JP5888116B2 - Hot water storage water heater - Google Patents

Description

  The present invention relates to a hot water storage type water heater.

  Equipped with a hot water storage tank that stores hot water boiled by heating means such as a heat pump unit, and a use-side heat exchanger for heating the object to be heated (for example, bath water in a bathtub), using hot water taken out from the hot water storage tank A hot water storage type hot water heater capable of heating the heating object by performing a heating operation of returning to the hot water storage tank via a side heat exchanger is widely used.

  In Patent Document 1, a plurality of recovery ports are provided at different positions in the height direction to return the hot water returning to the hot water tank after the heat exchange in the use side heat exchanger and returning to the hot water tank. A tank temperature sensor that detects the temperature of the hot water in the hot water storage tank is provided near the mouth, and a return temperature sensor that detects the temperature of the return hot water is provided in the return hot water piping, so that the return from the use side heat exchanger When returning the hot water to the hot water storage tank, the control means stores the hot water through a plurality of recovery ports according to the temperature of the return hot water detected by the return temperature sensor and the tank temperature sensor and the temperature distribution of the hot water in the hot water storage tank. There has been disclosed a hot water storage type hot water heater having a control configuration for controlling a flow rate adjusting valve so as to be collected in a tank.

  Patent Document 2 discloses a bath return pipe that returns hot water from the use-side heat exchanger (bath heat exchanger) to the middle of the hot water storage tank, a first hot water piping that discharges hot water from the upper part of the hot water storage tank, and the middle of the hot water storage tank. 2nd hot water discharge pipe from the hot water, a central connection port installed in the middle of the hot water storage tank, a low temperature return pipe that branches the bath return pipe to the lower part of the hot water storage tank, and the outlet temperature of the use side heat exchanger is the central connection port And a controller that guides the return hot water to a low temperature return pipe when the temperature is below a predetermined value below the temperature of the nearby hot water, and a bath return pipe and a second hot water supply pipe are connected to the middle connection port. There has been disclosed a hot water storage type hot water supply apparatus that mixes hot water from a pipe, hot water from a second outlet pipe, and water supply to supply hot water to the outside.

JP 2003-279151 A JP 2011-257105 A

  In the hot water storage type water heater of Patent Document 1 described above, the return hot water is distributed to the upper part of the hot water storage tank by distributing the return hot water at a predetermined distribution ratio to the temperature stratification on both sides of the hot water that is closest to the temperature of the return hot water in the hot water storage tank. It avoids mixing with certain high-temperature water and low-temperature water at the bottom of the hot water storage tank as much as possible to prevent a decrease in high-temperature hot-water supply capacity and to maintain a high operating efficiency of the heat pump unit during boiling operation. However, in the hot water storage type water heater of Patent Document 1, it is necessary to provide the hot water storage tank with a number of recovery ports having different positions in the height direction, which complicates the structure and piping configuration of the hot water storage tank. Furthermore, it is necessary to provide a temperature sensor for detecting the temperature of the return hot water. For this reason, when realizing the hot water storage type water heater of Patent Document 1, there is a problem that the manufacturing cost is high.

  Moreover, in the hot water storage type water heater of Patent Document 2 described above, the return hot water is returned to the middle of the hot water storage tank, and the return hot water accumulated in the middle of the hot water storage tank is taken out by the second hot water supply pipe and used for hot water supply. However, since the number of pipes and mixing valves increases, there is a problem that the manufacturing cost is high. Further, there is a possibility that the return hot water accumulated in the middle of the hot water storage tank may remain unused, and there is a problem that the operation efficiency of the heat pump unit during the boiling operation cannot be necessarily increased.

  The present invention has been made to solve the above-described problems, and the number of recovery ports for recovering the hot water returning from the use-side heat exchanger for heating the heating object to the hot water storage tank into the hot water storage tank is reduced. Hot water storage type hot water supply that can reduce the occurrence of hot water without fail and eliminate the need for a temperature sensor for detecting the temperature of the return hot water, and can maintain the efficiency of the heating operation by the heating means high. The purpose is to provide a machine.

The hot water storage type hot water supply apparatus according to the present invention includes a hot water storage tank capable of storing hot water, a heating means capable of heating water, water taken from the hot water storage tank being sent to the heating means, and hot water generated by being heated by the heating means. A boiling circuit for returning to the hot water storage tank, an upper return circuit for returning the hot water taken out from the upper area of the hot water storage tank to the upper area of the hot water storage tank via a use-side heat exchanger for heating the heating target, and hot water storage A lower return circuit for returning hot water taken out from the upper area of the tank to the lower area of the hot water storage tank via the use side heat exchanger, a flow path switching means for switching between the upper return circuit and the lower return circuit, and the hot water storage tank When starting the upper return heating operation to distribute the hot water extracted from the upper region of the hot water to the upper return circuit, the hot water extracted from the upper region of the hot water storage tank is returned to the lower portion prior to the start of the upper return heating operation. Replacing the hot water at least a portion of the lower back circuit by executing a lower return heating operation circulating in the circuit a predetermined time, then, and a control unit for starting the upper return heating operation is switched to the upper return circuit, the The control unit omits the execution of the lower return heating operation for a predetermined time when the elapsed time since the previous upper return heating operation or the lower return heating operation is executed is shorter than a predetermined threshold. Is something that starts .
Further, the hot water storage type hot water heater according to the present invention is generated by heating a hot water storage tank capable of storing hot water, heating means capable of heating water, and water taken from the hot water storage tank to the heating means and being heated by the heating means. A boiling circuit for returning hot water to the hot water storage tank, and an upper return circuit for returning hot water taken out from the upper area of the hot water storage tank to the upper area of the hot water storage tank via a use side heat exchanger for heating the heating target The lower return circuit for returning the hot water taken out from the upper area of the hot water storage tank to the lower area of the hot water storage tank via the use side heat exchanger, and the flow path switching means for switching between the upper return circuit and the lower return circuit, When starting the upper return heating operation in which the hot water taken out from the upper area of the hot water storage tank is circulated to the upper return circuit, the hot water taken out from the upper area of the hot water storage tank is started prior to the start of the upper return heating operation. A control unit that replaces at least a part of hot water in the lower return circuit by performing a lower return heating operation to be circulated to the partial return circuit for a predetermined time, and then switches to the upper return circuit to start the upper return heating operation; Temperature detecting means capable of detecting the atmospheric temperature of the pipe constituting the upper return circuit, the temperature of the water supplied to the hot water storage tank, or the outside air temperature, and the controller detects the temperature detected by the temperature detecting means at a predetermined level If it is higher than the threshold, the execution of the lower return heating operation for a predetermined time is omitted and the upper return heating operation is started.
Further, the hot water storage type hot water heater according to the present invention is generated by heating a hot water storage tank capable of storing hot water, heating means capable of heating water, and water taken from the hot water storage tank to the heating means and being heated by the heating means. A boiling circuit for returning hot water to the hot water storage tank, and an upper return circuit for returning hot water taken out from the upper area of the hot water storage tank to the upper area of the hot water storage tank via a use side heat exchanger for heating the heating target The lower return circuit for returning the hot water taken out from the upper area of the hot water storage tank to the lower area of the hot water storage tank via the use side heat exchanger, and the flow path switching means for switching between the upper return circuit and the lower return circuit, When starting the upper return heating operation in which the hot water taken out from the upper area of the hot water storage tank is circulated to the upper return circuit, the hot water taken out from the upper area of the hot water storage tank is started prior to the start of the upper return heating operation. A control unit that replaces at least a part of hot water in the lower return circuit by performing a lower return heating operation to be circulated to the partial return circuit for a predetermined time, and then switches to the upper return circuit to start the upper return heating operation; The hot water take-out position from the hot water storage tank in the lower return circuit is higher than the hot water take-out position from the hot water storage tank in the upper return circuit.
Further, the hot water storage type hot water heater according to the present invention is generated by heating a hot water storage tank capable of storing hot water, heating means capable of heating water, and water taken from the hot water storage tank to the heating means and being heated by the heating means. A boiling circuit for returning hot water to the hot water storage tank, and an upper return circuit for returning hot water taken out from the upper area of the hot water storage tank to the upper area of the hot water storage tank via a use side heat exchanger for heating the heating target The lower return circuit for returning the hot water taken out from the upper area of the hot water storage tank to the lower area of the hot water storage tank via the use side heat exchanger, and the flow path switching means for switching between the upper return circuit and the lower return circuit, When starting the upper return heating operation in which the hot water taken out from the upper area of the hot water storage tank is circulated to the upper return circuit, the hot water taken out from the upper area of the hot water storage tank is started prior to the start of the upper return heating operation. A control unit that replaces at least a part of hot water in the lower return circuit by performing a lower return heating operation to be circulated to the partial return circuit for a predetermined time, and then switches to the upper return circuit to start the upper return heating operation; The hot water return position to the hot water storage tank in the upper return circuit is higher than the hot water take-out position from the hot water storage tank in the upper return circuit.

  According to the present invention, in order to reduce the number of recovery ports for collecting the return hot water returned to the hot water storage tank from the use side heat exchanger for heating the heating target into the hot water storage tank, and to detect the temperature of the return hot water. Therefore, it is possible to reliably suppress the occurrence of hot water and to keep the efficiency of the heating operation by the heating means high.

It is a block diagram which shows the hot water storage type water heater of Embodiment 1 of this invention. It is a circuit block diagram at the time of the boiling operation in the hot water storage type water heater of Embodiment 1 of this invention. It is a circuit block diagram at the time of the upper return bathtub heating operation in the hot water storage type water heater of Embodiment 1 of the present invention. It is a circuit block diagram at the time of the lower return bathtub heating operation in the hot water storage type water heater of Embodiment 1 of the present invention. It is a flowchart which shows the control operation | movement of the automatic thermal insulation means in the hot water storage type water heater of Embodiment 1 of this invention.

  Embodiments of the present invention will be described below with reference to the drawings. In addition, the same code | symbol is attached | subjected to the element which is common in each figure, and the overlapping description is abbreviate | omitted.

Embodiment 1 FIG.
FIG. 1 is a configuration diagram illustrating a hot water storage type water heater according to Embodiment 1 of the present invention. As shown in FIG. 1, the hot water storage type water heater 100 of this embodiment includes a hot water storage tank unit 1 and a heat pump unit 60. The hot water storage tank unit 1 and the heat pump unit 60 are connected via a heat pump inlet pipe 41, a heat pump outlet pipe 42, and electrical wiring (not shown). The hot water tank unit 1 includes a control unit 70. Operations of various valves, pumps and the like provided in the hot water storage tank unit 1 and the heat pump unit 60 are controlled by a control unit 70 electrically connected thereto. Hereinafter, each component of the hot water storage type water heater 100 will be described.

  The heat pump unit 60 functions as a heating means for heating (boiling) the low temperature water led from the hot water storage tank unit 1 by a heat pump cycle. The heat pump unit 60 is equipped with a refrigeration cycle (heat pump cycle) in which a compressor 61, a heating heat exchanger 62, an expansion valve 63, and an air heat exchanger 64 are connected in an annular shape by a refrigerant circulation pipe 65. The heating heat exchanger 62 is for exchanging heat between the refrigerant flowing through the refrigerant circulation pipe 65 constituting the heat pump cycle and the low-temperature water led from the hot water storage tank unit 1. The heat pump outlet temperature sensor 66 is a temperature sensor that detects the temperature of the high-temperature water generated by being heated by the boiling heat exchanger 62, and is provided in the heat pump outlet pipe 42. In order to obtain high-temperature water with the heat pump unit 60, it is preferable that the heat pump cycle is operated at a pressure exceeding the critical pressure using carbon dioxide as a refrigerant.

  The hot water storage tank unit 1 includes the following various parts and piping. The hot water storage tank 10 is for storing hot water, and normally has a substantially cylindrical shape. A water supply pipe 2 that supplies water from a water source such as a water supply is connected to an introduction port 4 provided at a lower portion of the hot water storage tank 10. A second tank upper pipe 44 is connected to the upper port 5 provided in the upper part (the uppermost part in the illustrated configuration) of the hot water storage tank 10. The hot water supply pipe 3 for supplying the hot water stored in the hot water storage tank 10 to the outside of the water heater is branched from the second tank upper pipe 44.

  The hot water heated using the heat pump unit 60 flows into the hot water storage tank 10 from the upper port 5, and the low temperature water from the water supply pipe 2 flows into the hot water storage tank 10 from the introduction port 4. The hot water is stored so that the upper part is hot and the lower part is cold. In order to detect the temperature distribution of hot water in the hot water storage tank 10, a plurality of hot water temperature sensors 11, 12 are attached to the surface of the hot water storage tank 10 at different height positions. In the illustrated configuration, two hot water storage temperature sensors 11 and 12 are provided, but three or more hot water storage temperature sensors may be provided. These hot water storage temperature sensors 11 and 12 detect the temperature of hot water at a predetermined height in the hot water storage tank 10, respectively. The control unit 70 can calculate the amount of stored hot water (heat storage amount) in the hot water storage tank 10 based on the temperature distribution in the height direction in the hot water storage tank 10 acquired by the hot water storage temperature sensors 11 and 12. Based on the amount of stored hot water, the start and stop of the hot water boiling operation in the hot water storage tank 10 by the heat pump unit 60 is controlled. In the present embodiment, the hot water storage temperature sensor 11 is installed at a position above the center position in the height direction of the hot water storage tank 10, and detects the temperature of the hot water in the hot water storage tank 10.

  The hot water storage tank unit 1 includes a circulation pump 21 and a use side heat exchanger 22. The circulation pump 21 is a pump for circulating hot water through various pipes in the hot water storage tank unit 1. The use side heat exchanger 22 is a heat exchanger for heating a predetermined heating target using high-temperature water supplied from the hot water storage tank 10 or the heat pump unit 60. The bathtub water circulation circuit 51 is arranged so that hot water (tub water) derived from the bathtub 50 is returned to the bathtub 50 via the use-side heat exchanger 22. In the middle of the bathtub water circulation circuit 51, there are a secondary circulation pump 52 for circulating the bathtub water and a bathtub outlet side temperature sensor 53 (tub water temperature detection means) that detects the temperature of the bathtub water that has come out of the bathtub 50. is set up. As described above, in the present embodiment, as the secondary side configuration of the use side heat exchanger 22, the bathtub water circulation circuit 51 that circulates the bathtub water in the bathtub 50 is provided, and the bathtub water is supplied from the use side heat exchanger 22. Although what is heated is demonstrated to an example, the utilization side heat exchanger in this invention may heat heating objects (for example, circulating water for heating etc.) other than bathtub water.

  Next, the valves and piping included in the hot water storage tank unit 1 will be described. The hot water storage tank unit 1 has a first three-way valve 31, a second three-way valve 32, and a four-way valve 33. The first three-way valve 31 and the second three-way valve 32 are flow path switching means having two inlets (a port and b port) through which hot water flows and one outlet (c port) through which hot water flows out. Yes, the hot water path can be switched so that hot water flows from either the a port or the b port. The four-way valve 33 is a flow path switching means having two inlets (b port and c port) through which hot water flows and two outlets (a port and d port) through which hot water flows out. , A-b path, b-d path, and cd path are configured to be able to switch the flow path form.

  The hot water storage tank unit 1 includes a tank lower pipe 40, a first tank upper pipe 43, a second tank upper pipe 44, a lower return pipe 45, a use side heat exchanger primary side inlet pipe 46, and a use side heat exchanger. A primary outlet pipe 47, a bypass pipe 48, and an upper return pipe 49 are provided.

  The tank lower pipe 40 is a flow path that connects the outlet 6 provided in the lower part (the lowermost part in the illustrated configuration) of the hot water storage tank 10 and the a port of the second three-way valve 32. The heat pump inlet pipe 41 is a flow path that connects the c port of the second three-way valve 32 and the inlet side of the heat pump unit 60. The circulation pump 21 is installed in the middle of the heat pump inlet pipe 41. The heat pump outlet pipe 42 is a flow path that connects the outlet side of the heat pump unit 60 and the c port of the four-way valve 33.

  The first tank upper pipe 43 is a flow path that connects the outlet 7 provided in the upper region of the hot water storage tank 10 and the a port of the first three-way valve 31. Here, the “upper region of the hot water storage tank 10” refers to a region above the center position of the hot water storage tank 10 in the height direction. That is, the position of the outlet 7 may be between the center position in the height direction of the hot water storage tank 10 and the uppermost part. The second tank upper pipe 44 is a flow path that connects the upper port 5 of the hot water storage tank 10 and the b port of the first three-way valve 31. The “upper region of the hot water storage tank 10” is more preferably a region having a volume occupying 1/3 of the total volume from the uppermost part of the hot water storage tank 10; More preferably.

  The lower return pipe 45 is a flow path that connects the a port of the four-way valve 33 and the return port 8 provided in the lower region of the hot water storage tank 10. Here, the “lower region of the hot water storage tank 10” refers to a region below the center position in the height direction of the hot water storage tank 10. That is, the position of the return port 8 may be between the center position in the height direction of the hot water storage tank 10 and the lowest part. The use side heat exchanger primary side inlet pipe 46 is a flow path that connects the c port of the first three-way valve 31 and the primary side inlet of the use side heat exchanger 22. The use side heat exchanger primary side outlet pipe 47 is a flow path that connects the primary side outlet of the use side heat exchanger 22 and the b port of the second three-way valve 32. The bypass pipe 48 is a flow path that branches from the heat pump inlet pipe 41 on the downstream side of the circulation pump 21 and is connected to the b port of the four-way valve 33. The upper return pipe 49 is a flow path that branches from the middle of the second tank upper pipe 44 and is connected to the d port of the four-way valve 33. The “lower region of the hot water storage tank 10” is more preferably a region having a volume occupying 1/3 of the total volume from the lowermost part of the hot water storage tank 10; More preferably.

  A hot water supply temperature sensor 54 that detects the temperature of the hot water flowing through the hot water supply pipe 3 and a hot water supply flow rate sensor 55 that detects the flow rate of the hot water flowing through the hot water supply pipe 3 are installed in the hot water supply pipe 3 in the hot water storage tank unit 1. ing. In the hot water storage tank unit 1, high temperature water led out from the hot water storage tank 10 to the hot water supply pipe 3 and low temperature water supplied from a water supply branch pipe (not shown) branched from the water supply pipe 2 are mixed. A mixing valve (not shown) for adjusting the hot water supply temperature may be further provided. In that case, a hot water mixing valve for supplying hot water to the bathtub 50 and a general hot water mixing valve for supplying hot water to a shower, a faucet or the like may be provided.

  The control unit 70 is connected to a remote control device (not shown) installed in, for example, a bathroom or kitchen so as to be able to communicate with each other. Information such as the temperature and amount of hot water stored in the hot water storage tank 10, the hot water supply temperature, the time, and the heating mode can be displayed on the display unit provided in the remote control device. The user operates the operation unit provided on the remote control device to thereby control the hot water supply temperature, the temperature and amount of hot water (tub water) applied to the bathtub 50 (hereinafter referred to as “hot water filling amount”), the boiling mode, etc. Can be set.

  In the hot water storage type hot water heater 100 of the present embodiment, the first three-way valve 31 is controlled according to the operation state shown in FIGS. Are used by selectively switching. The “first flow path configuration” that can be selected by the first three-way valve 31 is that the outlet 7 of the hot water storage tank 10 and the use side heat exchanger 22 are connected to the first tank upper pipe 43 and the use side heat exchanger primary. It is a flow path form communicating through the side inlet pipe 46, and the “second flow path form” means that the upper port 5 of the hot water storage tank 10 and the use side heat exchanger 22 are connected to the second tank upper pipe 44 and the use. This is a flow path form communicating through the side heat exchanger primary side inlet pipe 46.

  Moreover, in the hot water storage type water heater 100 of the present embodiment, the following first flow path form and second flow path are controlled by controlling the second three-way valve 32 in accordance with the operation states shown in FIGS. Select and switch between forms. The “first flow path configuration” that can be selected by the second three-way valve 32 is that the outlet 6 of the hot water storage tank 10 and the heating heat exchanger 62 communicate with each other via the tank lower pipe 40 and the heat pump inlet pipe 41. The “second flow path configuration” means that the use side heat exchanger 22 and the four-way valve 33 are connected via the use side heat exchanger primary side outlet pipe 47, the heat pump inlet pipe 41, and the bypass pipe 48. This is a flow channel form communicating with each other.

  Furthermore, in the hot water storage type water heater 100 according to the present embodiment, the four-way valve 33 is controlled according to the operation states shown in FIGS. The three-channel configuration is selectively switched for use. The “first flow path configuration” that can be selected by the four-way valve 33 is that the heating heat exchanger 62 and the upper port 5 of the hot water storage tank 10 are connected to the heat pump outlet pipe 42, the upper return pipe 49, and the second tank upper pipe. 44 is a flow path form that communicates with each other via a second flow path form. The second three-way valve 32 and the upper port 5 of the hot water storage tank 10 are connected to a heat pump inlet pipe 41, a bypass pipe 48, and an upper return pipe. 49 and the second tank upper pipe 44, and the “third flow path configuration” means that the second three-way valve 32 and the return port 8 of the hot water storage tank 10 are connected to the heat pump inlet pipe 41. The flow path form communicates via the bypass pipe 48 and the lower return pipe 45.

  FIG. 2 is a circuit configuration diagram of the hot water storage type water heater 100 according to Embodiment 1 of the present invention during a boiling operation. The boiling operation is an operation for boiling water in the hot water storage tank 10 using the heat pump unit 60. At the time of this boiling operation, as shown in FIG. 2, the second three-way valve 32 is connected so that the a port and the c port communicate with each other and the b port is closed (that is, the second three-way valve 32 Controlled so that the first channel configuration is selected. As a result, the tank lower pipe 40 and the heat pump inlet pipe 41 communicate with each other, and the flow path from the usage side heat exchanger 22 is blocked by closing the usage side heat exchanger primary side inlet pipe 46 side. Further, during the heating operation, the four-way valve 33 is selected so that the c port and the d port communicate with each other and the a port and the b port are closed (that is, the first flow path configuration of the four-way valve 33 is selected. Controlled). As a result, the heat pump outlet pipe 42 and the upper return pipe 49 communicate with each other, and the flow path to the return port 8 of the hot water storage tank 10 is blocked by closing the lower return pipe 45 side.

  The boiling operation is executed by operating the circulation pump 21 and the heat pump unit 60 in a state where the boiling circuit is formed by controlling the second three-way valve 32 and the four-way valve 33 as described above. . As a result, the low-temperature water flowing out from the outlet 6 of the hot water storage tank 10 is led to the heat pump unit 60 via the tank lower pipe 40, the second three-way valve 32, the circulation pump 21 and the heat pump inlet pipe 41, and boiled up. After being heated in the heat exchanger 62, it becomes high-temperature water from the upper port 5 of the hot water storage tank 10 via the heat pump outlet pipe 42, the four-way valve 33, the upper return pipe 49, and the second tank upper pipe 44. It flows into the hot water storage tank 10 and is stored. By performing such boiling operation, high temperature water is stored in the hot water storage tank 10 from the upper layer portion, and this high temperature water layer is gradually thickened by the hot water storage temperature sensors 11 and 12. When the amount of stored hot water in the hot water storage tank 10 exceeds a predetermined amount, the boiling operation is stopped.

  FIG. 3 is a circuit configuration diagram at the time of an upper return bathtub heating operation in hot water storage type hot water supply apparatus 100 according to Embodiment 1 of the present invention. The upper return tub heating operation means that the hot water (high temperature water) taken out from the outlet 7 of the hot water storage tank 10 and the tub water circulating from the tub 50 are heat-exchanged in the use side heat exchanger 22 so that the tub water is exchanged. In this operation, hot water (medium temperature water) whose temperature has been lowered by heat exchange is returned to the upper port 5 of the hot water storage tank 10. At the time of this upper return bath heating operation, as shown in FIG. 3, the first three-way valve 31 communicates with the a port and the c port and the b port is closed (that is, the first three-way valve 31). 31 so that the first channel configuration is selected). As a result, the first tank upper pipe 43 and the use side heat exchanger primary side inlet pipe 46 communicate with each other, and the second tank upper pipe 44 side of the first three-way valve 31 is closed. Further, in the second three-way valve 32, the b port and the c port communicate with each other, and the a port is closed (that is, the second flow path configuration of the second three-way valve 32 is selected). Controlled). As a result, the use side heat exchanger primary side outlet pipe 47 and the heat pump inlet pipe 41 communicate with each other, and the flow path from the outlet 6 of the hot water storage tank 10 is blocked by closing the tank lower pipe 40 side. Further, the four-way valve 33 is controlled so that the b port and the d port communicate with each other and the a port and the c port are closed (that is, the second flow path configuration of the four-way valve 33 is selected). The As a result, the bypass pipe 48 and the upper return pipe 49 communicate with each other, and the flow path from the heating heat exchanger 62 is shut off with the heat pump outlet pipe 42 side closed.

  The upper return bathtub heating operation is performed in the state where the upper return circuit is formed by controlling the first three-way valve 31, the second three-way valve 32, and the four-way valve 33 as described above. It is executed by operating the side circulation pump 52. By the operation of the circulation pump 21, the hot water in the hot water storage tank 10 circulates as follows. The high temperature water flowing out from the outlet 7 of the hot water storage tank 10 passes to the usage side heat exchanger 22 via the first tank upper pipe 43, the first three-way valve 31, and the usage side heat exchanger primary side inlet pipe 46. The temperature is lowered by the heat exchange with the bathtub water and becomes medium-temperature water. This medium temperature water passes through the use side heat exchanger primary side outlet pipe 47, the second three-way valve 32, the heat pump inlet pipe 41, the bypass pipe 48, the four-way valve 33, the upper return pipe 49, and the second tank upper pipe 44. Then, it flows into the hot water storage tank 10 from the upper port 5. On the other hand, in the path on the bathtub 50 side, the bathtub water stretched around the bathtub 50 circulates in the bathtub water circulation circuit 51 by the operation of the secondary circulation pump 52. As a result, the heat of the high-temperature water flowing on the primary side of the usage-side heat exchanger 22 is transferred to the bathtub water flowing on the secondary side of the usage-side heat exchanger 22, and the bathtub water stretched in the bathtub 50 is heated. Is done.

  In the above-described upper return bath heating operation, since the middle temperature water is not allowed to flow into the lower part of the hot water storage tank 10, an increase in the water temperature in the lower part of the hot water storage tank 10 can be suppressed. When the water temperature in the lower part of the hot water storage tank 10 rises, the temperature of the water flowing into the heat pump unit 60 (boiling heat exchanger 62) at the time of the boiling operation increases, so that the operation efficiency of the heat pump unit 60 decreases. In the upper return tub heating operation, an increase in the water temperature in the lower part of the hot water storage tank 10 can be suppressed, so that the temperature of water entering the heat pump unit 60 can be kept low during the boiling operation. It is possible to maintain high driving efficiency. On the other hand, in the upper return bath heating operation, the intermediate temperature water flows into the upper part of the hot water storage tank 10, so the intermediate temperature water is mixed with the high temperature water in the upper part of the hot water storage tank 10, so that the hot water in the hot water storage tank 10 is mixed. The temperature drops.

  FIG. 4 is a circuit configuration diagram at the time of a lower return bathtub heating operation in hot water storage type hot water supply apparatus 100 according to Embodiment 1 of the present invention. The lower return tub heating operation means that the hot water (high temperature water) taken out from the upper port 5 of the hot water storage tank 10 and the tub water circulating from the tub 50 are heat-exchanged in the use side heat exchanger 22 so that the tub water is exchanged. In this operation, the hot water (medium temperature water) whose temperature has been lowered by heat exchange is returned to the return port 8 of the hot water storage tank 10. At the time of the lower return bath heating operation, as shown in FIG. 4, the first three-way valve 31 is configured so that the b port and the c port communicate with each other and the a port is closed (that is, the first three-way valve 31). 31) so that the second channel configuration is selected. As a result, the second tank upper pipe 44 and the use side heat exchanger primary side inlet pipe 46 communicate with each other, and the flow path from the outlet 7 of the hot water storage tank 10 is closed by closing the first tank upper pipe 43 side. Blocked. Further, in the second three-way valve 32, the b port and the c port communicate with each other, and the a port is closed (that is, the second flow path configuration of the second three-way valve 32 is selected). Controlled). As a result, the use side heat exchanger primary side outlet pipe 47 and the heat pump inlet pipe 41 communicate with each other, and the flow path from the outlet 6 of the hot water storage tank 10 is blocked by closing the tank lower pipe 40 side. Further, the four-way valve 33 is controlled so that the a port and the b port communicate with each other and the c port and the d port are closed (that is, the third flow path configuration of the four-way valve 33 is selected). The Thereby, the bypass pipe 48 and the lower return pipe 45 communicate with each other, and the flow path from the heat exchanger 62 for boiling is shut off with the heat pump outlet pipe 42 side closed.

  The lower return bathtub heating operation is performed in the state where the lower return circuit is formed by controlling the first three-way valve 31, the second three-way valve 32, and the four-way valve 33 as described above. It is executed by operating the side circulation pump 52. By the operation of the circulation pump 21, the hot water in the hot water storage tank 10 circulates as follows. The high-temperature water flowing out from the upper port 5 of the hot water storage tank 10 is transferred to the use side heat exchanger 22 via the second tank upper pipe 44, the first three-way valve 31, and the use side heat exchanger primary side inlet pipe 46. The temperature is lowered by the heat exchange with the bathtub water and becomes medium-temperature water. This medium-temperature water is stored in the hot water storage tank from the return port 8 via the use side heat exchanger primary side outlet pipe 47, the second three-way valve 32, the heat pump inlet pipe 41, the bypass pipe 48, the four-way valve 33, and the lower return pipe 45. 10 flows in. On the other hand, in the path on the bathtub 50 side, the bathtub water stretched around the bathtub 50 circulates in the bathtub water circulation circuit 51 by the operation of the secondary circulation pump 52. As a result, the heat of the high-temperature water flowing on the primary side of the usage-side heat exchanger 22 is transferred to the bathtub water flowing on the secondary side of the usage-side heat exchanger 22, and the bathtub water stretched in the bathtub 50 is heated. Is done.

  In the lower return bathtub heating operation described above, since the middle temperature water flows into the lower part of the hot water storage tank 10, the water temperature in the lower part of the hot water storage tank 10 rises. For this reason, when the lower return bathtub heating operation is performed, the temperature of water entering the heat pump unit 60 is increased during the boiling operation, and thus the operation efficiency of the heat pump unit 60 is reduced. On the other hand, in the lower return bathtub heating operation, since the medium-temperature water is not allowed to flow into the upper region of the hot water storage tank 10, it is possible to prevent the temperature of the hot water in the hot water storage tank 10 from being lowered.

  In addition, the hot water storage type water heater 100 of the present embodiment has a bath water temperature setting means that allows the user to arbitrarily set the temperature of hot water (tub water) from the remote controller and the amount of hot water in the bathtub 50. Hot water filling amount setting means that can be arbitrarily set from the remote control device, automatic hot water filling means that automatically fills the bathtub 50 with the temperature and hot water volume set by the bath water temperature setting means and the hot water amount setting means, and automatic Automatic warming means that automatically performs a warming operation of the bathtub 50 in order to keep the temperature of the bathtub water stretched on the bathtub 50 at a predetermined temperature for a predetermined time after the bathtub water is stretched on the bathtub 50 by the hot water filling means; It has.

  FIG. 5 is a flowchart showing the control operation of the automatic heat retaining means in hot water storage type hot water supply apparatus 100 according to Embodiment 1 of the present invention. Hereinafter, the operation of the automatic heat retaining means of the hot water storage type water heater 100 of the present embodiment will be described with reference to FIG. 5, but before that, the outline of the operation and effect of the present embodiment will be described.

  As described above, from the viewpoint of maintaining high operating efficiency of the heat pump unit 60 during the boiling operation, the upper return bathtub heating operation is preferable to the lower return bathtub heating operation. The temperature of the upper part of the hot water storage tank 10 is lowered by the inflow of. When the temperature of the upper part of the hot water storage tank 10 becomes lower than a lower limit temperature (for example, 45 ° C., hereinafter referred to as “minimum hot water storage temperature”) that can be used for hot water supply, there is no hot water available for hot water supply in the hot water storage tank 10 (hereinafter referred to as “hot water storage tank 10”). This is referred to as “running out of hot water”. For this reason, it is desirable to reliably prevent the temperature of the upper part of the hot water storage tank 10 from becoming lower than the minimum hot water storage temperature after the upper return bath heating operation is performed.

  Moreover, the temperature of the upper part of the hot water storage tank 10 may fall at the time of the start of an upper return bathtub heating operation for the following reasons. The inside of each pipe constituting the upper return circuit and the lower return circuit is always filled with hot water. For this reason, the hot and cold water in these pipes gradually dissipates heat according to the ambient temperature around each pipe and the elapsed time. In many cases, since the ambient temperature is lower than the temperature of the hot water in the pipe, the temperature of the hot water in the pipe decreases. Therefore, the hot water staying in the pipe (hereinafter referred to as “piping residual water”) decreases in temperature over time, and may become low-temperature water that cannot be used for hot water supply. When the upper return tub heating operation is started, if the pipe residual water having a low temperature flows into the upper part of the hot water storage tank 10 from the upper port 5, the temperature of the hot water in the upper part of the hot water storage tank 10 is lowered. Absent. Therefore, in the present embodiment, when the upper return tub heating operation is performed, at least a part of the pipe residual water is obtained by executing the lower return tub heating operation for a predetermined time prior to the start of the upper return tub heating operation. Was replaced with hot water supplied from the upper part of the hot water storage tank 10. Thereafter, by switching from the lower return circuit to the upper return circuit and starting the upper return bath heating operation, the amount of residual pipe water flowing into the upper part of the hot water storage tank 10 can be reduced, and the temperature drop at the upper part of the hot water storage tank 10 is ensured. Can be suppressed.

  Hereinafter, a description will be given based on FIG. First, the control unit 70 determines a start condition for the automatic heat retaining operation (step S201). The controller 70 detects the temperature of the bathtub water by the bathtub outlet side temperature sensor 53 at a predetermined interval (for example, every 10 minutes). In this step S201, when the temperature of the detected bathtub water is lower than a temperature set by the bathtub water temperature setting means (hereinafter referred to as “bath set temperature”) by a predetermined temperature or more (for example, a bathtub) When the temperature of the bath water is 41 ° C. or lower with respect to the set temperature of 42 ° C., it is determined that the start condition for the automatic heat retaining operation is satisfied, and the automatic heat retaining operation is started.

  When the automatic warming operation is started in step S201, the control unit 70 next determines whether or not the upper return bathtub heating operation can be performed (step S202). For example, when it is predicted that there is no possibility of running out of hot water by performing the upper return tub heating operation, the control unit 70 determines that the upper return tub heating operation can be performed and is predicted to have the possibility. When it is determined that the upper return tub heating operation is not possible. To what extent the temperature of the upper part of the hot water storage tank 10 decreases when the upper return bath heating operation is performed can be predicted by the temperature detected by the hot water storage temperature sensor 11 before the start of the upper return bathtub heating operation. That is, it can be predicted that the higher the temperature detected by the hot water storage temperature sensor 11 before the start of the upper return bath heating operation, the higher the temperature of the upper portion of the hot water storage tank 10 after performing the upper return bath heating operation. In this embodiment, when the upper return bath heating operation is performed, whether or not the temperature of the upper portion of the hot water storage tank 10 may be lowered below the minimum hot water storage temperature is determined based on whether or not the hot water storage temperature before the start of the upper return bath heating operation. A predetermined threshold for prediction based on the detected temperature of the sensor 11 is stored in the control unit 70 in advance. In step S202, the control unit 70 compares the detected temperature of the hot water storage temperature sensor 11 with the above threshold value, and when the detected temperature of the hot water storage temperature sensor 11 is equal to or higher than the above threshold value, the hot water is heated by performing the upper return bath heating operation. Since it can be predicted that there is no possibility of cutting, it is determined that the upper return bathtub heating operation can be performed. On the other hand, when the temperature detected by the hot water storage temperature sensor 11 is lower than the above threshold, it can be predicted that hot water may run out due to the execution of the upper return bath heating operation, and therefore the upper return bath heating operation cannot be performed. Judge.

  When it is determined in step S202 that the upper return bathtub heating operation cannot be performed, the control unit 70 starts the lower return bathtub heating operation (step S205). On the other hand, if it is determined in step S202 that the upper return bathtub heating operation can be performed, the control unit 70 determines whether or not a predetermined time has elapsed since the start of the automatic heat retaining operation. However, if the predetermined time has not elapsed, the lower return bathtub heating operation is performed (step S205). Thus, even if it is determined that the upper return bathtub heating operation can be performed, the lower return bathtub heating operation is first executed.

  When the predetermined time has elapsed since the start of the automatic heat retaining operation (that is, the start of the lower return bathtub heating operation) and the determination in step S203 is affirmed, the control unit 70 performs the first three-way valve 31 and the four-way valve 33. By switching from the lower return circuit to the upper return circuit, the upper return bathtub heating operation is started (step S204). Thus, prior to the start of the upper return tub heating operation, the lower return tub heating operation is executed for a predetermined time.

  Here, the predetermined time is, for example, the time until all the pipe residual water existing in the lower return circuit before flowing into the lower return circuit flows into the lower part of the hot water storage tank 10 (hereinafter referred to as “residual water discharge time”). ”). This will be specifically described below. During the lower return tub heating operation, the hot water in the hot water storage tank 10 is led out from the upper port 5 of the hot water storage tank 10, and the second tank upper pipe 44, the first three-way valve 31, the use side heat exchanger primary side inlet. Piping 46, use side heat exchanger 22, use side heat exchanger primary side outlet pipe 47, second three-way valve 32, heat pump inlet pipe 41, circulation pump 21, bypass pipe 48, four-way valve 33, lower return pipe 45, To the return port 8 of the hot water storage tank 10 in this order. The amount of pipe residual water present in the lower return circuit is the sum of the volumes of the pipes (flow paths), and can be calculated at the time of design. Further, if the head of the circulation pump 21 is determined at the time of design (the rotational speed at the time of driving is set to a predetermined rotational speed), the flow rate per hour can be calculated from the pipe pressure loss of the lower return circuit. Alternatively, a flow rate sensor may be provided upstream or downstream of the circulation pump 21 and the instantaneous flow rate may be integrated and obtained. By dividing the amount of residual pipe water existing in the lower return circuit by the flow rate per hour, the time until all the residual pipe water existing in the lower return circuit flows into the lower part of the hot water storage tank 10, that is, residual water. The discharge time can be calculated. The predetermined time may be set to a time equivalent to the remaining water discharge time, or may be set to a time slightly longer than the remaining water discharge time with a margin. In addition, the above-mentioned predetermined time is discharged so that the time until a part of the pipe residual water existing in the lower return circuit before flowing into the lower return circuit flows into the lower part of the hot water storage tank 10 is started. A time shorter than the time may be set.

  Prior to the start of the upper return bath heating operation, the lower return bathtub heating operation for the predetermined time is executed, and the high-temperature water led out from the upper port 5 of the hot water storage tank 10 is injected into the lower return circuit, and the remaining piping in the lower return circuit is left. Replaced with water. Thereafter, when the lower return tub heating operation is switched to the upper return tub heating operation, the flow path of the high-temperature water changes as the circuit is changed. That is, the high-temperature water flowing out from the outlet 7 of the hot water storage tank 10 passes through the first tank upper pipe 43, the first three-way valve 31, and the use side heat exchanger primary side inlet pipe 46 to the use side heat exchanger. It is guide | induced to 22 and heat-exchanges with bathtub water, and becomes middle temperature water. This medium-temperature water is supplied from the heat exchanger primary side outlet pipe 47, the second three-way valve 32, the heat pump inlet pipe 41, the circulation pump 21, the bypass pipe 48, the four-way valve 33, the upper return pipe 49, and the second tank upper part. It flows into the hot water storage tank 10 from the upper port 5 via the pipe 44. Among the upper return circuits, the first three-way valve 31, the use side heat exchanger primary side inlet pipe 46, the use side heat exchanger 22, the use side heat exchanger primary side outlet pipe 47, the second three way valve 32, The residual water in the heat pump inlet pipe 41, the circulation pump 21, the bypass pipe 48, and the four-way valve 33 is replaced with high-temperature water or medium-temperature water after heat exchange by the lower return tub heating operation previously performed for a predetermined time. ing. For this reason, since the pipe residual water which flows into the upper port 5 of the hot water storage tank 10 after the start of the upper return bath heating operation is only the amount existing in the first tank upper pipe 43 and the upper return pipe 49, The amount of hot water in the hot water storage tank 10 is negligibly small. In this way, according to the present embodiment, it is possible to suppress the inflow of pipe residual water to the upper part of the hot water storage tank 10 when the upper return bathtub heating operation is performed, and to reliably lower the temperature of the upper part of the hot water storage tank 10. Can be suppressed. In addition, by setting the length of the first tank upper pipe 43 and the upper return pipe 49 as short as possible, the amount of pipe residual water flowing into the upper part of the hot water storage tank 10 can be further suppressed.

  As described above, according to the present embodiment, when it is determined that the upper return tub heating operation can be performed when performing the automatic heat retaining operation, the use side heat exchange is performed by performing the upper return tub heating operation. It is possible to avoid the middle temperature water returning from the vessel 22 from flowing into the lower part of the hot water storage tank 10 and to suppress an increase in the water temperature at the lower part of the hot water storage tank 10. For this reason, the operating efficiency of the heat pump unit 60 during the boiling operation can be maintained high. In addition, by performing the lower return bathtub heating operation for the predetermined time before the upper return bathtub heating operation is started, the pipe residual water is prevented from flowing into the upper portion of the hot water storage tank 10 at the start of the upper return bathtub heating operation. Therefore, the temperature drop of the upper part of the hot water storage tank 10 due to the inflow of the pipe residual water can be reliably suppressed.

  In the present embodiment, when it is determined that the upper return bathtub heating operation cannot be performed (when it is predicted that hot water will run out due to the upper return bathtub heating operation), the intermediate warm water returning from the use-side heat exchanger 22 is used. By performing the lower return bathtub heating operation that does not flow into the upper part of the hot water storage tank 10, it is possible to suppress the temperature drop of the upper part of the hot water storage tank 10. For this reason, generation | occurrence | production of the hot water run by an upper return bathtub heating operation can be prevented reliably.

  In the present embodiment, only the upper port 5 and the return port 8 function as a recovery port for recovering the medium-temperature water returning from the use side heat exchanger 22 into the hot water storage tank 10. For this reason, in this embodiment, the number of the collection | recovery ports which collect | recover the inside warm water which returns from the utilization side heat exchanger 22 in the hot water storage tank 10 can be reduced as much as possible. Moreover, in this embodiment, the temperature sensor for detecting the temperature of the middle temperature water returning from the utilization side heat exchanger 22 is unnecessary. Thus, according to the present embodiment, the number of recovery ports provided in the hot water storage tank 10 can be reduced as much as possible, and the configuration of the pipe connected to the recovery port of the hot water storage tank 10 and the flow path switching for switching the recovery port The configuration of the valve can also be simplified, and there is no need to provide a temperature sensor for detecting the temperature of the medium-temperature water returning from the use-side heat exchanger 22, so that hot water storage can be performed while preventing hot water shortage with a low-cost system configuration. It is possible to suppress an increase in the water temperature in the lower part of the tank 10 and maintain high operating efficiency of the heat pump unit 60 during the boiling operation.

  In addition, since the temperature drop of the piping residual water depends on the elapsed time, if the time has not passed so much since the previous upper return tub heating operation or the lower return tub heating operation has been completed, Has not yet declined. In such a case, the necessity of replacing the pipe residual water by the lower return tub heating operation before the start of the upper return tub heating operation is relatively small. Therefore, in the present invention, when the elapsed time since the previous upper return bathtub heating operation or lower return bathtub heating operation is executed is shorter than the case where the elapsed time is longer, the predetermined time in step S203 is shortened. You may do it. For example, if the elapsed time from the end of the previous upper return tub heating operation or lower return tub heating operation is within 30 minutes, the predetermined time is 10 seconds, and if the elapsed time exceeds 30 minutes and is within 2 hours, The time may be 20 seconds, and when the elapsed time exceeds 2 hours, the predetermined time may be 30 seconds. The starting point of this elapsed time may be the start time of the previous upper return tub heating operation or lower return tub heating operation. The predetermined time may be continuously changed according to the elapsed time. By changing the predetermined time in step S203 as described above, when the elapsed time from the previous upper return bath heating operation or the lower return bathtub heating operation is short, that is, when the temperature drop amount of the pipe residual water is small In order to reduce the time of the lower return tub heating operation for replacing the pipe residual water and to switch to the upper return tub heating operation earlier, the rise in the water temperature at the lower part of the hot water storage tank 10 can be more reliably suppressed. Further, it becomes possible to maintain the operation efficiency of the heat pump unit 60 at the time of the boiling operation even higher.

  Moreover, if it is not long after the end of the previous upper return bath heating operation or the lower return bathtub heating operation (for example, within 10 minutes), the temperature drop amount of the pipe residual water is several degrees and is negligibly small. it is conceivable that. In such a case, it is considered that there is no problem even if the lower return bathtub heating operation for replacing the pipe residual water is omitted. For this reason, in this invention, when implementing an upper return bathtub heating operation, the elapsed time after the last upper return bathtub heating operation or lower return bathtub heating operation is performed is shorter than a predetermined threshold (for example, 10 minutes). In this case, the lower return tub heating operation for replacing the pipe residual water may be omitted, and the upper return circuit may be formed from the beginning to start the upper return tub heating operation.

  Further, the temperature drop of the pipe residual water depends on the ambient temperature around the pipe (that is, the temperature of the space in the hot water storage tank unit 1). When the pipe atmosphere temperature is high, the temperature drop of the pipe residual water is small, so the need to replace the pipe residual water by the lower return bathtub heating operation before the start of the upper return bathtub heating operation becomes relatively small. . Therefore, in the present invention, when the pipe atmosphere temperature is high, the predetermined time in step S203 may be shortened compared to when the pipe atmosphere temperature is low. In this case, the predetermined time in step S203 may be changed in multiple steps or continuously according to the piping atmosphere temperature. In this way, by changing the predetermined time in step S203, when the pipe atmosphere temperature is high, that is, when the temperature drop amount of the pipe residual water is small, the lower return bathtub heating operation for replacing the pipe residual water is performed. In order to shorten the time and switch to the upper return bathtub heating operation earlier, it is possible to more reliably suppress an increase in the water temperature in the lower part of the hot water storage tank 10 and further increase the operating efficiency of the heat pump unit 60 during the boiling operation. Can be maintained. The pipe atmosphere temperature may be detected by providing a dedicated pipe atmosphere temperature sensor, but other temperature sensors (such as a bath outlet side temperature sensor 53 and a hot water supply temperature sensor 54) incorporated in the hot water storage tank unit 1 may be used. Alternatively, it can be detected. For example, when the bathtub water in the bathtub water circulation circuit 51 is not flowing and the time for sufficiently radiating the piping of the bathtub water circulation circuit 51 in the hot water storage tank unit 1 has elapsed, the temperature sensor 53 of the bathtub outlet side temperature sensor 53 Since the detected temperature can be approximated to the piping atmosphere temperature, the detected temperature of the bathtub outlet side temperature sensor 53 can be used as the piping atmosphere temperature.

  Since the piping atmosphere temperature correlates with the outside air temperature, the same effect as described above can be obtained by changing the predetermined time in step S203 in the same manner as described above based on the outside air temperature instead of the piping atmosphere temperature. The outside air temperature may be detected by providing a dedicated outside temperature sensor, but may be detected by using another temperature sensor instead. For example, when the heat pump unit 60 is not in operation, the temperature detected by the heat pump outlet side temperature sensor 66 can be approximated to the outside air temperature, so that the temperature detected by the heat pump outlet side temperature sensor 66 can be regarded as the outside air temperature. .

  In addition, the temperature of water supplied to the hot water storage tank 10 from the outside through the water supply pipe 2 (hereinafter referred to as “water supply temperature”) correlates with the outside air temperature, and therefore also correlates with the pipe atmosphere temperature. Therefore, instead of the piping atmosphere temperature, the predetermined time in step S203 is changed similarly to the above based on the feed water temperature detected by the feed water temperature sensor (not shown) provided in the feed water pipe 2. Similar effects can be obtained.

  In addition, when the pipe atmosphere temperature (or outside air temperature or feed water temperature) is sufficiently high, the temperature drop of the pipe residual water is sufficiently small, so that the pipe residual water is replaced before the upper return bath heating operation starts. It is considered that there is no problem even if the lower return bathtub heating operation is omitted. Therefore, in the present invention, when the upper return tub heating operation is performed and the pipe atmosphere temperature (or outside air temperature or feed water temperature) is higher than a predetermined threshold, the lower return tub for replacing the residual pipe water The heating operation may be omitted, and the upper return circuit may be formed from the beginning to start the upper return bathtub heating operation.

  In the present embodiment, whether or not the upper return bath heating operation can be performed by comparing the detected temperature of the hot water storage temperature sensor 11 at a predetermined height position in the upper region of the hot water storage tank 10 with a predetermined threshold value. In the present invention, the amount of stored hot water (heat storage amount) in the hot water storage tank 10 calculated from the temperature distribution detected by the plurality of hot water storage temperature sensors 11 and 12 is compared with a predetermined threshold value. It may be determined whether or not the upper return bathtub heating operation can be performed.

  In the present embodiment, the hot water take-out position (upper port 5) from the hot water storage tank 10 in the lower return circuit is higher than the hot water take-out position (outlet 7) from the hot water storage tank 10 in the upper return circuit. There are the following advantages. Since hot water in the hot water storage tank 10 that is higher than the outlet 7 cannot be taken out by the first tank upper pipe 43, hot water that is higher than the outlet 7 in the hot water storage tank 10 in the upper return bath heating operation. Cannot be used. On the other hand, in the lower return bathtub heating operation, the hot water at a position higher than the outlet 7 in the hot water storage tank 10 can be taken out from the upper port 5 to the second tank upper pipe 44 and used. For this reason, since the temperature of the upper part of the hot water storage tank 10 falls, the upper return bathtub heating operation cannot be performed, and the hot water in the hot water storage tank 10 can be used to the maximum when performing the lower return bathtub heating operation. It is possible to increase the amount of hot water that can be used in the heating operation as much as possible. However, in the present invention, the hot water take-out position from the hot water storage tank 10 in the lower return circuit may be the same or lower than the hot water take-out position from the hot water storage tank 10 in the upper return circuit.

  In the present invention, the hot water return position to the hot water storage tank 10 in the upper return circuit may be the same or lower than the hot water take-out position from the hot water storage tank 10 in the upper return circuit. As in the embodiment, the hot water return position (upper port 5) to the hot water storage tank 10 in the upper return circuit is higher than the hot water take-out position (outlet 7) from the hot water storage tank 10 in the upper return circuit. preferable. This has the following advantages. Hot water has the property that the density increases as the temperature decreases. The hot water (medium temperature water) whose temperature has been reduced by the use-side heat exchanger 22 has a higher density than the hot water in the hot water storage tank 10 due to the temperature decrease. If it flows in, it will be sufficiently mixed with the hot water in the hot water storage tank 10 while diffusing downward due to the density difference. Thus, the hot water returned from the use side heat exchanger 22 is sufficiently mixed with the hot water in the hot water storage tank 10, so that the hot water returned from the use side heat exchanger 22 is directly supplied from the outlet 7 to the first. Outflow to the tank upper pipe 43 (short cycle) can be reliably prevented. On the other hand, if the hot water return position to the hot water storage tank 10 in the upper return circuit is lower than the hot water take-out position (outlet 7) from the hot water storage tank 10 in the upper return circuit, the use side heat The hot water (intermediate warm water) returned from the exchanger 22 may form an intermediate warm water layer without being sufficiently mixed with the hot water in the hot water storage tank 10. Then, the position of the intermediate warm water layer gradually rises, and there is a possibility that a short cycle in which the intermediate warm water flows out from the outlet 7 to the first tank upper pipe 43 may occur.

1 Hot water storage tank unit, 2 Water supply piping, 3 Hot water supply piping, 4 Inlet port, 5 Upper port, 6 Outlet port, 7 Outlet, 8 Return port, 10 Hot water tank, 11, 12 Hot water temperature sensor, 21 Circulation pump, 22 Side heat exchanger, 31 first three-way valve, 32 second three-way valve, 33 four-way valve, 40 tank lower pipe, 41 heat pump inlet pipe, 42 heat pump outlet pipe, 43 first tank upper pipe, 44 second Tank upper piping, 45 Lower return piping, 46 Usage side heat exchanger primary side inlet piping, 47 Usage side heat exchanger primary side outlet piping, 48 Bypass piping, 49 Upper return piping, 50 Bathtub, 51 Bathtub water circulation circuit, 52 Two Secondary circulation pump, 53 Bath outlet temperature sensor, 54 Hot water temperature sensor, 55 Hot water flow sensor, 60 Heat pump unit, 61 Compressor 62 heat exchanger for water heating, 63 expansion valve, 64 an air heat exchanger, 65 refrigerant circulation pipe, 66 heat pump outlet temperature sensor, 70 control unit, 100 storage type water heater

Claims (7)

A hot water storage tank capable of storing hot water,
Heating means capable of heating water;
A boiling circuit for sending water taken from the hot water storage tank to the heating means and returning the hot water generated by the heating means to the hot water storage tank;
An upper return circuit for returning hot water taken out from the upper region of the hot water storage tank to the upper region of the hot water storage tank via a use side heat exchanger for heating the heating target;
A lower return circuit for returning the hot water taken out from the upper region of the hot water storage tank to the lower region of the hot water storage tank via the use side heat exchanger;
Channel switching means for switching between the upper return circuit and the lower return circuit;
When starting the upper return heating operation for circulating the hot water taken out from the upper region of the hot water storage tank to the upper return circuit, the hot water taken out from the upper region of the hot water storage tank is started prior to the start of the upper return heating operation. By performing a lower return heating operation to flow through the lower return circuit for a predetermined time, at least a part of hot water in the lower return circuit is replaced, and then the upper return circuit is started by switching to the upper return circuit. A control unit;
Equipped with a,
The control unit omits the execution of the lower return heating operation for the predetermined time when the elapsed time since the previous upper return heating operation or the lower return heating operation is executed is shorter than a predetermined threshold. water storage type water heater you start a heating operation returns the top. A hot water storage tank capable of storing hot water,
Heating means capable of heating water;
A boiling circuit for sending water taken from the hot water storage tank to the heating means and returning the hot water generated by the heating means to the hot water storage tank;
An upper return circuit for returning hot water taken out from the upper region of the hot water storage tank to the upper region of the hot water storage tank via a use side heat exchanger for heating the heating target;
A lower return circuit for returning the hot water taken out from the upper region of the hot water storage tank to the lower region of the hot water storage tank via the use side heat exchanger;
Channel switching means for switching between the upper return circuit and the lower return circuit;
When starting the upper return heating operation for circulating the hot water taken out from the upper region of the hot water storage tank to the upper return circuit, the hot water taken out from the upper region of the hot water storage tank is started prior to the start of the upper return heating operation. By performing a lower return heating operation to flow through the lower return circuit for a predetermined time, at least a part of hot water in the lower return circuit is replaced, and then the upper return circuit is started by switching to the upper return circuit. A control unit;
Temperature detecting means capable of detecting the atmospheric temperature of the pipe constituting the upper return circuit, the temperature of water supplied to the hot water storage tank, or the outside air temperature ;
With
Wherein, savings water type temperature detected by said temperature detecting means that to start the heating operation returns the upper omit execution of the heating operation returning the lower portion of the predetermined time is higher than a predetermined threshold value Water heater. A hot water storage tank capable of storing hot water,
Heating means capable of heating water;
A boiling circuit for sending water taken from the hot water storage tank to the heating means and returning the hot water generated by the heating means to the hot water storage tank;
An upper return circuit for returning hot water taken out from the upper region of the hot water storage tank to the upper region of the hot water storage tank via a use side heat exchanger for heating the heating target;
A lower return circuit for returning the hot water taken out from the upper region of the hot water storage tank to the lower region of the hot water storage tank via the use side heat exchanger;
Channel switching means for switching between the upper return circuit and the lower return circuit;
When starting the upper return heating operation for circulating the hot water taken out from the upper region of the hot water storage tank to the upper return circuit, the hot water taken out from the upper region of the hot water storage tank is started prior to the start of the upper return heating operation. By performing a lower return heating operation to flow through the lower return circuit for a predetermined time, at least a part of hot water in the lower return circuit is replaced, and then the upper return circuit is started by switching to the upper return circuit. A control unit;
With
The take-out position of the hot water from the hot water storage tank in the lower return circuit, from the take-out position of the hot water from the hot water storage tank in the upper back circuit, Ru high position near savings hot water heater. A hot water storage tank capable of storing hot water,
Heating means capable of heating water;
A boiling circuit for sending water taken from the hot water storage tank to the heating means and returning the hot water generated by the heating means to the hot water storage tank;
An upper return circuit for returning hot water taken out from the upper region of the hot water storage tank to the upper region of the hot water storage tank via a use side heat exchanger for heating the heating target;
A lower return circuit for returning the hot water taken out from the upper region of the hot water storage tank to the lower region of the hot water storage tank via the use side heat exchanger;
Channel switching means for switching between the upper return circuit and the lower return circuit;
When starting the upper return heating operation for circulating the hot water taken out from the upper region of the hot water storage tank to the upper return circuit, the hot water taken out from the upper region of the hot water storage tank is started prior to the start of the upper return heating operation. By performing a lower return heating operation to flow through the lower return circuit for a predetermined time, at least a part of hot water in the lower return circuit is replaced, and then the upper return circuit is started by switching to the upper return circuit. A control unit;
With
The return position of the hot water to the hot water storage tank in the upper back circuit, wherein from the take-out position of the hot water from the hot water storage tank, Ru high position near savings hot water heater in the upper returning circuit. The control unit includes means for shortening the predetermined time when the elapsed time since the previous upper return heating operation or the lower return heating operation is shorter than when the elapsed time is long. Item 5. A hot water storage type water heater according to any one of Items 1 to 4 . A temperature detecting means capable of detecting an atmospheric temperature of piping constituting the upper return circuit, a temperature of water supplied to the hot water storage tank, or an outside air temperature;
Wherein, when the temperature is higher detected by said temperature detecting means any of claims 1 to 5 comprising means to shorten the predetermined time as compared with the case where the temperature detected by said temperature detecting means is lower The hot water storage type water heater according to claim 1 . The hot water storage type water heater according to any one of claims 1 to 6 , wherein the use side heat exchanger heats bathtub water of a bathtub.

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