JP2019190677A - Hot water storage type water heater - Google Patents

Abstract

To provide a hot water storage type water heater capable of reducing power consumption.SOLUTION: A hot water storage type water heater 10 comprises: a hot water storage tank; a heat pump 220; an auxiliary heat source machine; a hot water storage pump 215 for circulating water between the hot water storage tank and the heat pump 220; a circulation pump 414 for feeding the water in the hot water storage tank to the auxiliary heat source machine; a power supply circuit 910; a first pump power supply line 921 for supplying power from the power supply circuit 910 to the hot water storage pump 215; a second pump power line 922 for supplying power from the power circuit 910 to the circulation pump 414; a first pump line switching circuit 940 provided in the second pump power supply line 922, for connecting and disconnecting the second pump power supply line 922; and a microcomputer 800. The microcomputer 800 shuts off the second pump power supply line 922 by the first pump line switching circuit 940, based on the fact that the circulation pump 414 is not operated.SELECTED DRAWING: Figure 4

Description

  The present invention relates to a hot water storage type hot water supply apparatus.

  Conventionally, in a hot water storage type hot water supply device, water (hot water) in a hot water storage tank is circulated between a hot water storage tank and a heat source such as a heat pump by using a pump so that hot water of an appropriate temperature can be stored in the hot water storage tank. (For example, refer to Patent Document 1).

  In the hot water storage type hot water supply apparatus, a pump may be provided in addition to the hot water storage pump as described above. For example, hot water storage water heaters are usually equipped with an auxiliary heat source that heats the water (hot water) in the hot water storage tank when there is not enough hot water in the hot water tank at the time of hot water. A pump may be provided to guide the hot water) to the auxiliary heat source. Alternatively, when the hot water storage type hot water supply device has a function of chasing the bath water, a pump for circulating the hot water between the hot water storage type hot water supply device and the bathtub may be provided. Furthermore, when the hot water storage type hot water supply device has a function of heating the heating water supplied to the radiator of the bathroom heater (bathroom heating dryer), the heating water is circulated between the hot water storage type hot water supply device and the bathroom heater. A pump can be provided.

JP 2014-156987 A

  In a hot water storage type hot water supply apparatus, when a pump is provided in addition to a hot water storage pump, electric power can be supplied to these pumps from the same power supply line. In such a case, if the hot water storage pump operates but the other pumps do not operate and the other pumps remain connected to the power supply line, standby power is consumed by the other pumps, which is the hot water storage hot water supply. There is a possibility of leading to unnecessary power consumption of the apparatus.

  Then, an object of this invention is to provide the hot water storage type hot-water supply apparatus which can reduce power consumption.

  The hot water storage type hot water supply apparatus according to the first aspect of the present invention includes a hot water storage tank, a first heat source, a second heat source, and a first for circulating water between the hot water storage tank and the first heat source. A pump, a second pump for sending water in the hot water storage tank to the second heat source, a power source, and a first pump connected to the first pump and supplying power from the power source to the first pump; One power line, a second power line connected to the second pump and supplying power from the power supply unit to the second pump, and provided in the second power line, the connection of the second power line and The 1st switch part which performs interruption | blocking, and a control part are provided. Here, the control unit shuts off the second power supply line by the first switch unit based on not operating the second pump.

  In addition, the term “water” in the claims widely refers to water regardless of its temperature, such as cold water that is low-temperature water and hot water that is high-temperature water.

  According to the above configuration, when the first pump is operated but the second pump is not operated, standby power can be prevented from being generated by the second pump. Thereby, reduction of the power consumption of a hot water storage type hot-water supply apparatus can be aimed at.

  In the hot water storage type hot water supply apparatus according to this aspect, a configuration may be adopted in which a second switch unit provided on the first power supply line and connecting and disconnecting the first power supply line is further provided. In this case, the control unit shuts off the first power supply line by the second switch unit based on not operating the first pump.

  According to the above configuration, when not only the second pump but also the first pump is not operated, standby power can be prevented from being generated by the first pump. Thereby, reduction of the power consumption of a hot water storage type hot-water supply apparatus can be further aimed at.

  In the hot water storage type hot water supply apparatus according to this aspect, a third pump for circulating water between the hot water storage type hot water supply apparatus and an external device, and a heating unit for heating the water circulated by the third pump; , May further be adopted. In this case, the second power supply line is also connected to the third pump downstream of the first switch unit. And the said control part interrupts | blocks the said 2nd power supply line by the said 1st switch part based on not operating the said 2nd pump and the said 3rd pump.

  For example, the external device can be a bathtub or a bathroom heater.

  According to the above configuration, when the first pump is operated but the second pump and the third pump are not operated, standby power can be prevented from being generated by the second pump and the third pump.

  In the hot water storage type hot water supply apparatus according to this aspect, a third pump for circulating water between the hot water storage type hot water supply apparatus and an external device, and a heating unit for heating the water circulated by the third pump; A third power supply line connected to the third pump for supplying power from the power supply unit to the third pump; and a third power supply line provided on the third power supply line for connecting and disconnecting the third power supply line. A configuration that further includes three switch units may be employed. In this case, the control unit shuts off the third power supply line by the third switch unit based on the fact that the third pump is not operated.

  According to the above configuration, when one of the second pump and the third pump operates but the other does not operate, power can be not supplied to the other. The power consumption of the water heater is further reduced.

  In the hot water storage type hot water supply apparatus according to this aspect, the second heat source includes a combustor and a combustion fan that sends air to the combustor, and the second power supply line is located downstream of the first switch unit. A configuration may also be adopted in which it is also connected to the combustion fan. In this case, the control unit shuts off the second power supply line by the first switch unit based on not operating the second pump and the combustion fan.

  According to the above configuration, when the first pump is operated but the second pump and the combustion fan are not operated, standby power can be prevented from being generated by the second pump and the combustion fan.

  In the hot water storage type hot water supply apparatus according to this aspect, when the control unit detects that an abnormality has occurred in either the first pump or the second pump, the first switch unit shuts off the second power supply line. In addition, the first pump may be operated, and an abnormality notification may be performed based on the operation result.

  According to the above configuration, when an abnormality occurs in either the first pump or the second pump, the user knows whether the abnormality has occurred on either the first pump side or the second pump side. Can do.

  A hot water storage hot water supply apparatus according to a second aspect of the present invention includes a hot water storage tank, a heat source, a first pump for circulating water between the hot water storage tank and the heat source, and the hot water storage hot water supply apparatus. A second pump for circulating water between the external device, a heating unit for heating the water circulated by the second pump, a power supply unit, and the first pump; A first power supply line for supplying power from the power supply to the first pump, a second power supply line connected to the second pump and supplying power from the power supply unit to the second pump, and the second power supply line A first switch unit that connects and disconnects the second power supply line, and a control unit. Here, the control unit shuts off the second power supply line by the first switch unit based on not operating the second pump.

  According to the above configuration, when the first pump is operated but the second pump is not operated, standby power can be prevented from being generated by the second pump. Thereby, reduction of the power consumption of a hot water storage type hot-water supply apparatus can be aimed at.

  As described above, according to the present invention, it is possible to provide a hot water storage type hot water supply apparatus that can reduce power consumption.

  The effects and significance of the present invention will become more apparent from the following description of embodiments. However, the embodiment described below is merely an example when the present invention is implemented, and the present invention is not limited to what is described in the following embodiment.

Drawing 1 is a schematic diagram showing composition of a hot water storage type hot-water supply device concerning an embodiment. FIGS. 2A to 2C are diagrams for explaining a hot water storage operation, a hot water supply operation, and an auxiliary heat source hot water supply operation, respectively, according to the embodiment. FIGS. 3A and 3B are diagrams for explaining the reheating operation and the heating water heating operation, respectively, according to the embodiment. FIG. 4 is a block diagram showing a configuration of the hot water storage type hot water supply apparatus according to the embodiment. FIG. 5 is a flowchart illustrating a control operation of the power supply unit by the microcomputer according to the embodiment. FIG. 6 is a flowchart showing an abnormality processing control operation by the microcomputer according to the embodiment. FIG. 7 is a block diagram showing a configuration of a hot water storage type hot water supply apparatus according to a modified example. FIG. 8 is a flowchart illustrating a control operation of the power supply unit by the microcomputer according to the modification. FIG. 9 is a flowchart illustrating an abnormality processing control operation by the microcomputer according to the modification.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  In the present embodiment, the hot water storage pump 215 corresponds to the “first pump” recited in the claims. The heat pump 220 corresponds to “first heat source” and “heat source” recited in the claims. Furthermore, the circulation pump 414 corresponds to a “second pump” recited in the claims. Further, the auxiliary heat source unit 420 corresponds to the “second heat source” recited in the claims. Furthermore, the bath pump 512 and the heating pump 612 correspond to “third pump” and “second pump” recited in the claims. Furthermore, the bath heat exchanger 530 and the heating heat exchanger 630 correspond to the “heating unit” described in the claims. Further, the microcomputer 800 corresponds to a “control unit” recited in the claims. Furthermore, the power supply circuit 910 corresponds to a “power supply unit” recited in the claims. Further, the first pump power supply line 921, the second pump power supply line 922, and the third pump power supply line 925 are respectively “first power supply line”, “second power supply line”, and “third power supply” recited in the claims. Corresponds to the “power line”. Further, the first pump line switching circuit 940, the second pump line switching circuit 950, and the third pump line switching circuit 980 are respectively referred to as “first switch unit”, “second switch unit”, and This corresponds to the “third switch unit”.

  However, the above description is only for the purpose of associating the configuration of the claims with the configuration of the embodiment, and the invention described in the claims is incorporated into the configuration of the embodiment by the above association. It is not limited at all.

  FIG. 1 is a schematic diagram illustrating a configuration of a hot water storage type hot water supply apparatus 10.

  The hot water storage type hot water supply apparatus 10 is disposed, for example, outside a bathroom, and has a hot water storage tank 100, a hot water storage part 200, a hot water supply part 300, an auxiliary heating part 400, a reheating part 500, and a heating water heating part 600. And comprising. The hot water storage type hot water supply apparatus 10 includes a hot water storage operation for storing hot water at an appropriate temperature in the hot water storage tank 100, a hot water supply operation for supplying hot water stored in the hot water storage tank 100 to the water tap 20, and water (hot water) discharged from the hot water storage tank 100. Is heated by the auxiliary heat source unit 420 and supplied to the faucet 20, the reheating operation for reheating the hot water stretched on the bathtub 30, and the heating supplied to the radiator of the bathroom heater 40 Heating water heating operation for heating water can be performed. In the hot water storage type hot water supply apparatus 10, the frequency of the hot water storage operation is usually higher than the frequency of other operations (hot water supply operation, auxiliary heat source hot water supply operation, reheating operation, heating water heating operation).

  The faucet 20 is, for example, a bathroom faucet with a shower. By supplying hot water from the water tap 20 to the bathtub 30, the hot water can be filled in the bathtub 30. Note that the water tap 20 may be a kitchen tap, a wash tap, or the like. The bathroom heater 40 may be a bathroom heater / dryer provided with a drying function.

  The hot water storage tank 100 is a vertically long tank. Hot water at a preset target temperature is stored in the hot water storage tank 100. The hot water storage tank 100 is in a full state, and a temperature stratification is formed inside. Hot water is stored from the upper part of the hot water storage tank 100, and the portion where hot water is not stored becomes water. On the side surface of the hot water storage tank 100, a plurality of hot water temperature sensors 101 for measuring the hot water storage amount, which is the amount of hot water at the target temperature, are provided at respective height positions corresponding to the respective hot water storage amounts.

  The hot water storage unit 200 includes a hot water storage circuit 210 and a heat pump 220. Hot water storage circuit 210 includes an outward path 211, a return path 212, a bypass path 213, a hot water storage switching valve 214, and a hot water storage pump 215.

  The forward path 211 is connected to the lower part of the hot water storage tank 100 and the inlet of the condenser of the heat pump 220. The return path 212 is connected to the upper part of the hot water storage tank 100 and the outlet of the condenser of the heat pump 220. One end of the bypass path 213 is connected to the return path 212 via the hot water storage switching valve 214, and the other end is connected to the forward path 211. The hot water storage switching valve 214 switches whether the water (hot water) flowing through the return path 212 from the heat pump 220 side flows directly to the downstream side of the return path 212 or to the bypass path 213 side. The hot water storage pump 215 is provided on the downstream side (heat pump 220 side) of the forward path 211 from the position where the bypass path 213 is connected.

  The heat pump 220 includes a compressor, a condenser, an expansion valve, and an evaporator, and heats the water flowing in the forward path 211 through the condenser. The heated water, that is, hot water flows through the return path 212.

  The hot water storage circuit 210 is provided with a temperature sensor (not shown) that detects the temperature of the hot water discharged from the heat pump 220.

  Hot water supply unit 300 includes a water supply channel 301, a hot water supply channel 302, a branch water supply channel 303, a mixed hot water supply channel 304, and a mixing valve 305. The water supply channel 301 is connected to the water pipe and the lower end of the hot water storage tank 100. The hot water outlet 302 is connected to the upper end of the hot water storage tank 100 and one inlet of the mixing valve 305. The branch water supply channel 303 branches from the water supply channel 301 and is connected to the other inlet of the mixing valve 305. The mixed hot water outlet 304 is connected to the outlet of the mixing valve 305 and the water tap 20. The mixing valve 305 mixes the hot water from the hot water outlet 302 and the water from the branch water supply path 303 and flows the mixed hot water into the hot water outlet 304.

  In the hot water supply section 300, temperature sensors (not shown) are provided in the water supply passage 301, the hot water supply passage 302, and the mixed hot water supply passage 304, and check valves (not shown) are provided in the water supply passage 301 and the branch water supply passage 303. A water amount sensor (not shown) is provided in the mixed hot water outlet 304.

  The auxiliary heating unit 400 includes an auxiliary heating circuit 410 and an auxiliary heat source unit 420. The auxiliary heating circuit 410 includes an inlet channel 411, an outlet channel 412, a circulation switching valve 413, a circulation pump 414, and a proportional valve 415.

  The water inlet 411 is connected to the position near the hot water storage tank 100 in the hot water outlet 302 and the secondary heat exchanger 422 of the auxiliary heat source unit 420. One end of hot water circulation paths 521 and 621 to be described later is connected to the water inlet path 411 via a circulation switching valve 413. The outlet channel 412 is connected to the primary heat exchanger 421 of the auxiliary heat source unit 420 on the downstream side of the connecting position of the inlet channel 411 in the outlet channel 302. The circulation switching valve 413 flows the water (hot water) that has flowed from the hot water storage tank 100 side through the water inlet 411 to the downstream water inlet 411 or the water (hot water) that has flowed through the hot water circulation paths 521 and 621. Switching to the downstream inlet 411 is performed. The circulation pump 414 is provided on the downstream side of the circulation switching valve 413 in the water inlet 411. The proportional valve 415 is provided in the outlet channel 412 and adjusts the amount of water (hot water) that flows to the auxiliary heating circuit 410.

  The auxiliary heat source unit 420 includes a primary heat exchanger 421, a secondary heat exchanger 422, a combustor 423, and a combustion fan 424. Air is sent from the combustion fan 424 to the combustor 423. The combustor 423 burns with gas and heats the primary heat exchanger 421 and the secondary heat exchanger 422. Thereby, the water passing through the primary heat exchanger 421 and the secondary heat exchanger 422 is heated.

  In the auxiliary heating unit 400, a check valve (not shown) and a water amount sensor (not shown) are provided in the water inlet 411, and a temperature sensor (not shown) is provided in the water outlet 412.

  The reheating unit 500 includes a bath water circulation circuit 510, a hot water circulation circuit 520, and a bath heat exchanger 530. The bath water circulation circuit 510 includes a bath water circulation path 511 and a bath pump 512. The bath water circulation path 511 is connected to the bathtub 30. The bath pump 512 is provided upstream of the bath heat exchanger 530 in the bath water circulation path 511. The hot water circulation circuit 520 includes a hot water circulation path 521 and a bath solenoid valve 522.

  One end of the hot water circulation path 521 is connected to the upstream side of the proportional valve 415 of the water discharge path 412, and the other end is connected to the water inlet path 411 through the circulation switching valve 413. The bath solenoid valve 522 is provided on the downstream side of the bath heat exchanger 530 in the hot water circulation path 521.

  The bath heat exchanger 530 is a liquid-liquid heat exchanger, has a double tube structure, the inner tube forms part of the hot water circulation path 521, and the outer tube is a part of the bath water circulation path 511. Parts. The bath heat exchanger 530 heats the bath water by exchanging heat between the bath water flowing through the bath water circulation path 511 and the hot water flowing through the hot water circulation path 521.

  The heating water heating unit 600 includes a heating water circulation circuit 610, a hot water circulation circuit 620, and a heating heat exchanger 630. The heating water circulation circuit 610 includes a heating water circulation path 611, a heating pump 612, and an expansion tank 613. The heating water circulation path 611 is connected to the radiator of the bathroom heater 40. The heating pump 612 is provided upstream of the heating heat exchanger 630 in the heating water circulation path 611. The expansion tank 613 is provided on the upstream side of the heating pump 612 in the heating water circulation path 611, and has a function of absorbing the increase when the volume of the heating water increases and the volume thereof increases. The hot water circulation circuit 620 includes a hot water circulation path 621 and a heating electromagnetic valve 622.

  One end of the hot water circulation path 621 is connected to the upstream side of the proportional valve 415 of the water discharge path 412, and the other end is connected to the water inlet path 411 through the circulation switching valve 413. The heating electromagnetic valve 622 is provided on the downstream side of the heating heat exchanger 630 in the hot water circulation path 621. The hot water circulation path 621 is a pipe part 521a except for the pipe heat exchanger 630 and the heating electromagnetic valve 622, and the pipe part 521a of the hot water circulation path 521 provided with the bath heat exchanger 530 and the bath electromagnetic valve 522. It is comprised so that it may share with the part except.

  Heating heat exchanger 630 is a liquid-liquid heat exchanger and has two pipes arranged in parallel in close proximity, one pipe forming part of hot water circulation path 621 and the other pipe circulating in the heating water. A part of the path 611 is formed. The heating heat exchanger 630 heats the heating water by exchanging heat between the heating water flowing through the heating water circulation path 611 and the hot water flowing through the hot water circulation path 621.

  The reheating section 500 and the heating water heating section 600 have temperature sensors (not shown) in the bath water circulation path 511, the common pipe line in the two hot water circulation paths 521 and 621, and the heating water circulation path 611. Provided.

  FIGS. 2A to 2C are diagrams for explaining a hot water storage operation, a hot water supply operation, and an auxiliary heat source hot water supply operation, respectively. FIGS. 3A and 3B are diagrams for explaining the reheating operation and the heating water heating operation, respectively.

  The hot water storage operation will be described with reference to FIG.

  When the amount of hot water stored in the hot water storage tank 100 becomes less than the preset lower limit hot water storage amount, the hot water storage operation is started. The hot water storage operation is performed regardless of whether another operation such as a hot water supply operation is performed, and the other operation is performed regardless of whether the hot water storage operation is performed.

  First, the hot water storage pump 215 and the heat pump 220 operate in a state where the hot water storage switching valve 214 is switched to the bypass path 213 side, and water circulates and circulates between the forward path 211, the heat pump 220, the return path 212, and the bypass path 213. Water is heated by the heat pump 220. At first, the heat capacity of the heat pump 220 is low, and the water is not easily heated. Thereafter, when the heating capacity of the heat pump 220 increases and the water in the hot water storage tank 100 can be raised to the target temperature, the hot water storage switching valve 214 is switched to the return path 212 side. As a result, water circulates between the hot water storage tank 100, the forward path 211, the heat pump 220, and the return path 212, and the water discharged from the lower side of the hot water storage tank 100 is heated by the heat pump 220 to become hot water of a target temperature. Is stored on the upper side of the hot water storage tank 100. Thus, when the hot water storage amount of the hot water storage tank 100 reaches a preset upper limit hot water storage amount (for example, a full hot water storage amount), the hot water storage pump 215 and the heat pump 220 are stopped, and the hot water storage operation ends.

  The hot water supply operation and the auxiliary heat source hot water supply operation will be described with reference to FIGS.

  When the water tap 20 is opened, if there is a sufficient amount of hot water in the hot water storage tank 100, the hot water supply operation is started. Water (cold water) from the water pipe is supplied to the lower part of the hot water storage tank 100 through the water supply channel 301, and hot water comes out from the upper part of the hot water storage tank 100. Hot water discharged from the hot water storage tank 100 flows through the hot water outlet 302 and reaches the mixing valve 305. On the other hand, the water separated from the water supply channel 301 flows through the branch water supply channel 303 and reaches the mixing valve 305. Hot water from the hot water outlet 302 and water from the branch water supply passage 303 are mixed by the mixing valve 305. At this time, the mixing valve 305 is controlled so that hot water having a predetermined hot water supply temperature is generated. Hot water coming out of the mixing valve 305 flows through the mixed hot water passage 304 and is discharged from the water tap 20. When the water tap 20 is closed, the hot water supply operation ends.

  On the other hand, when the water tap 20 is opened, if the amount of hot water stored in the hot water storage tank 100 is insufficient, the auxiliary heat source hot water supply operation is started. The circulation pump 414 and the auxiliary heat source unit 420 are operated in a state where the circulation switching valve 413 is switched to the water inlet 411 side, and a part of the water flowing out from the hot water storage tank 100 to the hot water outlet 302 is drawn into the water inlet 411 to assist. It is sent to the heat source unit 420 and heated by the auxiliary heat source unit 420 to become hot water. Hot water flows through the outlet channel 412 and merges with the water in the outlet channel 302. At this time, the proportional valve 415 is controlled so that the temperature of the hot water after joining becomes the target temperature, and the amount of hot water to join is adjusted. Similar to the hot water supply operation, hot water flowing through the hot water supply path 302 is mixed with water from the branch water supply path 303 by the mixing valve 305, and hot water having a predetermined hot water supply temperature flows through the mixed hot water supply path 304 and is discharged from the water tap 20. The When the water tap 20 is closed, the circulation pump 414 and the auxiliary heat source unit 420 are stopped, and the auxiliary heat source hot water supply operation is ended.

  With reference to Fig.3 (a), a chasing operation is demonstrated.

  The chasing operation is started on the basis of the operation for chasing operation or information that the temperature of the bath water in the bathtub 30 has decreased to a temperature that requires chasing. The bath pump 512 operates and the bath water circulates between the bathtub 30 and the bath water circulation path 511. In addition, the circulation pump 414 and the auxiliary heat source unit 420 operate in a state where the bath solenoid valve 522 is opened and the circulation switching valve 413 is switched to the hot water circulation path 521 side. At this time, the heating electromagnetic valve 622 is in a closed state. Hot water circulates while being heated by the auxiliary heat source unit 420 between the hot water circulation channel 521, the inlet channel 411, the auxiliary heat source unit 420, and the outlet channel 412. The bath water from the bathtub 30 is heated by hot water flowing through the hot water circulation path 521 in the bath heat exchanger 530 and then returned to the bath 30. Thereby, the hot water in the bathtub 30 becomes hot. When the temperature in the bath 30 reaches a preset bath temperature, the bath pump 512, the circulation pump 414, and the auxiliary heat source unit 420 are stopped, and the reheating operation is ended.

  With reference to FIG.3 (b), heating water heating operation is demonstrated.

  When the bathroom heater 40 starts the heating operation of the bathroom and the start information is sent from the bathroom heater 40, the heating water heating operation is started. Heating pump 612 operates and heating water circulates between the radiator of bathroom heater 40 and heating water circulation path 611. Further, the circulation pump 414 and the auxiliary heat source unit 420 operate in a state where the heating electromagnetic valve 622 is opened and the circulation switching valve 413 is switched to the hot water circulation path 621 side. At this time, the bath solenoid valve 522 is in a closed state. Hot water circulates between the hot water circulation path 621, the incoming water path 411, the auxiliary heat source machine 420, and the outlet water path 412 while being heated by the auxiliary heat source machine 420. Heating water discharged from the radiator of the bathroom heater 40 is heated by hot water flowing through the hot water circulation path 621 in the heating heat exchanger 630 and then returns to the radiator of the bathroom heater 40. Thereby, the radiator of the bathroom heater 40 becomes hot. In the bathroom heater 40, the air heated by the radiator, that is, warm air is discharged into the bathroom, and the bathroom is warmed. When the heating operation of the bathroom heater 40 is stopped and the stop information is sent, the heating pump 612, the circulation pump 414, and the auxiliary heat source unit 420 are stopped, and the heating water heating operation is finished.

  FIG. 4 is a block diagram showing a configuration of the hot water storage type hot water supply apparatus 10.

  In addition to the above configuration, the hot water storage type hot water supply apparatus 10 includes a remote controller 700 (hereinafter abbreviated as “remote control 700”), a microcomputer 800 (hereinafter abbreviated as “microcomputer 800”), a power supply unit 900, .

  The remote control 700 is disposed in a bathroom or kitchen and includes an operation unit and a display unit. In the operation unit, various operations such as an operation for setting a hot water supply temperature, an operation for setting a bath temperature, and an operation for starting a reheating operation can be performed. Various kinds of information such as the set hot water temperature and bath temperature are displayed on the display unit.

  The microcomputer 800 includes a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), and the like. Various signals are input to the microcomputer 800 from the remote controller 700. Further, the microcomputer 800 receives temperature information from each hot water storage temperature sensor 101. The microcomputer 800 grasps the amount of hot water stored in the hot water storage tank 100 based on the temperature detected by each hot water storage temperature sensor 101.

  The microcomputer 800 includes a hot water storage pump 215, a circulation pump 414, a combustion fan 424, a bath pump 512, a heating pump 612, a hot water storage switching valve 214, a mixing valve 305, a circulation switching valve 413, according to various operation programs stored in a ROM or the like. The proportional valve 415, the bath solenoid valve 522, the heating solenoid valve 622, the heat pump 220, and the like are controlled. Further, the microcomputer 800 transmits various types of information to the remote controller 700.

  The power supply unit 900 includes a power supply circuit 910, a power supply line 920, a three-terminal regulator 930, a first pump line switching circuit 940, a second pump line switching circuit 950, a first valve line switching circuit 960, 2 valve line switching circuit 970. Hereinafter, for convenience, the first pump line switching circuit 940, the second pump line switching circuit 950, the first valve line switching circuit 960, and the second valve line switching circuit 970 are respectively referred to as the first PLSW circuit 940, the second PLSW circuit 950, and the second PLSW circuit 950. These are referred to as a 1VLSW circuit 960 and a second VLSW circuit 970.

  The power supply circuit 910 generates a direct current voltage V1 (for example, 19V) for the hot water storage pump 215, the circulation pump 414, the combustion fan 424, the bath pump 512, and the heating pump 612, a hot water storage switching valve 214, and a mixing valve. 305, a circulation switching valve 413, a proportional valve 415, a bath electromagnetic valve 522, and a heating electromagnetic valve 622 are generated with a DC voltage V2 (for example, 15V).

  The power line 920 includes a first pump power line 921, a second pump power line 922, a first valve power line 923, and a second valve power line 924. The first pump power supply line 921 extends from the power supply circuit 910 and is connected to the hot water storage pump 215. The second pump power supply line 922 branches from a branch point P1 in the middle of the first pump power supply line 921, and the line is divided on the downstream side of the first PLSW circuit 940. The circulation pump 414, the combustion fan 424, the bath pump 512, and the heating Connected to pump 612. The first valve power supply line 923 extends from the power supply circuit 910 and is connected to the hot water storage switching valve 214. The second valve power supply line 924 branches from a branch point P2 in the middle of the first valve power supply line 923, and the line is divided on the downstream side of the second VLSW circuit 970. The mixing valve 305, the circulation switching valve 413, the proportional valve 415, It is connected to the bath solenoid valve 522 and the heating solenoid valve 622.

  The three-terminal regulator 930 is provided at a position upstream of the branch point P1 of the first pump power supply line 921, and steps down the DC voltage V1 to generate a DC voltage V3 (for example, 15V). The direct-current voltage V3 is a voltage for operating the hot water storage pump 215, the circulation pump 414, the combustion fan 424, the bath pump 512, and the heating pump 612. Note that, when the power supply unit 900 is configured to directly generate the DC voltage V3 by the power supply circuit 910, the three-terminal regulator 930 can be omitted.

  The first PLSW circuit 940 is provided in the second pump power supply line 922 and connects and disconnects the second pump power supply line 922. The second PLSW circuit 950 is provided at a position upstream of the branch point P1 of the first pump power supply line 921 and the three-terminal regulator 930, and connects and disconnects the first pump power supply line 921. The first VLSW circuit 960 is provided on the downstream side of the branch point P2 of the first valve power supply line 923, and connects and disconnects the line downstream of the branch point P2 in the first valve power supply line 923. The second VLSW circuit 970 is provided in the second valve power supply line 924 and connects and disconnects the second valve power supply line 924. The first PLSW circuit 940, the second PLSW circuit 950, the first VLSW circuit 960, and the second VLSW circuit 970 are controlled by the microcomputer 800.

  Hot water storage pump 215, circulation pump 414, bath pump 512 and heating pump 612 are DC pumps, and combustion fan 424 is a DC fan. The hot water storage pump 215, the circulation pump 414, the combustion fan 424, the bath pump 512, and the heating pump 612 are controlled by the microcomputer 800 while being supplied with power from the first pump power line 921 and the second pump power line 922. When receiving the signal, the motors rotate at the number of rotations corresponding to the control signal. The hot water storage pump 215, the circulation pump 414, the combustion fan 424, the bath pump 512, and the heating pump 612 are stopped in a state where power is supplied from the first pump power supply line 921 and the second pump power supply line 922. When it consumes standby power.

  The hot water storage pump 215, the circulation pump 414, the combustion fan 424, the bath pump 512, and the heating pump 612 have a built-in rotation sensor that detects the rotation speed of the motor, and a rotation speed signal corresponding to the detected rotation speed is a microcomputer. 800 is output. Even though the microcomputer 800 issues an operation command to the hot water storage pump 215, the circulation pump 414, the combustion fan 424, the bath pump 512, and the heating pump 612, the rotational speed output from these loads remains zero, or When the load is extremely low, it is detected that an abnormality has occurred in these loads.

  FIG. 5 is a flowchart showing the control operation of the power supply unit 900 by the microcomputer 800.

  In the hot water storage type hot water supply apparatus 10 of the present embodiment, when any operation is not performed, the microcomputer 800 turns off any of the switching circuits 940, 950, 960, 970, and any of the power supply lines 921, 922, 923. , 924 are also cut off. Accordingly, standby power is not generated in hot water storage pump 215, circulation pump 414, bath pump 512, and heating pump 612, and power consumption during standby is greatly reduced.

  When any operation is performed (S101: YES), the microcomputer 800 determines whether or not the operation is a hot water supply operation (S102). When the hot water supply operation is performed (S102: YES), the microcomputer 800 turns on the second VLSW circuit 970 and sets the second valve power supply line 924 in a connected state (S103). As a result, power is supplied to the mixing valve 305 through the first valve power supply line 923 and the second valve power supply line 924. In the hot water supply operation described with reference to FIG. 2B, the mixing valve 305 operates in response to a command from the microcomputer 800.

  When an operation other than the hot water supply operation is performed (S102: NO), the microcomputer 800 turns on the second PLSW circuit 950 and puts the first pump power supply line 921 into a connected state (S104). As a result, electric power is supplied to the hot water storage pump 215 through the first pump power supply line 921. Next, if the hot water storage operation is performed (S105: YES), the microcomputer 800 turns on the first VLSW circuit 960, and connects the line downstream of the branch point P2 of the first valve power supply line 923 to the connected state ( S106). As a result, power is supplied to the hot water storage switching valve 214 through the first valve power supply line 923. During the hot water storage operation described with reference to FIG. 2A, the hot water storage pump 215 and the hot water storage switching valve 214 are operated in accordance with a command from the microcomputer 800.

  Note that when another operation is already performed when the hot water storage operation is started, the second PLSW circuit 950 is already turned on. Therefore, in this case, the ON state of the second PLSW circuit 950 is maintained in S104.

  On the other hand, the microcomputer 800 turns on the first PLSW circuit 940 and turns on the second pump power line 922 if the auxiliary heat source hot water supply operation, the reheating operation or the heating water heating operation is performed instead of the hot water storage operation (S105: NO). The connection state is set (S107). As a result, power is supplied to the circulation pump 414, the combustion fan 424, the bath pump 512, and the heating pump 612 through the first pump power line 921 and the second pump power line 922. Further, the microcomputer 800 turns on the second VLSW circuit 970 and puts the second valve power supply line 924 into a connected state (S108). As a result, power is supplied to the circulation switching valve 413, the proportional valve 415, the bottom electromagnetic valve 522, and the heating electromagnetic valve 622 through the first valve power supply line 923 and the second valve power supply line 924.

  In the auxiliary heat source hot water supply operation described with reference to FIG. 2C, the circulation pump 414, the combustion fan 424, the circulation switching valve 413, and the proportional valve 415 are operated according to commands from the microcomputer 800. Further, during the reheating operation described with reference to FIG. 3A, the bath pump 512 and the bath solenoid valve 522 are operated by a command from the microcomputer 800. Further, in the heating water heating operation described with reference to FIG. 3B, the heating pump 612 and the heating electromagnetic valve 622 are operated by a command from the microcomputer 800.

  The microcomputer 800 turns off the first PLSW circuit 940 when power supply through the second pump power supply line 922 is no longer necessary, for example, when the auxiliary heat source operation ends. Further, the microcomputer 800 turns off the second PLSW circuit 950 when the hot water storage operation is finished, for example, when power supply through the first pump power supply line 921 is not necessary. Furthermore, the microcomputer 800 turns off the first VLSW circuit 960 when power supply through the first valve power supply line 923 is no longer necessary, for example, when the hot water storage operation ends. The microcomputer 800 turns off the second VLSW circuit 970 when the hot water supply operation and the auxiliary heat source hot water supply operation are finished, for example, when power supply through the second valve power supply line 924 is not necessary.

  Next, an abnormality process performed when an abnormality such as a failure occurs in any of the pumps 215, 414, 512, 612 or the combustion fan 424 will be described.

  In a state where both the first pump power supply line 921 and the second pump power supply line 922 are connected, the power supply lines 921 and 922 are short-circuited to any of the pumps 215, 414, 512, 612 or the combustion fan 424. When such a failure occurs, power supply to all the pumps 215, 414, 512, 612 and the combustion fan 424 is interrupted. Therefore, it is difficult to specify which pump 215, 414, 512, 612 or combustion fan 424 has an abnormality. Therefore, in the abnormality processing of the present embodiment, a diagnosis is made as to whether an abnormality has occurred in the hot water storage pump 215 or an abnormality has occurred in the other pumps 414, 512, 612 or the combustion fan 424, and according to the diagnosis result. Abnormality notification is performed.

  FIG. 6 is a flowchart showing the control operation of the abnormality process by the microcomputer 800.

  The microcomputer 800 determines whether or not an abnormality has been detected in the hot water storage pump 215, and the circulation pump 414, the bath pump 512, the heating pump 612, or the combustion fan 424 (hereinafter referred to as “other pumps 414, 512, 612, 424”). ) To determine whether or not an abnormality has been detected (S201, 202).

  When an abnormality is detected in the hot water storage pump 215 (S201: YES), the microcomputer 800 supplies power to the other pumps 414, 512, 612, and 424 whether or not the first PLSW circuit 940 is on. It is determined whether it is in a state to be performed (S203). When the first PLSW circuit 940 is in the on state (S203: YES), there is a possibility that the hot water storage pump 215 has stopped operating due to an abnormality in the other pumps 414, 512, 612, 424. Therefore, the microcomputer 800 operates the hot water storage pump 215 (S205) after the first PLSW circuit 940 is turned off (S204).

  When the hot water storage pump 215 does not operate normally, that is, when an abnormality is detected in the hot water storage pump 215 (S206: YES), the microcomputer 800 notifies when the hot water storage pump 215 is abnormal (S207). For example, the microcomputer 800 displays a message indicating that there is an abnormality in the hot water storage pump 215 on the display unit of the remote controller 700 or displays an error code corresponding to the abnormality of the hot water storage pump 215.

  On the other hand, when the hot water storage pump 215 operates normally, that is, when no abnormality is detected in the hot water storage pump 215 (S206: NO), the microcomputer 800 has an abnormality in the other pumps 414, 512, 612, and 424. Time notification is performed (S208). For example, the microcomputer 800 displays a message indicating that there is an abnormality in the other pumps 414, 512, 612, 424 on the display unit of the remote controller 700, or causes an abnormality in other pumps 414, 512, 612, 424. Display the corresponding error code.

  In S203, when the first PLSW circuit 940 is in the OFF state (S203: NO), the other pumps 414, 512, 612, 424 are not related to the abnormality of the hot water storage pump 215. Therefore, the microcomputer 800 determines that there is an abnormality in the hot water storage pump 215 without performing the processes of S204 to S206, and notifies when there is an abnormality in the hot water storage pump 215 (S207).

  In S202, when an abnormality is detected in other pumps 414, 512, 612, 424 (S202: YES), other pumps 414, 512, 612, 424 are It may not work. Therefore, in this case, the microcomputer 800 immediately performs the processing of S205 to S208 after the first PLSW circuit 940 is turned off (S204). However, in this case, since an abnormality is detected in other pumps 414, 512, 612, 424, in S208, an abnormality is reported as a notification when there is an abnormality in other pumps 414, 512, 612, 424. Notification is given when there is an abnormality in the detected pumps 414, 512, 612 or the combustion fan 424. For example, when an abnormality is detected in the circulation pump 414, the microcomputer 800 displays a message indicating that the circulation pump 414 is abnormal on the display unit of the remote controller 700, or displays an error code corresponding to the abnormality of the circulation pump 414. Display.

<Effect of Embodiment>
According to the present embodiment, the following effects can be achieved.

  When the hot water storage pump 215 is operated but the other pumps 414, 512, 612, 424 are not operated, the second pump power supply line 922 that supplies power to the other pumps 414, 512, 612, 424 is cut off. Therefore, it is possible to prevent standby power from being generated in the other pumps 414, 512, 612, and 424. Thereby, reduction of the power consumption of the hot water storage type hot water supply apparatus 10 can be aimed at.

  Further, when not only the other pumps 414, 512, 612, 424 but also the hot water storage pump 215 is operated, the first pump power supply line 921 that supplies electric power to the hot water storage pump 215 is shut off. It is possible to prevent standby power from being generated. Thereby, reduction of the power consumption of the hot water storage type hot water supply apparatus 10 can be further achieved.

  Furthermore, when an abnormality occurs in the hot water storage pump 215 or other pumps 414, 512, 612, 424, the hot water storage pump 215 is operated after the second pump power supply line 922 is shut off, and an abnormality is detected based on the operation result. Since the notification is performed, the user can know which side of the hot water storage pump 215 and the other pumps 414, 512, 612, and 424 is abnormal.

  Further, when the hot water storage switching valve 214 is operated but the other valves 305, 413, 415, 522, 622 are not operated, the second valve power supply line 924 that supplies power to the other valves 305, 413, 415, 522, 622. Therefore, standby power can be prevented from being generated in the other valves 305, 413, 415, 522, and 622. Thereby, the power consumption of the hot water storage type hot water supply apparatus 10 can be further reduced.

  Although the embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments, and various modifications other than those described above can be made to the embodiments of the present invention. .

<Example of change>
FIG. 7 is a block diagram illustrating a configuration of the hot water storage type hot water supply apparatus 10 according to a modified example.

  In the above embodiment, the circulation pump 414, the combustion fan 424, the bath pump 512, and the heating pump 612 are connected to the same power line, that is, the second pump power line 922. On the other hand, in the present modification, the power supply unit 900 is provided with a third pump power supply line 925 that branches from the branch point P1 of the first pump power supply line 921. The third pump power supply line 925 is provided with a third pump line switching circuit 980 (hereinafter referred to as “third PLSW circuit 980”) that connects and disconnects the third pump power supply line 925. The third pump power supply line 925 is divided on the downstream side of the third PLSW circuit 980 and is connected to the bath pump 512 and the heating pump 612. Third PLSW circuit 980 is controlled by microcomputer 800. The second pump power supply line 922 is connected to the circulation pump 414 and the combustion fan 424.

  Note that the third pump power supply line 925 may be branched from the upstream side of the first PLSW circuit 940 of the second pump power supply line 922.

  FIG. 8 is a flowchart illustrating a control operation of the power supply unit 900 by the microcomputer 800 according to the modification. In the flowchart of FIG. 8 according to this modification, the processes of S121 and S122 are added to the flowchart of FIG. 5 according to the above embodiment.

  In this modification, the microcomputer 800 turns on the first PLSW circuit 940 and connects the second pump power supply line 922 when the auxiliary heat source hot water supply operation is performed instead of the hot water storage operation (S105: NO, S121: YES). (S107), the second VLSW circuit 970 is turned on, and the second valve power supply line 924 is connected (S108). As a result, power is supplied to the circulation pump 414 and the combustion fan 424 through the first pump power supply line 921 and the second pump power supply line 922, and the circulation switching valve is supplied through the first valve power supply line 923 and the second valve power supply line 924. The power is supplied to 413 and the proportional valve 415.

  On the other hand, the microcomputer 800 turns on the third PLSW circuit 980 and connects the third pump power supply line 925 if the reheating operation or the heating water heating operation is performed instead of the hot water storage operation (S105: NO, S121: NO). At the same time (S122), the second VLSW circuit 970 is turned on, and the second valve power supply line 924 is connected (S108). As a result, power is supplied to the bath pump 512 and the heating pump 612 through the first pump power line 921 and the third pump power line 925, and the bath solenoid valve is passed through the first valve power line 923 and the second valve power line 924. Electric power is supplied to 522 and heating electromagnetic valve 622.

  FIG. 9 is a flowchart illustrating an abnormality processing control operation by the microcomputer 800 according to the modification. In the flowchart of FIG. 9 according to this modification, the processing of S203 and S204 is replaced with the processing of S221 and S222, and the processing of S208 is replaced with the processing of S223 to S227, compared to the flowchart of FIG. It is done.

  In this modified example, when an abnormality is detected in the hot water storage pump 215 (S201: YES), the microcomputer 800 is in a state where one or both of the first PLSW circuit 940 and the third PLSW circuit 980 are on (S221: YES). Then, the PLSW circuits 940 and 980 in the on state are turned off (S222). Further, when an abnormality is detected in other pumps 414, 512, 612, and 424 (S202), the microcomputer 800 turns off the PLSW circuits 940 and 980 that are on (S222). That is, when an abnormality is detected in the circulation pump 414 or the combustion fan 424, the first PLSW circuit 940 is turned off, and if the third PLSW circuit 980 is in an on state, the third PLSW circuit 980 is also turned off. If an abnormality is detected by the bath pump 512 or the heating pump 612, the third PLSW circuit 980 is turned off, and if the first PLSW circuit 940 is in an on state, the first PLSW circuit 940 is also turned off. Then, when the processes of S205 and S206 are performed and no abnormality is detected in the hot water storage pump 215 in S206 (S206: NO), the microcomputer 800 determines which of the first PLSW circuit 940 and the third PLSW circuit 980 is on. Is determined (S223).

  When both the first PLSW circuit 940 and the third PLSW circuit 980 are in the on state (S223: both), the microcomputer 800 operates the circulation pump 414 (S224). When the abnormality is detected in the circulation pump 414 (S225: YES), the microcomputer 800 notifies when the abnormality exists in the circulation pump 414 or the combustion fan 424 (S226). For example, the microcomputer 800 displays a message indicating that there is an abnormality in the circulation pump 414 or the combustion fan 424 on the display unit of the remote controller 700, or displays an error code corresponding to the abnormality in the circulation pump 414 or the combustion fan 424. To do.

  On the other hand, if only the first PLSW circuit 940 is in the ON state as a result of the determination in S223 (S223: first), the microcomputer 800 notifies when the circulation pump 414 or the combustion fan 424 is abnormal (S226). ).

  On the other hand, as a result of the determination in S223, when only the third PLSW circuit 980 is in the ON state (S223: third), and as a result of the determination in S225, no abnormality is detected in the circulation pump 414 (S225). : NO), the microcomputer 800 notifies when there is an abnormality in the bath pump 512 or the heating pump 612 (S227). For example, the microcomputer 800 displays a message indicating that there is an abnormality in the bath pump 512 or the heating pump 612 on the display unit of the remote controller 700, or displays an error code corresponding to the abnormality in the bath pump 512 or the heating pump 612. To do.

  According to the configuration of the present modified example, one set of the set of the circulation pump 414 and the combustion fan 424 and the set of the bath pump 512 and the heating pump 612 operates, but the other set does not operate. Since no power is supplied to one set, no standby power is generated in the other set, and the power consumption of the hot water storage type hot water supply apparatus 10 is further reduced.

  Further, according to the configuration of this modified example, when an abnormality occurs in the hot water storage pump 215 or other pumps 414, 512, 612, 424, the user can use the hot water storage pump 215, the circulation pump 414, and the combustion fan 424. And which side of the pair of bath pumps 512 and heating pumps 612 is abnormal.

<Other changes>
In the above embodiment, the second PLSW circuit 950 is provided on the upstream side of the branch point P1 in the first pump power supply line 921, but may be provided on the downstream side of the branch point P1. In this case, the process of S104 in FIG. 5 is moved between the process of S105 and the process of S106, and when the operation to be performed is a hot water storage operation (S105: YES), the microcomputer 800 turns on the second PLSW circuit 950. .

  In the above embodiment, the bath water is heated by hot water that is heated by the auxiliary heat source unit 420 and passes through the bath heat exchanger 530. Further, the heating water is heated by hot water that is heated by the auxiliary heat source unit 420 and passes through the heating heat exchanger 630. However, the reheating unit 500 may be configured such that the bath water is directly heated by the auxiliary heat source unit 420. Similarly, the heating water heating unit 600 may be configured such that the heating water is directly heated by the auxiliary heat source unit 420. When it is set as these structures, the auxiliary heat source machine 420 will respond | correspond to the "heating part" of a claim.

  Further, in the above embodiment and the above modification, as shown in FIGS. 4 and 7, the bath solenoid valve 522 and the heating solenoid valve 622 are connected to the downstream side of the second VLSW circuit 970 in the second valve power supply line 924. It was. However, since these solenoid valves 522 and 622 consume little power during standby, they may be connected to the upstream side of the second VLSW circuit 970 in the second valve power supply line 924.

  Furthermore, in the above embodiment, the heat pump 220 is used as a heat source for heating the hot water in the hot water storage tank 100. However, other heat sources can be used. For example, a power generation device composed of a fuel cell or the like can be used as a heat source. In this case, the power generation device includes a heat exchanger that recovers exhaust heat generated during power generation, and water (hot water) circulates between the heat exchanger and the hot water storage tank 100.

  Furthermore, the present invention can be applied to a hot water storage type hot water supply apparatus that does not include at least one of the reheating unit 500 and the heating water heating unit 600. The present invention can also be applied to a hot water storage type hot water supply apparatus that does not have the circulation pump 414 in the auxiliary heating circuit 410 of the auxiliary heating unit 400.

  In addition, the embodiment of the present invention can be appropriately changed within the scope of the claims.

10 Hot water storage type hot water supply device 100 Hot water storage tank 215 Hot water storage pump (first pump)
220 Heat pump (first heat source, heat source)
414 Circulation pump (second pump)
420 Auxiliary heat source machine (second heat source)
423 Combustor 424 Combustion fan 512 Bath pump (3rd pump, 2nd pump)
530 bath heat exchanger (heating unit)
612 Heating pump (3rd pump, 2nd pump)
630 Heating heat exchanger (heating unit)
800 Microcomputer (control unit)
910 Power supply circuit (Power supply unit)
921 First pump power line (first power line)
922 Second pump power line (second power line)
925 Third pump power line (third power line)
940 First pump line switching circuit (first switch part)
950 Second pump line switching circuit (second switch part)
980 Third pump line switching circuit (third switch part)

Claims (7)

A hot water storage tank,
A first heat source;
A second heat source;
A first pump for circulating water between the hot water storage tank and the first heat source;
A second pump for sending water in the hot water storage tank to the second heat source;
A power supply,
A first power supply line connected to the first pump and supplying power from the power supply unit to the first pump;
A second power supply line connected to the second pump and supplying power from the power supply unit to the second pump;
A first switch unit provided on the second power supply line for connecting and disconnecting the second power supply line;
A control unit,
The control unit shuts off the second power line by the first switch unit based on not operating the second pump.
A hot water storage type hot water supply device characterized by that. In the hot water storage type hot water supply apparatus according to claim 1,
A second switch portion provided on the first power supply line for connecting and disconnecting the first power supply line;
The control unit shuts off the first power supply line by the second switch unit based on not operating the first pump.
A hot water storage type hot water supply device characterized by that. In the hot water storage type hot water supply device according to claim 1 or 2,
A third pump for circulating water between the hot water storage hot water supply device and an external device;
A heating unit for heating the water circulated by the third pump,
The second power supply line is also connected to the third pump on the downstream side of the first switch unit,
The control unit shuts off the second power supply line by the first switch unit based on not operating the second pump and the third pump.
A hot water storage type hot water supply device characterized by that. In the hot water storage type hot water supply device according to claim 1 or 2,
A third pump for circulating water between the hot water storage hot water supply device and an external device;
A heating unit for heating water circulated by the third pump;
A third power supply line connected to the third pump and supplying power from the power supply unit to the third pump;
A third switch portion provided on the third power supply line for connecting and disconnecting the third power supply line;
The control unit shuts off the third power supply line by the third switch unit based on not operating the third pump.
A hot water storage type hot water supply device characterized by that. In the hot water storage type hot water supply device according to any one of claims 1 to 4,
The second heat source includes a combustor and a combustion fan that sends air to the combustor,
The second power supply line is also connected to the combustion fan on the downstream side of the first switch part,
The control unit shuts off the second power supply line by the first switch unit based on not operating the second pump and the combustion fan.
A hot water storage type hot water supply device characterized by that. In the hot water storage type hot water supply apparatus according to any one of claims 1 to 5,
When the control unit detects that an abnormality has occurred in either the first pump or the second pump, the control unit shuts off the second power supply line by the first switch unit, and operates the first pump. Anomaly notification is performed based on the operation result,
A hot water storage type hot water supply device characterized by that. In hot water storage type hot water supply equipment,
A hot water storage tank,
A heat source,
A first pump for circulating water between the hot water storage tank and the heat source;
A second pump for circulating water between the hot water storage hot water supply device and an external device;
A heating unit for heating the water circulated by the second pump;
A power supply,
A first power supply line connected to the first pump and supplying power from the power supply unit to the first pump;
A second power supply line connected to the second pump and supplying power from the power supply unit to the second pump;
A first switch unit provided on the second power supply line for connecting and disconnecting the second power supply line;
A control unit,
The control unit shuts off the second power line by the first switch unit based on not operating the second pump.
A hot water storage type hot water supply device characterized by that.

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