JP2015068578A - Heat pump system and hot water supply heating system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a heat pump system in which both of a hot water supply heat exchanger and a heating heat exchanger can be utilized as a condenser without using a separate expansion mechanism.SOLUTION: A heat pump system includes a compressor, a condenser, an expansion mechanism, and an evaporator, and circulates refrigerant in the order of the compressor, the condenser, the expansion mechanism, and the evaporator. In the heat pump system, the condenser includes a heating heat exchanger in which the refrigerant exchanges heat with heating heat medium, and a hot water supply heat exchanger in which the refrigerant exchanges heat with a hot water supply heat medium, at downstream of the heating heat exchanger.

Description

  The present invention relates to a heat pump device and a hot water supply / room heating device.

  Patent Document 1 discloses a heat pump device that includes a compressor, a condenser, an expansion mechanism, and an evaporator, and circulates refrigerant in the order of the compressor, the condenser, the expansion mechanism, and the evaporator. In this heat pump device, the condenser includes a three-fluid heat exchanger that exchanges heat between the refrigerant and the heating medium and the heating medium.

JP 2009-243747 A

  Three-fluid heat exchangers tend to be complex in structure, and are more difficult to design and manufacture than conventional two-fluid heat exchangers. Therefore, studies are being made to arrange a hot water supply heat exchanger that exchanges heat between the refrigerant and the heating medium and a heating heat exchanger that exchanges heat between the refrigerant and the heating medium as separate two-fluid heat exchangers. ing.

  If a hot water supply heat exchanger and a heating heat exchanger are connected in parallel as condensers, the refrigerant flowing into each heat exchanger has the same temperature and pressure, but the refrigerant flowing out from each heat exchanger is different. It becomes temperature and pressure. For this reason, in order to appropriately expand the refrigerant sent to the evaporator, it is necessary to provide separate expansion mechanisms on the downstream side of the hot water supply heat exchanger and the heating heat exchanger, respectively. A heat pump device that can use both a hot water heat exchanger and a heating heat exchanger as a condenser with a simpler configuration is expected.

  The present specification provides a technique for solving the above problems. The present specification provides a heat pump device that can use both a hot water heat exchanger and a heating heat exchanger as a condenser without using a separate expansion mechanism.

  The present specification discloses a heat pump device that includes a compressor, a condenser, an expansion mechanism, and an evaporator, and circulates refrigerant in the order of the compressor, the condenser, the expansion mechanism, and the evaporator. In the heat pump device, the condenser includes a heating heat exchanger that exchanges heat between the refrigerant and the heating medium, and a hot water supply heat exchanger that exchanges heat between the refrigerant and the hot water supply medium downstream from the heating heat exchanger. .

  In the above heat pump device, in the condenser, the heating heat exchanger and the hot water supply heat exchanger are connected in series. For this reason, the refrigerant | coolant sent to an evaporator can be expanded appropriately with the independent expansion | swelling mechanism provided downstream of the hot water supply heat exchanger. Both a heating heat exchanger and a hot water supply heat exchanger can be used as a condenser without using a separate expansion mechanism.

  Moreover, according to said heat pump apparatus, since the heating heat exchanger is arrange | positioned upstream from the hot water supply heat exchanger, the high temperature / high pressure refrigerant | coolant sent out from the compressor flows in into a heating heat exchanger. Thereby, the heating efficiency of the heating medium in the heating heat exchanger can be improved. In addition, in the heating heat exchanger, it is not necessary to increase the temperature increase range of the heating medium, so that only the latent heat accompanying the condensation of the refrigerant needs to be transferred to the heating medium, which reduces the temperature of the refrigerant. There is no need to transfer the sensible heat to the heating medium. For this reason, about the heating heat exchanger, the pressure loss at the time of a refrigerant | coolant passing a heating heat exchanger can be made low by shortening the length of the flow path through which a refrigerant | coolant and a heating heat medium flow. Therefore, according to the above heat pump device, when heat exchange with the heating medium is not performed in the heating heat exchanger, and heat exchange with the hot water supply medium is performed in the hot water heat exchanger, the temperature and pressure are not so much. The refrigerant which has not fallen can be made to flow into the hot water supply heat exchanger. According to the above heat pump device, the heating efficiency of the heating medium in the heating heat exchanger can be improved without significantly reducing the heating efficiency of the heating medium in the hot water heat exchanger.

  Said heat pump apparatus can be comprised so that a condenser may further be provided with the bypass path | pass which bypasses a heating heat exchanger, and the bypass valve provided in the bypass path | route.

  When the refrigerant passes through the heating heat exchanger, there is a slight pressure loss. In the above heat pump device, when the heat exchange with the heating heat medium is not performed with the heating heat exchanger and the heat exchange with the hot water heating medium is performed with the hot water supply heat exchanger, the bypass valve is opened to By flowing the refrigerant through the bypass path, the high-temperature and high-pressure refrigerant can flow into the hot water supply heat exchanger. The heating efficiency of the hot water supply heat medium in the hot water supply heat exchanger can be improved.

  In addition, according to the heat pump device described above, when the heating medium is heated by the hot water supply heat exchanger while the heating medium is circulating in the heating heat exchanger to prevent freezing, the bypass valve Is opened and the refrigerant from the compressor is caused to flow through the bypass path, so that the heat of the refrigerant is prevented from being taken away by the heating medium, and the high-temperature and high-pressure refrigerant can be caused to flow into the hot water supply heat exchanger. Even when the heating medium is circulating in the heating heat exchanger to prevent freezing, it is possible to prevent the heating efficiency of the hot water heating medium in the hot water supply heat exchanger from being lowered.

  The present specification also discloses a hot water supply / room heating device including the heat pump device.

  According to the heat pump device and the hot water supply / heating device disclosed in this specification, both the hot water supply heat exchanger and the heating heat exchanger can be used as a condenser without using a separate expansion mechanism.

It is a figure which shows typically the structure of the hot water supply heating apparatus 2 and the heat pump apparatus 50 of an Example. It is a figure which shows typically another structure of the hot-water supply heating apparatus 2 and the heat pump apparatus 50 of an Example.

(Example)
FIG. 1 shows a hot water supply / room heating device 2 of the present embodiment. The hot water supply / room heating device 2 includes a tank unit 4, a heat pump unit 6, a heat source unit 8, and a control device 100.

The heat pump unit 6 includes a heat pump device 50 and a hot water supply water circulation pump 22. The heat pump device 50 includes a refrigerant circulation path 52 for circulating a refrigerant (for example, an HFC refrigerant such as R410A, a natural refrigerant such as CO ₂ , isobutane, and propane), an air heat exchanger 54, a fan 56, and a compressor 62, a heating heat exchanger 53, a hot water supply heat exchanger 51, and an expansion valve 60 are provided. In the heat pump apparatus 50, the air heat exchanger 54 constitutes an evaporator, and the heating heat exchanger 53 and the hot water supply heat exchanger 51 constitute a condenser.

  The air heat exchanger 54 exchanges heat between the outside air blown by the fan 56 and the refrigerant in the refrigerant circulation path 52. The air heat exchanger 54 is supplied with refrigerant in a low-pressure and low-temperature liquid state after passing through the expansion valve 60. The air heat exchanger 54 heats the refrigerant by exchanging heat between the refrigerant and the outside air. The refrigerant is vaporized by being heated, and is in a gas state at a relatively high temperature and a low pressure.

  The refrigerant after passing through the air heat exchanger 54 is supplied to the compressor 62. That is, the compressor 62 is supplied with a refrigerant in a gaseous state at a relatively high temperature and low pressure. When the refrigerant is compressed by the compressor 62, the refrigerant becomes a high-temperature and high-pressure gas state. The compressor 62 sends the compressed high-temperature and high-pressure gaseous refrigerant to the heating heat exchanger 53.

  The heating heat exchanger 53 is supplied with a high-temperature and high-pressure gaseous refrigerant sent from the compressor 62. The heating heat exchanger 53 performs heat exchange between the refrigerant in the refrigerant circulation path 52 and water from a second heating heating path 84 described later (hereinafter also referred to as heating water). The refrigerant that has passed through the heating heat exchanger 53 is sent to the hot water supply heat exchanger 51. The hot water supply heat exchanger 51 performs heat exchange between the refrigerant from the heating heat exchanger 53 and water in the tank water circulation path 20 (hereinafter also referred to as hot water supply water). As a result of heat exchange in the heating heat exchanger 53 and / or the hot water supply heat exchanger 51, the refrigerant is deprived of heat and condensed. Thereby, a refrigerant | coolant will be in a high-pressure liquid state with a comparatively low temperature.

  The expansion valve 60 is supplied with a relatively low-temperature and high-pressure liquid refrigerant after passing through the hot water supply heat exchanger 51. The refrigerant is depressurized by passing through the expansion valve 60 and becomes a low-temperature and low-pressure liquid state. The refrigerant that has passed through the expansion valve 60 is sent to the air heat exchanger 54 as described above.

  When the compressor 62 is operated in the heat pump device 50, the refrigerant in the refrigerant circulation path 52 circulates in the order of the compressor 62, the heating heat exchanger 53, the hot water supply heat exchanger 51, the expansion valve 60, and the air heat exchanger 54. To do. Thereby, the heating water from the second heating heating path 84 is heated in the heating heat exchanger 53 and / or the hot water supply water in the tank water circulation path 20 is heated in the hot water supply heat exchanger 51.

  The tank unit 4 includes a tank 10. The tank 10 stores hot water supply water heated by the heat pump device 50. The hot water supply water in this embodiment is tap water. The tank 10 is a hermetically sealed type, and the outside is covered with a heat insulating material. Water for hot water supply is stored in the tank 10 until it is full.

  The tank water circulation path 20 has an upstream end connected to the lower part of the tank 10, passes through the hot water supply heat exchanger 51 of the heat pump unit 6, and a downstream end connected to the upper part of the tank 10. A water circulation pump 22 for hot water supply of the heat pump unit 6 is interposed in the tank water circulation path 20. In the heat pump unit 6, when the heat pump device 50 is operated to drive the hot water supply water circulation pump 22, the hot water supply water at the lower part of the tank 10 is sent to the hot water supply heat exchanger 51 and heated, and the heated hot water supply water is supplied to the tank 10. Return to the top of the. Inside the tank 10, a temperature stratification is formed in which a layer of hot water supply water is stacked on a layer of low temperature hot water supply water.

  The upstream end of the tap water introduction path 24 is connected to a tap water supply source 32 outside the hot water supply and heating device 2. The downstream side of the tap water introduction path 24 is branched into a first introduction path 24a and a second introduction path 24b. The downstream end of the first introduction path 24 a is connected to the lower part of the tank 10. The downstream end of the second introduction path 24 b is connected in the middle of the first hot water supply path 36.

  An upstream end of the first hot water supply path 36 is connected to the upper part of the tank 10. As described above, the second introduction path 24 b of the tap water introduction path 24 is connected to the middle of the first hot water supply path 36. A mixing valve 30 is interposed at the connection between the first hot water supply path 36 and the second introduction path 24b. The mixing valve 30 adjusts the ratio of the flow rate of hot water for hot water flowing into the first hot water supply path 36 from the upper part of the tank 10 and the flow rate of cold tap water flowing into the first hot water supply path 36 from the second introduction path 24b. To do. The first hot water supply path 36 on the downstream side of the connection portion with the second introduction path 24 b passes through the hot water supply heating path 37 of the heat source unit 8 and is connected to the second hot water supply path 39. The first hot water supply path 36 and the second hot water supply path 39 are connected by a heat source unit bypass path 33. A bypass valve 34 is interposed in the heat source bypass path 33. A downstream end of the second hot water supply passage 39 is connected to a hot water tap 38.

  The heat source unit 8 includes a cistern 70, a heating burner 82, and a hot water supply burner 81. The cistern 70 is a container having an open top and stores heating water therein. The heating water in this embodiment is, for example, tap water or antifreeze. The upstream end of the heating forward path 72 is connected to the systern 70. A heating water circulation pump 74 is interposed in the heating forward path 72. When the heating water circulation pump 74 is driven, the heating water in the systern 70 flows into the heating forward path 72.

  The downstream end of the heating forward path 72 is branched into a first heating heating path 73 and a low temperature heating circulation path 75. A low temperature heater 78 is attached to the low temperature heating circuit 75. The low temperature heater 78 of the present embodiment is, for example, a floor heater. The low temperature heater 78 heats using the heat of the supplied heating water. A heating burner 82 is interposed in the first heating heating path 73. The heating burner 82 heats the heating water in the first heating heating path 73. The downstream end of the first heating heating path 73 branches into a high temperature heating circulation path 77 and a reheating circulation path 79. A high temperature heater 76 is attached to the high temperature heating circuit 77. The high temperature heater 76 of the present embodiment is, for example, a bathroom heater / dryer. The high temperature heater 76 heats using the heat of the supplied heating water. The low temperature heating circuit 75 and the high temperature heating circuit 77 merge at their downstream ends and are connected to the upstream end of the second heating heating path 84.

  The downstream end of the second heating heating path 84 passes through the heating heat exchanger 53 of the heat pump unit 6 and is connected to the heating return path 96. The downstream end of the heating return path 96 is connected to the systern 70 of the heat source unit 8.

  A reheating heat valve 83 and a reheating heat exchanger 97 are interposed in the reheating circulation path 79. The reheating thermal valve 83 opens and closes the reheating circulation path 79. In the reheating heat exchanger 97, heat exchange is performed between the heating water flowing in the reheating circulation path 79 and the bathtub water flowing in the bathtub water circulation path 91. The downstream end of the recirculation circulation path 79 is connected to the heating return path 96.

  The upstream end of the bathtub water circulation path 91 is connected to the bottom of the bathtub 98. The downstream end of the bathtub water circulation path 91 is connected to the side of the bathtub 98. A bathtub water circulation pump 99 is interposed in the bathtub water circulation path 91. When the bathtub water circulation pump 99 is driven, the bathtub water sucked out from the bottom of the bathtub 98 passes through the reheating heat exchanger 97 and is returned to the side of the bathtub 98.

  A hot water supply burner 81 is interposed in the hot water supply heating path 37. From the downstream side of the hot water supply burner 81 of the hot water supply heating path 37, the bathtub pouring path 40 is branched. The bathtub pouring passage 40 is provided with a pouring solenoid valve 42 for opening and closing the bathtub pouring passage 40. The downstream end of the bathtub pouring channel 40 is connected to the bathtub water circulation pump 99.

  The control device 100 controls the operation of each component of the tank unit 4, the heat pump unit 6, and the heat source unit 8.

  The hot water supply / room heating device 2 can perform a heat storage operation, a hot water supply operation, a heating operation, a hot water operation, a reheating operation, an antifreezing operation, and the like as follows.

(Heat storage operation)
In the heat storage operation, the hot water supply water in the tank 10 is heated by the heat pump device 50, and the hot water supply water that has become hot is returned to the tank 10. When executing the heat storage operation, the control device 100 drives the compressor 62 and the fan 56 to operate the heat pump device 50 and also drives the hot water supply water circulation pump 22.

  By driving the compressor 62, the refrigerant in the refrigerant circulation path 52 circulates in the order of the compressor 62, the heating heat exchanger 53, the hot water supply heat exchanger 51, the expansion valve 60, and the air heat exchanger 54. In this case, the refrigerant in the refrigerant circuit 52 passing through the hot water supply heat exchanger 51 is in a high-temperature and high-pressure gas state. Further, the hot water supply water circulating pump 20 drives the hot water supply water in the tank 10 to circulate in the tank water circulation path 20. That is, hot water supply water existing in the lower portion of the tank 10 is introduced into the tank water circulation path 20, and when the introduced hot water supply water passes through the hot water supply heat exchanger 51, it is heated by the heat of the refrigerant in the refrigerant circulation path 52. The heated hot water supply water is returned to the upper part of the tank 10. Thereby, hot water for hot water supply is stored in the tank 10. When the inside of the tank 10 is in a fully stored state filled with hot water for hot water supply, the heat storage operation is terminated.

(Hot water operation)
The hot water supply operation is an operation of supplying hot water in the tank 10 to the hot water tap 38. The hot water supply operation can also be performed in parallel with the above heat storage operation. When the hot-water tap 38 is opened, tap water flows into the lower part of the tank 10 from the tap water introduction path 24 (first introduction path 24 a) due to the water pressure from the tap water supply source 32. At the same time, the hot water supply water in the upper part of the tank 10 is supplied to the hot water tap 38 via the first hot water supply path 36.

  When the temperature of the hot water supplied from the tank 10 to the first hot water supply path 36 is higher than the set hot water temperature, the control device 100 drives the mixing valve 30 to connect the first hot water supply path 36 from the second introduction path 24b. Introduce tap water. Therefore, the hot water supply water supplied from the tank 10 and the tap water supplied from the second introduction path 24 b are mixed in the first hot water supply path 36. The control device 100 adjusts the opening of the mixing valve 30 so that the temperature of the hot water supplied to the hot water tap 38 coincides with the hot water set temperature. On the other hand, when the temperature of the hot water supplied from the tank 10 to the first hot water supply path 36 is lower than the set hot water temperature, the control device 100 heats the water passing through the first hot water supply path 36 by the hot water supply burner 81. To do. The control device 100 controls the output of the hot water supply burner 81 so that the temperature of the hot water supply water supplied to the hot water tap 38 matches the hot water supply set temperature.

(Heating operation)
The heating operation is an operation in which the heating water is heated by the heat pump device 50 and heated by the low-temperature heater 78 or the high-temperature heater 76 using the high-temperature heating water. When the execution of the heating operation is instructed by the user, the control device 100 rotates the heating water circulation pump 74. Further, the control device 100 drives the compressor 62 and the fan 56.

  By driving the compressor 62, the refrigerant in the refrigerant circulation path 52 circulates in the order of the compressor 62, the heating heat exchanger 53, the hot water supply heat exchanger 51, the expansion valve 60, and the air heat exchanger 54. In this case, the refrigerant in the refrigerant circuit 52 passing through the heating heat exchanger 53 is in a high-temperature and high-pressure gas state. Further, the heating water in the cistern 70 circulates through the second heating heating path 84 by driving the heating water circulation pump 74. The heating water circulating in the second heating heating path 84 is heated by the heat of the refrigerant in the refrigerant circulation path 52 when passing through the heating heat exchanger 53. Heating water heated by the heating heat exchanger 53 is supplied to the low-temperature heater 78 and the high-temperature heater 76 via the cistern 70. Furthermore, the control apparatus 100 operates the heating burner 82 as necessary. As a result, the high-temperature heater 76 is supplied with heating water that has been heated to a higher temperature by the heating by the heating burner 82. In the heating operation, so that the temperature of the heating water supplied to the low temperature heater 78 becomes the low temperature heating set temperature, and the temperature of the heating water supplied to the high temperature heater 76 becomes the high temperature heating set temperature, The operation of the heat pump device 50 and the output of the heating burner 82 are adjusted.

(Hot water operation)
The hot water operation is an operation in which hot water is applied to the bathtub 98. When the user instructs the start of the hot water operation, the hot water supply and heating device 2 starts the hot water operation. In the hot water operation, the hot water solenoid valve 42 is opened. When the hot water solenoid valve 42 is opened, tap water flows into the lower part of the tank 10 from the tap water introduction path 24 (first introduction path 24a) due to the water pressure from the tap water supply source 32. At the same time, the hot water supply water in the upper part of the tank 10 is supplied to the bathtub 98 via the first hot water supply path 36, the bathtub pouring path 40, and the bathtub water circulation path 91. In the hot water operation, the temperature of the water supplied to the bathtub pouring channel 40 is adjusted to the hot water setting temperature in the same manner as in the hot water operation. When the amount of water supplied to the bathtub 98 reaches the hot water setting water amount, the hot water operation is terminated.

(Reaping driving)
The chasing operation is an operation for chasing the bathtub water stored in the bathtub 98. When the user instructs the start of the chasing operation, the hot water supply and heating device 2 starts the chasing operation. In the reheating operation, the bathtub water circulation pump 99 is driven. Further, the reheating heat valve 83 is opened, and the heating water circulation pump 74 is driven. Thereby, bathtub water is sucked out from the bottom part of the bathtub 98, and is heated by heat exchange with the heating water in the reheating heat exchanger 97. The heated bathtub water is returned to the side of the bathtub 98. In the reheating operation, heating water is heated by the heating burner 82.

(Anti-freezing operation)
The freeze prevention operation prevents the hot water supply water in the hot water supply heat exchanger 51 and the tank water circulation path 20 and the heating water in the heating heat exchanger 53, the second heating heating path 84, and the heating return path 96 from freezing. Driving. Since part of the hot water supply heat exchanger 51 and the tank water circulation path 20 is disposed outdoors, if the hot water supply water stays in the interior for a long time at a low outside air temperature, the hot water supply water may freeze. There is. Therefore, when there is a possibility that the hot water supply water may freeze, the hot water supply / room heating device 2 drives the hot water supply water circulation pump 22. Thereby, the hot water supply water in the hot water supply heat exchanger 51 and the tank water circulation path 20 is replaced with the hot water supply water from the tank 10, and the hot water supply water can be prevented from freezing due to staying for a long time. Similarly, since part of the heating heat exchanger 53 and the second heating heating path 84 and the heating return path 96 are arranged outdoors, the heating water stays in the interior for a long time at a low outside air temperature. Then, there is a risk that the water for heating will freeze. Then, when there is a possibility that the heating water may freeze, the hot water supply / room heating device 2 drives the heating water circulation pump 74. Thereby, the heating water in the heating heat exchanger 53, the second heating heating path 84, and the heating return path 96 is replaced with the heating water from the systern 70, and the heating water is frozen due to a long stay. Can be prevented.

  As described above, in the heat pump device 50 of this embodiment, both the hot water supply heat exchanger 51 that exchanges heat between the refrigerant and hot water and the heating heat exchanger 53 that exchanges heat between the refrigerant and heating water are used as condensers. can do. In the heat pump device 50 of the present embodiment, a heating heat exchanger 53 and a hot water supply heat exchanger 51 are connected in series. For this reason, the refrigerant sent to the air heat exchanger 54 can be appropriately expanded by a single expansion valve 60 provided downstream of the hot water supply heat exchanger 51.

  Further, according to the heat pump device 50 of the present embodiment, the heating heat exchanger 53 is disposed upstream of the hot water supply heat exchanger 51, and therefore, the heating heat exchanger 53 is supplied with a high temperature and a high pressure fed from the compressor 62. Refrigerant flows in. Thereby, the heating efficiency of the heating water in the heating heat exchanger 53 can be improved. In addition, heating water having residual heat after being radiated by the low temperature heater 78 or the high temperature heater 76 flows into the heating heat exchanger 53. Therefore, in the heating heat exchanger 53, it is not necessary to increase the temperature rise width of the heating water so much, so that only the latent heat accompanying the condensation of the refrigerant needs to be transferred to the heating water, and the sensible heat accompanying the temperature drop of the refrigerant is reduced. There is no need to move to heating water. For this reason, about the heating heat exchanger 53, the length of the flow path through which a refrigerant and heating water flow can be shortened, and the pressure loss at the time of a refrigerant passing through the heating heat exchanger 53 can be made low. Therefore, according to the heat pump device 50 of the present embodiment, when the heat exchange with the heating water is not performed by the heating heat exchanger 53 and the heat exchange with the hot water is performed by the hot water supply heat exchanger 51, the temperature and the pressure are increased. The refrigerant which has not decreased so much can be caused to flow into the hot water supply heat exchanger 51. According to the heat pump device 50 of the present embodiment, the heating efficiency of the heating water in the heating heat exchanger 53 can be improved without significantly reducing the heating efficiency of the hot water supply water in the hot water supply heat exchanger 51.

  As shown in FIG. 2, the heat pump device 50 may include a bypass path 59 through which the refrigerant bypasses the heating heat exchanger 53 and a bypass valve 57 provided in the bypass path 59. When the refrigerant passes through the heating heat exchanger 53, there is a slight pressure loss. In the heat pump device 50 of FIG. 2, when the heat exchange with the heating water is not performed by the heating heat exchanger 53 and the heat exchange with the hot water is performed by the hot water supply heat exchanger 51, the bypass valve 57 is opened and the compressor 62 is opened. The high-temperature and high-pressure refrigerant can be caused to flow into the hot water supply heat exchanger 51 by flowing the refrigerant from The heating efficiency of the hot water supply water in the hot water supply heat exchanger 51 can be improved.

  Further, according to the heat pump device 50 shown in FIG. 2, when the freezing prevention operation and the heat storage operation of the heating water are performed at the same time, the bypass valve 57 is opened and the refrigerant from the compressor 62 is caused to flow to the bypass path 59. It is possible to prevent the heat of the refrigerant from being taken away by the heating water circulating through the heating heat exchanger 53 in order to prevent freezing, and to allow the high-temperature and high-pressure refrigerant to flow into the hot water supply heat exchanger 51. Even when the heating water freeze prevention operation and the heat storage operation are performed at the same time, the heating efficiency of the hot water supply water in the hot water supply heat exchanger 51 can be prevented from decreasing.

  As mentioned above, although the Example of this invention was described in detail, these are only illustrations and do not limit a claim. The technology described in the claims includes various modifications and changes of the specific examples illustrated above.

  The technical elements described in this specification or the drawings exhibit technical usefulness alone or in various combinations, and are not limited to the combinations described in the claims at the time of filing. In addition, the technology exemplified in this specification or the drawings can achieve a plurality of objects at the same time, and has technical usefulness by achieving one of the objects.

2 Hot-water heater 4 Tank unit 6 Heat pump unit 8 Heat source unit 10 Tank 20 Tank water circulation path 22 Hot water circulation pump 24 Tap water introduction path 24a First introduction path 24b Second introduction path 30 Mixing valve 32 Tap water supply source 33 Heat source Machine bypass path 34 Bypass valve 36 First hot water path 37 Hot water heating path 38 Hot water tap 39 Second hot water path 40 Bath pouring path 42 Pouring hot water solenoid valve 50 Heat pump device 51 Hot water heat exchanger 52 Refrigerant circulation path 53 Heating heat exchanger 54 Air Heat Exchanger 56 Fan 57 Bypass Valve 59 Bypass Path 60 Expansion Valve 62 Compressor 70 Sistern 72 Heating Outward Path 73 First Heating Heating Path 74 Heating Water Circulation Pump 75 Low Temperature Heating Circulation Path 76 High Temperature Heating Circulation Path 78 High Temperature Heating Circulation Path 78 Low temperature heater 79 Reheating circuit 81 Hot water supply burner 82 Heating burner 83 Reheating Netsudoben 84 second heating heating channel 91 bath water circulation path 96 Heating return 97 Reheating heat exchanger 98 bath 99 bath water circulating pump 100 controller

Claims (3)

A heat pump device that includes a compressor, a condenser, an expansion mechanism, and an evaporator, and circulates refrigerant in the order of the compressor, the condenser, the expansion mechanism, and the evaporator,
A heat pump device in which the condenser includes a heating heat exchanger that exchanges heat between the refrigerant and the heating medium, and a hot water supply heat exchanger that exchanges heat between the refrigerant and the hot water supply medium downstream from the heating heat exchanger.   The heat pump apparatus according to claim 1, wherein the condenser further includes a bypass path that bypasses the heating heat exchanger and a bypass valve provided in the bypass path.   A hot water supply and heating device comprising the heat pump device according to claim 1.

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