JP2011027320A - Storage water heater - Google Patents

Abstract

[PROBLEMS] To provide a hot water storage type hot water heater capable of rewarming bathtub water without generating medium temperature water in a hot water storage tank while reliably preventing a drop in the water level of the bathtub.
A hot water storage type water heater 10 using a heat pump unit 18 is provided. A reheating heat exchanger 68 for exchanging heat between the bath water and the tank water is provided. A drain pipe 72 connected in the middle of the bathtub water circulation circuit 58 is provided. A switching valve 64 and a four-way valve 82 for switching the bath water channel form are provided. When a request to reheat the bathtub water is detected, the hot water supply is started so that the tank hot water is supplied to the bathtub 12, and at the same time, the bathtub water flow path is drained from the bathtub water circulation circuit 58 via the drain pipe 72. Switch form. Moreover, when the said request | requirement is detected, the bath circulation pump 60 is controlled so that the amount of hot water supplied to the bathtub 12 and the drainage amount of the bathtub water through the drain pipe 72 may become equal.
[Selection] Figure 1

Description

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

  As a conventional hot water storage heat pump water heater, a three-way valve that switches between circulation and drainage is provided in the bath circulation circuit, and when bathing is performed, the three-way valve is first switched to the drainage side, and the bathtub water is drained. There is a hot water storage tank that uses hot water in the bathtub. According to such a configuration, when performing bathing, heat exchange between the hot water in the hot water storage tank and the bath water is not performed, so the temperature of the hot water in the hot water storage tank is not lowered (that is, in the hot water storage tank). The bath water can be reheated (without generating intermediate temperature water at about 60 ° C.). Thereby, when boiling the hot water in the hot water storage tank, operation of a highly efficient heat pump can be ensured (see, for example, Patent Document 1).

JP 2005-147500 A JP-A-2003-06642 JP-A-6-50602

  However, in the above conventional method, the bath water is once drained when reheating. For this reason, there has been a problem that the water level of the bathtub is temporarily lowered but the user's anxiety is induced.

  The present invention has been made to solve the above-described problems, and is capable of reheating the bathtub water without generating intermediate temperature water in the hot water storage tank while reliably preventing a decrease in the water level of the bathtub. An object is to provide a hot water heater.

  A hot water storage type hot water supply apparatus according to the present invention includes a hot water storage tank for storing hot water supplied to a bathtub, heating means for heating water in the hot water storage tank, and hot water supply for supplying tank hot water stored in the hot water storage tank to the bathtub. And a bath water circulation circuit that has a bath water circulation circuit connected to the bathtub, circulates the bath water in the bathtub, and a tank hot water circulation circuit that connects between the upper part of the hot water storage tank and the lower part of the hot water storage tank A tank hot water circulation means for circulating the tank hot water coming out from the upper part of the hot water storage tank to the lower part of the hot water storage tank, and a heat exchanger for exchanging heat between the bathtub water flowing in the bathtub water circulation circuit and the tank hot water flowing in the tank hot water circulation circuit; A drainage channel connected in the middle of the bathtub water circulation circuit, a first channel configuration for returning to the bathtub as it is through the bathtub water circulation circuit, and a drainage channel from the bathtub water circulation circuit through the bathtub water circulation circuit When the flow path switching means capable of selecting the second flow path configuration to be drained, the temperature increase request detection means for detecting the presence or absence of a request to reheat the bath water, and the request to reheat the bath water are detected, When controlling the hot water supply means so that the tank hot water is supplied to the bathtub, and simultaneously detecting a control means for controlling the flow path switching means so that the second flow path configuration is selected, and a request to reheat the bathtub water And adjusting means for adjusting at least one of the amount of hot water and the amount of drainage so that the amount of hot water supplied to the bathtub by the hot water supply unit and the amount of drainage of the bathtub water through the drainage channel are equal to each other. is there.

  According to this invention, it becomes possible to reheat the bathtub water without generating medium-temperature water in the hot water storage tank while reliably preventing a drop in the water level of the bathtub.

It is the schematic which shows the whole structure of the hot water storage type water heater in Embodiment 1 of this invention. It is a figure for demonstrating the two flow-path forms implement | achieved by the four-way valve shown in FIG. It is a figure which shows the control state of the flow path at the time of each operation | movement of a hot water storage type water heater. It is a flowchart showing the routine performed in Embodiment 1 of this invention. It is a figure for demonstrating the flow path of the bath water and tank hot water at the time of normal chasing operation | movement. It is a figure for demonstrating the flow path of the bathtub water at the time of bathtub water temperature rising operation, and a tank hot water. It is the schematic which shows the structure of the modification of Embodiment 1 of this invention. It is the schematic which shows the structure of the other modification of Embodiment 1 of this invention.

  A mode for carrying out the invention will be described with reference to the accompanying drawings. In the drawings, the same or corresponding parts are denoted by the same reference numerals, and the description thereof is simplified or omitted as appropriate.

Embodiment 1 FIG.
FIG. 1 is a schematic diagram showing an overall configuration of a hot water storage type water heater 10 according to Embodiment 1 of the present invention.
A hot water storage type water heater 10 shown in FIG. 1 includes a hot water storage tank unit 16 including a hot water storage tank 14 for storing hot water supplied to a bathtub 12. The hot water storage type water heater 10 includes a heat pump unit 18 having a refrigeration cycle as a heating means for heating (boiling) water in the hot water storage tank 14.

  The heat pump unit 18 includes a refrigerant circuit 28 configured by sequentially connecting a compressor 20, a water refrigerant heat exchanger 22, an expansion valve 24, and an air heat exchanger 26 in an annular manner. The water-refrigerant heat exchanger 22 is for exchanging heat between the water in the hot water storage tank 14 and the refrigerant in the refrigerant circuit 28, and functions as a condenser. The air heat exchanger 26 is for exchanging heat between air and the refrigerant, and functions as an evaporator.

  The hot water storage tank unit 16 includes a hot water storage tank boiling circuit (hereinafter simply referred to as “boiling circuit”) 30 for boiling water in the hot water storage tank 14 using the heat pump unit 18. Specifically, the boiling circuit 30 includes a first heat pump pipe 32 that connects the lower part (more specifically, the bottom part) of the hot water storage tank 14 and the water refrigerant heat exchanger 22, the water refrigerant heat exchanger 22, and the hot water storage. A second heat pump pipe 34 that connects the upper part (more specifically, the top part) of the tank 14 is provided. In the boiling circuit 30, a heat pump circulation pump 36 is installed in the middle of the first heat pump pipe 32. The heat pump circulation pump 36 is a pump for circulating water from the lower part of the hot water storage tank 14 to the upper part of the hot water storage tank 14 after passing through the water refrigerant heat exchanger 22.

  In addition, a water supply pipe 38 for supplying water from a water supply source (not shown) is connected to the lower part (more specifically, the bottom part) of the hot water storage tank 14. More specifically, a pressure reducing valve 40 is installed in the middle of the water supply pipe 38, and water that has been reduced to an appropriate pressure by the pressure reducing valve 40 is supplied to the hot water storage tank 14. . The hot water storage tank 14 is always maintained in a full water state by replenishing water through the water supply pipe 38 during hot water supply.

  On the other hand, one end of a hot water supply pipe 42 through which high-temperature water (hereinafter sometimes referred to as “tank hot water”) from the hot water storage tank 14 flows is connected to the upper portion (more specifically, the top portion) of the hot water storage tank 14. Yes. The other end of the hot water supply pipe 42 is joined to the other end of the water supply branch pipe 44 branched from the water supply pipe 38 on the downstream side of the pressure reducing valve 40 via a mixing valve 46 that is a three-way valve. The mixing valve 46 is controlled by a control unit 86 to be described later, thereby adjusting the mixing ratio of the tank hot water supplied from the hot water supply pipe 42 and the water supplied from the water supply branch pipe 44 at an arbitrary ratio. The hot water is discharged to the mixed hot water pipe 48.

  One end of a mixed hot water pipe 48 through which mixed hot water of tank water and water flows is connected to the outlet of the mixing valve 46. An electromagnetic valve 50 responsible for opening and closing the flow path of the mixed hot water pipe 48 and a first flow sensor 52 for detecting the flow rate of the mixed hot water flowing through the mixed hot water pipe 48 are installed in the middle of the mixed hot water pipe 48. Has been. In addition, the mixed hot water pipe 48 is bifurcated at the other end as a bath outlet pipe 54 and a bath return pipe 56. The other ends of the bath outlet pipe 54 and the bath return pipe 56 are connected to the bathtub 12, respectively.

  According to the bath outlet pipe 54 and the bath return pipe 56, the control unit 86, which will be described later, controls the switching valve 64 and the four-way valve 82 to circulate water in the bathtub 12 (tub water). A circuit 58 can be formed. A bath circulation pump 60 and a second flow rate sensor 62 are installed in order from the side closer to the bathtub 12 in the middle of the bath outlet pipe 54. When the bath circulation pump 60 is operated in a state where the bathtub water circulation circuit 58 is formed, the bath water is discharged from the bathtub 12 to the bath outlet pipe 54 and then returned to the bathtub 12 again through the bath return pipe 56. It is configured to be able to. The second flow rate sensor 62 is a sensor for detecting the flow rate of water flowing through the bath outlet pipe 54.

  Further, in the middle of the bath return pipe 56, a switching valve 64 that is a three-way valve, a first temperature sensor 66, a reheating heat exchanger 68, and a second temperature are sequentially arranged from the side close to the branch point with the bath outlet pipe 54. Each sensor 70 is installed. A drain pipe 72 for discharging bathtub water to the outside is connected to the remaining port of the switching valve 64.

  The switching valve 64 has a communication state FH (a state where the mixed hot water pipe 48 and the bath outlet pipe 54 and the bath return pipe 56 communicate) and a communication state FG (a bath return pipe 56 and a drain pipe 72 shown in FIG. Is a valve that switches between the two). The reheating heat exchanger 68 is for exchanging heat between the bath water flowing in the bath return pipe 56 and the tank hot water in the hot water storage tank 14. The first temperature sensor 66 and the second temperature sensor 70 are sensors for detecting the temperature of water in the bath return pipe 56 upstream and downstream of the reheating heat exchanger 68.

  The hot water storage tank unit 16 further includes a tank hot water circulation circuit 74 that connects the upper part (more specifically, the upper part of the side surface) of the hot water storage tank 14 and the lower part (more specifically, the lower part of the side surface) of the hot water storage tank 14. . Specifically, the tank hot water circulation circuit 74 connects the first reheating pipe 76 that connects the upper part of the hot water storage tank 14 and the reheating heat exchanger 68, and the reheating heat exchanger 68 and the lower part of the hot water storage tank 14. A second reheating pipe 78 to be connected is provided. Further, a tank-side circulation pump 80 is disposed in the tank hot water circulation circuit 74 in the middle of the second reheating pipe 78. The tank-side circulation pump 80 is a pump for recirculating tank hot water coming out from the upper part of the hot water storage tank 14 to the lower part of the hot water storage tank 14 after passing through the heat exchanger 68.

  Further, as shown in FIG. 1, the hot water storage tank unit 16 is located in a portion farther from the bathtub 12 than the second flow rate sensor 62 in the bath outlet pipe 54 and in the bathtub 12 than in the reheating heat exchanger 68 in the bath return pipe 56. A four-way valve 82 is provided to be interposed between the adjacent parts. The four-way valve 82 is an electromagnetic solenoid type valve and includes four ports P1, A1, E1, and B1. The port P1 is connected to the non-tub side portion of the bath outlet pipe 54, the port A1 is connected to the bathtub side portion of the bath outlet pipe 54, and the port E1 is connected to the non-tub side portion of the bath return pipe 56. The port B <b> 1 is connected to a bathtub-side portion of the bath return pipe 56.

  FIG. 2 is a view for explaining two flow path forms realized by the four-way valve 82 shown in FIG. More specifically, FIG. 2 (A) shows a flow path configuration when energization to the solenoid included in the four-way valve 82 is turned off (normal time). That is, at the time of the control shown in FIG. 2 (A), the port P1 and the port A1 are in communication (the non-tub side and the bathtub side of the bath outlet pipe 54 are in communication), and the port E1 and the port A1 are connected. B1 is in a communication state (a state where the non-tub side and the bathtub side of the bath return pipe 56 are in communication).

  On the other hand, FIG. 2 (B) shows a flow path configuration when energization of the solenoid is turned on (at the time of a bath water temperature raising operation using a hot water supply to be described later). That is, at the time of the control shown in FIG. 2 (B), the port P1 and the port B1 are in communication with each other (the state in which the non-tub side of the bath outlet pipe 54 and the bathtub side of the bath return pipe 56 are in communication). The port A1 and the port E1 are in communication with each other (the bath side of the bath going-out piping 54 and the non-tub side of the bath return piping 56 are in communication). According to such a configuration, by switching the energization of the four-way valve 82, it is possible to reverse the direction of the bath water flow toward the reheating heat exchanger when the bath circulation pump 60 is driven.

  Further, as shown in FIG. 1, the hot water storage tank unit 16 generates micro bubbles for mixing in the bathtub water flowing through the part at the part between the port A1 and the second flow rate sensor 62 in the bath outlet pipe 54. A microbubble generator 84 is installed. More specifically, the microbubble generator 84 controls the flow of the bath water with respect to the reheating heat exchanger 68 when the flow path configuration shown in FIG. 2B is selected by the control of the four-way valve 82. It is arranged at a site on the upstream side.

  The system shown in FIG. 1 includes a control unit 86 that comprehensively controls the hot water storage type water heater 10. Various sensors for detecting the operation state of the hot water storage hot water heater 10 such as the flow rate sensors 52 and 62 and the temperature sensors 66 and 70 described above are electrically connected to the input of the control unit 86. Further, the output of the control unit 86 includes the heat pump unit 18, the heat pump circulation pump 36, the mixing valve 46, the electromagnetic valve 50, the bath circulation pump 60, the switching valve 64, the tank side circulation pump 80, the four-way valve 82, and Various actuators for controlling the hot water storage type water heater 10 such as the microbubble generator 84 are electrically connected. The control unit 86 is electrically connected to an operation unit 88 that receives requests from a user who uses the bathtub 12 (for example, a hot water filling instruction and a chasing instruction).

Next, various operations of the hot water storage type water heater 10 having the above-described configuration will be described with reference to FIGS. 3 to 6 as appropriate.
(Boiling operation)
The boiling operation here is an operation in which the water supplied to the hot water storage tank 14 is heated using the heat pump unit 18 to raise the entire water in the hot water storage tank 14 to a predetermined temperature. When a predetermined condition for performing the boiling operation is established, the heat pump unit 18 is driven while the heat pump circulation pump 36 of the control unit 86 is driven. Thereby, in the water-refrigerant heat exchanger 22, the water flowing out from the lower portion of the hot water storage tank 14 and flowing through the boiling circuit 30 is heated by exchanging heat with the high-temperature refrigerant gas compressed by the compressor 20. It is returned to the upper part of the hot water storage tank 14. In the boiling operation, the above operation is performed until the temperature of the water in the hot water storage tank 14 reaches the predetermined temperature using a temperature sensor (not shown), so that the water in the hot water storage tank 14 is heated. .

(Water filling operation)
Next, a hot water filling operation for filling hot water in the bathtub 12 will be described.
FIG. 3 is a diagram illustrating a control state of the flow path during each operation of the hot water storage type water heater 10.
When a hot water filling instruction is issued from the user via the operation unit 88, the switching valve 64 is controlled so as to be in the communication state F-H, and the power supply to the four-way valve 82 is turned off (port In a state where P1 and port A1, and port E1 and port B1 communicate with each other), the solenoid valve 50 is opened. As a result, the high-temperature tank hot water flowing out of the hot water storage tank 14 and flowing through the hot water supply pipe 42 is mixed with the water supplied from the water supply branch pipe 44 when passing through the mixing valve 46 and then introduced into the mixed hot water pipe 48. The The mixed hot water introduced into the mixed hot water piping 48 is supplied to the bathtub 12 through both the bath going-out piping 54 and the bath return piping 56 as shown in FIG.

  During the hot water filling operation, the temperature of the mixed hot water supplied to the bathtub 12 is indicated based on the temperature of the mixed hot water detected using the first temperature sensor 66 or the second temperature sensor 70 installed in the bath return pipe 56. The opening degree of the mixing valve 46 is adjusted so as to achieve the adjusted temperature. Further, the amount of filling during the filling operation is detected using the first flow sensor 52. When the amount of hot water detected in this way reaches the specified hot water amount, the solenoid valve 50 is closed and the hot water filling operation is completed.

(Reluctant movement)
The system of the hot water storage type water heater 10 of the present embodiment is characterized by control when a request to reheat the bath water (refreshing request) is issued. FIG. 4 is a flowchart showing a control routine executed by the control unit 86 when such a request is issued.

  In the routine shown in FIG. 4, first, the operation of the bath circulation pump 60 is executed, and the bath temperature (the temperature of the bath water) is detected using the first temperature sensor 66 or the second temperature sensor 70 (step S1). ). In this case, the energization to the four-way valve 82 is OFF, and the switching valve 64 is controlled so as to be in the communication state FH shown in FIG. 1, so that the bathtub water circulation circuit 58 is formed. It is in a state. For this reason, when the operation of the bath circulation pump 60 is executed in this state, the bath water can be circulated through the bath water circulation circuit 58 and the bath temperature can be detected.

  Next, based on the bath temperature detected in step S1, it is determined whether or not the difference between the bath setting temperature at the time of reheating request and the current bath temperature is greater than a predetermined value (for example, 5 ° C.). (Step S2). As a result, when the determination of step S2 is not established, that is, when the difference between the bath set temperature and the current bath temperature is equal to or less than a predetermined value, the normal reheating operation shown in steps S3 to S5 below. Is executed.

In the normal reheating operation, first, the control of the bath circulation pump 60 is executed, and the operation of the tank side circulation pump 80 is executed (step S3).
FIG. 5 is a diagram for explaining the flow paths of bathtub water and tank hot water during a normal chase operation. In FIG. 5, a flow path used during a normal reheating operation is indicated by a thick line.

  In this step S3, the bath water pump 60 is operated in a state where the bath water circulation circuit 58 is formed, so that the bath water led from the bath 12 to the bath outlet pipe 54 as shown in FIG. Is returned to the bathtub 12 through the bath return pipe 56. Then, when the bathtub water passes through the bath return pipe 56, the bathtub water is warmed by exchanging heat with the tank hot water circulating in the tank hot water circulation circuit 74 in the reheating heat exchanger 68. At this time, based on the temperature detection value by the second temperature sensor 70, the tank so that the bath water after passing through the reheating heat exchanger 68 becomes a predetermined temperature (for example, 5 ° C.) higher than the bath set temperature. The rotational speed of the side circulation pump 80 is controlled.

  Next, it is determined whether or not the bath temperature has reached the bath target temperature (that is, the bath set temperature) (step S4). As a result, while the temperature detection value by the first temperature sensor 66 has not yet reached the bath target temperature, the process of step S3 is continuously executed. The operations of the pump 60 and the tank side circulation pump 80 are stopped (step S5). As a result, the normal chasing operation ends.

  On the other hand, when the determination of the above step S2 is established, that is, when the difference between the bath set temperature and the current bath temperature is larger than the predetermined value, the hot water supply shown in the following steps S6 to S10 is used. The “tub water temperature raising operation” is performed.

  In this bath water temperature raising operation, first, the energization to the solenoid is turned ON, whereby the flow channel forms (port P1 and port B1, port E1 and port A1 are respectively connected to each other) shown in FIG. ), The four-way valve 82 is switched (step S6). After that, the electromagnetic valve 50 is opened, the switching valve 64 is switched to the drain side, the bath circulation pump 60 is controlled, and the microbubble generator 84 is activated (step S7). Hereinafter, it will be described in more detail with reference to FIG. During the bath water temperature raising operation, the circulation of the tank hot water in the tank hot water circulation circuit 74 by the operation of the tank side circulation pump 80 is not executed.

FIG. 6 is a diagram for explaining the flow paths of the bath water and tank hot water during the bath water temperature raising operation. In addition, in FIG. 6, the flow path of the bathtub water (drainage) and the tank hot water (mixed hot water) at the time of bathtub water temperature rising operation is shown by the very thick line and the thick line, respectively.
According to the process of this step S7, supply of the tank hot water from the hot water storage tank 14 to the bathtub 12 is performed by opening the solenoid valve 50. More specifically, the hot water from the upper part of the hot water storage tank 14 is mixed with water when passing through the mixing valve 46 and then returned to the bath from the bath outlet pipe 54 via the four-way valve 82 as shown in FIG. After being sent to the pipe 56, it is supplied to the bathtub 12. That is, hot hot water using hot water having a temperature higher than the bath set temperature is executed. Here, the hot water supplied to the bathtub 12 is not necessarily limited to the mixed hot water mixed with water when passing through the mixing valve 46, and when the difference between the bath set temperature and the bath temperature is large, the mixing valve The hot water supply hot water supply may be performed only with tank hot water by controlling the opening degree on the hot water supply pipe 42 side in 46 to be fully open and controlling the opening degree on the water supply branch pipe 44 side to be fully closed.

  Further, in this step S7, the switching valve 64 is set so as to be in a communication state FG (a state in which the bath return pipe 56 and the drain pipe 72 are in communication) simultaneously with the execution of the high temperature hot water by opening the electromagnetic valve 50. Can be switched. Thereby, as shown in FIG. 6, after the bath water that has come out of the bathtub 12 through the bath outlet pipe 54 is introduced into the bath return pipe 56 through the four-way valve 82 and passes through the reheating heat exchanger 68. It is discharged to the outside through the drain pipe 72.

  Furthermore, in this step S <b> 7, the amount of drainage at the time of draining the bathtub water performed as described above is controlled by the bath circulation pump 60. More specifically, the amount of hot water (mixed hot water or tank hot water) supplied to the bathtub 12 and the bath water discharged from the bathtub 12 based on the flow rate detection values by the first flow sensor 52 and the second flow sensor 62. The rotation speed of the bath circulation pump 60 is controlled so that the amount of drainage becomes equal.

  Furthermore, in this step S7, the operation of the microbubble generator 84 is executed, whereby a process of mixing microbubbles in the bath water discharged from the bath 12 is performed. As a result, the mixed microbubbles are supplied from the bath outlet pipe 54 to the bath return pipe 56 including the reheating heat exchanger 68.

  Next, it is determined whether or not the bath temperature has reached the bath target temperature (the bath set temperature) (step S8). As a result, while the temperature detection value by the first temperature sensor 66 has not yet reached the bath target temperature, the process of step S7 is continuously executed. 50, the switching of the switching valve 64 to the normal side, the stop of the bath circulation pump 60, and the stop of the microbubble generator 84 are respectively executed (step S9). Further, by turning off the energization to the solenoid, the control state of the four-way valve 82 is returned to the normal state (port P1 and port A1, and port E1 and port B1 are in communication with each other) (step S10). . Thereby, bathtub water temperature rising operation is complete | finished.

  According to the routine shown in FIG. 4 described above, when a request to reheat the bath water is issued, if the difference between the bath set temperature and the current bath temperature is greater than a predetermined value, Instead of the normal reheating operation of the bath water using heat exchange with the bath water, the above bath water temperature raising operation for performing the hot water hot water and the drainage of the bath water is executed.

According to the above bath water temperature raising operation, heat exchange between the bath water and the tank hot water is not performed, so that the tank hot water cooled by the heat exchange with the bath water does not return to the lower part of the hot water storage tank 14. For this reason, when the cold tank hot water returns to the hot water storage tank 14, the mixed layer existing at the boundary between the upper hot water layer and the lower aqueous water layer in the hot water storage tank 14 is disturbed, and intermediate hot water is generated. It can be avoided.
Moreover, according to said bathtub water temperature rising operation, drainage of bathtub water is performed by switching the switching valve 64 to the waste_water | drain side simultaneously with execution of the high temperature hot water by opening of the solenoid valve 50. Furthermore, at this time, the amount of drainage is adjusted by controlling the number of revolutions of the bath circulation pump 60 so that the amount of hot water supplied to the bathtub 12 and the amount of drainage of bathtub water discharged from the bathtub 12 become equal. For this reason, it is possible to reheat the bathtub water without temporarily lowering the water level of the bathtub 12.
As described above, according to the control of the present embodiment, it is possible to reheat the bathtub water without generating intermediate temperature water in the hot water storage tank 14 while reliably preventing the water level of the bathtub 12 from being lowered. Moreover, a user's anxiety is not induced by being able to prevent the water level fall of the bathtub 12 reliably.

  Moreover, in this embodiment, said bathtub water temperature rising operation is applied with respect to the hot water storage type water heater 10 which is a heat pump water heater using the heat pump unit 18 as a heating means. In the heat pump water heater, if medium temperature water is generated in the hot water storage tank 14 due to the above-mentioned cause, when the water in the hot water storage tank 14 is again heated using the heat pump unit 18, the hot water storage tank 14 passes through the water supply pipe 38. Boiling of the medium temperature water having a temperature higher than that of the low temperature water supplied to the water is performed. As a result, the equipment efficiency of the heat pump is reduced. On the other hand, according to the method of the present embodiment that does not generate intermediate temperature water, when warming the bathtub water, the intermediate temperature water is not generated in the hot water storage tank 14 while reliably preventing the water level of the bathtub 12 from being lowered. In addition, a highly efficient heat pump water heater can be realized.

  Further, as described above, the bathtub water temperature raising operation is executed instead of the normal reheating operation when the difference between the bath set temperature and the current bath temperature is larger than a predetermined value. When this difference is small, even if a bath water reheating operation using high-temperature tank hot water is performed, the temperature drop of the tank hot water accompanying heat exchange with the bath water is small. Hot water is less likely to be generated. In the control of the present embodiment, when the bathtub water discharge operation with the drainage of the bathtub water is performed only when the difference is large, a request for reheating the bathtub water from the user is issued. Compared with the case where the bathtub water temperature rising operation is always performed, it is possible to satisfactorily meet the user's request while minimizing the opportunity for draining the bathtub water.

  Further, the system of the present embodiment drains the bath water in the middle of the bath outlet pipe 54 (more specifically, the bath water temperature rising operation), which becomes a flow path for draining the bath water during the bath water temperature rising operation. A microbubble generator 84 that mixes microbubbles in the bathtub water (drainage) is installed at a location upstream of the reheating heat exchanger 68 in the flow path. According to such a configuration, the hot water supply to the bathtub 12 is performed, and the drainage containing the microbubbles is used to clean the piping such as the bath outlet pipe 54 and the bath return pipe 56 and the reheating heat exchanger 68. can do. Thereby, drainage can be used effectively.

  Furthermore, in the system according to the present embodiment, the bath water heading toward the reheating heat exchanger 68 during the bath water temperature rising operation is different from the direction of the bath water flow toward the reheating heat exchanger 68 during the normal reheating operation. A four-way valve 82 for switching the flow path is provided so that the flow direction is reversed. At the time of normal cleaning using microbubbles, a flow path during normal reheating operation using the bathtub water circulation circuit 58 is used. In addition, at the time of the bathtub water temperature raising operation, the reheating heat exchanger 68 is washed while flowing the bathtub water containing microbubbles in the direction opposite to the flow path. As a result, the cleaning effect can be sufficiently enhanced.

  Moreover, in the system of this embodiment, the bath water pump 60 for circulating the bath water in the bath water circulation circuit 58 is used during the normal reheating operation, and is supplied to the bath 12 during the bath water temperature raising operation. It can control so that the amount of hot water and the amount of drainage of the bathtub water discharged | emitted from the bathtub 12 may become equal.

  By the way, in Embodiment 1 mentioned above, at the time of the said bath water temperature rising operation, the rotation speed of the bath circulation pump 60 is controlled based on the flow rate detection value by the 1st flow sensor 52 and the 2nd flow sensor 62, and the amount of drainage is set. By adjusting, it controls so that the amount of hot water supplied to the bathtub 12 and the drainage amount of the bathtub water discharged | emitted from the bathtub 12 may become equal. However, in the present invention, the method of controlling the amount of hot water supplied to the bathtub by the hot water supply means and the amount of drainage of the bathtub water through the drainage channel is not limited to this. That is, for example, the amount of hot water supplied to the bathtub 12 by adjusting the amount of hot water supplied to the bathtub 12 by controlling the opening and closing of the electromagnetic valve 50 based on the flow rate detection values by the first flow sensor 52 and the second flow sensor 62. And the amount of bathtub water discharged from the bathtub 12 may be controlled to be equal. Further, such a flow rate control may be realized by using a configuration shown with reference to FIG. 7 or FIG.

  FIG. 7 is a schematic diagram showing a configuration of a modification of the first embodiment of the present invention. In FIG. 7, the same components as those shown in FIG. 1 are denoted by the same reference numerals, and the description thereof is omitted or simplified. Moreover, in FIG. 7, while the illustration of the heat pump unit 18 is abbreviate | omitted, the flow-path form at the time of the said bathtub water temperature rising operation is shown.

  The hot water storage type water heater 90 shown in FIG. 7 includes a bath outlet pipe 54 through which hot water supplied to the bathtub 12 flows during the bath water temperature raising operation, and bath water drained from the bathtub 12 during the bath water temperature raising operation. A gear pump 92 is provided so as to be interposed between the flowing drain pipe 72. More specifically, the gear pump 92 includes a pair of gears 92a and 92b that mesh with each other in the pump body 92c. One gear 92 a is disposed in the middle of the bathroom pipe 54, and the other gear 92 b is disposed in the middle of the drain pipe 72. Further, the gear pump 92 has a rotation direction indicated by an arrow in FIG. 7, that is, a rotation direction in which the engagement of the pair of gears 92 a and 92 b is released on the hot water and drainage supply side. ) Is rotated (not shown) (for example, an electric motor).

  When the control unit 86 drives the gear pump 92 having the above configuration during the bath water temperature raising operation, each of the hot water flowing through the bath outlet pipe 54 and the drainage flowing through the drain pipe 72 is indicated by an arrow in FIG. Thus, the gas passes through between the gears 92a and 92b and the pump body 92c and flows out to the downstream side. At this time, since the pair of gears 92a and 92b mesh with each other, they are mechanically adjusted so that the flow rates of hot water and waste water passing through the gear pump 92 become equal.

  FIG. 8 is a schematic diagram showing the configuration of another modification of the first embodiment of the present invention. In FIG. 8, the same components as those shown in FIG. 1 are denoted by the same reference numerals, and the description thereof is omitted or simplified. Moreover, in FIG. 8, while the illustration of the heat pump unit 18 is abbreviate | omitted, the flow-path form at the time of the said bathtub water temperature rising operation is shown.

  The hot water storage type water heater 100 shown in FIG. 8 is provided with a flow rate adjusting valve 102 in the middle of the drain pipe 72. Using such a flow rate adjustment valve 102, the control unit 86 controls the flow rate adjustment valve 102 based on the flow rate detection values by the first flow rate sensor 52 and the second flow rate sensor 62 to adjust the amount of drainage, whereby the bathtub 12 The amount of hot water supplied to the bath and the amount of drainage of the bath water discharged from the bathtub 12 may be controlled to be equal. Further, by arranging the flow rate adjusting valve 102 at the drain pipe 72 on the downstream side of the switching valve 64, it is possible to reduce the pressure loss of the flow path at the time of hot water filling and normal reheating operation.

  Moreover, in Embodiment 1 mentioned above, the heat pump unit 18 is used as a heating means for heating the water in the hot water storage tank 14. Thus, as described above, a high-efficiency heat pump water heater is realized without causing intermediate temperature water to be generated in the hot water storage tank 14 while reliably preventing a drop in the water level of the bathtub 12 when reheating the bathtub water. It becomes possible to do. However, the heating means in the present invention is not necessarily limited to the heat pump unit 18 and may be, for example, an electric heater.

In the first embodiment described above, the hot water supply pipe 42, the mixing valve 46, the mixed hot water pipe 48, the electromagnetic valve 50, the bath outlet pipe 54, and the bath return pipe 56 are the "hot water supply means" in the first invention. The reheating heat exchanger 68 is the “heat exchanger” in the first invention, the drain pipe 72 is the “drainage channel” in the first invention, and the flow path configuration shown in FIG. Is the “first flow channel configuration” in the first invention, the flow channel configuration shown in FIG. 3C or FIG. 6 is the “second flow channel configuration” in the first invention, the switching valve 64 and four-way The valves 82 correspond to the “flow path switching means” in the first invention. Further, the controller 86 drives the bath circulation pump 60 in a state in which the bathtub water circulation circuit 58 is formed, whereby the “tub water circulation means” in the first invention is disposed on the tank side where the tank hot water circulation circuit 74 is disposed. By driving the circulation pump 80, the “tank hot water circulation means” in the first invention detects a request for reheating the bath water (refreshing request) via the operation portion 88. The “temperature rise request detection means” executes the processes of steps S6 and S7, so that the “control means” of the first invention executes the processes of step S7. "Adjustment means" is realized respectively.
In the first embodiment, the bath circulation pump 60 corresponds to the “pump” in the seventh aspect of the invention.

10, 90, 100 Hot water storage type hot water heater 12 Bath 14 Hot water storage tank 16 Hot water storage tank unit 18 Heat pump unit 22 Water refrigerant heat exchanger 30 Hot water storage tank hot water heating circuit 36 Heat pump circulation pump 38 Hot water supply pipe 42 Hot water supply pipe 46 Mixing valve 48 Mixed hot water Pipe 50 Solenoid valve 52 First flow sensor 54 Bath return pipe 56 Bath return pipe 58 Bath water circulation circuit 60 Bath circulation pump 62 Second flow sensor 64 Switching valve 66 First temperature sensor 68 Reheating heat exchanger 70 Second temperature sensor 72 Drain pipe 74 Tank hot water circulation circuit 80 Tank-side circulation pump 82 Four-way valve 84 Micro bubble generator 86 Control unit 88 Operation unit 92 Gear pump 92a, 92b A pair of gears 102 Flow control valves A1, B1, E1, P1 Ports of four-way valve

Claims (8)

A hot water storage tank for storing hot water supplied to the bathtub,
Heating means for heating water in the hot water storage tank;
Hot water supply means for supplying tank hot water stored in the hot water storage tank to the bathtub;
A bathtub water circulation circuit having a bathtub water circulation circuit connected to the bathtub, and circulating the bathtub water in the bathtub;
A tank hot water circulation circuit that connects between an upper part of the hot water storage tank and a lower part of the hot water storage tank, and circulates the hot water from the upper part of the hot water storage tank to the lower part of the hot water storage tank;
A heat exchanger for exchanging heat between the bathtub water flowing in the bathtub water circulation circuit and the tank hot water flowing in the tank hot water circulation circuit;
A drainage channel connected in the middle of the bathtub water circulation circuit;
As a flow path form of the bathtub water coming out of the bathtub, a first flow path form that returns to the bathtub as it is through the bathtub water circulation circuit, and a second flow path form that drains from the bathtub water circulation circuit via the drainage channel, A flow path switching means capable of selecting
A temperature rise request detecting means for detecting the presence or absence of a request to reheat the bath water;
When the request to reheat bath water is detected, the flow path switching means is selected so that the second flow path configuration is selected at the same time as controlling the hot water supply means so that hot water is supplied to the bathtub. Control means for controlling
When the request to reheat the bath water is detected, the amount of hot water and the amount of drainage are set such that the amount of hot water supplied to the bath by the hot water supply means is equal to the amount of drainage of the bath water through the drainage channel. Adjusting means for adjusting at least one of
A hot water storage type water heater characterized by comprising   When the request to reheat the bathtub water is detected, if the difference between the set temperature of the bathtub water and the temperature of the bathtub water is greater than a predetermined value, heat exchange with the tank water via the heat exchanger The hot water storage type hot water heater according to claim 1, wherein the bath water is reheated using the control means and the adjusting means instead of the reheating operation for reheating the bathtub water flowing in the bathtub water circulation circuit. .   The hot water storage type hot water supply apparatus according to claim 1 or 2, further comprising a microbubble generator that mixes microbubbles in the bath water in the middle of the flow path of the bath water when the second flow path form is selected. .   The hot water storage type hot water supply according to claim 3, wherein the microbubble generator is arranged at a position upstream of the flow of bath water from the heat exchanger when the second flow path configuration is selected. Machine.   The flow path switching means is adapted to change the direction of the bathtub water flow toward the heat exchanger during the reheating operation for reheating the bathtub water flowing in the bathtub water circulation circuit by heat exchange with the tank hot water via the heat exchanger. On the other hand, the hot water storage system according to claim 4, wherein the hot water storage type is a means for switching the flow path so that the direction of the flow of the bath water toward the heat exchanger is opposite when the second flow path form is selected. Water heater. A pump disposed on the upstream side of the heat exchanger at the time of the reheating operation and switching of the flow path by the second flow path switching means;
The adjustment means adjusts the amount of drainage using the pump so that the amount of hot water supplied to the bathtub by the hot water supply means is equal to the amount of drainage of the bathtub water via the drainage channel. The hot water storage type water heater according to claim 5.   The adjusting means includes a gear pump that is a pair of gears that mesh with each other and that has one gear disposed in the middle of the flow path of the hot water supply means and the other gear disposed in the middle of the drainage path. The hot water storage type water heater according to any one of claims 1 to 5. The adjustment means includes a flow rate adjustment valve that adjusts the amount of drainage so that the amount of hot water supplied to the bathtub by the hot water supply unit and the amount of drainage of the bathtub water through the drainage channel are equal.
The hot water storage type hot water heater according to any one of claims 1 to 5, wherein the flow rate adjustment valve is disposed in the drainage channel.

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