FIG. 2 is mounted, and a tank 9 shown on the right side of the drawing. And a tank unit 2 in which the hot water supply circuit is included. And the heat pump unit 1 and the tank unit 2 have a structure connected using the connection piping 3 in the installation place of a heat pump water heater. The tank 9 often stores hot water, and in this case is called a hot water storage tank.

  The refrigeration cycle includes a compressor 4 that compresses the refrigerant, a water-refrigerant heat exchanger 5 that exchanges heat between the high-temperature and high-pressure refrigerant discharged from the compressor 4 and water introduced from the tank 9, and water-refrigerant heat. The pressure reducing valve 6 for reducing the pressure of the refrigerant flowing out of the exchanger 5 and the evaporator 7 for exchanging heat with the air for the low-temperature and low-pressure pressure reduced by the pressure reducing valve 6 are connected in an annular manner via a refrigerant pipe. It has a configuration. The evaporator 7 has a structure in which outside air is ventilated by a fan 8. In this refrigeration cycle, carbon dioxide is used as a refrigerant.

  The capacity of the compressor 4 is controlled by the heat pump unit side controller 18 so that the temperature of the hot water heat-exchanged by the water-refrigerant heat exchanger 5 becomes a preset target hot water temperature. Specifically, the compressor 4 is an inverter compressor whose capacity is controlled by controlling the rotation speed of the compressor. However, it is not limited to this, For example, the compressor which performs capacity control by returning the discharged refrigerant to the suction side may be used. The compression method of the compressor is a scroll method, but may be a rotary method or a reciprocating method.

  The water cycle includes a tank 9 that stores a necessary amount of hot water, a pump (circulation pump) 10 that guides water at the bottom of the tank 9, and water-refrigerant that exchanges heat discharged from the pump (circulation pump) 10 with the refrigerant. The heat exchanger 5 is annularly connected by a circulation pipe, and the water discharged from the water-refrigerant heat exchanger 5 is returned to the top of the tank 9. That is, in the embodiment, the water flow path F starts from a portion where water is extracted from the tank 9 and ends as a portion where hot water is returned to the tank 9. The bottom of the tank 9 is connected to a water supply source such as a water supply (not shown) via a water supply pipe 11, and a hot water supply pipe 12 for supplying hot water to a hot water supply terminal such as a faucet or a shower is connected to the top.

  The compressor 4 is provided with a compressor temperature sensor 13 for measuring the housing temperature. Thereby, the temperature of the refrigerant discharged from the compressor 4 (refrigerant discharge temperature) can be detected. The refrigerant discharge temperature may be a temperature detected by a temperature sensor provided in the refrigerant discharge pipe. However, the detection of the casing temperature of the compressor 4 as the refrigerant discharge temperature can suppress the fluctuation of the refrigerant temperature and can control the compressor 4 more easily than the temperature of the refrigerant discharge pipe. Has merit.

  A water-refrigerant heat exchanger serving as a water temperature detector 15 that detects the temperature of water flowing into the water-refrigerant heat exchanger 5 is provided in a water cycle pipe provided before and after the water-refrigerant heat exchanger 5. An inlet water temperature sensor and a water-refrigerant heat exchanger outlet hot water temperature sensor are provided as a water temperature detector 16 that measures the temperature of water flowing out of the water-refrigerant heat exchanger 5.

  In the heat pump water heater, a hot water storage tank is arranged in a tank unit, and a hot water supply pipe for supplying hot water to a hot water supply terminal such as a faucet or a shower is connected. Therefore, the temperature of each part of the tank is detected from the detected values of the tank temperature sensors 20a to 20e. It is necessary to perform control such as determining the necessity of raising operation and adjusting the hot water temperature supplied to the hot water supply terminal such as a faucet or shower to a desired temperature. Centralized management is desirable.

  For example, when performing a boiling operation to store hot water in the hot water storage tank 9, the tank unit side controller calculates the remaining hot water amount (ratio of hot water to the hot water storage tank capacity) from the current temperature of each part of the tank, and Calculate the operation time for boiling hot water to a predetermined temperature and determine the timing to start the operation, and start the operation from the tank unit side controller 19 to the heat pump unit side controller 18 at this timing It is only necessary to output a command to communicate. At this time, the target temperature for boiling is similarly output from the tank unit controller 19 to the heat pump unit controller 18 so that the heat pump unit can obtain the target boiling temperature.

  In addition, when it is judged that the heat pump water heater is not enough for the amount of heat boiled at night, the heat pump water heater may be operated in the daytime.

  The heat pump unit 1 can perform not only the above-described boiling operation and boiling operation, but also an air venting operation that operates only the circulation pump, and a freeze prevention operation that prevents freezing of residual water in the heat pump unit 1 and the connection pipe 3. Generally, in these operations, the tank unit side controller 19 determines whether or not the operation is necessary in the same manner as the boiling operation, and when the operation is necessary, the tank unit side controller 19 to the heat pump unit side controller. The operation command may be output to 18 by communication.

  Thus, the heat pump side controller switches between supplying and shutting off the operating power to the compressor drive circuit based on the state of the heat pump water heater during operation standby. The conditions of the heat pump water heater include the status of the tank, such as whether the amount of heat in the tank requires boiling operation or additional heating operation, the status of the heat pump unit, such as whether anti-freezing operation is necessary, The situation of the heat pump water heater straddling the tank and the heat pump unit, such as whether it is necessary to vent the heating circuit of the heating liquid or the pump arranged in this heating circuit, is mentioned.

  Next, a method for reducing standby power when the heat pump unit 1 of the heat pump water heater is stopped (in operation standby state) by the water heater controller of the present embodiment will be described with reference to the flowchart of FIG. explain.

  In step S1, the heat pump unit 1 whose operation has been stopped communicates an operation command from the tank unit controller 102 mounted on the tank unit side controller 19 by the main controller 105 mounted on the heat pump unit side controller 18. Then, it is determined whether or not there is a predetermined operation command. Here, for example, when a heat pump cycle operation involving the operation of the compressor 4 or the fan 8 is required, such as a boiling operation, the process proceeds to step S2, and the main controller 105 energizes the load power breaker 108 to turn on the sub power Operating power is supplied to the controller 110, the compressor drive circuit 111, and the fan motor drive circuit 112. And it progresses to step S3 and performs the driving | operation accompanied by the driving | operation of the heat pump cycle instruct | indicated by the tank unit controller 102. FIG.

  On the other hand, if there is no operation command from the tank unit side controller or there is no operation involving the operation of the compressor 4 or the fan 8 in step S1, the process proceeds to step S4, where the main controller 105 The operation power supply to the sub-controller 110, the compressor drive circuit 111, and the fan motor drive circuit 112 is cut off by setting 108 to the cut-off side. Thereby, first, unnecessary standby power consumption can be cut.

  In step S4, after the load power breaker 108 is set to the breaker side, in step S5, the main controller 105 confirms the control information in the heat pump unit and confirms that there is no problem even if the main controller 105 stops operating. In the case where the stop preparation is completed, the process proceeds to step S6 and the main controller 105 communicates and outputs a stop preparation completion signal to the tank unit controller 102.

  In step S <b> 7, the main controller 105 of the heat pump unit side controller 18 determines whether or not there is communication reception from the tank unit controller 102 of the tank unit side controller 19. For example, after the main controller 105 communicates and outputs a stop preparation completion signal to the tank unit controller 102, the main controller 105 does not receive communication from the tank unit controller for a predetermined time (for example, 30 seconds). In other words, if a communication pulse input cannot be obtained, the process proceeds to step 8 as the meaning of permitting the operation stop from the tank unit controller 102 to the main controller 105, and the main controller 105 stops the operation. Here, in this embodiment, the main controller 105 determines that the operation stop from the tank unit controller 102 is permitted due to the stop of communication from the tank unit controller 102 to the main controller 105. It goes without saying that the same effect can be obtained by a method of adding permission information or a method of transmitting a signal by providing a dedicated operation stop permission signal line.

  Thus, the main controller 105 mounted on the heat pump unit-side controller 18 stops operating, thereby further reducing the power (standby power) consumed by the heat pump unit 1 from the state where the load power breaker 108 is disconnected. be able to.

  Here, the main controller 105 stops operating by setting a microcomputer (not shown) constituting the main controller 105 to a standby mode or a sleep mode, which are functions unique to the microcomputer, and executing a program, a timer in the microcomputer, or the like. Just stop.

  Next, a method for restarting the operation of the main controller 105 mounted on the heat pump unit side controller 18 will be described.

  The microcomputer mentioned above generally resumes operation under its own control because the program is stopped from a state in which operations such as standby mode and sleep mode are stopped, especially in a state where power consumption is reduced. Usually, the operation of changing the input state of a dedicated terminal of the microcomputer, for example, changing the input state of a predetermined terminal from H (high) to L (low) or from L to H To resume. Therefore, the connection wiring 103 that is mounted on the tank unit side controller 19 and communicatively connects the tank unit controller 102 and the main controller 105 mounted on the heat pump unit side controller 18 is branched in the heat pump unit side controller 18. The tank unit controller 102 mounted on the tank unit side controller 19 outputs a pulse signal such as a communication output to the main controller 105 of the heat pump unit side controller 18 by connecting the microcomputer to a dedicated terminal for restarting the operation. Thus, the operation of the main controller 105 can be resumed (steps S9 and S10).

  As described above, the heat pump unit-side controller 18 can greatly reduce the power consumption in a state where the operation of the heat pump unit 1 is stopped, that is, the standby power.

  Next, when the operation of the heat pump unit is stopped and the operation of the heat pump unit side controller 18 is stopped, the tank unit side controller 19 obtains information such as a sensor detection value mounted on the heat pump unit 1. The operation will be described.

  In the heat pump water heater, since the heat pump unit 1 and the tank unit 2 are separate casings, the heat pump water heater can be installed in a place where the heat pump unit 1 and the tank unit 2 are separated depending on the installation environment. The unit 1 and the tank unit 2 are often installed outdoors, but in some cases, the tank unit 2 is installed indoors and the heat pump unit 1 is installed outdoors.

  In the heat pump water heater, since the residual water remains in the water piping inside the device even when the operation is stopped, the residual water in the device may be frozen when the ambient temperature decreases. In particular, in the heat pump unit 1, the water in the pipe is completely retained in a state where the operation is stopped, and the heat pump unit 1 is generally installed outdoors, so that the water in the device is more likely to freeze. .

  Here, as described above, when the tank unit 2 is installed indoors and the heat pump unit 1 is installed outdoors, or when the tank unit 2 and the heat pump unit 1 are installed separately, the tank unit side control mounted on the tank unit 2 is controlled. The vessel 19 is mounted on the heat pump unit 1 in order to reliably prevent the freezing of the heat pump unit 1 because it is difficult to predict the freezing of the heat pump unit 1 with only the detection value of the sensor inside the tank unit. Information such as the detection value of the sensor, for example, the incoming water temperature Twi and the outside air temperature Ta is required.

  In the water heater controller of the present embodiment, the power consumption when the sensor information of the heat pump unit 1 is transmitted to the tank unit side controller can be reduced in order to predict and prevent such freezing.

  Specifically, as described above, in the standby state in which the operation of the heat controller 1 is stopped and the main controller 105 mounted on the heat pump unit controller 18 is also stopped, the tank mounted on the tank unit controller 19. In order for the unit controller 102 to predict freezing of the accumulated water in the heat pump unit 1, for example, the detected value of the outside air temperature Ta detection unit 17 provided in the heat pump unit 1, the incoming water temperature Twi to the water-refrigerant heat exchanger 5. When acquiring the detection value of the detection unit 15 and the detection value of the hot water temperature Two detection unit 16 discharged from the water-refrigerant heat exchanger 5, the tank unit controller 102 mounted on the tank unit side controller 19 is a heat pump unit. Communication control to the main controller 105 mounted on the side controller 18 The main controller 105 resumes its operation by temporarily resuming from a state where it has been stopped to put the heat pump unit into a standby state, and can immediately communicate the detection values of the detection units in response (several seconds or less). .

  In order to reduce standby power, the method of shutting off the power supply itself to the heat pump unit during operation standby is a power-on operation when temporarily operating as described above, and the controller mounted on the heat pump controller Since it is activated from the reset state, it is usually necessary to initialize the control components that make up the controller and heat pump unit equipment. For example, even when information on the heat pump unit is transmitted to the tank unit, time is required. (For example, about 30 seconds or more), and the power consumption in the case of temporary operation becomes relatively high.

  In addition, in products with a configuration that cuts off the power supply to the heat pump unit and manages power supply, for example, the tank unit side controller acquired it during operation without performing the temporary operation as described above. For example, there is a method of performing operation to prevent freezing based on the information, but in this case, it is difficult to grasp the state of the heat pump unit with certainty, so there is a risk of freezing of the remaining water in the heat pump unit. Therefore, it is necessary to perform an operation that prevents freezing, and power is consumed unnecessarily.

  Furthermore, in one example of the present embodiment, the controller mounted on the heat pump unit side controller 18 drives the compressor drive circuit 111 that drives the compressor 4 at a variable speed and the fan motor 113 that drives the fan 8 at a variable speed. Since the sub-controller 110 that controls the fan motor drive circuit 112 and the main controller 105 that inputs the detection value of each detection unit and performs communication control with the tank unit controller 102 are provided independently, When only the detected value is transmitted to the tank unit controller 102, the sub controller 110, the compressor drive circuit 111, and the fan motor drive circuit 112 do not need to be energized, and the main controller 105 sets the load power breaker 108 on. Since it can remain off, it does not consume unnecessary power. To become.

  Here, in general, a controller for driving a compressor or a fan motor at a variable speed requires a relatively high-speed computing capability and consumes relatively high power for operation. Since the main controller 105 of this embodiment does not require such a high-speed computing capability, the power consumption for operation is relatively low, and in the case of the temporary operation as described above, the power consumption is further reduced. It is advantageous for reduction.

  FIG. 3 shows a block diagram of another embodiment in which a controller mounted on the heat pump unit side controller 18 is one of the main controllers 105, and the main controller 105 drives the compressor 4 at a variable speed. 1 shows a configuration for controlling a fan motor drive circuit 112 that drives a fan motor 113 that drives 111 and a fan 8 at a variable speed.

  In the embodiment of FIG. 3, unlike the embodiment of FIG. 1, the effect of reducing the power consumption during the operation when performing the temporary operation described above cannot be expected, but the operation resuming time from the standby state is the same. Since it can be reduced, the power required for temporary operation can be reduced.

DESCRIPTION OF SYMBOLS 1 Heat pump unit 2 Tank unit 3 Connection piping 4 Compressor 5 Water-refrigerant heat exchanger 6 Pressure reducing valve 7 Evaporator 8 Fan 9 Tank 10 Circulation pump 11 Water supply piping 12 Hot water supply piping 13 Compressor temperature sensor 15 Incoming temperature Twi detection part 16 Hot water supply temperature Two detection unit 17 Outside air temperature Ta detection unit 18 Heat pump unit side controller 19 Tank unit side controller 102 Tank unit controller 103 Communication connection wiring 104 Main controller operating power supply unit 105 Main controller 107 Communication wiring 108 Load power circuit breaker 109 Heat pump unit load power supply unit 110 Sub-controller 111 Compressor drive circuit 112 Fan motor drive circuit 113 Fan motor

Claims (4)

A heat pump cycle in which a compressor for compressing a refrigerant, a refrigerant flow path of a liquid-refrigerant heat exchanger, a pressure reducing valve, and an evaporator are annularly connected via a refrigerant pipe;
A tank for storing a liquid to be heated heated by the liquid-refrigerant heat exchanger; a pump for flowing the liquid to be heated to the liquid-refrigerant heat exchanger;
A fan for blowing air to exchange heat between the air and the refrigerant in the evaporator;
A compressor drive circuit for driving the compressor at a variable speed;
A fan drive circuit for driving the fan at a variable speed;
Based on sensor outputs from various connected sensors, the pressure reducing valve, the circulation pump, and the compressor drive circuit are controlled to perform a boiling operation in which the liquid to be heated at a target boiling temperature is stored in a tank. A heat pump unit side controller,
A load power breaker that switches between supply and interruption of operating power to the compressor drive circuit and the fan drive circuit ;
Disposed in the tank unit side, and a tank unit side controller communicates with the heat pump unit side controller,
A heat pump water heater in which the heat pump cycle, the compressor drive circuit, the fan drive circuit and the heat pump unit side controller are arranged on the heat pump unit side,
The heat pump unit side controller is connected in communication with the tank unit side controller, inputs sensor outputs from the sensors of the heat pump cycle, controls the pressure reducing valve, the circulation pump, and targets the compressor A main controller for calculating a frequency and a target frequency of the fan;
The compressor is connected to the main controller for variable speed control so that the compressor has a target frequency calculated by the main controller, and the fan can be set to a target frequency calculated by the main controller. A sub-controller for controlling the shift,
The main controller controls the load power circuit breaker based on the state of the heat pump water heater during operation standby, and based on the tank state on the tank unit side acquired by communication from the tank unit side controller. A heat pump water heater characterized by stopping its operation . The sensor includes an outside air temperature sensor that detects an outside air temperature,
The tank unit side controller activates the main controller when detecting the outside air temperature during operation standby, detects the outside air temperature when the load circuit breaker is shut off, and the heat pump cycle during operation standby. when operating the, start the main controller, the heat pump water heater according to claim 1, characterized in that the energizing state of the load breaker. 2. The heat pump controller according to claim 1, wherein the sub-controller is disposed at a subsequent stage of the load power breaker, the main controller controls the load power breaker, and supplies operating power to the sub-controller, A heat pump water heater characterized by switching the shutoff . 2. The main controller according to claim 1, wherein the main controller inputs a signal obtained by communication output of an operation signal based on a tank condition on the tank unit side, and switches from an operation stop to an operation state. Heat pump water heater.