KR20130102479A - Heat pump type hot water supply heater - Google Patents

Abstract

PURPOSE: A heat pump type hot water supply heater is provided to reduce the amount of fluid flowing in a bottom heating device and to control the temperature of the bottom heating device with high accuracy. CONSTITUTION: A heat pump type hot water supply heater (100) comprises a heating circuit, a hot water supply circuit, a hot water supply and heating heat exchanger (114), and a heater (130). A liquid pipe in which the fluid flows and a water pipe in which the water flows interpose a refrigerant pipe in which the refrigerant flows and the hot water supply and heating heat exchanger is indirectly connected. The refrigerant flows in an outdoor heat exchanger and defrosts the same in case the heat exchanger can be defrosted by calories of the refrigerant. The refrigerant flows in the hot water supply and heating heat exchanger and is hybrid-defrosted by heating the liquid with the heater and supplementing the calories of the refrigerant with the hot water supply and heating heat exchanger in case the heat exchanger cannot be defrosted with the calories of the refrigerant.

Description

Heat pump type hot water heater {HEAT PUMP TYPE HOT WATER SUPPLY HEATER}

The present invention relates to a heat pump type hot water heater, and more particularly, to a heat pump type hot water heater that can be used in cold districts.

Japanese Patent Laid-Open Publication No. 2003-90653 discloses a prior art that discloses a heat pump type hot water heater which flows refrigerant in the same direction as in normal operation during defrosting operation. Patent document 1) exists. In the heat pump type hot water heater described in Patent Document 1, when defrosting the outdoor heat exchanger, the valve opening degree of the pressure reducing valve is maximized, the water pump is stopped, and the heat pump cycle is performed in the same direction as during normal operation. It is circulating.

Japanese Patent Application Laid-Open No. 2009-243747 (Patent Document 2) is a prior art document that discloses a heat pump type hot water heater that can transfer heat of a refrigerant to water flowing through a hot water supply pipe and water flowing through a heating pipe.

In the heat pump type hot water heater described in Patent Literature 2, the refrigerant pipe, the bottom heating pipe, and the hot water pipe are stacked in contact with each other. As a result, each of the refrigerant pipe and the floor heating pipe, the floor heating pipe and the hot water pipe, the hot water pipe and the refrigerant pipe are thermally coupled.

Patent Document 1: Japanese Patent Publication No. 2003-90653 Patent Document 2: Japanese Patent Publication No. 2009-243747

In the heat pump type hot water heater, in order to prevent the water from freezing in the hot water supply pipe, it cannot be defrosted by the reverse cycle (cooling operation) in which the flow direction of the refrigerant is reversed from the heating operation, such as an air conditioner. .

Therefore, the defrosting capacity depends on the heat amount of the refrigerant circulating in the heat pump cycle. If the amount of heat of the refrigerant is insufficient for defrosting, the outdoor heat exchanger cannot be sufficiently defrosted. As a result, problems such as destabilization of heat exchange performance in the outdoor heat exchanger or poor drainage due to refreezing of the drain have occurred. Moreover, in order to avoid such a phenomenon, defrosting operation is frequently performed, and there also existed a problem that it interrupted normal operation.

The present invention has been made in view of the above problems, and an object thereof is to provide a heat pump type hot water heater that can reliably defrost an outdoor heat exchanger.

The heat pump type hot water heater according to the present invention includes a heat pump cycle including an outdoor heat exchanger for circulating a refrigerant and exchanging heat between the outside air and the refrigerant, a heating circuit for circulating a liquid to a heating device, and heated water. A hot water circuit for hot water or hot water, a hot water heating heat exchanger for exchanging heat between the refrigerant, the liquid and the water, a heating circuit and a hot water circuit, and a heater for heating the liquid and the water. do. In the hot water heating heat exchanger, the liquid pipe through which the liquid flows and the water pipe through which the water flows are indirectly contacted through the refrigerant pipe so as to sandwich the refrigerant pipe through which the refrigerant flows. When defrosting the outdoor heat exchanger in the heat pump cycle, if the heat can be defrosted by the heat amount of the refrigerant, the refrigerant is passed through the outdoor heat exchanger for normal defrosting, and when the heat amount of the refrigerant cannot defrost, the heater The liquid is heated, and the refrigerant is passed through the outdoor heat exchanger while supplementing the amount of heat of the refrigerant with the hot water heating heat exchanger, thereby performing hybrid defrosting.

In one embodiment of the present invention, the heat pump type hot water heater further includes a temperature measuring device for measuring at least one of the outside air temperature and the temperature of the outdoor heat exchanger. When defrosting in the heat pump cycle, it is determined on the basis of the measurement result by the temperature measuring device whether or not defrosting is possible with the heat amount of the refrigerant.

In one embodiment of the present invention, it is determined based on the accumulated number of normal defrosts during operation whether or not defrosting can be performed by the heat amount of the refrigerant when defrosting in a heat pump cycle.

In one embodiment of the present invention, the heat pump type hot water heater further includes a temperature measuring device that measures at least one of an outside air temperature and a temperature in an outdoor heat exchanger. Whether to defrost with the amount of heat of the refrigerant when defrosting in the heat pump cycle is determined based on the measurement result by the temperature measuring instrument and the cumulative number of normal defrosts during operation.

According to the present invention, it is possible to reliably defrost the outdoor heat exchanger.

1 is a system diagram showing a configuration of a heat pump type hot water heater according to Embodiment 1 of the present invention.
2 is a flowchart showing the flow up to the start of the normal defrost or hybrid defrost in the heat pump type hot water heater according to the embodiment.
3 is a flowchart showing the flow up to the start of the normal defrost or hybrid defrost in the heat pump type hot water heater according to the second embodiment of the present invention.
4 is a flowchart showing the flow up to the start of the normal defrost or hybrid defrost in the heat pump type hot water heater according to the third embodiment of the present invention.

Hereinafter, the heat pump type hot water heater according to the first embodiment of the present invention will be described. In description of the following embodiment, the same code | symbol is attached | subjected to the same or equivalent part in drawing, and the description is not repeated.

(Embodiment 1)

1 is a system diagram showing a configuration of a heat pump type hot water heater according to Embodiment 1 of the present invention. As shown in FIG. 1, the heat pump type hot water heater 100 according to the first embodiment of the present invention includes a heat pump cycle 110 for circulating a refrigerant, a heating circuit for circulating a liquid with a heating device, and heating. A hot water supply circuit for boiling or hot water is provided.

As the refrigerant circulating in the heat pump cycle 110, an HFC refrigerant such as R410A, a natural refrigerant such as CO ₂ , or the like can be used. As a liquid which circulates a heating circuit, water, an antifreeze, etc. can be used.

The heat pump cycle 110 includes a compressor 113 for compressing a refrigerant, a hot water heat exchanger 114 for heating a liquid and water by heat exchange between the refrigerant flowing out of the compressor 113 and liquid and water, and a hot water supply. An expansion valve 116 for expanding the refrigerant flowing out of the heating heat exchanger 114 and an outdoor heat exchanger 111 for heating the refrigerant by heat-exchanging between the refrigerant expanded through the expansion valve 116 and the outside air; Doing.

The compressor 113, the hot water heat exchanger 114, the expansion valve 116, and the outdoor heat exchanger 111 are connected by a refrigerant pipe 117. The refrigerant pipe 117 is connected with a bypass pipe 118 for the refrigerant to bypass the expansion valve 116. The bypass pipe 118 is provided with an electromagnetic valve 115 that opens and closes the bypass pipe 118.

In the outdoor heat exchanger 111, a fan 112 for blowing outside air to the outdoor heat exchanger 111 is disposed to face each other.

The heating circuit includes a heater 130 that further heats the liquid heated by heat exchange with the refrigerant in the hot water supply heat exchanger 114, and a floor heating device that heats the floor by flowing the heated liquid under the floor. 140, a circulation pump 144 for circulating liquid between the hot water heating heat exchanger 114 and the floor heating device 140, and a hot water heating heat exchanger 114.

In this embodiment, although the gas heater is used as the heater 130, the heater 130 is not limited to this, For example, an electric heater may be sufficient. Moreover, although the floor heating apparatus 140 is used as a heating apparatus, the heating apparatus is not limited to this, For example, the heating apparatus which heats a window or a wall may be sufficient. The heating device may be an air conditioner using a liquid instead of the refrigerant.

The hot water supply heat exchanger 114, the heater 130, the floor heating device 140, the circulation pump 144, and the hot water supply heat exchanger 114 are connected by a liquid pipe 143. The thermostatic valve 141 which adjusts the inflow time of the liquid to the floor heating apparatus 140 is provided in the liquid piping 143 upstream of the inlet of the floor heating apparatus 140. In addition, a bypass pipe 145 is connected to the liquid pipe 143 for the liquid to bypass the floor heating device 140. The bypass pipe 145 is provided with an adjustment valve 142 for opening and closing the bypass pipe 145.

The hot water supply circuit includes a hot water tank 120 for boiling water heated by heat exchange with a refrigerant in the hot water heater heat exchanger 114, and a hot water tank through the hot water heater heat exchanger 114 from the lower portion of the hot water tank 120. The circulation pump 121 which circulates water to the upper part of 120, the heater 130 which further heats the water heated by heat exchange with the refrigerant in the hot water heating heat exchanger 114, and the heat exchanger 114 for hot water heating ).

The storage tank 120, the circulation pump 121, and the heat exchanger 114 for hot water heating are connected by a water pipe 123. The drain valve 122 is provided in the water pipe 123 at the lower position of the water storage tank 120. The water supply pipe 125 is connected to the lower part of the water storage tank 120. The water supply pipe 125 is provided with a pressure reducing valve 124.

The upper part of the water storage tank 120 and the heater 130 are connected by the hot water supply piping 132. In the hot water supply pipe 132, an escape valve 131 is provided at a position above the water storage tank 120.

In the hot water heating heat exchanger 114, the liquid pipe 143 and the water pipe 123 are indirectly contacted via the refrigerant pipe 117 so as to sandwich the refrigerant pipe 117. Specifically, the liquid pipe 143 and the water pipe 123 are disposed above, below, or left and right of the refrigerant pipe 117.

In the heat exchanger 114 for hot water heating, each of the refrigerant pipe 117, the liquid pipe 143, the liquid pipe 143, the water pipe 123, the water pipe 123, and the refrigerant pipe 117 is brazed. thermally bound by brazing. As the brazing filler metal, silver lead, copper lead, brass lead, copper lead, or the like can be used. Moreover, it is not limited to brazing, For example, you may thermally couple the said pipes using welding, soldering, adhesive with high thermal conductivity, etc.

Hereinafter, operation | movement in hot water supply operation of the heat pump type hot water heater 100 is demonstrated. In the heat pump cycle 110 during the hot water supply operation, the refrigerant circulates through the compressor 113, the hot water heating heat exchanger 114, the expansion valve 116, and the outdoor heat exchanger 111 in sequence.

In the hot water supply circuit during the hot water supply operation, the water circulates in the lower part of the hot water tank 120, the circulation pump 121, the hot water heat exchanger 114 for hot water heating, and the top of the hot water tank 120. In this way, the temperature of the water in the boiling tank 120 is maintained above a predetermined temperature by heating the water having a relatively low temperature located in the lower portion of the boiling tank 120 and returning it to the upper portion of the boiling tank 120. Can be.

In addition, water stored in the storage tank 120 is heated from the upper portion of the storage tank 120 via the heater 130. At this time, when the temperature of the water reaching the heater 130 is lower than the predetermined hot water supply temperature, the water is heated by the heater 130. When the temperature of the water reaching the heater 130 is equal to or higher than the predetermined hot water supply temperature, the heater 130 does not operate and does not heat the water.

Next, operation | movement during the heating operation of the heat pump type hot water heater 100 is demonstrated. In the heat pump cycle 110 during the heating operation, the refrigerant circulates through the compressor 113, the hot water heating heat exchanger 114, the expansion valve 116, and the outdoor heat exchanger 111 in sequence.

In the heating circuit during the heating operation, the liquid circulates through the heat exchanger 114 for hot water heating, the heater 130, the floor heater 140, and the circulation pump 144 in order.

At this time, when the liquid has more heat than the heat required for the floor heating, the output of the floor heating device 140 is adjusted by adjusting the opening / closing time of the thermal valve 141. The thermal valve 141 is provided for each load of floor heating, and the output adjustment of the floor heating apparatus 140 is performed.

As described later, when the heat pump cycle 110 enters the hybrid defrost, the regulating valve 142 is opened to supply the heat amount of the liquid in the heating circuit to the heat pump cycle 110 side. Therefore, the opening / closing of the thermal valve 141 and the adjustment valve 142 is adjusted in response to the distribution of the amount of heat of the liquid.

It is preferable that the thermal valve 141 and the adjustment valve 142 are not only two stages of an open state and a closed state, but also a valve which can adjust flow volume more finely. In this case, by operating the adjustment valve 142 in the closing direction when the thermal valve 141 operates in the opening direction, the flow rate of the liquid flowing to the floor heating device 140 is increased, and the thermal valve 141 is closed. By operating the adjustment valve 142 in the opening direction when operating in the direction, the liquid flow rate flowing through the floor heating device 140 can be reduced. By this structure, temperature control of the floor heating apparatus 140 can be performed with high precision.

When the liquid has more heat than the heat required for floor heating in this way, the heater 130 does not operate and does not heat the liquid. On the other hand, when the liquid has a heat amount smaller than the heat amount required for floor heating, the liquid is heated by the heater 130. That is, the heater 130 is operated and operated at the output corresponding to the output of the floor heating apparatus 140.

Next, operation | movement in defrost operation of the heat pump type hot water heater 100 is demonstrated. In the heat pump cycle 110 during the defrosting operation, the refrigerant circulates through the compressor 113, the hot water heating heat exchanger 114, the solenoid valve 115, the expansion valve 116, and the outdoor heat exchanger 111 in order. .

Since the refrigerant mainly passes through the solenoid valve 115, the hot refrigerant flows to the outdoor heat exchanger 111 as compared with the case where the refrigerant passes only the expansion valve 116. The outdoor heat exchanger 111 is defrosted by the relatively high temperature refrigerant. The operation | movement operation | movement which defrosts the outdoor heat exchanger 111 only by circulation of the refrigerant | coolant in this heat pump cycle 110 is called normally defrost.

As described above, the defrosting capacity depends on the amount of heat possessed by the refrigerant circulating in the heat pump cycle 110. The amount of heat the refrigerant obtains in the outdoor heat exchanger 111 depends on the outside temperature.

For example, when the outside temperature of 2 degrees C or less is low, the heat capacity of a refrigerant | coolant decreases, and the defrosting ability in normal defrost falls, and normal defrost cannot fully defrost the outdoor heat exchanger 111. In such a case, the heat pump type hot water heater 100 circulates the liquid in the heating circuit and flows the refrigerant to the outdoor heat exchanger 111 while replenishing the heat quantity of the refrigerant by the hot water heating heat exchanger 114 to defrost the defrost. do. The operation of defrosting by using both the circulation of the liquid in the heating circuit and the circulation of the refrigerant in the heat pump cycle 110 is called hybrid defrost.

In the heating circuit during hybrid defrosting operation, the liquid circulates through the hot water supply heat exchanger 114, the heater 130, and the circulation pump 144 in order. The liquid is heated by the heater 130 and flows into the hot water heating heat exchanger 114 in a high temperature state.

In addition, when at least one of the hot water supply operation and the heating operation is performed during the hybrid defrost operation, the liquid is heated to a higher temperature by the heater 130 in order to supply the amount of heat required for the defrosting operation, the hot water supply operation and the heating operation.

For example, when heating operation and hybrid defrosting operation are performed simultaneously, the opening degree of each of the thermal valve 141 and the adjustment valve 142 is adjusted, and liquid is distributed. The liquid is heated by the heater 130 so that the liquid flowing through each of the thermal valve 141 and the regulating valve 142 has the required amount of heat.

In addition, when the heat pump type hot water heater 100 includes a plurality of floor heaters 140, a thermal valve 141 is provided in each floor heater 140. In this case, the opening degree of each of the plurality of thermal valves 141 and the control valve 142 installed in the floor heater 140 in operation is adjusted to distribute the liquid, and the plurality of thermal valves 141 and the control valve ( The liquid is heated by the heater 130 so that the liquid flowing through each of the 142 has the required amount of heat.

In the hot water heating heat exchanger 114, the refrigerant is heated by heat exchange between the liquid and the refrigerant. The refrigerant which has been heated and supplemented with heat passes through the solenoid valve 115 and flows to the outdoor heat exchanger 111, whereby the defrosting of the outdoor heat exchanger 111 can be performed reliably.

That is, the heat pump type hot water heater 100, when defrosting the outdoor heat exchanger 111 in the heat pump cycle 110, when the heat can be defrosted by the amount of heat of the refrigerant to the outdoor heat exchanger 111. When defrosting by normal flow, and defrosting is not possible with the heat amount of the refrigerant, the liquid is heated by the heater 130 and the refrigerant is passed through the outdoor heat exchanger 111 while supplementing the heat amount of the refrigerant with the hot water heating heat exchanger. do.

In this way, even when the outside temperature is low and normal defrosting cannot sufficiently defrost the outdoor heat exchanger 111, the defrosting of the outdoor heat exchanger 111 can be reliably performed by the hybrid defrosting. As a result, operation of the heat pump type hot water heater 100 can be continued stably.

Hereinafter, the flow which determines which of normal defrost and hybrid defrost is performed in the heat pump type hot water heater 100 is demonstrated.

Fig. 2 is a flowchart showing the flow up to the start of the normal defrost or hybrid defrost in the heat pump type hot water heater according to the present embodiment.

Moreover, the heat-pump type hot water heater 100 which concerns on this embodiment is further equipped with the temperature measuring device which is not shown in figure which measures at least any one of an outside air temperature and the temperature of the outdoor heat exchanger 111. As shown in FIG. Moreover, the heat pump type hot water heater 100 is provided with the control part which is not shown in figure which receives the signal of a measurement result from a temperature measuring device, and controls each structure of the heat pump type hot water heater 100.

In the heat pump type hot water heater 100, when at least one of the hot water operation and the heating operation is performed and the operation of the heat pump cycle 110 continues, the temperature in the outdoor heat exchanger 111 gradually decreases.

Therefore, the control part is a heat pump type hot water heater in order to prepare for defrosting when at least one of the outside temperature measured by the temperature measuring device and the temperature of the outdoor heat exchanger 111 reaches the predetermined temperature range. Activate each configuration of 100. Said predetermined temperature range is called defrost preparation area. Specifically, in the step of entering the defrost preparation zone, the control unit operates the heater 130 to prepare a predetermined amount of the heated liquid.

In the present embodiment, the temperature in the outdoor heat exchanger 111 is higher than -2 ° C and lower than 0 ° C as a defrost preparation zone, and the temperature in the outdoor heat exchanger 111 is -2 ° C or lower. When the defrost is set to start. However, the above-mentioned defrost preparation area and defrost start condition are an example, and can be set with various factors.

As shown in FIG. 2, when operation of the heat pump type hot water heater 100 is started (S100), the control part confirms whether hot water operation is performed in the heat pump type hot water heater 100 (S110).

When the hot water operation is performed in the heat pump type hot water heater 100 and the temperature in the outdoor heat exchanger 111 is -2 ° C. or lower, the control unit determines that the measurement result of the outside temperature received from the temperature measuring instrument is 2; Check whether it is below ℃ (S120). If outside temperature is 2 degrees C or less, the control part judges that it cannot normally defrost enough with normal defrost, and starts hybrid defrost (S130). Specifically, the control unit starts the circulation of the liquid in the heating circuit by operating the circulation pump 144, and circulates the refrigerant of the heat pump cycle 110 by using the solenoid valve 115 as a whole. .

On the other hand, when the outside temperature is higher than 2 ° C, the control unit determines that the normal defrosting can be sufficiently defrosted, and starts normal defrosting (S140). Specifically, the control unit circulates the refrigerant of the heat pump cycle 110 by developing the solenoid valve 115.

Moreover, when hot water supply operation is not performed in the heat pump type hot water heater 100, the control part confirms whether heating operation is performed in the heat pump type hot water heater 100 (S111).

When the heating operation is performed in the heat pump type hot water heater 100 and the temperature in the outdoor heat exchanger 111 becomes -2 degrees C or less, a control part advances to the confirmation process (S120) of external temperature. When the heating operation is not performed in the heat pump type hot water heater 100, the control unit returns to the operation confirmation step (S110) of the hot water operation.

As described above, by deciding on the basis of the measurement result by the temperature measuring device whether or not defrosting can be performed by the amount of heat of the refrigerant during the defrosting in the heat pump cycle 110, the normal defrosting or hybrid defrosting is started. And any one of the hybrid defrosts can be appropriately selected to perform defrosting.

Normal defrosting and hybrid defrosting are terminated at the stage where the control unit confirms that the defrost preparation zone has been entered again. Specifically, the control unit makes the heat pump cycle 110 normal operation with the solenoid valve 115 fully closed.

In the termination operation of the hybrid defrost, the control unit may close the solenoid valve 115 and stop the circulation pump 144, or first stop the circulation pump 144 and then close the solenoid valve 115. good.

In hybrid defrosting, it is preferable that the circulation of water in the hot water supply circuit is stopped. By doing so, since a large amount of heat of the liquid circulating in the heating circuit can be replenished with the refrigerant, defrosting of the outdoor heat exchanger 111 can be performed efficiently.

Hereinafter, the heat pump type hot water heater according to Embodiment 2 of the present invention will be described. In addition, since the heat pump type hot water heater according to the present embodiment differs from the heat pump type hot water heater 100 according to the first embodiment only in a method of selecting a defrost and a hybrid defrost, the description of other configurations is not repeated. .

(Embodiment 2)

3 is a flowchart showing the flow up to the start of the normal defrost or hybrid defrost in the heat pump type hot water heater according to the second embodiment of the present invention.

As shown in FIG. 3, when the operation of the heat pump type hot water heater according to the present embodiment is started (S100), the controller checks whether hot water operation is performed in the heat pump type hot water heater (Sl10).

When the hot water supply operation is performed in the heat pump type hot water heater and the temperature in the outdoor heat exchanger 111 is -2 ° C or lower, the control unit checks whether the accumulated number of normal defrosts during operation is three or more times ( S220). If the cumulative number of normal defrosts during operation is three or more times, the control unit determines that normal defrosting cannot sufficiently defrost, and starts hybrid defrosting (S130). Specifically, the control unit starts the circulation of the liquid in the heating circuit by operating the circulation pump 144, and circulates the refrigerant of the heat pump cycle 110 by developing the solenoid valve 115.

On the other hand, if the cumulative number of normal defrosts during operation is less than three, the control unit determines that normal defrosting can be sufficiently performed and starts normal defrosting (S140). Specifically, the control unit circulates the refrigerant of the heat pump cycle 110 by developing the solenoid valve 115.

Moreover, when hot water supply operation is not performed in a heat pump type hot water heater, the control part confirms whether heating operation is performed in a heat pump type hot water heater (S111).

When heating operation is performed in the heat pump type hot water heater and the temperature in the outdoor heat exchanger 111 is -2 degrees C or less, a control part advances to the confirmation process (S220) of the number of times of defrosting normally. When the heating operation is not performed in the heat pump type hot water heater, the control unit returns to the operation confirmation step (S110) of the hot water operation.

As described above, the normal defrost or hybrid defrost is started by determining whether defrosting can be performed by the amount of heat of the refrigerant during defrosting in the heat pump cycle 110 based on the cumulative number of normal defrosts during operation. Defrost can be performed by selecting any of defrost and hybrid defrost as appropriate.

By selecting the normal defrost and the hybrid defrost in the above-described manner, it is possible to suppress the frequent repetition of the normal defrost and to continue the normal operation of the heat pump type hot water heater in a stable manner.

Hereinafter, the heat pump type hot water heater according to Embodiment 3 of the present invention will be described. In addition, since the heat pump type hot water heater according to the present embodiment differs from the heat pump type hot water heater 100 according to the first embodiment only in a method of selecting a defrost and a hybrid defrost, the description of other configurations is not repeated. .

(Embodiment 3)

4 is a flowchart showing the flow up to the start of the normal defrost or hybrid defrost in the heat pump type hot water heater according to the third embodiment of the present invention.

As shown in FIG. 4, when operation of the heat pump type hot water heater according to the present embodiment is started (S100), the control unit checks whether hot water operation is performed in the heat pump type hot water heater (S110).

When the hot water operation is performed in the heat pump type hot water heater and the temperature in the outdoor heat exchanger 111 is -2 ° C or lower, the control unit determines whether the measurement result of the outside temperature received from the temperature measuring device is 2 ° C or lower. Or, it is checked whether the accumulated number of normal defrosts during operation is three or more times (S320).

When the measurement result of the outside temperature received from the temperature measuring device is 2 degrees C or less, or when the accumulated number of normal defrosts during operation is three or more times, the control part judges that it cannot defrost enough normally and starts hybrid defrosting (S130). ). Specifically, the control unit starts the circulation of the liquid in the heating circuit by operating the circulation pump 144, and circulates the refrigerant of the heat pump cycle 110 by developing the solenoid valve 115.

On the other hand, if the measurement result of the outside temperature received from the temperature measuring device is higher than 2 ° C or the cumulative number of normal defrosts during operation is less than three times, the control unit determines that normal defrosting can be sufficiently performed with normal defrosting. It starts (S140). Specifically, the control unit circulates the refrigerant of the heat pump cycle 110 by developing the solenoid valve 115.

Moreover, when hot water supply operation is not performed in a heat pump type hot water heater, the control part confirms whether heating operation is performed in a heat pump type hot water heater (S111).

When the heating operation is performed in the heat pump type hot water heater and the temperature in the outdoor heat exchanger 111 is -2 ° C or lower, the control unit confirms the outside temperature or confirms the number of normal defrost times (S320). Proceeds. When the heating operation is not performed in the heat pump type hot water heater, the control unit returns to the operation confirmation step (S110) of the hot water operation.

As described above, the normal defrost or hybrid defrost is determined based on the measurement result by the temperature measuring instrument and the cumulative number of normal defrosts during operation, whether or not defrosting can be performed by the amount of heat of the refrigerant during defrosting in the heat pump cycle 110. By initiating, the defrost can be performed by appropriately selecting any one of a normal defrost and a hybrid defrost.

By selecting the normal defrost and the hybrid defrost in the above-described manner, the outdoor heat exchanger 111 can be defrosted reliably while suppressing the frequent repetition of the normal defrost, thereby stably operating the normal operation of the heat pump type hot water heater. It becomes possible to continue.

The embodiment disclosed herein is to be considered in all respects only as illustrative and not restrictive. The scope of the invention is set forth by the claims rather than the foregoing description, and is intended to include any modifications within the scope and meaning equivalent to the claims.

100-Heat Pump Hot Water Heater 110-Heat Pump Cycle
111-Outdoor Heat Exchanger 112-Fan
113-Compressor 114-Heat Exchanger for Hot Water Heating
115-Solenoid Valve 116-Expansion Valve
117-Refrigerant piping 118,145-Bypass piping
120-Storage Tanks 121144-Circulation Pumps
122-Drain Valve 123-Water Piping
124-Pressure Reducing Valves 125-Water Piping
130-Heater 131-Evacuation Valve
132-hot water supply pipe 140- floor heating
141-Thermal Valves 142-Control Valves
143-liquid piping

Claims (4)

A heat pump cycle including an outdoor heat exchanger for circulating a refrigerant to heat exchange between the outside air and the refrigerant;
A heating circuit for circulating the liquid to the heating device,
Hot water supply circuit for boiling or hot water of heated water,
A hot water heating heat exchanger configured to heat exchange between the refrigerant, the liquid, and the water;
It is provided in the heating circuit and the hot water supply circuit, and provided with a heater for heating the liquid and the water,
In the hot water supply heat exchanger, the liquid pipe through which the liquid flows and the water pipe through which the water flows are indirectly contacted through the refrigerant pipe so as to sandwich a refrigerant pipe through which the refrigerant flows.
When the outdoor heat exchanger is defrosted in the heat pump cycle, if the heat can be defrosted by the amount of heat of the refrigerant, the refrigerant is passed through the outdoor heat exchanger to be defrosted normally and defrosted by the amount of heat of the refrigerant. And a heat pump type hot water heater, wherein the liquid is heated by the heater to make the refrigerant flow through the outdoor heat exchanger while replenishing the heat quantity of the refrigerant with the hot water heating heat exchanger.
The method according to claim 1,
Further comprising a temperature measuring device for measuring at least one of the outside air temperature and the temperature in the outdoor heat exchanger,
The heat pump type hot water heater according to the measurement result by the said temperature measuring device determines whether it can defrost by the quantity of heat of the said coolant at the time of defrosting in the said heat pump cycle.
The method according to claim 1,
A heat pump type hot water heater, which determines whether or not defrosting can be performed by the amount of heat of the refrigerant when defrosting in the heat pump cycle based on the cumulative number of the normal defrosts during operation.
The method according to claim 1,
Further comprising a temperature measuring device for measuring at least one of the outside air temperature and the temperature in the outdoor heat exchanger,
The heat pump type hot water heater according to the measurement result by the said temperature measuring device and the cumulative frequency of the said normal defrosting in operation is determined whether it can defrost by the amount of heat of the said refrigerant at the time of defrosting in the said heat pump cycle.

Images