JP2016183838A - Hot water storage type heat pump water heater - Google Patents

Abstract

PROBLEM TO BE SOLVED: To achieve an operation with high energy efficiency by avoiding the situation in which a hot water source at hot water supply time is limited only to one of heat pump heating means and a hot water storage tank.SOLUTION: A hot water storage type heat pump water heater 35 includes: a HP unit 7; a hot water storage tank 8; a water supply pipeline 9; a hot water supply pipeline 21; a mixing valve 23 for bath; a second three-way valve 73; a medium temperature pipeline 79; a medium temperature hot water delivery pipeline 80 and the like. During a direct water filling operation, hot water heated by the HP unit 7 and medium temperature water taken out from a medium temperature lead-out port 8f of the hot water storage tank 8 are merged in the medium temperature pipeline 79 beforehand, and the medium temperature water generated in the medium temperature pipeline 79 by this is supplied to the mixing valve 23 for bath. Then, the mixing valve 23 for bath mixes at least two types of hot water out of three types comprising high temperature water in the hot water supply pipeline 21, medium temperature water in the medium temperature pipeline 79 and low temperature water in the water supply pipeline 9, and the medium temperature water generated by this is supplied to a bathtub 30.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a hot water storage heat pump water heater capable of storing hot water and supplying hot water.

  As a prior art, for example, a hot water storage type heat pump water heater as described in Patent Document 1 is known. In the prior art, the hot water boiled by the heat pump unit is not allowed to flow into the hot water storage tank, but this hot water is directly supplied to the hot water supply use side terminal via the hot water flow path. This prevents the hot water layer stored in the upper part of the hot water tank from being disturbed, and the boiling temperature by the heat pump unit can be lowered to the hot water filling temperature. The coefficient (COP) can be improved.

JP 2009-85439 A

  However, in the above-described prior art, if hot water boiled by the heat pump unit is used during hot water filling, medium hot water stored in the hot water storage tank cannot be used for hot water filling. In addition, when the hot water storage tank is used with hot water during hot water filling, there is a problem that the hot water from the heat pump unit cannot be used for hot water filling.

  The present invention has been made to solve the above-mentioned problems, and avoids limiting the hot water source during hot water supply to only one of the heat pump heating means and the hot water storage tank, and realizes an operation with high energy efficiency. The object is to provide a hot water storage type heat pump water heater.

  A hot water storage heat pump water heater according to the present invention includes a hot water storage tank for storing hot water, a water supply pipe for supplying low temperature water from a water source to the lower part of the hot water storage tank, a high temperature hot water supply pipe for taking out hot water from the upper part of the hot water storage tank, A medium temperature hot water pipe for extracting hot water from the middle part of the hot water tank in the vertical direction, a heat pump heating means for heating hot water supplied from the lower part of the hot water tank or the water supply pipe by a heat pump cycle, and hot water and medium temperature heated by the heat pump heating means. A mixing valve that mixes hot water supplied from at least two pipes among a merging pipe that joins hot water taken out by the hot water piping and high-temperature hot water piping, merging pipe, and water supply pipe, and supplies the mixed hot water to the hot water supply target And.

  According to the present invention, at the time of hot water supply, using a mixing valve, hot water supplied from at least two pipes among a high temperature hot water supply pipe, a junction pipe and a water supply pipe can be mixed, and the mixed hot water can be supplied to a hot water supply target. it can. Thereby, two types of hot water selected according to the situation can be mixed at an appropriate ratio that improves the efficiency at the time of hot water supply, and an operation with high energy efficiency can be realized. Further, according to the present invention, the warm water heated by the heat pump heating means and the intermediate warm water taken out from the hot water storage tank are pre-merged in the merge pipe, and thereby the medium warm water generated in the merge pipe is supplied to the mixing valve. Can do. According to this configuration, it is possible to suppress the number of inflow ports of the mixing valve while realizing high efficiency hot water supply using both hot water from the heat pump heating means and high temperature water in the hot water storage tank. The configuration can be simplified.

It is a block diagram which shows the hot water storage type heat pump water heater by Embodiment 1 of this invention. It is operation | movement explanatory drawing which shows the boiling single operation in Embodiment 1 of this invention. It is operation | movement explanatory drawing which shows the direct filling operation in Embodiment 1 of this invention. In Embodiment 1 of this invention, it is a flowchart which shows the example of control at the time of filling operation. In Embodiment 1 of this invention, it is a flowchart which shows the example of control of the mixing valve for bathing at the time of filling operation.

  Embodiments of the present invention will be described below with reference to the drawings. In each drawing used in this specification, common elements are denoted by the same reference numerals, and redundant description is omitted. Further, the present invention is not limited to the following embodiments, and can be variously modified without departing from the gist of the present invention. Moreover, in this specification, "hot water" is a general term for warm water (hot water) and water. Further, “low temperature water” means low temperature water similar to, for example, tap water, and “high temperature water” means high temperature hot water heated by the HP unit 7 at the time of a single boiling operation. Moreover, warm water in an intermediate temperature range between high and low temperatures may be referred to as “medium warm water”.

Embodiment 1 FIG.
1 is a configuration diagram showing a hot water storage type heat pump water heater according to Embodiment 1 of the present invention. As shown in this figure, the hot water storage type heat pump water heater 35 includes a tank unit 33, an HP unit 7 that uses a heat pump cycle, and a remote controller 44 described later. The HP unit 7 and the tank unit 33 are connected to each other via an HP outgoing pipe 14 and an HP return pipe 15 and are electrically connected to each other via a wiring (not shown).

  The HP unit 7 heats (boils) hot water supplied from a lower part of a hot water storage tank 8 or a water supply pipe 9 described later, and constitutes a heat pump heating means. The hot water heated by the HP unit 7 is stored in the upper part of the hot water storage tank 8 or supplied to the hot water supply object depending on the operation mode. The HP unit 7 is formed by connecting the compressor 1, the water refrigerant heat exchanger 3, the expansion valve 4, and the air heat exchanger 6 in a ring shape with a refrigerant pipe 5, and constitutes a heat pump cycle. The water-refrigerant heat exchanger 3 is for exchanging heat between the refrigerant flowing through the refrigerant pipe 5 and the low-temperature water introduced from the hot water storage tank 8. The water refrigerant heat exchanger 3 may be configured to perform heat exchange between the refrigerant flowing through the refrigerant pipe 5 and the low-temperature water directly supplied from a water source such as water.

  The tank unit 33 includes various parts, piping, and the like described below, including the hot water storage tank 8. The hot water storage tank 8 stores hot water boiled by the HP unit 7. A third water supply pipe 9 c is connected to a water inlet 8 a provided at the lower part of the hot water storage tank 8. Low-temperature water supplied from a water source such as water supply is adjusted to a predetermined pressure by the pressure reducing valve 31 and then flows into the hot water storage tank 8 through the third water supply pipe 9c. A hot water inlet 8d and a hot water outlet 8e are provided in the upper part of the hot water storage tank 8. A hot water supply pipe 21 for supplying hot water stored in the hot water storage tank 8 to the outside of the tank unit 33 and a second hot water supply pipe 13b are connected to the hot water introduction outlet 8d. A warm water introduction pipe 20a is connected to the warm water outlet 8e. In the present embodiment, the hot water supply pipe 21 corresponds to a high temperature hot water supply pipe that takes out hot water from the upper part of the hot water storage tank 8.

  Here, hot water heated by the HP unit 7 is introduced into the hot water introduction outlet 8 d of the hot water storage tank 8. When hot water in the hot water storage tank 8 is used for hot water supply, low temperature water is introduced from the water source into the water inlet 8a of the hot water storage tank 8 via the first water supply pipe 9a, the second water supply pipe 9b, and the like. For this reason, a temperature stratification is formed inside the hot water storage tank 8 such that the temperature of the hot water increases in the upper part in the vertical direction and the temperature of the hot water decreases in the lower part. A plurality of hot water storage temperature sensors 42 and 43 are attached to the surface of the hot water storage tank 8 at different heights. These hot water storage temperature sensors 42 and 43 detect the temperature distribution of hot water in the hot water storage tank 8. The detection results of the hot water storage temperature sensors 42 and 43 are used to grasp the amount of hot water stored in the hot water storage tank 8 and to control the start and stop of the boiling operation described later.

  The tank unit 33 incorporates the heat source pump 12 and the bath heat exchanger 20. The heat source pump 12 is a pump for circulating hot water through various pipes to be described later in the tank unit 33, and is provided on the HP outgoing pipe 14. The bath heat exchanger 20 is a heat exchanger for heating secondary water to be heated (tub water, heating water, etc.) using high-temperature water supplied from the hot water storage tank 8. In the present embodiment, as the secondary side configuration of the bath heat exchanger 20, a bath piping 27 and a bath return piping 28 for circulating hot water in the bathtub 30 are illustrated. The bath heat exchanger 20 is installed in the middle of a circulation path formed by the bath piping 27, the bath return piping 28, and the bathtub 30. In the bath return pipe 28, a bath circulation pump 29 that circulates bathtub water in the circulation path, a bath return temperature sensor 38 that detects the temperature of the bath water flowing out from the bath 30, and a water level in the bath 30 are detected. There are provided a water level sensor 46 and a flow switch 47 for detecting the flow of hot water flowing through the return pipe 28. The bathing pipe 27 is provided with a bathing temperature sensor 37 for detecting the temperature of the hot water flowing out from the bath heat exchanger 20. In the present embodiment, the bath temperature sensor 37 corresponds to a specific example of hot water supply temperature detection means.

  The tank unit 33 includes the first three-way valve 11, the second three-way valve 73, and the four-way valve 18. The first three-way valve 11 is a flow path switching means having a and b ports through which hot water flows and a c port through which hot water flows out. The first three-way valve 11 is configured to switch the flow path of hot water between the three paths a-c, bc, a-b-c. The second three-way valve 73 is a flow path switching means having a c port through which hot water flows and a and b ports through which hot water flows out. The second three-way valve 73 is configured to switch the hot water flow path between the three flow paths ac, bc, abc. In the present embodiment, the second three-way valve 73 corresponds to a switching valve that switches the supply destination of the hot water heated by the HP unit 7 to either the upper part of the hot water storage tank 8 or the intermediate temperature pipe 79. The four-way valve 18 is a flow path switching means having b and c ports through which hot water flows and a and d ports through which hot water flows out. The four-way valve 18 is configured to switch the flow path of hot water between the four paths ab, ac, bd, and cd.

  The tank unit 33 includes a water outlet pipe 10, a first hot water supply pipe 13 a, a second hot water supply pipe 13 b, an HP outgoing pipe 14, an HP return pipe 15, a hot water introduction pipe 20 a, a first bypass pipe 16, and hot water derivation. A pipe 20b and a second bypass pipe 17 are provided. The water outlet port pipe 10 connects a water outlet port 8 b provided at the lower part of the hot water storage tank 8 and the a port of the first three-way valve 11. The HP outgoing pipe 14 connects the c port of the first three-way valve 11 and the inlet side of the HP unit 7. The HP return pipe 15 connects the outlet side of the HP unit 7 and the c port of the four-way valve 18. The HP return pipe 15 is provided with an HP hot water temperature sensor 39 for detecting the temperature of the hot water flowing out from the HP unit 7 (hot water temperature).

  The first hot water supply pipe 13 a connects the d port of the four-way valve 18 and the c port of the second three-way valve 73. The second hot water supply pipe 13 b connects the a port of the second three-way valve 73 and the hot water introduction outlet 8 d above the hot water storage tank 8. The first bypass pipe 16 connects the a port of the four-way valve 18 and a hot water inlet 8 c provided between the central part and the lower part of the hot water storage tank 8. The hot water introduction pipe 20 a connects the hot water outlet 8 e of the hot water storage tank 8 and the primary side inlet of the bath heat exchanger 20. The hot water outlet pipe 20 b connects the primary side outlet of the bath heat exchanger 20 and the b port of the first three-way valve 11. The second bypass pipe 17 branches from a portion of the HP outgoing pipe 14 between the heat source pump 12 and the HP unit 7 and is connected to the b port of the four-way valve 18.

  Further, the tank unit 33 includes an intermediate temperature pipe 79, a first water supply pipe 9a, a second water supply pipe 9b, a first hot water supply mixing valve 22, a bath mixing valve 23, a second hot water supply mixing valve 78, and a first hot water supply pipe 24. And the 2nd hot water supply piping 25 is provided. One end of the first water supply pipe 9a is connected to a water source such as a water supply. A second water supply pipe 9 b and a third water supply pipe 9 c are connected to the other end of the first water supply pipe 9 a through a pressure reducing valve 31. The second water supply pipe 9b is branched from the middle and connected to the first hot water supply mixing valve 22 and the bath mixing valve 23, respectively. The water supply pipe 9 is constituted by the first water supply pipe 9a, the second water supply pipe 9b, and the third water supply pipe 9c. The hot water supply pipe 21 is branched from the middle and connected to the first hot water supply mixing valve 22 and the bath mixing valve 23, respectively.

  The second hot water supply mixing valve 78 is provided in the middle of the first hot water supply pipe 24 and is connected to the intermediate temperature pipe 79. The intermediate temperature pipe 79 connects an intermediate temperature outlet 8f provided at an intermediate portion of the hot water storage tank 8 and the second hot water supply mixing valve 78. Accordingly, the second hot water supply mixing valve 78 mixes the hot water discharged from the intermediate temperature outlet 8f of the hot water storage tank 8 with the hot water mixed by the first hot water mixing valve 22. Further, the intermediate temperature pipe 79 branches from the middle and is also connected to the bath mixing valve 23. In the present embodiment, the intermediate temperature pipe 79 joins the intermediate temperature hot water discharge pipe that extracts hot water from the middle portion of the hot water storage tank 8 in the vertical direction, and the hot water heated by the HP unit 7 and the hot water extracted by the intermediate temperature hot water supply pipe. It corresponds to the merged pipe. On the other hand, a second hot water supply pipe 25 is connected to the outflow side of the bath mixing valve 23. In the middle of the second hot water supply pipe 25, there are provided a solenoid valve 26 for opening and closing the second hot water supply pipe 25, and a flow sensor 45 for detecting the flow of hot water passing through the second hot water supply pipe 25.

  In addition, in FIG. 1, the single valve apparatus which drives one valve body with one motor was illustrated as the mixing valve 23 for a bath. However, the mixing valve for a bath according to the present invention may be constituted by a composite type valve device in which a plurality of valve bodies are driven by a plurality of motors. However, from the viewpoint of cost reduction, a single valve device is preferable as the mixing valve 23 for the bath. Moreover, since the hot water temperature in the hot water storage tank 8 becomes higher toward the upper side, the temperature of hot water flowing through the hot water supply pipe 21, the intermediate temperature pipe 79, and the second water supply pipe 9b is as follows: hot water supply pipe 21> medium temperature pipe 79> second water supply pipe 9b. Have the relationship. Therefore, the bath mixing valve 23 has a function of mixing hot water flowing through two or more pipes among the hot water supply pipe 21, the intermediate temperature pipe 79 and the second water supply pipe 9 b, while the hot water from the hot water supply pipe 21 is mixed. And the low-temperature water from the second water supply pipe 9b are preferably constituted by a single valve device having a function of preventing mixing.

  The first hot-water supply mixing valve 22, the second hot-water supply mixing valve 78, and the bath mixing valve 23 are composed of high-temperature water supplied from the hot-water supply pipe 21, medium-temperature water supplied from the intermediate-temperature pipe 79, and the second water supply pipe 9b. By adjusting the flow rate ratio with the low-temperature water supplied from, medium-temperature water set by the user at the set temperature set by the remote controller 44 is generated. Then, the generated medium-temperature water is supplied to the first hot water supply pipe 24 and the second hot water supply pipe 25, respectively. The hot water whose temperature has been adjusted by the first hot water supply mixing valve 22 and the second hot water supply mixing valve 78 passes through the hot water supply tap 34 from the first hot water supply pipe 24 and is used as a faucet (not shown) such as a shower or currant. )). On the other hand, the hot water adjusted to the set temperature by the bath mixing valve 23 passes through the second hot water supply pipe 25 through the bath flow sensor 45, the bath solenoid valve 26, the bath feed pipe 27, or the bath return pipe 28 sequentially. It is supplied to the bathtub 30. In the present embodiment, the bathtub 30 corresponds to a specific example of a hot water supply target supplied from the bath mixing valve 23.

  The first three-way valve 11 has a configuration in which the water outlet piping 10 and the HP outgoing piping 14 communicate with each other (ac route), and a configuration in which the hot water outlet piping 20b and the HP outgoing piping 14 communicate with each other (bc route). And a mode (abc route) in which the water outlet port pipe 10, the HP outgoing pipe 14, and the hot water outlet pipe 20b communicate with each other. The four-way valve 18 is configured such that the HP return pipe 15 and the first hot water supply pipe 13a communicate with each other (cd path), and the HP return pipe 15 and the first bypass pipe 16 communicate with each other (ac path). And a form (ab path) in which the first bypass pipe 16 and the second bypass pipe 17 communicate with each other, and a form (bd path) in which the first hot water supply pipe 13a and the second bypass pipe 17 communicate with each other. Can be switched to any of the four forms. The second three-way valve 73 is configured such that the first hot water supply pipe 13a and the second hot water supply pipe 13b communicate with each other (ac path), and the first hot water supply pipe 13a and the intermediate hot water pipe 80 communicate with each other. (B-c route), and any one of three forms consisting of a form (abc path) in which the first hot water supply pipe 13a, the second hot water supply pipe 13b, and the hot water supply pipe 80 communicate with each other. Switched. The hot water supply pipe 80 is a pipe that connects the b port of the second three-way valve 73 and the intermediate temperature pipe 79.

  The control unit 36 controls the hot water storage type heat pump water heater 35, is constituted by a microcomputer or the like, and is built in the tank unit 33. The control unit 36 includes a storage circuit in which a control program and the like are stored in advance, an arithmetic processing unit (CPU) that performs an operation based on the control program, and an input / output port that inputs and outputs a signal. The above-mentioned various sensors, various valves, pumps and the like included in the HP unit 7 and the tank unit 33 are connected to the input / output port. In addition, a remote controller 44 is connected to the control unit 36 so as to be able to communicate with each other.

  The remote controller 44 is used by the user to change the operation command and the set value, and corresponds to a specific example of hot water temperature setting means for setting a target temperature value of hot water to be supplied to the bathtub 30 as a target hot water temperature. The remote controller 44 is equipped with a display unit for displaying information such as the state of the hot water storage heat pump water heater 35, an operation unit such as a switch operated by the user, a speaker, a microphone, and the like. The controller 36 controls the hot water storage heat pump water heater 35 by driving actuators such as various valves and pumps based on the output of each sensor, the setting of the remote controller 44, and the like. This control includes a boiling-only operation, a direct hot water operation, a normal hot water operation, an end control of the direct hot water operation, a cooling operation of the water refrigerant heat exchanger 3, and the like. Hereinafter, these operations and controls will be described.

(Boiling only operation)
FIG. 2 is an operation explanatory diagram showing a single boiling operation in the first embodiment of the present invention. As shown in this figure, the single boiling operation is a single boiling operation for boiling hot water in the hot water storage tank 8 by the HP unit 7. In the boiling single operation, first, the first three-way valve 11 is held in the ac path. In the a-c route, the a port and the c port communicate with each other and the b port is kept closed. As a result, the water outlet port pipe 10 and the HP outgoing pipe 14 communicate with each other, the hot water outlet pipe 20b is closed, and the flow path returning from the bath heat exchanger 20 is blocked. The four-way valve 18 is held in the cd path. In the cd path, the c port and the d port communicate with each other, and the a port and the b port are held closed. As a result, the HP return pipe 15 and the first hot water supply pipe 13 a communicate with each other, the first bypass pipe 16 is closed, and the flow path toward the hot water inlet 8 c of the hot water storage tank 8 is blocked. The second three-way valve 73 is held in the ac path. In the a-c route, the a port and the c port communicate with each other and the b port is kept closed. As a result, the first hot water supply pipe 13a and the second hot water supply pipe 13b communicate with each other, the hot water hot water pipe 80 is closed, and the flow path toward the second hot water supply mixing valve 78 is blocked.

  In the boiling-only operation, the HP unit 7 and the heat source pump 12 are driven in the above state. Thereby, the low temperature water flowing out from the lower part of the hot water storage tank 8 flows into the HP unit 7 via the water outlet port pipe 10, the first three-way valve 11, the heat source pump 12, and the HP outgoing pipe 14 in order. Is heated by. The hot water flowing out from the HP unit 7 passes through the HP return pipe 15, the four-way valve 18, the first hot water supply pipe 13 a, the second three-way valve 73, and the second hot water supply pipe 13 b in order, and the hot water in the hot water storage tank 8. It flows into the introduction outlet 8d and is stored in the hot water storage tank 8. In this way, by performing the boiling-only operation, high-temperature water is stored in the hot water storage tank 8 from the upper side, and the increase in the amount of stored hot water is detected by the hot water storage temperature sensors 42 and 43. The Then, the boiling-only operation is terminated when the amount of stored hot water exceeds a preset reference amount, and the heat source pump 12 and the HP unit 7 are stopped.

(Direct hot water operation)
FIG. 3 is an operation explanatory diagram showing a direct filling operation in Embodiment 1 of the present invention. In the direct hot water operation, the hot water boiled by the HP unit 7 is directly supplied to the bathtub 30 and the temperature is adjusted so that the temperature of the bathtub water matches the set temperature set by the user with the remote controller 44. It is. This temperature adjustment is performed by mixing the hot water stored in the hot water storage tank 8 and the low-temperature water supplied from a water source such as tap water and supplying it to the bathtub 30. The direct filling operation is executed when the start operation of the filling operation is performed by the remote controller 44, or when the reserved setting time of the filling operation set by the remote control 44 has come.

  In the direct hot water operation, as shown in FIG. 3, first, the first three-way valve 11 is held in the ac path, and the four-way valve 18 is held in the cd path. These switching states are the same as in the case of the boiling-only operation. On the other hand, the second three-way valve 73 is held in the bc path. In the bc route, the b port and the c port communicate with each other and the a port is kept closed. Thereby, the first hot water supply pipe 13a and the hot water supply hot water pipe 80 communicate with each other, the second hot water supply pipe 13b is closed, and the flow path toward the hot water introduction outlet 8d of the hot water storage tank 8 is blocked. Further, the bath solenoid valve 26 is held in an open state.

  In the direct filling operation, the HP unit 7 and the heat source pump 12 are driven in the above state. Thereby, low temperature water, medium temperature water, and high temperature water are supplied to the mixing valve 23 for bath. Specifically, first, when the bath solenoid valve 26 is opened, hot water on the hot water storage tank 8 side flows into the run-off piping 27 or the bath return piping 28, so that low-temperature water from the water source is supplied to the first water supply. It passes through the pipe 9a and the pressure reducing valve 31. This low-temperature water is supplied to the basin mixing valve 23 through the second water supply pipe 9b and flows into the water inlet 8a of the hot water storage tank 8 through the third water supply pipe 9c. Then, when the low temperature water flows into the hot water storage tank 8, the high temperature water in the hot water storage tank 8 is supplied from the hot water introduction outlet 8 d through the hot water supply pipe 21 to the bath mixing valve 23, and in the hot water storage tank 8. Hot water is supplied from the intermediate temperature outlet 8f to the bath mixing valve 23 via the intermediate temperature pipe 79.

  On the other hand, on the HP unit 7 side, the low temperature water flows out from the lower part of the hot water storage tank 8 by operating the heat source pump 12 as in the case of the single boiling operation, and this low temperature water is heated by the HP unit 7. After reaching warm water, the second three-way valve 73 is reached. Here, the hot water that has reached the second three-way valve 73 flows into the intermediate temperature pipe 79 via the hot water supply pipe 80 and is mixed with the intermediate temperature water in the intermediate temperature pipe 79 and then supplied to the mixing valve 23 for the bath. The In this way, in the direct hot water filling operation, low temperature water, medium temperature water and high temperature water are supplied to the bath mixing valve 23, and these three types of hot water can be mixed by the bath mixing valve 23. Then, the control unit 36 controls the bath mixing valve 23 to adjust the flow rate ratio of the low temperature water, the medium temperature water and the high temperature water, thereby mixing at least two types of hot water and the intermediate temperature. Produces mixed water. The mixed water flows out from the bath mixing valve 23 to the second hot water supply pipe 25 and is supplied to the bathtub 30 via the bath electromagnetic valve 26 and the bath piping 27.

  At this time, the control unit 36 controls the HP unit 7 to a low capacity equal to or less than the heating capacity at the time of the single heating operation. Further, the control unit 36 sets the expansion valve 4 in the HP unit 7 so that the hot water temperature detected by the HP hot water temperature sensor 39 is equal to or lower than the hot water filling temperature set value (target hot water temperature) set by the remote controller 44. To control. As described above, the direct hot water operation is an operation with a lower heating capacity and a higher boiling temperature than a single boiling operation. Thereby, in the boiling operation of the HP unit 7 necessary for storing hot water in the hot water storage tank 8, the difference in pressure between the heat pump cycles can be reduced, and the energy consumption efficiency (COP) can be increased. Further, since the torque load applied to the compressor 1 is reduced, the motor efficiency of the compressor 1 can be improved. Furthermore, since the heat radiation of the shell from the compressor 1 can be reduced, energy saving in the hot water filling operation can be promoted.

  In the direct hot water filling operation, the hot water mixing valve 23 is controlled so that the temperature of hot water (hot water temperature) detected by the hot water temperature sensor 37 approaches the hot water temperature setting value, and the HP unit 7 Control the heating operation. By this control, the mixing valve 23 for the bath is supplied with low temperature water flowing from the second water supply pipe 9 b to the mixing valve 23 for bathing, medium temperature water flowing into the mixing valve 23 for bathing from the intermediate temperature pipe 79, and the hot water from the hot water supply pipe 21. The flow ratio (mixing ratio) of the three types of hot water composed of the high-temperature water flowing into the mixing valve 23 is appropriately adjusted.

  Here, the operation of the mixing valve 23 for bathing during the direct filling operation will be described. As described above, hot water flows into the bath mixing valve 23 from the hot water supply pipe 21, the intermediate temperature pipe 79, and the second water supply pipe 9b. Among these hot waters, the temperature of hot water (high temperature water) flowing from the hot water supply pipe 21 into the mixing bath 23 for hot water is higher than the temperature of hot water (cold water) flowing into the mixing valve 23 for bathing from the second water supply piping 9b. high. Moreover, the temperature of the hot water in the hot water storage tank 8 in the vicinity of the intermediate temperature outlet 8f is an intermediate temperature between the high temperature water and the low temperature water.

  Further, in the direct hot water filling operation, the temperature of the hot water boiled by the HP unit 7 is higher than the temperature of the low-temperature water supplied from the water source and higher than the temperature of the hot water stored in the upper part of the hot water storage tank 8. Low. For this reason, when the medium-temperature water led out from the medium-temperature outlet 8f and the high-temperature water boiled by the HP unit 7 merge in the medium-temperature pipe 79, the temperature of the medium-temperature water flowing from the medium-temperature pipe 79 into the mixing valve 23 for the bath. (For example, 40 ° C.) is lower than the temperature (for example, 80 ° C.) of the high-temperature water flowing from the hot water supply pipe 21 into the mixing bath 23 and the low-temperature water flowing into the mixing bath 23 from the second water supply pipe 9b. Higher than the temperature (for example, 10 ° C.).

  In the direct hot water filling operation, the first mixing mode for mixing the medium temperature water in the intermediate temperature pipe 79 and the high temperature water in the hot water supply pipe 21 is selected by controlling the bath mixing valve 23, or the intermediate temperature pipe 79 The second mixing mode for mixing the medium temperature water and the low temperature water in the second water supply pipe 9b is selected, and the temperature of the hot water flowing out from the bath mixing valve 23 toward the bathtub 30 is equal to the hot water temperature setting value. Adjust the temperature as follows. More specifically, when the water temperature of the intermediate temperature pipe 79 is lower than the hot water temperature setting value, the first mixing mode is selected. On the other hand, when the water temperature of the intermediate temperature pipe 79 is higher than the hot water temperature setting value, the second mixing mode is selected.

  In the temperature adjustment, the first and second mixing are performed based on whether or not the temperature detected by the bath temperature sensor 37 disposed on the downstream side of the bath mixing valve 23 is higher than the hot water temperature setting value. You may determine which form to select. More specifically, in the state where the first mixing mode is selected, if the detected temperature of the forward temperature sensor 37 is higher than the hot water temperature setting value, the mixing ratio of the intermediate temperature water in the intermediate temperature pipe 79 is increased, In addition, by reducing the mixing ratio of the hot water in the hot water supply pipe 21, the temperature of the hot water flowing out from the bath mixing valve 23 is lowered to approach the hot water temperature setting value. And even if the mixing ratio of the medium temperature water in the medium temperature pipe 79 is 100% by this control, if the detected temperature of the forward temperature sensor 37 is higher than the hot water temperature setting value, the hot water temperature after mixing is further increased. Switch to the second mixing mode to reduce.

  In the state where the first mixing mode is selected, when the detected temperature of the bath temperature sensor 37 is lower than the hot water filling temperature set value, the mixing ratio of the intermediate temperature water in the intermediate temperature pipe 79 is reduced, and the hot water supply pipe By increasing the mixing ratio of the hot water 21, the temperature of the hot water flowing out from the bath mixing valve 23 is increased to approach the hot water temperature setting value.

  On the other hand, in the state where the second mixing mode is selected, if the detected temperature of the forward temperature sensor 37 is higher than the hot water filling temperature set value, the mixing ratio of the intermediate temperature water in the intermediate temperature pipe 79 is reduced and the second By increasing the mixing ratio of the low-temperature water in the water supply pipe 9b, the temperature of the hot water flowing out of the mixing valve 23 for the bath is lowered to approach the hot water temperature setting value. In the state where the second mixing mode is selected, if the detected temperature of the forward temperature sensor 37 is lower than the hot water temperature setting value, the mixing ratio of the intermediate temperature water in the intermediate temperature pipe 79 is increased, and the second By lowering the mixing ratio of the low-temperature water in the water supply pipe 9b, the temperature of the hot water flowing out from the mixing valve 23 for the bath is increased to approach the hot water temperature setting value. Even when the mixing ratio of the medium temperature water in the intermediate temperature pipe 79 is set to 100% by this control, if the detected temperature of the forward temperature sensor 37 is lower than the hot water filling temperature setting value, the hot water temperature after mixing is further increased. Switch to the first mixing mode for higher.

(Normal hot water operation)
Next, a normal hot water filling operation in which only hot water stored in the hot water storage tank 8 is supplied to the bathtub 30 will be described. In the normal hot water filling operation, the first three-way valve 11 and the four-way valve 18 are held at an arbitrary opening degree, and the second three-way valve 73 is held in the ac path. As a result, the first hot water supply pipe 13a and the second hot water supply pipe 13b communicate with each other, the hot water hot water pipe 80 is closed, and the flow path toward the second hot water supply mixing valve 78 is blocked. In this state, the bath solenoid valve 26 is held in the open state. Thereby, in the normal hot water filling operation, as in the case of the direct hot water filling operation, the hot water of the hot water supply pipe 21, the intermediate temperature water of the intermediate temperature pipe 79, and the low temperature water of the second water supply pipe 9 b are mixed in the bath mixing valve 23. The bath mixing valve 23 is in a state in which these three types of hot and cold water can be mixed.

  In normal hot water filling operation, the mixing valve 23 for the bath is controlled to select one of the first and second mixing modes described above, and flows out from the bathing mixing valve 23 toward the bathtub 30 side. Adjust the temperature so that the temperature of the hot water matches the set temperature of the hot water. In this temperature adjustment, as in the case of the direct hot water filling operation, when the water temperature of the intermediate temperature pipe 79 is lower than the hot water filling temperature set value, the first mixing mode is selected. On the other hand, when the water temperature of the intermediate temperature pipe 79 is higher than the hot water temperature setting value, the second mixing mode is selected.

  In the temperature adjustment, as described as an example of the direct filling operation, the first and second mixing are performed based on whether or not the detected temperature of the bath temperature sensor 37 is higher than the filling temperature setting value. You may determine which form to select. Further, an additional hot water storage temperature sensor (not shown) is attached to the wall surface of the hot water storage tank 8 in the vicinity of the medium temperature outlet 8f, and whether or not the detected temperature of the hot water storage temperature sensor is higher than the hot water filling temperature setting value. It may be determined which of the first and second mixed forms is selected.

  The temperature of the hot water taken out from the hot water storage tank 8 to the intermediate temperature pipe 79 depends on the temperature distribution in the hot water storage tank 8. In particular, when the boundary between the high temperature water layer staying in the upper part of the hot water storage tank 8 and the low temperature water layer staying in the lower part of the hot water storage tank 8 exists in the vicinity of the intermediate temperature outlet 8f, it is taken out to the intermediate temperature pipe 79. The temperature change of the hot water increases, and the temperature adjustment by the bath mixing valve 23 may not completely absorb the temperature change. In this case, the third mixing mode is adopted in which the high temperature water of the hot water supply pipe 21 and the low temperature water of the second water supply pipe 9b are mixed without using the medium temperature water of the intermediate temperature pipe 79. The temperature may be adjusted by Moreover, in this Embodiment, the 4th mixing form which mixes all the high temperature water of the hot water supply piping 21, the intermediate temperature water of the intermediate temperature piping 79, and the low temperature water of the 2nd water supply piping 9b is employ | adopted. The temperature may be adjusted depending on the form.

(End control of direct filling operation)
Next, the termination control executed when the control unit 36 directly terminates the filling operation will be described. In the direct hot water operation, the boiling temperature by the HP unit 7 is higher than the temperature of the low temperature water from the water source and lower than the temperature of the high temperature water stored in the upper part of the hot water storage tank 8. For this reason, if the boiling operation of the HP unit 7 is continued even after the hot water filling to the bathtub 30 is completed, hot water having a low temperature flows into the upper part of the hot water storage tank 8, and the upper part of the hot water storage tank 8 is heated to a high temperature. It becomes impossible to maintain the state.

  Therefore, at the end of the direct hot water filling operation, the HP unit 7 is stopped and the boiling operation is completed, and then the bath solenoid valve 26 and the bath circulation pump 29 are stopped to complete the hot water filling operation (hot water supply operation). There is a need. Thereby, it is possible to prevent hot water having a low temperature from flowing into the upper portion of the hot water storage tank 8 and protect the temperature stratification in the hot water storage tank 8.

  As a method for detecting (or determining) completion of the hot water filling operation, for example, the following three methods are conceivable. First, in the first method, the user inputs the amount of hot water for the bathtub 30 to the remote controller 44, and the control unit 36 sets the amount of hot water detected by the flow sensor 45 for the bath to the amount of hot water input to the remote controller 44. When reaching, it is determined that the filling operation has been completed. In the second method, for example, the control unit 36 estimates the completion point of the filling operation based on the amount of filling water input to the remote controller 44, the past performance data of the filling operation performed in the past, and the like. In the third method, when the hot water filling operation is performed with hot water remaining in the bathtub 30, first, the difference between the amount of hot water input to the remote control 44 and the remaining amount of bathtub water detected by the water level sensor 46. Calculate the flow rate or time required for refilling. Then, based on this calculation result and the amount of hot water supplied by the bath flow sensor 45 during the hot water filling operation, the completion point of the hot water filling operation is determined.

  Since the amount of hot water stored in the hot water storage tank 8 is relatively small at the end of the direct hot water filling operation, if a boiling request is generated, the direct hot water of the HP unit 7 is stopped before the direct hot water filling operation is finished. After finishing the tensioning operation and shifting to the boiling operation using the heating capacity and the boiling temperature during the boiling single operation, the hot water filling operation is finished directly. Here, the direct hot water filling operation of the HP unit 7 means that the heating capacity of the HP unit 7 is controlled to a low capacity equal to or less than the heating capacity at the time of the single heating operation, and the detection temperature of the HP hot water temperature sensor 39 is set to the This is the operation to control below the tension temperature setting value. Further, in the above transition process (transition process from direct hot water operation to boiling operation operation using the heating capacity and the boiling temperature at the time of single heating operation), the first three-way valve 11 is held in the a-c path, Although the four-way valve 18 is held in the cd path, the second three-way valve 73 is switched from the state held in the bc path to the ac path.

  On the other hand, at the end of the direct hot water filling operation, the amount of hot water stored in the hot water storage tank 8 is relatively large. 7 completes the direct filling operation. Subsequently, the cooling operation of the water-refrigerant heat exchanger 3 is executed, and then the HP unit 7 and the heat source pump 12 are stopped. Here, the cooling operation is an operation for preventing the scale from adhering to the water refrigerant heat exchanger 3.

(Cooling operation of water refrigerant heat exchanger 3)
During this cooling operation, the first three-way valve 11 and the four-way valve 18 are held in the ac path. In the a-c route of the four-way valve 18, the a port and the c port are communicated, and the b port and the d port are kept closed. As a result, the HP return pipe 15 and the first bypass pipe 16 communicate with each other, the first hot water supply pipe 13a and the second bypass pipe 17 are closed, and the flow path toward the upper portion of the hot water storage tank 8 is blocked. The second three-way valve 73 is held in the ac path or the bc path. Thereby, in the cooling operation, even when unexpected hot water is supplied to the hot water tap 34 located at the end of the first hot water supply pipe 24, it is possible to suppress a sudden change in the pressure of the second hot water supply pipe 13b. . Further, since the temperature adjustment by the first hot water supply mixing valve 22 or the second hot water supply mixing valve 78 is delayed, it is possible to reduce the occurrence of hot water temperature hunting in the hot water tap 34.

[Specific Control Example According to Embodiment 1]
Next, with reference to FIG. 4, the control at the time of filling operation will be described. FIG. 4 is a flowchart showing an example of control during the filling operation in the first embodiment of the present invention. In the routine shown in this figure, first, in step S1, it is determined whether or not the filling operation is started, for example, by determining whether or not the start operation of the filling operation is performed by the remote controller 44. When the determination in step S1 is established, the process proceeds to step S2. On the other hand, if the determination in step S1 is not established, this routine ends. Next, in step S2, it is determined whether direct hot water operation is possible. If this determination is established, the process proceeds to step S3. On the other hand, if the determination in step S2 is not established, the process proceeds to step S10 described later.

  In step S3, a direct filling operation is executed. Subsequently, in step S4, it is determined whether or not it is immediately before the end of the direct filling operation. If this determination is established, the process proceeds to step S5. On the other hand, if the determination in step S4 is not satisfied, the process waits until the determination is satisfied. Next, in step S5, it is determined whether there is a boiling request. If the determination in step S5 is satisfied, the normal boiling operation is performed in step S7 after the direct filling operation is terminated in step S6. If the determination in step S5 is not satisfied, the cooling operation of the water-refrigerant heat exchanger 3 is executed in step S9 after the hot water filling operation is directly terminated in step S8.

  On the other hand, in step S10, the normal hot water filling operation is started. Subsequently, in step S11, it is determined whether or not it is immediately before the end of the direct filling operation. If this determination is established, the routine proceeds to step S12 and the normal filling operation is ended. If the determination in step S11 is not satisfied, the process waits until the determination is satisfied.

  Next, with reference to FIG. 5, the control of the mixing valve 23 for bathing during the filling operation will be described. FIG. 5 is a flowchart showing a control example of the mixing valve for bathing during the filling operation in the first embodiment of the present invention. In the routine shown in this figure, first, in step S1, it is determined whether or not the direct filling operation is being performed. If this determination is established, the process proceeds to step S2. On the other hand, if the determination in step S1 is not established, this routine ends. Next, in Step S <b> 2, it is determined whether or not the first mixing mode in which the middle temperature water in the middle temperature pipe 79 and the high temperature water in the hot water supply pipe 21 are mixed is performed by the bath mixing valve 23. If the determination in step S2 is established, the process proceeds to step S3. On the other hand, if the determination in step S2 is not established, the process proceeds to step S9 described later.

  Next, in step S3, it is determined whether or not the temperature detected by the bath temperature sensor 37 (the bath temperature) is higher than a set temperature (a hot water temperature setting value). When the determination in step S3 is established, the process proceeds to step S4, where the mixing ratio of the medium temperature water in the intermediate temperature pipe 79 is increased and the mixing ratio of the hot water in the hot water supply pipe 21 is decreased. Subsequently, in step S5, it is determined whether or not the mixing ratio of the medium-temperature water in the medium-temperature pipe 79 is 100%. If this determination is established, the bath mixing valve 23 is controlled in step S6. A second mixing mode is selected that mixes the medium temperature water in the medium temperature pipe 79 and the low temperature water in the second water supply pipe 9b. If the determination in step S5 is not established, step S6 is not executed and the process proceeds to step S7.

  In step S7, it is determined whether or not the direct filling operation is to be terminated. If this determination is established, the direct filling operation is terminated. If the determination in step S7 is not established, the process returns to step S2, and the processes after step S2 are repeated. If the determination in step S3 is not established, the process proceeds to step S8, where the mixing ratio of the medium temperature water in the intermediate temperature pipe 79 is lowered and the mixing ratio of the hot water in the hot water supply pipe 21 is increased.

  On the other hand, in step S9, it is determined whether or not the bathing temperature is lower than the set temperature. When the determination in step S9 is established, the process proceeds to step S10, where the mixing ratio of the medium temperature water in the intermediate temperature pipe 79 is increased and the mixing ratio of the low temperature water in the second water supply pipe 9b is decreased. Subsequently, in step S11, it is determined whether or not the mixing ratio of the medium-temperature water in the medium-temperature pipe 79 is 100%. If this determination is established, the first mixing valve 23 is used for the first in step S12. Select a mixed form. On the other hand, if the determination in step S11 is not established, the process proceeds to step S7 without executing step S12. On the other hand, if the determination in step S9 is not established, the process proceeds to step S13, where the mixing ratio of the medium temperature water in the intermediate temperature pipe 79 is lowered and the mixing ratio of the low temperature water in the second water supply pipe 9b is increased.

  As described above in detail, in the present embodiment, when the hot water filling operation is performed directly, the hot water of the hot water supply pipe 21, the intermediate temperature water of the intermediate temperature pipe 79, and the second water supply pipe are used using the bath mixing valve 23. It is set as the structure which mixes at least 2 types of hot water among 3 types consisting of the low temperature water of 9b, and supplies the hot water to the bathtub 30 with the intermediate temperature water produced | generated by this. Further, in the direct hot water operation, a configuration in which only the high temperature water in the hot water supply pipe 21 and the low temperature water in the second water supply pipe 9b are mixed is not used. Therefore, according to the present embodiment, it is avoided that the hot water source during hot water filling operation is limited to only one of the HP unit 7 and the hot water storage tank 8, and two types of hot water selected according to the situation are supplied during hot water supply. Can be mixed at an appropriate ratio to improve the efficiency. Thereby, hot water filling operation with high energy efficiency is realizable.

  Moreover, in the present embodiment, in the direct hot water filling operation, the warm water heated by the HP unit 7 and the warm water taken out from the warm temperature outlet 8f of the hot water storage tank 8 are preliminarily joined by the warm temperature pipe 79. The intermediate temperature water generated in the pipe 79 is supplied to the mixing valve 23 for bathing. According to this configuration, the hot water supply from the HP unit 7 and the hot water in the hot water storage tank 8 are both used to achieve high efficiency hot water supply, and the inflow port of the mixing valve 23 for bathing is suppressed to three. And the system configuration can be simplified.

  In the first embodiment, step S3 in FIG. 4 and FIG. 5 show specific examples of the hot water filling control means and the hot water supply temperature control means. Moreover, although the bathtub 30 was illustrated as hot water supply object in Embodiment 1, this invention is not restricted to this, It is good also considering faucets, such as a shower and a currant, and a hot water heater.

DESCRIPTION OF SYMBOLS 1 Compressor, 3 Water refrigerant heat exchanger, 4 Expansion valve, 5 Refrigerant piping, 6 Air heat exchanger, 7 HP unit (heat pump heating means), 8 Hot water storage tank, 8a Water inlet, 8c Hot water inlet, 8d Hot water Inlet, 8e Hot water outlet, 8f Medium temperature outlet, 9 Water supply pipe, 9a First water supply pipe, 9b Second water supply pipe, 9c Third water supply pipe, 10 Water outlet pipe, 11 First three-way valve, 12 Heat source pump , 13a First hot water supply pipe, 13b Second hot water supply pipe, 14 HP outgoing pipe, 15 HP return pipe, 16 First bypass pipe, 17 Second bypass pipe, 18 Four-way valve, 20a Hot water introduction pipe, 20b Hot water outlet pipe 20 Heater for bathing, 21 Hot water supply piping (high temperature hot water piping), 22 Mixing valve for first hot water supply, 23 Mixing valve for bathing (mixing valve), 24 First hot water supply piping, 25 Second hot water distribution 26 Solenoid valve, 27 Back piping, 28 Back return piping, 29 Bath circulation pump, 30 Bathtub (object for hot water supply), 31 Pressure reducing valve, 33 Tank unit, 34 Hot water tap, 35 Hot water storage heat pump water heater, 36 Control , 37 bath temperature sensor (hot water supply temperature detection means), 38 bath return temperature sensor, 39 HP hot water temperature sensor, 42, 43 hot water storage temperature sensor, 44 remote control (hot water temperature setting means), 45 bath flow sensor, 46 water level Sensor, 47 Flow switch, 73 Second three-way valve (switching valve), 78 Second mixing valve for hot water supply, 79 Medium temperature pipe (medium temperature hot water supply pipe, merge pipe), 80 Hot water supply pipe

Claims (4)

A hot water storage tank for storing hot water,
A water supply pipe for supplying low-temperature water from a water source to the lower part of the hot water storage tank;
A high temperature hot water supply pipe for taking out hot water from the upper part of the hot water storage tank;
A medium-temperature hot-water supply pipe for extracting hot water from an intermediate portion in the vertical direction of the hot water storage tank;
A heat pump heating means for heating hot water supplied from a lower part of the hot water storage tank or the water supply pipe by a heat pump cycle;
A merging pipe for joining the hot water heated by the heat pump heating means and the hot water taken out by the medium temperature hot water pipe;
A mixing valve for mixing hot water supplied from at least two of the high-temperature hot water piping, the merging pipe and the water supply pipe, and supplying the mixed hot water to a hot water supply target;
Hot water storage heat pump water heater equipped with. A switching valve for switching the supply destination of hot water heated by the heat pump heating means to either the upper part of the hot water storage tank or the junction pipe;
When supplying hot water to the hot water supply object, the hot pump heating means is operated, and the hot water filling control means for switching the supply destination of the hot water to the junction pipe by the switching valve;
The hot water storage type heat pump water heater according to claim 1, comprising: A hot water supply temperature setting means for setting a temperature target value of hot water to be supplied to the hot water supply object as a target hot water supply temperature;
Hot water supply temperature detecting means for detecting the temperature of hot water supplied to the hot water supply object from the mixing valve;
The mixing valve is controlled so that the temperature detected by the hot water supply temperature detection means approaches the target hot water supply temperature, and the flow rate of hot water supplied from at least two of the high temperature hot water supply pipe, the junction pipe and the water supply pipe Hot water temperature control means for adjusting the ratio;
A hot water storage type heat pump water heater according to claim 1 or 2, further comprising:   The hot water storage type heat pump water heater according to any one of claims 1 to 3, wherein the heat pump heating means is stopped before the hot water supply to the hot water supply object is finished.

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