JP2013137152A - Hot water supply device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To adjust a temperature of a molten-salt battery, without increase in power consumption.SOLUTION: A molten-salt battery (55) is disposed to a hot water supply device (10). The hot water supply device (10) includes: a water circulation path (21) in which water in a water storage tank (40) circulates; a heat medium circuit (50) in which heat medium is circulated; and a heat medium heat exchanger (30) performing heat exchange between a water in the water circulation path (21) and the heat medium of the heat medium circuit (50). The molten-salt battery (55) is connected with the heat medium circuit (50), and the temperature thereof is adjusted by the heat medium of the heat medium circuit (50).

Description

  The present invention relates to a hot water supply apparatus provided with a molten salt battery.

  Conventionally, a molten salt battery using a molten salt as an electrolyte is known. The molten salt battery can be charged and discharged at a temperature equal to or higher than the melting point of the molten salt because the molten salt dissolves and ions can move. On the other hand, at a temperature lower than the melting point of the molten salt (for example, room temperature), the molten salt is solidified and ions cannot move, so that spontaneous discharge can be suppressed.

  For example, the molten salt battery disclosed in Patent Document 1 is a sodium sulfur battery. This molten salt battery can be charged and discharged at 300 ° C., accommodated in a heat insulating container, and melted by heating with an electric heater.

JP-A-2005-149977

  In recent years, a molten salt battery using a molten salt having a low melting point as an electrolyte has attracted attention. This molten salt battery has a melting point of about 60 ° C. and, unlike other molten salt batteries, can be charged and discharged at 100 ° C. or less. Therefore, a temperature adjusting means that heats to a temperature close to 100 ° C. during charge and discharge and cools to 60 ° C. or less after use to suppress spontaneous discharge is desired.

  However, when the electric heater is used as a heat source as in the prior art, such a temperature adjustment is possible, but the power consumption of the electric heater increases.

  This invention is made | formed in view of this point, The objective is to temperature-control a low melting point molten salt battery with low power consumption.

  According to a first aspect of the present invention, a refrigerant circuit (65) that circulates a refrigerant to perform a refrigeration cycle is connected to the refrigerant circuit (65), and heat is exchanged between the refrigerant and water in the refrigerant circuit (65) to exchange water. A water circulation path (21) having a water heat exchanger (63) for heating and a tank (40) for storing water, and circulating water between the water heat exchanger (63) and the tank (40) ). This hot water supply device has a heat medium heat exchanger (30) connected to the water circulation path (21) and exchanging heat between the water in the water circulation path (21) and the heat medium, and circulates the heat medium. A circuit (50) and a molten salt battery (55) connected to the heat medium circuit (50) and temperature-controlled by the heat medium of the heat medium circuit (50) are provided.

  In the first invention, the molten salt battery (55) is heated in the hot water supply device (10) by a heat medium exchanged with high-temperature hot water, and the molten salt is heated by a heat medium exchanged with low-temperature water (hot water). The battery (55) is cooled. In the case of a low-melting-point molten salt battery (55), when heated by a heat medium that exchanges heat with high-temperature hot water, it becomes chargeable / dischargeable while it is cooled by a heat medium that exchanges heat with low-temperature water (hot water). As a result, the spontaneous discharge is suppressed.

  In a second aspect based on the first aspect, the water circulation path (21) sends the water in the tank (40) to the water heat exchanger (63), and then the heat medium heat exchanger (30 ) To return to the tank (40).

  In the second aspect of the invention, the water (warm water) in the water circulation path (21) passes through the water heat exchanger (63) and exchanges heat with the heat medium in the heat medium heat exchanger (30). Therefore, during the refrigeration cycle, the molten salt battery (55) is heated to the hot water supply temperature by the heat medium exchanged with the hot water heated by the water heat exchanger (63). On the other hand, while the refrigeration cycle is stopped, the molten salt battery (55) is cooled to a temperature lower than the hot water supply temperature by the heat medium exchanged with the water (hot water) that has passed without being heated by the water heat exchanger (63). The

  According to a third aspect, in the second aspect, the tank (40) is characterized in that the outflow port (42) is provided below the inflow port (45).

  In the third aspect of the invention, water (warm water) flowing out from the outlet (42) of the tank (40) is heated by the hydrothermal exchanger (63), and the inlet ( 45) Therefore, in the tank (40), the bottom water (warm water) is cooler than the upper water (warm water). Then, while the refrigeration cycle is stopped, the relatively low temperature water (hot water) at the bottom of the tank (40) flows out and is sent to the heat medium heat exchanger (30) without being heated by the water heat exchanger (63). Thus, since the heat exchange with the heat medium is performed, the molten salt battery (55) is reliably cooled.

  In a fourth aspect based on the third aspect, the water circulation path (21) is configured so that the water in the upper part of the tank (40) is not transferred through the water heat exchanger (63) but the heat medium heat exchanger (63). It is characterized by having a bypass (23) to 30).

  In the fourth aspect of the invention, while the refrigeration cycle is stopped, the relatively hot water at the top of the tank (40) is sent to the heat medium heat exchanger (30) through the bypass (23), and the heat medium and the heat In order to exchange, the heated state of the molten salt battery (55) is maintained.

  According to a fifth aspect of the present invention, there is provided a refrigerant circuit (65) for circulating a refrigerant to perform a refrigeration cycle, and the refrigerant circuit (65) connected to the refrigerant circuit (65) for heat exchange between the refrigerant and water in the refrigerant circuit (65). A water circulation path (21) having a water heat exchanger (63) for heating and a tank (40) for storing water, and circulating water between the water heat exchanger (63) and the tank (40) ). This hot water supply apparatus is characterized by comprising a molten salt battery (55) connected to the water circulation path (21) and temperature-controlled by the water in the water circulation path (21).

  In the fifth aspect of the invention, the molten salt battery (55) is heated by hot hot water and cooled by low temperature water (hot water) in the hot water supply device (10). In the case of a low-melting-point molten salt battery (55), when it is heated by high-temperature hot water, it is in a chargeable / dischargeable state, while when cooled by low-temperature water (hot water), spontaneous discharge is suppressed. Become.

  In a sixth aspect based on the fifth aspect, the water circulation path (21) sends the water in the tank (40) to the water heat exchanger (63), and then supplies the molten salt battery (55). It is characterized by being constituted so that it may return to the above-mentioned tank (40) via.

  In the sixth aspect of the invention, the water (warm water) in the water circulation path (21) is sent to the molten salt battery (55) after passing through the water heat exchanger (63). Therefore, during the refrigeration cycle, the molten salt battery (55) is heated to the hot water supply temperature by the hot water heated by the water heat exchanger (63). On the other hand, while the refrigeration cycle is stopped, the molten salt battery (55) is cooled to a temperature lower than the hot water supply temperature by the water (warm water) that has passed without being heated by the water heat exchanger (63).

  In a seventh aspect based on the sixth aspect, the tank (40) is characterized in that the outlet (42) is provided below the inlet (45).

  In the seventh aspect of the invention, water (warm water) flowing out from the outlet (42) of the tank (40) is heated by the hydrothermal exchanger (63), and the inlet ( 45) Therefore, in the tank (40), the bottom water (warm water) is cooler than the upper water (warm water). And while the refrigeration cycle is stopped, the relatively low temperature water (hot water) at the bottom of the tank (40) flows out and is sent to the molten salt battery (55) without being heated by the hydrothermal exchanger (63). The molten salt battery (55) is reliably cooled.

  In an eighth aspect based on the seventh aspect, the water circulation path (21) is configured such that the water in the upper part of the tank (40) is not passed through the water heat exchanger (63) and the molten salt battery (55) It is characterized by having a bypass (23) to send to.

  In the eighth aspect of the invention, while the refrigeration cycle is stopped, hot water at a relatively high temperature in the upper part of the tank (40) is sent to the molten salt battery (55) via the bypass (23), so the molten salt battery (55) The heating state is maintained.

  According to a ninth aspect of the invention, there is provided a refrigerant circuit (65) for circulating a refrigerant to perform a refrigeration cycle, and the refrigerant circuit (65) connected to the refrigerant circuit (65) for heat exchange between the refrigerant and water in the refrigerant circuit (65). A water circulation path (21) having a water heat exchanger (63) for heating and a tank (40) for storing water, and circulating water between the water heat exchanger (63) and the tank (40) ). This hot water supply apparatus is characterized by comprising a molten salt battery (55) connected to the refrigerant circuit (65) and temperature-controlled by the refrigerant of the refrigerant circuit (65).

  In the ninth aspect of the invention, in the hot water supply device (10), the molten salt battery (55) is heated by the compressed high-temperature refrigerant, and the molten salt battery (55) is cooled by the uncompressed low-temperature refrigerant. . In the case of a low-melting-point molten salt battery (55), when it is heated by a high-temperature refrigerant, it is in a chargeable / dischargeable state, whereas when it is cooled by a low-temperature refrigerant, spontaneous discharge is suppressed.

  In a tenth aspect based on the ninth aspect, the refrigerant circuit (65) includes a branch path (66) connected in parallel to the water heat exchanger (63), and both ends of the branch path (66). And a switching valve (67, 68) for switching the flow of the refrigerant, and the molten salt battery (55) is connected to the branch passage (66).

  In the tenth aspect of the present invention, when the switching valve (67, 68) causes the refrigerant to flow to the water heat exchanger (63) without flowing to the molten salt battery (55), the water (warm water) in the water circuit (21) ) Is heated. On the other hand, when the switching valve (67, 68) is switched to allow the refrigerant to flow to the molten salt battery (55) without flowing to the water heat exchanger (63), the molten salt battery (55) is heated. As described above, the water heating operation and the molten salt battery (55) heating operation are switched by the switching valve (67, 68).

  In an eleventh aspect based on the tenth aspect, the water circulation passage (21) sends water at the bottom of the tank (40) to the water heat exchanger (63), and then the tank (40) The refrigerant circuit (65) is configured to return to the upper part, and the refrigerant circuit (65) is configured to circulate refrigerant between the water heat exchanger (63) and the molten salt battery (55) while the refrigeration cycle is stopped. It is characterized by having.

  In the eleventh aspect of the invention, the water at the bottom of the tank (40) is heated by the water heat exchanger (63) and then returned to the top of the tank (40). (Warm water) becomes cooler than upper water (warm water). While the refrigeration cycle is stopped, the water (warm water) at the bottom of the tank (40) is circulated between the water heat exchanger (63) and the molten salt battery (55) while the water (hot water) at the bottom of the tank (40) ). Therefore, in the water heat exchanger (63), the refrigerant at the bottom of the tank (40) and the refrigerant are heat-exchanged to cool the refrigerant, and the molten salt battery (55) is cooled by the cooled refrigerant. Is reliably cooled.

  In a twelfth aspect based on the eleventh aspect, the water circulation path (21) is configured to send water in the upper part of the tank (40) to the water heat exchanger (63) while the refrigeration cycle is stopped. It is characterized by being.

  In the twelfth aspect of the present invention, while the refrigerant is circulated between the water heat exchanger (63) and the molten salt battery (55) while the refrigeration cycle is stopped, the water in the upper part of the tank (40) is supplied to the water heat exchanger. Sent to (63). Therefore, the relatively hot water and refrigerant at the upper part of the tank (40) exchange heat with the water heat exchanger (63) to heat the refrigerant, and the heated refrigerant heats the molten salt battery (55). Maintained.

  According to the present invention, in the hot water supply device (10), the molten salt battery (55) is heated by a heat medium exchanged with high-temperature hot water, and the molten salt battery (55) is heated by a heat medium exchanged with low-temperature hot water. It was made to cool. As a result, the molten salt battery (55) having a low melting point can be heated to be in a chargeable / dischargeable state, and the molten salt battery (55) having a low melting point can be cooled to suppress spontaneous discharge. can do. That is, the state of the low melting point molten salt battery (55) can be controlled within the temperature range of the hot water. Furthermore, since the temperature is adjusted using the heat of the heat medium, it is not necessary to generate heat with an electric heater or the like, and the power consumption can be reduced as compared with the prior art.

  According to the second invention, the water (hot water) after passing through the water heat exchanger (63) and the heat medium are subjected to heat exchange. Thus, during the refrigeration cycle, the low melting point molten salt battery (55) can be heated to the oil supply temperature by the heat medium exchanged with the hot water heated by the water heat exchanger (63), and as a result, The molten salt battery (55) can be charged. On the other hand, while the refrigeration cycle is stopped, the low-melting-point molten salt battery (55) is cooled to low-temperature water (55) by the heat medium exchanged with low-temperature water (hot water) that has passed without being heated by the water heat exchanger (63). It is possible to cool the molten salt battery (55) to a natural discharge.

  According to the third aspect of the invention, the outlet (42) of the tank (40) is provided below the inlet (45). As a result, while the refrigeration cycle is stopped, the low melting point molten salt battery (55) is cooled by the heat medium that exchanges heat with the relatively low temperature water (hot water) at the bottom of the tank (40) to ensure spontaneous discharge. Can be suppressed.

  According to the fourth aspect, the hot water in the upper part of the tank (40) is sent to the heat medium heat exchanger (30) without passing through the water heat exchanger (63) to exchange heat with the heat medium. As a result, when the refrigeration cycle is stopped, the molten salt battery (55) having a low melting point can be heated by a heat medium exchanging heat with relatively hot water at the upper part of the tank (40). 55) can be maintained in a chargeable state.

  According to the fifth invention, in the hot water supply device (10), the molten salt battery (55) is heated with hot hot water, and the molten salt battery (55) is cooled with low temperature hot water. As a result, the molten salt battery (55) having a low melting point can be heated to be in a chargeable / dischargeable state, and the molten salt battery (55) having a low melting point can be cooled to suppress spontaneous discharge. can do. That is, the state of the low melting point molten salt battery (55) can be controlled within the temperature range of the refrigerant. Furthermore, since the temperature is adjusted using the heat of hot water, it is not necessary to generate heat with an electric heater or the like, and the power consumption can be reduced as compared with the prior art.

  According to the sixth aspect of the invention, the water (warm water) that has passed through the water heat exchanger (63) is sent to the molten salt battery (55). As a result, during the refrigeration cycle, the molten salt battery (55) having a low melting point can be heated to the oil supply temperature by the hot water heated by the water heat exchanger (63). As a result, the molten salt battery (55) ) Can be charged. On the other hand, while the refrigeration cycle is stopped, the low-melting point molten salt battery (55) is cooled to the temperature of the low-temperature water (hot water) by the low-temperature water (hot water) that has passed without being heated by the water heat exchanger (63). As a result, spontaneous discharge of the molten salt battery (55) can be suppressed.

  According to the seventh aspect, the outlet (42) of the tank (40) is provided below the inlet (45). Thereby, while the refrigeration cycle is stopped, the low melting point molten salt battery (55) is cooled by the relatively low temperature water (warm water) at the bottom of the tank (40), so that spontaneous discharge can be reliably suppressed.

  According to the eighth aspect of the invention, the hot water in the upper part of the tank (40) is sent to the molten salt battery (55) without going through the water heat exchanger (63). Thereby, while the refrigeration cycle is stopped, the molten salt battery (55) having a low melting point can be heated by the relatively hot water at the top of the tank (40), and the molten salt battery (55) can be charged. Can be maintained in a state.

  According to the ninth aspect of the invention, in the hot water supply device (10), the molten salt battery (55) is heated by the high-temperature refrigerant of the refrigerant circuit (65), and the molten salt battery (65) is heated by the low-temperature refrigerant of the refrigerant circuit (65). 55) was cooled. As a result, the molten salt battery (55) having a low melting point can be heated to be in a chargeable / dischargeable state, and the molten salt battery (55) having a low melting point can be cooled to suppress spontaneous discharge. can do. That is, the state of the low melting point molten salt battery (55) can be controlled within the temperature range of the refrigerant. Furthermore, since the temperature is adjusted using the heat of the refrigerant, it is not necessary to generate heat with an electric heater or the like, and the power consumption can be reduced as compared with the prior art.

  According to the tenth aspect of the invention, in the refrigerant circuit (65), the branch path (66) is connected in parallel to the water heat exchanger (63), and the molten salt battery (55) is connected to the branch path (66). At the same time, a switching valve (67, 68) is provided at the connecting portion at both ends of the branch path (66). Thereby, the water boiling operation and the heating operation of the molten salt battery can be switched by the switching valve (67, 68).

  According to the eleventh invention, while the refrigeration cycle is stopped, the refrigerant is circulated between the water heat exchanger (63) and the molten salt battery (55), and the hot water at the bottom of the tank (40) is I sent it to the exchanger (63). As a result, the low melting point molten salt battery (55) can be cooled with a relatively low temperature hot water at the bottom of the tank (40), and as a result, the natural discharge of the low melting point molten salt battery (55) is surely suppressed. be able to.

  According to the twelfth invention, while the refrigeration cycle is stopped, the refrigerant is circulated between the water heat exchanger (63) and the molten salt battery (55), and the hot water in the upper part of the tank (40) is I sent it to the exchanger (63). As a result, the low melting point molten salt battery (55) can be heated by the relatively hot water at the top of the tank (40), and as a result, the low melting point molten salt battery (55) can be charged. can do.

FIG. 1 is a schematic configuration diagram of a hot water supply apparatus according to the first embodiment. FIG. 2 is a state diagram of the hot water supply apparatus according to Embodiment 1 during a boiling operation. FIG. 3 is a state diagram during battery heating operation of the hot water supply apparatus according to the first embodiment. FIG. 4 is a state diagram during battery cooling operation of the hot water supply apparatus according to the first embodiment. FIG. 5 is a state diagram of the hot water supply device according to Embodiment 1 during a battery temperature maintenance operation. FIG. 6 is a schematic configuration diagram of a hot water supply apparatus according to the second embodiment. FIG. 7 is a state diagram of the hot water supply apparatus according to the second embodiment during a boiling operation. FIG. 8 is a state diagram during battery heating operation of the water heater according to the second embodiment. FIG. 9 is a state diagram during battery cooling operation of the water heater according to the second embodiment. FIG. 10 is a state diagram of the hot water supply device according to the second embodiment during a battery temperature maintenance operation. FIG. 11 is a schematic configuration diagram of a hot water supply apparatus according to the third embodiment. FIG. 12 is a state diagram of the hot water supply apparatus according to the third embodiment during a boiling operation. FIG. 13 is a state diagram of the hot water supply device according to Embodiment 3 during battery heating operation. FIG. 14 is a state diagram during battery cooling operation of the water heater according to the third embodiment. FIG. 15 is a state diagram of the hot water supply device according to Embodiment 3 during a battery temperature maintenance operation.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. The following embodiments are essentially preferable examples, and are not intended to limit the scope of the present invention, its application, or its use.

Embodiment 1 of the Invention
As shown in FIG. 1, the hot water supply device (10) of the present embodiment is a heat pump type hot water heater, and includes a heat source unit (60) and a hot water storage unit (20). The heat source unit (60) and the hot water storage unit (20) are connected by a pipe constituting the water circulation path (21).

(Heat source unit)
The heat source unit (60) is installed outside and accommodates the refrigerant circuit (65). The refrigerant circuit (65) is a closed circuit filled with a refrigerant such as carbon dioxide, and performs a vapor compression refrigeration cycle by circulating the refrigerant. A compressor (61), an air heat exchanger (62), an expansion valve (64), and a water heat exchanger (63) are connected to the refrigerant circuit (65) in this order.

  The compressor (61) compresses the refrigerant in the refrigerant circuit (65), the discharge side is connected to the water heat exchanger (63), and the suction side is connected to the air heat exchanger (62).

  The air heat exchanger (62) is constituted by a cross fin type fin-and-tube heat exchanger, and exchanges heat between the outdoor air supplied by an outdoor fan (not shown) and the refrigerant. The expansion valve (64) is an electric expansion valve with a variable opening.

  The water heat exchanger (63) is a so-called plate heat exchanger, and includes a water flow path (63a) and a refrigerant flow path (63b) that are partitioned from each other. The water channel (63a) is connected to the water circuit (21). On the other hand, the refrigerant flow path (63b) is connected to the refrigerant circuit (65) so that the high-temperature and high-pressure refrigerant discharged from the compressor (61) flows in. In the water heat exchanger (63), the water in the water circulation path (21) flowing through the water flow path (63a) and the refrigerant in the refrigerant circuit (65) flowing through the refrigerant flow path (63b) exchange heat.

(Hot water storage unit)
The hot water storage unit (20) includes a hot water storage tank (40), a heat medium circuit (50), and a molten salt battery (55).

  The hot water storage tank (40) is a sealed container for storing water formed in a vertically long cylindrical shape, and constitutes the tank of the present invention. The hot water storage tank (40) has a water inlet (41) and a water inlet (42) at the bottom, an intermediate hot water inlet (43) at the middle, a hot water outlet (44), an upper hot water inlet (45), and Upper inlet / outlet (46) is formed respectively.

  An outlet end of a water supply pipe (35) for supplying city water to the hot water storage tank (40) is connected to the water supply port (41) of the hot water storage tank (40). Further, the outlet end (44) of the hot water storage tank (40) is connected to the inlet end of a hot water supply pipe (36) for taking out hot hot water accumulated in the upper part of the hot water storage tank (40).

  The intake end (42) of the hot water storage tank (40) is connected to the inlet end of the water circulation path (21), and the upper end inlet (45) of the hot water storage tank (40) is connected to the outlet end of the water circulation path (21). It is connected. The water intake (42) constitutes the outlet of the tank of the present invention, and the upper hot water inlet (45) constitutes the inlet of the tank of the present invention.

  The water circuit (21) is provided across the hot water storage unit (20) and the heat source unit (60). A pump (22), a water heat exchanger (63), and a heat medium heat exchanger (30) are connected to the water circulation path (21) in order from the inlet end to the outlet end. The pump (22) and the heat medium heat exchanger (30) are accommodated in the hot water storage unit (20), and the water heat exchanger (63) is accommodated in the heat source unit (60). In this water circuit (21), the water at the bottom of the hot water storage tank (40) is sent to the water heat exchanger (63) by the pump (22), then passes through the heat medium heat exchanger (30), It is returned to the upper part of the hot water storage tank (40). That is, the water circulation path (21) is configured to circulate water between the water heat exchanger (63) and the hot water storage tank (40).

  The heat medium heat exchanger (30) includes a water flow path (30a) and a heat medium flow path (30b) that are partitioned from each other. The water channel (30a) is connected to the water circuit (21). On the other hand, the heat medium flow path (30b) is connected to the heat medium circuit (50). In the heat medium heat exchanger (30), the water in the water circulation path (21) flowing through the water flow path (30a) and the heat medium in the heat medium circuit (50) flowing through the heat medium flow path (30b) exchange heat.

  The heat medium circuit (50) is a closed circuit filled with water or refrigerator oil. The refrigerating machine oil preferably has a boiling point of 100 ° C. or higher. For example, Daikin demnum, Idemitsu Kosan FVC68D, Sumitomo 3M “Florinart”, SOLVAY SOLEXIS Galden is used. The heat medium heat exchanger (30), the pump (51), and the molten salt battery (55) are sequentially connected to the heat medium circuit (50). In the heat medium circuit (50), the heat medium circulates between the heat medium heat exchanger (30) and the molten salt battery (55) by the pump (51).

  The molten salt battery (55) is a battery using a molten salt as an electrolyte. The molten salt battery (55) can be charged and discharged at a temperature equal to or higher than the melting point of the molten salt because the molten salt dissolves and ions can move. On the other hand, at a temperature lower than the melting point of the molten salt, since the molten salt is solidified and ions cannot move, spontaneous discharge is suppressed. An example of the molten salt battery (55) is a sodium ion battery. In this sodium ion battery, for example, a mixture of sodium bis (fluorosulfonyl) amide (NaFSA) and potassium bis (fluorosulfonyl) amide (KFSA) is used as a molten salt. Since this sodium ion battery has a melting point of about 60 ° C., unlike other molten salt batteries, it can be charged / discharged at 100 ° C. or lower, and at a temperature lower than 60 ° C., natural discharge is suppressed. Is done.

  The water circulation path (21) is provided with a bypass pipe (23) and an intermediate return pipe (24). The bypass pipe (23) sends hot hot water accumulated in the upper part of the hot water storage tank (40) to the heat medium heat exchanger (30) without passing through the water heat exchanger (63). Constitutes the road. One end of the bypass pipe (23) is connected to the upper hot water inlet / outlet (46) of the hot water storage tank (40), and the other end is connected to the water heat exchanger (63) of the water circulation path (21) and the heat medium heat exchanger (30 ) Is connected between. The intermediate portion return pipe (24) returns the hot water that has passed through the heat medium heat exchanger (30) to the intermediate portion of the hot water storage tank (40) in the water circulation path (21). One end of the intermediate return pipe (24) is connected between the heat medium heat exchanger (30) of the water circulation path (21) and the upper hot water inlet (45), and the other end is intermediate between the hot water storage tank (40). It is connected to the section entrance (43).

  Moreover, the 1st three-way valve (25) and the 2nd three-way valve (26) are connected to the water circuit (21). The first three-way valve (25) is provided at a location where the bypass pipe (23) and the water circulation path (21) are connected. The first port of the first three-way valve (25) is connected to the water heat exchanger (63) side of the water circuit (21), and the second port is the heat medium heat exchanger (30) side of the water circuit (21) The third port is connected to one end of the bypass pipe (23). The second three-way valve (26) is provided at a location where the intermediate return pipe (24) and the water circulation path (21) are connected. The first port of the second three-way valve (26) is connected to the heat medium heat exchanger (30) side of the water circuit (21), and the second port of the second three-way valve (26) is connected to the water circuit (21). The third port of the second three-way valve (26) is connected to one end of the intermediate return pipe (24).

  In addition, a pump (27) is connected between the first three-way valve (25) and the heat medium heat exchanger (30) in the water circulation path (21). This pump (27) is for taking out hot hot water accumulated in the upper part of the hot water storage tank (40) from the upper hot water inlet / outlet (46) and sending it to the heat medium heat exchanger (30).

-Driving action-
Next, the operation of the hot water supply device (10) will be described. The following operation is controlled by a controller (not shown).

(Boiling operation)
The operation of boiling water in the hot water storage tank (40) will be described. When performing the boiling operation, as shown in FIG. 2, the first three-way valve (25) is set in a state in which the first port and the third port communicate with each other and the second port is blocked.

  In the boiling operation, when the compressor (61) is driven and the refrigeration cycle is started, the high-temperature refrigerant discharged from the compressor (61) flows into the refrigerant flow path (63b) of the water heat exchanger (63). To do. In the water heat exchanger (63), the high-temperature refrigerant in the refrigerant channel (63b) exchanges heat with the water in the water channel (63a), and the water absorbs heat from the high-pressure refrigerant and is heated. On the other hand, the refrigerant that has dissipated heat with respect to water is sent to the expansion valve (64) and decompressed, and then flows into the air heat exchanger (62). In the air heat exchanger (62), the refrigerant exchanges heat with outdoor air. The outdoor air is cooled and sent out by the outdoor fan. On the other hand, the refrigerant evaporates and is sent to the compressor (61) again.

  At this time, in the water circulation path (21), the water at the bottom of the hot water storage tank (40) is sent from the water intake (42) to the water heat exchanger (63) by the pump (22), and the water heat exchanger (63) Is heated. Thereafter, the heated hot water passes through the bypass pipe (23) and flows into the upper portion of the hot water storage tank (40) from the upper inlet / outlet hot water outlet (46). When water (warm water) is circulated in the water circulation path (21) in this way, the hot water temperature in the upper part of the hot water storage tank (40) gradually rises to reach a predetermined hot water supply temperature (for example, 90 ° C), and the boiling is completed. To do.

  When supplying hot water such as filling a bathtub, hot water in the hot water storage tank (40) is supplied from a hot water outlet (44) through a hot water supply pipe (36). At that time, the same amount of tap water as the hot water flowing out to the hot water supply pipe (36) is replenished from the water supply opening (41) to the hot water storage tank (40) through the water supply pipe (35).

(Battery heating operation)
A battery heating operation for heating the molten salt battery (55) to a temperature equal to or higher than the melting point of the molten salt will be described. When the battery heating operation is performed, as shown in FIG. 3, the first three-way valve (25) is set in a state in which the first port and the second port communicate with each other and the third port is blocked. On the other hand, the second three-way valve (26) is set in a state where the first port communicates with the third port and the second port is blocked.

  In the battery heating operation, when the pump (22) is driven, high-temperature hot water heated by the water heat exchanger (13) passes through the pump (27) and flows to the heat medium heat exchanger (30). At this time, in the heat medium circuit (50), the heat medium is circulated between the heat medium heat exchanger (30) and the molten salt battery (55) by the pump (51) while the heat medium heat exchanger (30). In this case, heat is exchanged with high-temperature hot water, and heat is absorbed from the high-temperature hot water. Therefore, the temperature of the circulating heat medium gradually rises and approaches the temperature of the hot water heated by the water heat exchanger (63), that is, the hot water supply temperature (for example, 90 ° C.) and receives the heat from the heat medium. The battery (55) also approaches the hot water supply temperature (for example, 90 ° C.). Thus, the molten salt battery (55) is at a temperature higher than the melting point of the molten salt, and is in a state where charge and discharge are possible.

  Moreover, in the heat medium heat exchanger (30), the hot water that has radiated heat to the heat medium and has fallen in temperature passes through the intermediate return pipe (24) and passes from the intermediate hot water inlet (43) to the middle of the hot water storage tank (40). Returned to the department. As described above, when the temperature of the heat medium in the heat medium circuit (50) rises, the temperature difference between the hot water sent to the heat medium heat exchanger (30) and the heat medium becomes small, and the heat dissipation amount of the hot water becomes small. For this reason, the temperature of the hot water gradually increases. In the second three-way valve (26), when the temperature of the hot water rises, the first port and the second port communicate with each other and the third port is switched off, and the hot water is supplied from the upper hot water inlet (45). It is returned to the upper part of the hot water storage tank (40).

(Battery cooling operation)
A battery cooling operation for cooling the molten salt battery (55) to a temperature lower than the melting point of the molten salt will be described. When the battery cooling operation is performed, as shown in FIG. 4, the first three-way valve (25) is set in a state in which the first port and the second port are communicated and the third port is blocked. On the other hand, the second three-way valve (26) is set in a state where the first port communicates with the third port and the second port is blocked.

  The battery cooling operation is performed in a state where the drive of the compressor (61) is stopped, that is, while the refrigeration cycle is stopped. When the compressor (61) is stopped, the high-temperature and high-pressure refrigerant is not discharged from the compressor (61) and does not flow into the water heat exchanger (63). Therefore, the relatively low temperature (20 ° C. to 60 ° C.) hot water sent from the bottom of the hot water storage tank (40) to the water heat exchanger (63) is not heated by the refrigerant, but the water heat exchanger (63). Is sent to the heat medium heat exchanger (30). At this time, in the heat medium circuit (50), the heat medium is circulated between the heat medium heat exchanger (30) and the molten salt battery (55) by the pump (51) while the heat medium heat exchanger (30). In this case, heat is exchanged with the hot water at the bottom of the hot water storage tank (40), and the heat is radiated to the hot water and cooled. Therefore, the temperature of the circulating heat medium gradually decreases, approaches the hot water temperature (20 ° C. to 60 ° C.) at the bottom of the hot water storage tank (40), and the molten salt battery (55) that receives heat from the heat medium is also a hot water storage tank. (40) The hot water temperature at the bottom (20 ° C to 60 ° C) is approached. Thus, the molten salt battery (55) is at a temperature lower than the melting point of the molten salt, and the molten salt is solidified so that spontaneous discharge is suppressed. Thereafter, the hot water that has passed through the heat medium heat exchanger (30) is returned to the intermediate portion of the hot water storage tank (40) from the intermediate hot water inlet (43) through the intermediate return pipe (24).

(Battery temperature maintenance operation)
A battery temperature maintaining operation for maintaining the molten salt battery (55) at a temperature equal to or higher than the melting point of the molten salt in a state where the compressor (61) is stopped will be described. When the battery temperature maintaining operation is performed, as shown in FIG. 5, the first three-way valve (25) is set in a state where the second port and the third port communicate with each other and the first port is blocked. On the other hand, the second three-way valve (26) is set in a state where the first port communicates with the third port and the second port is blocked.

  Similarly to the battery cooling operation, the battery temperature maintaining operation is also performed in a state where the driving of the compressor (61) is stopped, that is, while the refrigeration cycle is stopped. When the pump (27) is driven, the hot water (65 ° C to 90 ° C) at the upper part of the hot water storage tank (40) flows out from the upper inlet / outlet (46) and passes through the bypass pipe (23) to generate heat. It is sent to the medium heat exchanger (30). At this time, in the heat medium circuit (50), the heat medium is circulated between the heat medium heat exchanger (30) and the molten salt battery (55) by the pump (51) while the heat medium heat exchanger (30). Heat exchange with hot water at the top of the hot water storage tank (40). Therefore, the temperature of the circulating heat medium gradually approaches the hot water temperature (65 ° C. to 90 ° C.) at the upper part of the hot water storage tank (40), and the molten salt battery (55) receiving heat from the heat medium is also used in the hot water storage tank (40 ) Approaches the hot water temperature (65 ° C. to 90 ° C.) at the top of the head. Thus, the molten salt battery (55) is maintained at a temperature higher than the melting point of the molten salt and in a chargeable / dischargeable state even when the refrigeration cycle is stopped. Thereafter, the hot water that has passed through the heat medium heat exchanger (30) is returned to the intermediate portion of the hot water storage tank (40) from the intermediate hot water inlet (43) through the intermediate return pipe (24).

-Effect of Embodiment 1-
According to this embodiment, in the hot water supply device (10), the molten salt battery (55) is heated by a heat medium exchanged with high-temperature hot water, and the molten salt battery (55) is heated by a heat medium exchanged with low-temperature hot water. ) Was cooled. As a result, the molten salt battery (55) having a low melting point can be heated to be in a chargeable / dischargeable state, and the molten salt battery (55) having a low melting point can be cooled to suppress spontaneous discharge. can do. That is, the state of the low melting point molten salt battery (55) can be controlled within the temperature range of the hot water. Furthermore, since the temperature is adjusted using the heat of the heat medium, it is not necessary to generate heat with an electric heater or the like, and the power consumption can be reduced as compared with the prior art.

  Further, according to the present embodiment, the water (hot water) after passing through the water heat exchanger (63) and the heat medium are subjected to heat exchange. Thus, during the refrigeration cycle, the low melting point molten salt battery (55) can be heated to the oil supply temperature (90 ° C.) by the heat medium exchanged with the hot water heated by the water heat exchanger (63). As a result, the molten salt battery (55) can be charged. On the other hand, while the refrigeration cycle is stopped, the low-melting-point molten salt battery (55) is cooled to low-temperature water (55) by the heat medium exchanged with low-temperature water (hot water) that has passed without being heated by the water heat exchanger (63). It can cool to the temperature (20 degreeC-60 degreeC) of warm water, As a result, the natural discharge of this molten salt battery (55) can be suppressed.

  Further, according to the present embodiment, the water intake (42) of the tank (40) is provided below the upper hot water inlet (45). Thus, while the refrigeration cycle is stopped, the low melting point molten salt battery (55) is cooled by the heat medium exchanged with water (warm water) of relatively low temperature (20 ° C to 60 ° C) at the bottom of the tank (40). Thus, spontaneous discharge can be reliably suppressed.

  Further, according to the present embodiment, the hot water in the upper part of the tank (40) is sent to the heat medium heat exchanger (30) without passing through the water heat exchanger (63) to exchange heat with the heat medium. Thereby, while the refrigeration cycle is stopped, the low-melting-point molten salt battery (55) can be heated by the heat medium exchanging heat with the relatively high temperature (65 ° C. to 90 ° C.) hot water at the top of the tank (40). The molten salt battery (55) can be maintained in a chargeable state.

<< Embodiment 2 of the Invention >>
The hot water supply device (10) according to Embodiment 2 is obtained by changing the method of adjusting the temperature of the molten salt battery (55) in Embodiment 1 described above. That is, in the first embodiment, the temperature of the molten salt battery (55) is adjusted using the heat of the heat medium that exchanges heat with the water (warm water) in the water circulation path (21). As shown in FIG. 6, the temperature of the molten salt battery (55) was adjusted by directly using the heat of the water (warm water) in the water circuit (21).

  In the hot water supply device (10) of the second embodiment, the molten salt battery (55) is connected between the pump (27) of the water circulation path (21) and the second three-way valve (26). The water circulation path (21) passes through the first three-way valve (25) and the pump (27) in this order after the water at the bottom of the hot water storage unit (20) is sent to the water heat exchanger (63). (55), and then passes through the second three-way valve (26) and returns to the upper part of the hot water storage unit (20).

-Driving action-
Next, the operation of the hot water supply device (10) according to the second embodiment will be described.

(Boiling operation)
The operation of boiling water in the hot water storage tank (40) will be described. When performing the boiling operation, as shown in FIG. 7, the first three-way valve (25) is set in a state in which the first port and the third port communicate with each other and the second port is blocked.

  In the boiling operation, when the compressor (61) is driven and the refrigeration cycle is started, the high-temperature refrigerant discharged from the compressor (61) flows into the refrigerant flow path (63b) of the water heat exchanger (63). To do. In the water heat exchanger (63), the high-temperature refrigerant in the refrigerant channel (63b) exchanges heat with the water in the water channel (63a), and the water absorbs heat from the high-pressure refrigerant and is heated. On the other hand, the refrigerant that has dissipated heat with respect to water passes through the expansion valve (64) and the air heat exchanger (62) in this order, and is sent again to the compressor (61).

  At this time, in the water circulation path (21), the water at the bottom of the hot water storage tank (40) is sent from the water intake (42) to the water heat exchanger (63) by the pump (22), and the water heat exchanger (63) Is heated. Thereafter, the heated hot water passes through the bypass pipe (23) and flows into the upper portion of the hot water storage tank (40) from the upper inlet / outlet hot water outlet (46). When water (warm water) is circulated in the water circulation path (21) in this way, the hot water temperature in the upper part of the hot water storage tank (40) gradually rises to reach a predetermined hot water supply temperature (for example, 90 ° C), and the boiling is completed. To do.

  When supplying hot water such as filling a bathtub, hot water in the hot water storage tank (40) is supplied from a hot water outlet (44) through a hot water supply pipe (36). At that time, the same amount of tap water as the hot water flowing out to the hot water supply pipe (36) is replenished from the water supply opening (41) to the hot water storage tank (40) through the water supply pipe (35).

(Battery heating operation)
A battery heating operation for heating the molten salt battery (55) to a temperature equal to or higher than the melting point of the molten salt will be described. When the battery heating operation is performed, as shown in FIG. 8, the first three-way valve (25) is set in a state where the first port and the second port communicate with each other and the third port is blocked. On the other hand, the second three-way valve (26) is set in a state where the first port communicates with the third port and the second port is blocked.

  In the battery heating operation, when the pump (22) is driven, hot hot water heated by the water heat exchanger (13) flows to the molten salt battery (55). At this time, the molten salt battery (55) receives heat from the high-temperature hot water and rises in temperature, and approaches the temperature of the hot water heated by the water heat exchanger (63), that is, the hot water supply temperature (for example, 90 ° C.). . Thus, the molten salt battery (55) is at a temperature higher than the melting point of the molten salt, and is in a state where charge and discharge are possible.

  Further, the hot water whose temperature has decreased due to heat dissipation in the molten salt battery (55) passes through the intermediate return pipe (24) and is returned from the intermediate hot water inlet (43) to the intermediate portion of the hot water storage tank (40). As described above, when the temperature of the molten salt battery (55) rises, the temperature difference between the hot water sent to the molten salt battery (55) and the molten salt battery (55) becomes small, and the heat dissipation amount of the hot water becomes small. The temperature of the hot water gradually rises. In the second three-way valve (26), when the temperature of the hot water rises, the first port and the second port communicate with each other and the third port is switched off, and the hot water is supplied from the upper hot water inlet (45). It is returned to the upper part of the hot water storage tank (40).

(Battery cooling operation)
A battery cooling operation for cooling the molten salt battery (55) to a temperature lower than the melting point of the molten salt will be described. When the battery cooling operation is performed, as shown in FIG. 9, the first three-way valve (25) is set in a state where the first port and the second port communicate with each other and the third port is blocked. On the other hand, the second three-way valve (26) is set in a state where the first port communicates with the third port and the second port is blocked.

  The battery cooling operation is performed in a state where the drive of the compressor (61) is stopped, that is, while the refrigeration cycle is stopped. When the compressor (61) is stopped, the high-temperature and high-pressure refrigerant is not discharged from the compressor (61) and does not flow into the water heat exchanger (63). Therefore, the relatively low temperature (20 ° C. to 60 ° C.) hot water sent from the bottom of the hot water storage tank (40) to the water heat exchanger (63) is not heated by the refrigerant, but the water heat exchanger (63). Is sent to the molten salt battery (55). At this time, if the molten salt battery (55) is hotter than the hot water at the bottom of the hot water storage tank (40), the molten salt battery (55) is cooled by releasing heat to the hot water, and the temperature of the molten salt battery (55) gradually increases. 40) Approach the bottom hot water temperature (20 ° C to 60 ° C). Thus, the molten salt battery (55) is at a temperature lower than the melting point of the molten salt, and the molten salt is solidified so that spontaneous discharge is suppressed. Thereafter, the hot water that has passed through the molten salt battery (55) passes through the intermediate return pipe (24) and is returned from the intermediate hot water inlet (43) to the intermediate portion of the hot water storage tank (40).

(Battery temperature maintenance operation)
A battery temperature maintaining operation for maintaining the molten salt battery (55) at a temperature equal to or higher than the melting point of the molten salt in a state where the compressor (61) is stopped will be described. When the battery temperature maintaining operation is performed, as shown in FIG. 10, the first three-way valve (25) is set in a state where the second port and the third port communicate with each other and the first port is blocked. On the other hand, the second three-way valve (26) is set in a state where the first port communicates with the third port and the second port is blocked.

  Similarly to the battery cooling operation, the battery temperature maintaining operation is also performed in a state where the driving of the compressor (61) is stopped, that is, while the refrigeration cycle is stopped. When the pump (27) is driven, the hot water at the upper part of the hot water storage tank (40) flows out from the upper inlet / outlet (46), passes through the bypass pipe (23), and melts. Sent to the salt battery (55). At this time, the molten salt battery (55) receives heat from the hot water and approaches the hot water temperature (65 ° C. to 90 ° C.) in the upper part of the hot water storage tank (40). Thus, the molten salt battery (55) is maintained at a temperature higher than the melting point of the molten salt even during the refrigeration cycle stop, and the chargeable / dischargeable state is maintained. Thereafter, the hot water that has passed through the molten salt battery (55) passes through the intermediate return pipe (24) and is returned from the intermediate hot water inlet (43) to the intermediate portion of the hot water storage tank (40).

-Effect of Embodiment 2-
According to the present embodiment, the molten salt battery (55) is heated with hot hot water and the molten salt battery (55) is cooled with cold hot water in the hot water supply device (10). As a result, the molten salt battery (55) having a low melting point can be heated to be in a chargeable / dischargeable state, and the molten salt battery (55) having a low melting point can be cooled to suppress spontaneous discharge. can do. That is, the state of the low melting point molten salt battery (55) can be controlled within the temperature range of the refrigerant. Furthermore, since the temperature is adjusted using the heat of hot water, it is not necessary to generate heat with an electric heater or the like, and the power consumption can be reduced as compared with the prior art.

  Further, according to the present embodiment, the water (warm water) that has passed through the water heat exchanger (63) is sent to the molten salt battery (55). Thus, during the refrigeration cycle, the molten salt battery (55) having a low melting point can be heated to the oil supply temperature (90 ° C.) with the hot water heated by the water heat exchanger (63). The salt battery (55) can be charged. On the other hand, while the refrigeration cycle is stopped, the low-melting-point molten salt battery (55) is passed through the low-temperature water (hot water) temperature (20) by the low-temperature water (hot water) passed without being heated by the water heat exchanger (63). C. to 60.degree. C.), and as a result, natural discharge of the molten salt battery (55) can be suppressed.

  Further, according to the present embodiment, the outlet (42) of the tank (40) is provided below the inlet (45). As a result, while the refrigeration cycle is stopped, the low-melting-point molten salt battery (55) is cooled by water (hot water) at a relatively low temperature (20 ° C to 60 ° C) at the bottom of the tank (40) to ensure natural discharge. Can be suppressed.

  Further, according to the present embodiment, the hot water in the upper part of the tank (40) is sent to the molten salt battery (55) without going through the hydrothermal exchanger (63). Thereby, the low melting point molten salt battery (55) can be heated by the relatively high temperature (65 ° C. to 90 ° C.) hot water in the upper part of the tank (40) while the refrigeration cycle is stopped. (55) can be maintained in a chargeable state.

<< Embodiment 3 of the Invention >>
The hot water supply device (10) according to Embodiment 3 is obtained by changing the method of adjusting the temperature of the molten salt battery (55) in Embodiment 1 described above. That is, in the first embodiment, the temperature of the molten salt battery (55) is adjusted by the heat medium that exchanges heat with the water (warm water) in the water circulation path (21), but in the second embodiment, as shown in FIG. In addition, the temperature of the molten salt battery (55) was adjusted by the refrigerant in the refrigerant circuit (65).

  In the hot water supply device (10) of the third embodiment, the molten salt battery (55) is connected to the refrigerant circuit (65). Specifically, in the refrigerant circuit (65), a branch path (66) is connected in parallel to the water heat exchanger (63), and a molten salt battery (55) is connected to the branch path (66). In addition, the third three-way valve (67) and the fourth three-way valve (68) are respectively connected to the connecting portions at both ends of the branch path (66). The first port of the third three-way valve (67) is connected to the discharge side of the compressor (61), the second port is connected to the inflow side of the water heat exchanger (63), and the third port is a branch ( 66) is connected to one end. On the other hand, the first port of the fourth three-way valve (68) is connected to the expansion valve (64), the second port is connected to the outflow side of the water heat exchanger (63), and the third port is the branch path (66). It is connected to one end. These two three-way valves (67, 68) constitute the switching valve of the present invention. In addition, a pump (69) is connected to the branch path (66) between the molten salt battery (55) and the fourth three-way valve (68).

-Driving action-
Next, the operation of the hot water supply device (10) of Embodiment 3 will be described.

(Boiling operation)
The operation of boiling water in the hot water storage tank (40) will be described. When performing the boiling operation, as shown in FIG. 12, the third three-way valve (67) is set in a state in which the first port and the second port communicate with each other and the third port is blocked. On the other hand, the fourth three-way valve (68) is set in a state where the first port communicates with the second port and the third port is blocked.

  In the boiling operation, when the compressor (61) is driven and the refrigeration cycle is started, the high-temperature refrigerant discharged from the compressor (61) does not flow into the molten salt battery (55), but the water heat exchange Flows into the refrigerant flow path (63b) of the vessel (63). In the water heat exchanger (63), the high-temperature refrigerant in the refrigerant channel (63b) exchanges heat with the water in the water channel (63a), and the water absorbs heat from the high-temperature refrigerant and is heated. On the other hand, the refrigerant that has dissipated heat with respect to water passes through the expansion valve (64) and the air heat exchanger (62) in this order, and is sent to the compressor (61) again.

  At this time, in the water circulation path (21), the water at the bottom of the hot water storage tank (40) is sent from the water intake (42) to the water heat exchanger (63) by the pump (22), and the water heat exchanger (63) Is heated. Thereafter, the heated hot water flows from the upper hot water inlet (45) to the upper part of the hot water storage tank (40). When water (warm water) is circulated in the water circulation path (21) in this way, the hot water temperature in the upper part of the hot water storage tank (40) gradually rises to reach a predetermined hot water supply temperature (for example, 90 ° C), and the boiling is completed. To do.

  When supplying hot water such as filling a bathtub, hot water in the hot water storage tank (40) is supplied from a hot water outlet (44) through a hot water supply pipe (36). At that time, the same amount of tap water as the hot water flowing out to the hot water supply pipe (36) is replenished from the water supply opening (41) to the hot water storage tank (40) through the water supply pipe (35).

(Battery heating operation)
A battery heating operation for heating the molten salt battery (55) to a temperature equal to or higher than the melting point of the molten salt will be described. When the battery heating operation is performed, as shown in FIG. 13, the third three-way valve (67) is set in a state in which the first port and the third port are communicated and the second port is blocked. On the other hand, the fourth three-way valve (68) is set in a state where the first port communicates with the third port and the second port is blocked.

  In battery heating operation, when the compressor (61) is driven and the refrigeration cycle is started, the high-temperature refrigerant discharged from the compressor (61) does not flow into the water heat exchanger (63), but the molten salt Flows into the battery (55). At this time, the molten salt battery (55) absorbs heat from the high-temperature refrigerant and rises in temperature to reach the refrigerant temperature (95 ° C. to 115 ° C.). Thus, the molten salt battery (55) is at a temperature higher than the melting point of the molten salt, and is in a state where charge and discharge are possible. The refrigerant that dissipated heat to the molten salt battery (55) passes through the expansion valve (64) and the air heat exchanger (62) in this order, and is sent again to the compressor (61).

(Battery cooling operation)
A battery cooling operation for cooling the molten salt battery (55) to a temperature lower than the melting point of the molten salt will be described. When the battery cooling operation is performed, as shown in FIG. 14, the third three-way valve (67) is set in a state where the second port and the third port communicate with each other and the first port is blocked. On the other hand, the fourth three-way valve (68) is set in a state where the second port communicates with the third port and the first port is blocked.

  The battery cooling operation is performed in a state where the drive of the compressor (61) is stopped, that is, while the refrigeration cycle is stopped. When the pump (22) is driven, hot water at a relatively low temperature (20 ° C. to 60 ° C.) at the bottom of the hot water storage tank (40) is sent to the water heat exchanger (63). At this time, in the refrigerant circuit (65), the refrigerant circulates between the water heat exchanger (63) and the molten salt battery (55) by the pump (69), while the water heat exchanger (63) 40) Heat exchange with the bottom water (hot water). Therefore, the temperature of the circulating refrigerant gradually approaches the temperature (20 ° C. to 60 ° C.) of the water (hot water) at the bottom of the hot water storage tank (40), and the molten salt battery (55) that receives heat from the refrigerant is also used in the hot water storage tank ( 40) approaches the temperature (20 ° C. to 60 ° C.) of the bottom water (warm water). Thus, the molten salt battery (55) is at a temperature lower than the melting point of the molten salt, and the molten salt is solidified so that spontaneous discharge is suppressed.

(Battery temperature maintenance operation)
A battery temperature maintaining operation for maintaining the molten salt battery (55) at a temperature equal to or higher than the melting point of the molten salt in a state where the compressor (61) is stopped will be described. When the battery temperature maintaining operation is performed, as shown in FIG. 15, the third three-way valve (67) is set in a state where the second port and the third port communicate with each other and the first port is blocked. On the other hand, the fourth three-way valve (68) is set in a state where the second port communicates with the third port and the first port is blocked.

  Similarly to the battery cooling operation, the battery temperature maintaining operation is also performed in a state where the driving of the compressor (61) is stopped, that is, while the refrigeration cycle is stopped. When the pump (22) is driven, the relatively high temperature (65 ° C. to 90 ° C.) hot water in the upper portion of the hot water storage tank (40) is sent to the water heat exchanger (63). At this time, in the refrigerant circuit (65), the refrigerant circulates between the water heat exchanger (63) and the molten salt battery (55) by the pump (69), while the water heat exchanger (63) 40) Heat exchange with the upper water (hot water). Therefore, the temperature of the circulating refrigerant gradually approaches the temperature (65 ° C. to 90 ° C.) of the water (hot water) in the upper part of the hot water storage tank (40), and the molten salt battery (55) that receives heat from the refrigerant is also used in the hot water storage tank ( 40) It approaches the temperature (65 ° C. to 90 ° C.) of the upper water (warm water). Thus, the molten salt battery (55) is maintained at a temperature higher than the melting point of the molten salt and in a chargeable / dischargeable state even when the refrigeration cycle is stopped.

-Effect of Embodiment 3-
According to this embodiment, in the hot water supply device (10), the molten salt battery (55) is heated by the high-temperature refrigerant in the refrigerant circuit (65), and the molten salt battery (55) is heated by the low-temperature refrigerant in the refrigerant circuit (65). ) Was cooled. As a result, the molten salt battery (55) having a low melting point can be heated to be in a chargeable / dischargeable state, and the molten salt battery (55) having a low melting point can be cooled to suppress spontaneous discharge. can do. That is, the state of the low melting point molten salt battery (55) can be controlled within the temperature range of the refrigerant. Furthermore, since the temperature is adjusted using the heat of the refrigerant, it is not necessary to generate heat with an electric heater or the like, and the power consumption can be reduced as compared with the prior art.

  Further, according to the present embodiment, in the refrigerant circuit (65), the branch path (66) is connected in parallel to the water heat exchanger (63), and the molten salt battery (55) is connected to the branch path (66). And a three-way valve (67, 68) is provided at the connecting portion at both ends of the branch path (66). Accordingly, the water boiling operation and the molten salt battery heating operation can be switched by the three-way valve (67, 68).

  Further, according to the present embodiment, the refrigerant is circulated between the water heat exchanger (63) and the molten salt battery (55) while the refrigeration cycle is stopped, and the hot water at the bottom of the tank (40) is further supplied to the water. It was sent to the heat exchanger (63). Thereby, the low melting point molten salt battery (55) can be cooled with the relatively low temperature (20 ° C. to 60 ° C.) hot water at the bottom of the tank (40). As a result, the low melting point molten salt battery (55) Spontaneous discharge can be reliably suppressed.

  Further, according to the present embodiment, the refrigerant is circulated between the water heat exchanger (63) and the molten salt battery (55) while the refrigeration cycle is stopped, and the hot water in the upper part of the tank (40) is further circulated. It was sent to the heat exchanger (63). As a result, the low melting point molten salt battery (55) can be heated with the relatively high temperature (65 ° C. to 90 ° C.) hot water in the upper part of the tank (40). As a result, this low melting point molten salt battery (55) Can be maintained in a chargeable state.

  As described above, the present invention is useful for the hot water supply device (10) including the molten salt battery (55).

21 Water circuit
23 Bypass pipe (bypass)
30 Heat transfer heat exchanger
40 Hot water storage tank
42 Water intake (outlet)
45 Upper entrance (inlet)
50 Heat transfer circuit
55 Molten salt battery
63 Water heat exchanger
65 Refrigerant circuit
66 forks
67 Switching valve (third three-way valve)
68 Switching valve (4th three way valve)

Claims (12)

A refrigerant circuit (65) for performing a refrigeration cycle by circulating the refrigerant;
A water heat exchanger (63) connected to the refrigerant circuit (65) for exchanging heat between the refrigerant in the refrigerant circuit (65) and water to heat the water and a tank (40) for storing water are provided. A water heater comprising a water circulation path (21) for circulating water between the water heat exchanger (63) and the tank (40),
A heat medium circuit (50) connected to the water circuit (21), having a heat medium heat exchanger (30) for exchanging heat between the water in the water circuit (21) and the heat medium, and circulating the heat medium; ,
A hot water supply apparatus comprising: a molten salt battery (55) connected to the heat medium circuit (50) and temperature-controlled by the heat medium of the heat medium circuit (50). In claim 1,
The water circulation path (21) is configured to send water from the tank (40) to the water heat exchanger (63) and then return the water to the tank (40) through the heat medium heat exchanger (30). A hot water supply apparatus characterized by being configured. In claim 2,
The tank (40) is provided with a hot water supply device in which an outlet (42) is provided below the inlet (45). In claim 3,
The water circulation path (21) has a bypass path (23) for sending water in the upper part of the tank (40) to the heat medium heat exchanger (30) without passing through the water heat exchanger (63). A hot water supply device characterized by being. A refrigerant circuit (65) for performing a refrigeration cycle by circulating the refrigerant;
A water heat exchanger (63) connected to the refrigerant circuit (65) for exchanging heat between the refrigerant in the refrigerant circuit (65) and water to heat the water and a tank (40) for storing water are provided. A water heater comprising a water circulation path (21) for circulating water between the water heat exchanger (63) and the tank (40),
A hot water supply apparatus comprising a molten salt battery (55) connected to the water circulation path (21) and temperature-controlled by water in the water circulation path (21). In claim 5,
The water circulation path (21) is configured to return water from the tank (40) to the water heat exchanger (63) and then return to the tank (40) via the molten salt battery (55). A hot water supply apparatus characterized by In claim 6,
The tank (40) is provided with a hot water supply device in which an outlet (42) is provided below the inlet (45). In claim 7,
The water circulation path (21) has a bypass path (23) for sending water in the upper part of the tank (40) to the molten salt battery (55) without passing through the water heat exchanger (63). Hot water supply device characterized by A refrigerant circuit (65) for performing a refrigeration cycle by circulating the refrigerant;
A water heat exchanger (63) connected to the refrigerant circuit (65) for exchanging heat between the refrigerant in the refrigerant circuit (65) and water to heat the water and a tank (40) for storing water are provided. A water heater comprising a water circulation path (21) for circulating water between the water heat exchanger (63) and the tank (40),
A hot water supply apparatus comprising a molten salt battery (55) connected to the refrigerant circuit (65) and temperature-controlled by the refrigerant of the refrigerant circuit (65). In claim 9,
The refrigerant circuit (65) is provided at a branch path (66) connected in parallel to the water heat exchanger (63), and at a connecting portion at both ends of the branch path (66), and is switched to switch a refrigerant flow A valve (67,68),
The hot water supply apparatus, wherein the molten salt battery (55) is connected to the branch path (66). In claim 10,
The water circulation path (21) is configured to send water at the bottom of the tank (40) to the water heat exchanger (63) and then return to the upper part of the tank (40).
The refrigerant circuit (65) is configured such that the refrigerant circulates between the water heat exchanger (63) and the molten salt battery (55) while the refrigeration cycle is stopped. apparatus. In claim 11,
The water heater (21) is configured to send water in the upper part of the tank (40) to the water heat exchanger (63) while the refrigeration cycle is stopped.

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