JP5831382B2 - Hot water storage water heater - Google Patents

Description

  The present invention relates to a hot water storage type hot water heater having a function of supplying hot water containing bubbles into a bathtub.

  As a prior art, for example, as described in Patent Document 1, a water heater that supplies air into a bathtub is known. Moreover, as other prior art, as described in Patent Document 2, high-temperature water heated by a heat pump unit and bath water introduced into a reheating heat exchanger (use side heat exchanger) There is known a water heater that exchanges heat and heats bathtub water. Furthermore, as described in Patent Document 3, a water heater that supplies air into a bathtub using an ejector is known.

JP-A-2005-55101 JP 2005-42985 A JP 2009-186151 A

  In the prior art described in Patent Document 1 described above, since the hot water temperature is lowered when air is supplied into the bathtub, in order to avoid this phenomenon, the hot water in the hot water storage tank is used when the air is supplied. The structure which heats water is considered. However, when there is not a sufficient amount of bathtub water at the time of air supply, the circulation of the bathtub water circulating through the secondary side of the reheating heat exchanger may be small or stop. At this time, since high-temperature water is circulated on the primary side of the heat exchanger for reheating, if heat is not exchanged with the secondary side, the heat exchanger and the circulation circuit around it are connected. It becomes a high temperature state. In this state, when a hot water supply operation or the like to the bathtub is performed, hot water that is too hot for the user to be handled may be supplied from the heat exchanger into the bathtub, and the convenience of the water heater deteriorates. There's a problem.

  The present invention has been made in order to solve the above-described problems. In a configuration having a function of supplying bubbles into the bathtub and a function of heating the bathtub water, the bathtub water containing fine bubbles is used. It is an object of the present invention to provide a hot water storage type hot water heater capable of appropriately controlling the hot water supply temperature and improving convenience.

The hot water storage type hot water heater according to the present invention includes a heating device for heating bathtub water stored in the bathtub, a bathtub water circulation circuit that connects the bathtub and the heating device, and the bathtub and heating device via the bathtub water circulation circuit. A bathtub water circulation pump that circulates the bathtub water between and a bubble generator that generates bubbles in the bathtub water flowing through the bathtub water circulation circuit in a state in which the bathtub water circulation pump is operated to supply bubbles into the bathtub, The water flow detection means for detecting the water flow in the bathtub water circulation circuit, and the water flow detection means detects the water flow generated by operating the bathtub water circulation pump based on the request when air bubbles are supplied into the bathtub. The first operating means for operating the heating device, the bath water circulation pump and the bubble generating device, and when a request is generated and the bath water circulation pump is operated based on the request, If the water flow is not detected by the detecting means, and a second operating means for operating the bathtub water circulating pump and the bubble generation apparatus after stopping the heating device, the bubble generating device, bath water flowing bath water circulation circuit This is an ejector that introduces air from the outside using the water flow of the water and mixes the air as bubbles in the bathtub water. When the water flow inside is detected, the bubble generating device is activated .

  According to the present invention, a sufficient amount of bathtub water is present when a water flow generated by operating the bathtub water circulation pump is detected in a state where a request to supply bubbles into the bathtub has occurred. It is judged. In this case, it is possible to select an operation in which reheating is used together so that the temperature of the bath water does not decrease due to mixing of bubbles. Thereby, even when a bubble bath is performed, for example, when it is cold, bubbled bath water adjusted to an appropriate temperature can be supplied into the bathtub, and a comfortable bathing environment can be realized. On the other hand, if the water flow is not detected even when the bathtub water circulation pump is operated, it is determined that the bathtub water is insufficient, so that no reheating is performed so that the heating device does not overheat, and only bubbles are generated. be able to. Thereby, at the time of the next hot water supply, it can prevent that the overheated high temperature water is hot-watered in a bathtub. Therefore, when the bather selects the bubble bath, it is possible to automatically select whether or not to use chasing for the generation of bubbles, and the convenience of the water heater can be improved.

BRIEF DESCRIPTION OF THE DRAWINGS It is a whole block diagram which shows the hot water storage type water heater by Embodiment 1 of this invention. It is sectional drawing which shows typically the bathtub adapter installed in the bathtub. In Embodiment 1 of this invention, it is a circuit block diagram which shows the boiling operation by a water heater. In Embodiment 1 of this invention, it is a circuit block diagram which shows the foaming chase operation by a water heater. In Embodiment 1 of this invention, it is a circuit block diagram which shows the foaming independent driving | operation by a water heater. In Embodiment 1 of this invention, it is a flowchart which shows the control performed by the control part. In Embodiment 2 of this invention, it is a flowchart which shows the control performed by the control part.

Embodiment 1 FIG.
Hereinafter, Embodiment 1 of the present invention will be described with reference to FIGS. In each drawing used in this specification, common elements are denoted by the same reference numerals, and redundant description is omitted. FIG. 1 is an overall configuration diagram showing a hot water storage type hot water heater according to Embodiment 1 of the present invention. As shown in this figure, the hot water storage type water heater 100 of this embodiment includes a tank unit 1, a heat pump unit 60, a fine bubble generating device 80, and the like. The tank unit 1 and the heat pump unit 60 are connected via a heat pump inlet pipe 41 and a heat pump outlet pipe 42. The tank unit 1 includes a control unit 70. The control unit 70 controls operations of various valves and pumps mounted on the tank unit 1 and the heat pump unit 60. In addition, the controller 70 is provided with a remote controller (remote controller) 90 for the user of the water heater to set and select various temperatures and operation modes, and to start, stop, and switch operations. The remote controller 90 constitutes the operating means of the present embodiment. Hereinafter, each component of the hot water storage type water heater 100 will be described.

  The heat pump unit 60 heats (boils) the low temperature water taken out from the tank unit 1 by a heat pump cycle. The heat pump unit 60 includes a compressor 61, a heating heat exchanger 62, an expansion valve 63, and an air heat exchanger 64, and a refrigeration cycle (heat pump cycle) in which these devices are connected in an annular shape by a refrigerant circulation pipe 65. It is equipped with. The boiling heat exchanger 62 exchanges heat between the refrigerant flowing through the refrigerant circulation pipe 65 and the low-temperature water taken out from the tank unit 1. The heat pump outlet temperature sensor 66 detects the temperature of the high-temperature water flowing out from the boiling heat exchanger 62 and is provided in the heat pump outlet pipe 42. The heat pump cycle preferably uses carbon dioxide as a refrigerant and is operated at a pressure exceeding the critical pressure.

  The tank unit 1 incorporates the following various parts and piping. The hot water storage tank 10 is constituted by a substantially cylindrical sealed tank for storing hot water. A water supply pipe 2 that supplies water from a water source such as a water supply is connected to an introduction port 10 </ b> A provided at a lower portion of the hot water storage tank 10. A hot water supply pipe 3 for supplying hot water in the hot water storage tank 10 to the outside of the water heater is connected to a first upper port 10B provided in the upper part of the hot water storage tank 10. In addition, although illustration is abbreviate | omitted, the hot water supply piping 3 has branched into several, and one of them is connected to the bathtub water circulation circuit 51 mentioned later. Supply of hot water to the bathtub 50 (hot water supply operation) is configured to be performed from the hot water supply pipe 3 via a bathtub water circulation circuit 51 (and a heat exchanger 22 described later). Hot water heated by the heat pump unit 60 is stored in the hot water storage tank 10 from the upper part of the tank, and low temperature water supplied by the water supply pipe 2 is introduced from the lower part of the tank. Hot water is stored so as to occur. Further, for example, two remaining hot water temperature sensors 11 and 12 are attached to the surface of the hot water storage tank 10 so as to be separated in the vertical direction. The control unit 70 detects the temperature distribution in the hot water storage tank 10 and the amount of remaining hot water based on the outputs of the remaining hot water temperature sensors 11 and 12, and controls the start and stop of the boiling operation described later.

  Further, the tank unit 1 includes a circulation pump 21 and a use side heat exchanger 22. As will be described later, the circulation pump 21 circulates hot water through various pipes in the tank unit 1. The use-side heat exchanger 22 heats the secondary heating target water (tub water, circulating water for heating, etc.) using the primary high-temperature water supplied from the hot water storage tank 10 or the heat pump unit 60. Is. In the present embodiment, as a circuit connected to the secondary side of the use side heat exchanger 22, a bath water circulation circuit 51 described later will be described as an example. In addition, the circulation pump 21 and the use-side heat exchanger 22 use the high-temperature water stored in the hot water storage tank 10 to generate bathtub water stored in the bathtub 50 (tub water flowing in the bathtub water circulation circuit 51). A heating device for heating is configured.

  Next, the valves and piping built in the tank unit 1 will be described. The tank unit 1 is equipped with a three-way valve 31 and a four-way valve 32. The three-way valve 31 has two inlets (a and b ports) through which hot water flows and one outlet (c ports) through which hot water flows out, and has two routes (ac route and bc route). It is comprised so that a flow path form can be switched between. The four-way valve 32 has two inlets (b port and c port) through which hot water flows and two outlets (a port and d port) through which hot water flows out, and has three paths (that is, an ab path). , B-d route, and cd route).

  The tank unit 1 includes a tank lower pipe 40, a heat pump inlet pipe 41, a heat pump outlet pipe 42, a tank upper pipe 43, a tank return pipe 44, a use side heat exchanger primary side inlet pipe 45, and a use side heat exchanger. A primary outlet pipe 46 and a bypass pipe 47 are incorporated. The individual pipes will be described. First, the tank lower pipe 40 connects the first lower port 10C provided at the lower part of the hot water storage tank 10 and the a port of the three-way valve 31, and the heat pump inlet pipe 41 has three sides. The c port of the valve 31 and the inlet side of the heat pump unit 60 are connected. A circulation pump 21 is arranged in the middle of the heat pump inlet pipe 41. The heat pump outlet pipe 42 connects the outlet side of the heat pump unit 60 and the c port of the four-way valve 32. The tank upper pipe 43 connects the second upper port 10D provided in the upper part of the hot water storage tank 10 and the d port of the four-way valve 32, and the tank return pipe 44 is provided in the lower part of the hot water storage tank 10. 2 The lower port 10E and the a port of the four-way valve 32 are connected. The use side heat exchanger primary side inlet pipe 45 connects the tank upper pipe 43 and the primary side inlet of the use side heat exchanger 22, and the use side heat exchanger primary side outlet pipe 46 is The primary side outlet of the use side heat exchanger 22 and the b port of the three-way valve 31 are connected. Further, the bypass pipe 47 connects a portion of the heat pump inlet pipe 41 that is downstream of the circulation pump 21 and the b port of the four-way valve 32.

  Next, a circuit on the bathtub 50 side connected to the hot water storage type hot water heater 100 will be described. The bathtub 50 is provided with a bathtub water circulation circuit 51, a bathtub water circulation pump 54, a water flow sensor 55, a bathtub outlet side temperature sensor 56, a microbubble generator 80 and a bathtub adapter 84 described later. The bathtub water circulation circuit 51 connects the bathtub 50 and the use side heat exchanger 22 and forms a bathtub water circulation path therebetween. The bathtub water circulation circuit 51 flows the bathtub water flowing from the bathtub 50 into the secondary side inlet of the usage side heat exchanger 22 and the bathtub water flowing out from the secondary side outlet of the usage side heat exchanger 22 in the bathtub 50. And a return pipe 53 for returning to the inside. The bathtub water circulation pump 54 circulates bathtub water between the bathtub 50 and the use side heat exchanger 22 via the bathtub water circulation circuit 51, and is provided, for example, in the going pipe 52.

  The water flow sensor 55 is constituted by, for example, a flow switch or the like provided in the outgoing pipe 52 and detects the presence or absence of water flow in the bathtub water circulation circuit 51, and corresponds to the water flow detection means of the present embodiment. The bathtub outlet side temperature sensor 56 is provided, for example, in the outgoing pipe 52 and detects the temperature of the bathtub water flowing through the bathtub water circulation circuit 51 on the outlet side of the bathtub 50, and corresponds to the temperature detection means of the present embodiment. Yes.

  The fine bubble generator 80 generates fine bubbles in the bathtub water flowing through the bathtub water circulation circuit 51 in a state where the bathtub water circulation pump 54 is operated, and is configured by a general ejector mechanism. This ejector mechanism introduces air from the outside using the water flow of the bathtub water flowing through the bathtub water circulation circuit 51, and mixes the air into the bathtub water as bubbles. More specifically, the fine bubble generator 80 includes an ejector pipe in which a hot water flow path is formed and a diameter of the middle part of the flow path is reduced, and air in a direction perpendicular to the water flow at the reduced diameter portion of the ejector pipe. And an air inlet for introducing air. An air solenoid valve 82 is connected to the air introduction port via an air pipe 81. Further, the air pipe 81 is provided with a check valve 83 for preventing a back flow from the fine bubble generating device 80 to the air electromagnetic valve 82.

  When the fine bubble generator 80 is used, the bathtub water circulation pump 54 is operated to open the air solenoid valve 82. Thus, when a predetermined amount or more of the bath water flows in the ejector pipe, a negative pressure is generated in the reduced diameter portion by the water flow at this time, and a negative pressure acts on the air inlet. As a result, air is introduced from the air solenoid valve 82 to the air inlet through the air pipe 81, and the introduced air is mixed with the flow of the bath water to generate fine bubbles. Then, the bathtub water containing fine bubbles is supplied into the bathtub 50 via the return pipe 53. The fine bubble generator 80 does not necessarily have an ejector structure, and may be configured to generate fine bubbles by, for example, a forced pressurization method.

  On the other hand, FIG. 2 is sectional drawing which shows typically the bathtub adapter installed in the bathtub. As shown in this figure, the bathtub adapter 84 is installed on the wall surface of the bathtub 50, and is connected to the suction pipe 85 connected to the going pipe 52 and the return pipe 53 on the downstream side of the fine bubble generating device 80. The discharge port 86 is provided. The bathtub water in the bathtub 50 is sucked into the outgoing pipe 52 from the suction port 85 and discharged into the bathtub 50 from the discharge port 86, so that the bathtub water circulation water channel 51 is circulated. Further, the discharge direction of the discharge port 86 is set to a direction that is substantially perpendicular to the wall surface of the bathtub 50. According to this setting, the fine bubbles discharged from the discharge port 86 can be positively attached to the bather's skin.

(Boiling operation)
Next, the operation mode of the water heater will be described with reference to FIGS. In these drawings, the remote controller 90 is not shown. First, FIG. 3 is a circuit configuration diagram showing a boiling operation by the hot water heater in Embodiment 1 of the present invention. The boiling operation is an operation for heating (boiling) hot water in the hot water storage tank 10 by using the heat pump unit 60 alone. At the time of boiling operation, as shown in FIG. 3, the three-way valve 31 is switched to the ac path and the four-way valve 32 is switched to the cd path. As a result, the tank lower pipe 40 and the heat pump inlet pipe 41 communicate with each other, and the tank upper pipe 43 and the heat pump outlet pipe 42 communicate with each other. Further, the tank return pipe 44, the use side heat exchanger primary side outlet pipe 46 and the bypass pipe 47 are closed by the valves 31 and 32, and the flow path passing through the use side heat exchanger 22 is blocked. .

  In the boiling operation, the circulation pump 21 and the heat pump unit 60 are operated in this state. Thereby, the low temperature water is taken out from the first lower port 10C of the hot water storage tank 10 to the tank lower pipe 40, and this low temperature water is heated through the three-way valve 31, the circulation pump 21 and the heat pump inlet pipe 41. It flows into the secondary side of 62 and becomes high-temperature water by exchanging heat with a high-temperature refrigerant. The hot water reaches the second upper port 10D of the hot water storage tank 10 via the heat pump outlet pipe 42, the four-way valve 32, and the tank upper pipe 43 and flows into the upper part of the hot water storage tank 10. Thus, high temperature water can be stored in the hot water storage tank 10 in the boiling operation.

(Hot water storage operation)
Next, with reference to FIG. 4, the hot water reheating operation will be described. FIG. 4 is a circuit configuration diagram showing a foam reheating operation by the water heater in Embodiment 1 of the present invention. In this figure, the state where the air electromagnetic valve 82 is closed and the fine bubble generating device 80 (the air flow flowing through the air pipe 81) is stopped corresponds to the hot water reheating operation. The hot water reheating operation heats (reheats) the bath water using the high-temperature water in the hot water storage tank 10.

  At the time of hot water reheating operation, as shown in FIG. 4, the three-way valve 31 is switched to the bc path and the four-way valve 32 is switched to the ab path. As a result, the heat pump inlet pipe 41 and the use side heat exchanger primary side outlet pipe 46 communicate with each other, and the tank return pipe 44 and the bypass pipe 47 communicate with each other. In addition, the tank lower pipe 40 and the heat pump outlet pipe 42 are closed, and a portion of the tank upper pipe 43 downstream of the connection portion of the use side heat exchanger primary side inlet pipe 45 is closed. . In the hot water reheating operation, the circulation pump 21 and the bath water circulation pump 54 are operated in this state. The heat pump unit 60 is held in a stopped state.

  As a result, the high temperature water is taken out from the second upper port 10D of the hot water storage tank 10, and this high temperature water is used side heat exchange via the upstream side of the tank upper pipe 43 and the use side heat exchanger primary side inlet pipe 45. It flows into the primary side of the vessel 22 and becomes hot water by exchanging heat with bathtub water in the use side heat exchanger 22. Then, this medium-temperature water passes through the use side heat exchanger primary side outlet pipe 46, the three-way valve 31, the upstream side of the heat pump inlet pipe 41, the circulation pump 21, the bypass pipe 47, the four-way valve 32, and the tank return pipe 44. It reaches the second lower port 10E of the hot water storage tank 10 and flows into the lower part of the hot water storage tank 10. On the other hand, on the bathtub side, the bathtub water that has flowed out of the bathtub 50 passes through the secondary side of the use side heat exchanger 22 while flowing through the bathtub water circulation circuit 51. Thereby, bathtub water is heated with the use side heat exchanger 22, and is returned in the bathtub 50 via the fine bubble generator 80 after that. Thus, in hot water storage renewal operation, bath water can be reclaimed.

(Foaming operation)
Next, the foam chasing operation will be described with reference to FIG. As shown in this figure, the foaming reheating operation is to operate the fine bubble generating device 80 while executing the hot water reheating operation described above. More specifically, in the foam reheating operation, the air solenoid valve 82 is further opened while the hot water reheating operation described above is executed. Thereby, the bathtub water that has flowed out of the bathtub 50 into the bathtub water circulation path 51 is circulated through the return pipe 53 after being heated by the use-side heat exchanger 22 as in the case of the hot water reheating operation. Are mixed with fine bubbles generated by the fine bubble generator 80.

  Therefore, according to the foaming chasing operation, the temperature of the bath water returned to the bathtub 50 together with the fine bubbles can be kept high while supplying the fine bubbles into the bathtub 50. Thereby, the bather can implement | achieve bathing (bubble bath) in the state enclosed by the fine bubble by comfortable hot water temperature, and can obtain the comfort and warm bath effect by a bubble bath effectively. In addition, it is possible to realize a heat retaining effect that is difficult to cool. More specifically, generally, when the fine bubbles are simply mixed in the bathtub water flowing through the bathtub water circulation circuit 51, the temperature of the bathtub water tends to decrease. For this reason, in the present embodiment, the air electromagnetic valve 82 is arranged inside the tank unit 1 and the fine bubbles are generated using the air in the tank unit 1. Inside the tank unit 1, there are a hot water storage tank 10 for storing hot water and various pipes, valves, etc. through which the high temperature water circulates. It is kept at a higher temperature than the outside air temperature by heat dissipation. For this reason, the fine bubble generator 80 can bubble the air in the tank unit 1 having a relatively high temperature and mix it with the bath water, and can suppress the temperature drop of the bath water.

  However, since the air in the tank unit 1 is also cooled when the outside air temperature is low, there is a limit in suppressing the temperature drop of the bath water even if the air is bubbled. For this reason, in the foaming chasing operation, bath water is chased by the use side heat exchanger 22 while the fine bubble generating device 80 is operated. Thereby, the bathtub water containing fine bubbles can be supplied into the bathtub 50 while maintaining a moderately high temperature, and the convenience of the bather can be improved.

(Foaming single operation)
FIG. 5 is a circuit configuration diagram showing a single foaming operation by the water heater in Embodiment 1 of the present invention. As shown in this figure, the foaming single operation is to supply the fine bubbles into the bathtub 50 without performing the pursuit of the bathtub water. More specifically, in the foaming single operation, the bathtub water circulation pump 54 is operated and the air electromagnetic valve 82 is opened. On the other hand, the use side heat exchanger 22 stops the circulation pump 21 and keeps the use side heat exchanger 22 in a stopped state. That is, in the present embodiment, the stopping of the heating device is realized by stopping the circulation pump 21.

  Thus, at the time of foaming single operation, bath water is circulated to the secondary side (tub water circulation circuit 51) in the state where circulation of high temperature water on the primary side of use side heat exchanger 22 was stopped. This bathtub water is supplied into the bathtub 50 together with the fine bubbles generated from the fine bubble generator 80. Moreover, since the bathtub water which flows through the bathtub water circulation circuit 51 is supplied in the bathtub 50 in the state heated by the residual heat of the utilization side heat exchanger 22, the bather has the bathtub water containing the fine bubbles adjusted to the appropriate temperature. You can enjoy the comfort and warm bath effect.

(Foaming operation switching control)
The foaming operation switching control is for determining whether or not to carry out chasing during the foaming operation based on the amount of bath water and temperature conditions. The “foaming operation” is a general term for the above-described foaming pursuit operation and foaming single operation, and means an operation of supplying fine bubbles into the bathtub 50. When performing the foaming operation, it is necessary to pay attention to the amount of bathtub water. That is, for example, if the amount of bath water is insufficient and an attempt to carry out the foaming operation is performed, the heat exchanger 22 does not perform proper heat exchange and the heat exchanger becomes overheated. When a hot water supply operation or the like to the bathtub is performed, there is a possibility that the overheated high-temperature water is supplied into the bathtub.

  For this reason, in this Embodiment, when the request | requirement which performs foaming operation generate | occur | produces and the water flow produced in the bathtub water circulation circuit 51 by operating the bathtub water circulation pump 54 based on the said request | requirement is detected Execute foaming chasing operation. That is, in this case, it is determined that there is a sufficient amount of bathtub water, and the circulation pump 21 (use side heat exchanger 22), the bathtub water circulation pump 54, and the fine bubble generator 80 are all operated. The “request to execute the foaming operation” is generated, for example, when the user of the water heater selects “bubble bath” by operating the remote controller 90. The presence or absence of a water flow is detected by a water flow sensor 55.

  On the other hand, if a request for executing the foaming operation is generated and the water flow in the bathtub water circulation circuit 51 is not detected even if the bathtub water circulation pump 54 is operated based on the request, the amount of bathtub water is insufficient. It is judged that it is, and the foaming independent operation is executed. That is, in this case, the bathtub water circulation pump 54 and the fine bubble generating device 80 are operated in a state where the heating device is stopped (the circulation pump 21 is stopped).

  According to the above control, for example, when the user of the water heater selects a bubble bath by using the remote controller 90, it is possible to automatically select one of the foam refill operation and the foam single operation based on the amount of the bath water. And an appropriate foaming operation can be performed based on the selection result. Thereby, the user can easily perform the foaming operation without paying excessive attention to the amount of bath water, and can improve the convenience of the water heater. More specifically, according to the present embodiment, when the bathtub water is sufficiently present, the foam reheating operation can be selected so that the temperature of the bathtub water does not decrease due to the mixing of fine bubbles. Thereby, even when foaming operation is performed at the time of cold, for example, it is possible to mix the fine bubbles while chasing the bathtub water, so that the bathtub water containing the fine bubbles adjusted to an appropriate temperature is supplied into the bathtub 50. A comfortable bathing environment can be realized.

  On the other hand, when the bathtub water is insufficient, the single foaming operation can be selected so that the use side heat exchanger 22 is not heated. Thereby, at the time of the next hot water supply, it can prevent that the overheated high temperature water is hot-watered in the bathtub 50. FIG. Moreover, even when foaming single operation is selected, the bath water containing fine bubbles can be kept at an appropriate temperature by using the residual heat of the use-side heat exchanger 22, and a comfortable bathing environment can be realized. Moreover, by moving the residual heat of the use side heat exchanger 22 to the bathtub water side, the use side heat exchanger 22 that has been stopped is appropriately cooled, and overheating of the use side heat exchanger 22 is reliably prevented. be able to.

  Moreover, in this Embodiment, it is good also as a structure which switches a driving | operation not only with the quantity of bathtub water but with temperature conditions. As an example, even if a water flow is detected when the bathtub water circulation pump 54 is operated (even if it is determined that a sufficient amount of bathtub water exists), the temperature T of the bathtub water is equal to or higher than a predetermined high temperature determination value TH. In that case, the circulation pump 21 (use side heat exchanger 22) may be stopped and the foaming single operation may be executed. Here, the temperature T of the bathtub water is detected by the bathtub outlet temperature sensor 56.

  The high temperature determination value TH is set, for example, as the minimum value of the water temperature that is allowed to mix bubbles without performing re chasing. That is, when the temperature T of the bath water is equal to or higher than the high temperature determination value TH, even if bubbles are mixed into the bath water without performing reheating, the temperature does not decrease to an inappropriate temperature for bathing. Single operation can be executed. Thereby, at the time of foaming operation, the increase in energy consumption by performing unnecessary pursuit can be avoided, and a water heater can be operated efficiently.

  Further, in the present embodiment, even if the water flow is not detected when the bathtub water circulation pump 54 is operated (even if it is determined that the amount of the bathtub water is insufficient), the temperature T of the bathtub water is a predetermined low temperature. When the temperature is lower than the determination value TL, the circulation pump 21 may be controlled so that the temperature T becomes equal to or higher than the low temperature determination value TL. Here, when the rotation speed (discharge flow rate) of the circulation pump 21 is changed, the flow rate of the high-temperature water flowing on the primary side of the use side heat exchanger 22 is changed accordingly. Therefore, when the flow rate of the high-temperature water is increased, the temperature is increased, and when the flow rate of the high-temperature water is decreased, the temperature is decreased, and the temperature of the bath water can be controlled based on the discharge flow rate of the circulation pump 21. .

  The low temperature determination value TL is set, for example, as the maximum value of the water temperature at which bubbles are not allowed to be mixed without performing re chasing. That is, when the temperature T of the bathtub water is lower than the low temperature determination value TL, if bubbles are mixed into the bathtub water without performing reheating, the temperature drops to a temperature inappropriate for bathing. In this case, the circulation pump 21 is operated to perform the foaming chasing operation, and the minimum chasing is performed so that the temperature T of the bathtub water becomes equal to or higher than the low temperature determination value TL. According to this control, even if there is little bath water, if the hot water temperature is likely to drop significantly due to foaming operation, the minimum required replenishment can be forcibly executed, and priority is given to comfort during bathing. can do.

  In the example of the control described above, it is automatically determined whether or not to perform chasing during the foaming operation based on the outputs of the water flow sensor 55 and the bathtub outlet side temperature sensor 56. However, since the necessity of chasing at the time of foaming operation varies depending on the user's preference, environment, and the like, in this embodiment, whether or not chasing is performed at the time of foaming operation (the circulation pump 21 is operated). Whether or not) can be selected by operating the remote controller 90. That is, when the remote control 90 is operated to set the chasing during the foaming operation to ON (execution) or OFF (stop), this setting is executed with priority over the above-described foaming operation switching control.

  As a specific example, during foaming chasing operation, high temperature water containing fine bubbles is discharged from the discharge port 86 of the bathtub adapter 84, so that some bathers may feel uncomfortable. In this case, if the chasing at the time of foaming operation is set to OFF by operating the remote controller 90, when performing bubble bathing, the foaming independent operation is always executed regardless of the amount of bath water and temperature conditions. Therefore, at the time of foaming operation, the presence / absence of chasing can be set according to the user's wish, and the convenience can be enhanced.

  Moreover, in this Embodiment, it is set as the structure which can switch the heating capability of the use side heat exchanger 22 at the time of a foaming chase operation in several steps. For example, the remote controller 90 can select any one of a plurality of foaming pursuit setting temperatures T1 to Tn prepared in advance. The foaming chasing set temperatures T1 to Tn are target values of the temperature of the bath water discharged from the discharge port 86 during the foaming chasing operation. For example, the target value of the bath water temperature when the foaming chasing operation is not executed ( It is set in advance based on the bathtub set temperature T0). Here, to give a specific example in the case where three types of foaming additional setting temperatures T1 to T3 are prepared, T1 is set to T0 + 2 ° C., T2 is set to T0 + 4 ° C., and T3 is set to T0 + 8 ° C. ing. The bathtub set temperature T0 is set by the remote controller 90.

  For example, when the user of the water heater selects the foaming chase setting temperature T2 by using the remote controller 90, when the foaming chase operation is executed, the temperature of the bathtub water matches the foaming chase setting temperature T2. Controlled. Moreover, the temperature of the bathtub water when not performing the foaming chasing operation is controlled so as to coincide with the bathtub set temperature T0. These temperature controls are executed by making the discharge flow rate of the circulation pump 21 variable as described above. According to the above control, the temperature of the bathtub water during the foaming chasing operation can be set according to the user's preference, and the user can comfortably perform the bubble bath at the desired hot water temperature.

  Further, in the above control, the foam pursuit operation is executed on the assumption that the hot water in the hot water storage tank 10 is available. However, when the high-temperature water in the hot water storage tank 10 cannot be used by the use-side heat exchanger 22, it is preferable to execute the single foaming operation even if the conditions for executing the foaming additional operation are satisfied. As such a case, for example, a case where the amount of remaining hot water in the hot water storage tank 10 is small, or a case where the hot water temperature in the hot water storage tank 10 is not so high as to heat the bath water can be considered. That is, in the present embodiment, even if the condition for executing the foaming pursuit operation is satisfied when it is determined that it is difficult to perform the foaming pursuit operation based on the amount of remaining hot water in the hot water storage tank 10 or the hot water temperature. A configuration in which a single foaming operation is performed may be employed. According to this control, when it is difficult to carry out the foaming chasing operation, this operation function can be replaced by the foaming single operation, so that the redundancy of the water heater can be improved.

[Specific Processing for Realizing Embodiment 1]
Next, specific processing for realizing the above-described control will be described with reference to FIG. FIG. 6 is a flowchart showing the control executed by the control unit 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 a request for foaming operation has occurred. Specifically, for example, when the user of the water heater selects “bubble bath” by operating the remote controller 90, it is determined that a request for the foaming operation has occurred. If the determination in step S1 is not established, it is not necessary to perform the foaming operation, and thus this routine ends. Moreover, when determination of step S1 is materialized, it transfers to step S2 and the bathtub water circulation pump 54 is operated. In step S <b> 3, it is determined whether the water flow in the bathtub water circulation circuit 51 is detected by the water flow sensor 55.

  When the determination in step S3 is established, it is determined that there is a sufficient amount of bathtub water and the water flow is generated by the operation of the bathtub water circulation pump 54, and thus the process proceeds to step S4. In step S4, based on the output of the bathtub outlet side temperature sensor 56, it is determined whether or not the temperature T of the bathtub water is equal to or higher than the high temperature determination value TH. If this determination is not established, the bath water is not so hot as to require reheating when performing the foaming operation, so the routine proceeds to step S5, where the use side heat exchanger 22 (circulation pump 21) is operated. In step S6, the air electromagnetic valve 82 is opened and the fine bubble generating device 80 is operated. As a result, the foam pursuit operation is executed. In addition, when the determination in step S4 is established, since the bath water is so hot that it does not require reheating when performing the foaming operation, after stopping the use-side heat exchanger 22 in step S8 described later, The process proceeds to step S6, and the foaming single operation is executed.

  On the other hand, if the determination in step S3 is not established, it is determined that no water flow is detected even if the bathtub water circulation pump 54 is operated because the amount of bathtub water is small. In this case, it transfers to step S7 and it is determined whether the water temperature T of bathtub water is less than the low temperature determination value TL. If this determination is not established, it is determined that the temperature of the bath water will not be too low even if the chase is not performed during the foaming operation, so the use-side heat exchanger 22 is stopped in step S8. Later, the process proceeds to step S6, and the foaming single operation is executed. In addition, when the determination in step S7 is established, it is determined that the temperature of the bath water is too low unless the reheating is performed during the foaming operation. Therefore, by performing steps S5 and 6, the refining operation is performed. Execute.

  In the first embodiment, steps S1, S2, S3, S4, S5, S6, and S8 in FIG. 7 show a specific example of the first operating means. Steps S1, S2, S3, S5, S6, S7, and S8 show specific examples of the second operating means.

Embodiment 2. FIG.
Next, a second embodiment of the present invention will be described with reference to FIG. The present embodiment is characterized in that, in the configuration described in the first embodiment, the water draining operation is performed to drain the water accumulated on the air introduction side of the fine bubble generating device. More specifically, in the operation modes other than the foaming operation, it is not necessary to operate the fine bubble generating device 80 shown in FIG. 1, so the air electromagnetic valve 82 is held in the closed state. In this state, since warm water flows through the fine bubble generating device 80, a negative pressure is generated in the air pipe 81 between the air solenoid valve 82 and the check valve 83 due to the internal air being released during thermal expansion. Has occurred. Therefore, when the function of the check valve 83 is reduced or moisture in the air pipe 81 is condensed, water stays inside the air pipe 81.

  For this reason, in this Embodiment, when the water flow in the bathtub water circulation circuit 51 is detected by the water flow sensor 55 in the state where the request for the foaming operation has not occurred, the water drain operation for draining the accumulated water in the air pipe 81. Is configured to execute. FIG. 7 is a flowchart showing the control executed by the control unit 70 in the second embodiment of the present invention. In the routine shown in this figure, first, in S11, it is determined whether or not a request for foaming operation has occurred. When this determination is not established, the process proceeds to step S12, and it is determined whether or not the water flow in the bathtub water circulation circuit 51 is detected by the water flow sensor 55.

  And when determination of step S12 is materialized, it transfers to step S13 and performs draining operation. Specifically, for example, the air electromagnetic valve 82 is opened for a predetermined time, and the fine bubble generating device 80 is operated. Thereby, the stagnant water in the air pipe 81 can be sucked into the bathtub water circulation circuit 51 by negative pressure and extracted to the bathtub 50 side, and the maintainability of the water heater can be improved. On the other hand, if the determination in step S11 is established, or if the determination in step S12 is not established, this routine ends because it is not the timing for executing the water draining operation.

  As a timing for performing the water draining operation, for example, during the period of performing the circulating operation for confirming the presence or absence of bath water or draining the air in the water flow of the bath water at the time of performing the automatic water filling operation . The automatic hot water filling operation is defined as an operation for automatically storing hot water at a temperature set by the user up to a set water level in the bathtub 50, and the circulation operation is defined as an operation for circulating the bathtub water in the bathtub water circulation circuit 51. Is done. The reason for executing the water draining operation during the automatic water filling operation is as follows.

  First, after completion of the automatic hot water filling operation, the water level in the bathtub is in a high state, so that the pressure in the fine bubble generating device 80 is relatively increased and hardly becomes negative pressure. As a result, the negative pressure acting on the accumulated water in the air pipe 81 is reduced, and it may be difficult to remove the accumulated water due to the negative pressure. On the other hand, during the hot water filling operation, the hot water filling operation is incomplete, and the water level in the bathtub is relatively low. Therefore, a large negative pressure is applied to the accumulated water in the air pipe 81, The staying water can be easily drained to the bathtub side.

  Moreover, since the possibility that a bathing person exists is low during the execution of the automatic hot water filling operation, the operation of discharging the accumulated water to the bathtub side can be performed without conspicuously. In addition, in the case of automatic hot water filling operation, even if an operation of releasing bubbles containing stagnant water is witnessed in the bathtub, it is unlikely to be abnormal, so the water draining operation can be completed with ease. . However, the execution timing of the water draining operation is not limited to the automatic hot water filling operation, and any other circulation is possible as long as a sufficiently large negative pressure acts on the accumulated water in the air pipe 81. It is possible to perform a water drain operation during operation.

  In the first embodiment, the heat pump unit 60 is configured by a heat pump cycle that is operated in a supercritical state in which the refrigerant pressure is equal to or higher than the critical pressure. However, the present invention is not limited thereto, and the pressure is equal to or lower than the critical pressure. A heat pump cycle operated at may be adopted. In this case, the refrigerant may be configured to use Freon gas, ammonia, or the like.

1 Tank unit 10 Hot water storage tank 21 Circulation pump (heating device)
22 Use-side heat exchanger (heating device)
31 Three-way valve 32 Four-way valve 40 Tank lower piping 41 Heat pump inlet piping 42 Heat pump outlet piping 43 Tank upper piping 44 Tank return piping 45 Usage side heat exchanger primary side inlet piping 46 Usage side heat exchanger primary side outlet piping 47 Bypass Piping 50 Bath 51 Bath water circulation circuit 52 Outgoing pipe 53 Return pipe 54 Bath water circulation pump 55 Water flow sensor (water flow detection means)
56 Bath outlet side temperature sensor (temperature detection means)
60 heat pump unit 70 control unit 80 fine bubble generator (bubble generator)
81 Air Piping 82 Air Solenoid Valve 83 Check Valve 84 Bathtub Adapter 85 Suction Port 86 Discharge Port 90 Remote Control (Operating Means)
100 Hot water storage water heater

Claims (9)

A heating device for heating the bathtub water stored in the bathtub;
A bathtub water circulation circuit connecting the bathtub and the heating device;
A bathtub water circulation pump for circulating bathtub water between the bathtub and the heating device via the bathtub water circulation circuit;
A bubble generator for generating bubbles in the bathtub water flowing through the bathtub water circulation circuit in a state where the bathtub water circulation pump is operated to supply bubbles into the bathtub,
A water flow detecting means for detecting a water flow in the bathtub water circulation circuit;
When a request for supplying air bubbles into the bathtub is generated and a water flow generated by operating the bathtub water circulation pump based on the request is detected by the water flow detection means, the heating device, the bathtub First operating means for operating a water circulation pump and the bubble generating device;
When the request is generated and the water flow is not detected by the water flow detecting means even if the bathtub water circulation pump is operated based on the request, the bath water circulation pump and the bubbles are generated with the heating device stopped. Second operating means for operating the device ,
The bubble generating device is an ejector that introduces air from the outside using the water flow of the bathtub water flowing through the bathtub water circulation circuit and mixes the air into the bathtub water as bubbles,
A hot water storage type hot water heater configured to operate the bubble generating device when a water flow in the bathtub water circulation circuit is detected by the water flow detecting means in a state where a request for supplying bubbles into the bathtub is not generated . A heating device for heating the bathtub water stored in the bathtub;
A bathtub water circulation circuit connecting the bathtub and the heating device;
A bathtub water circulation pump for circulating bathtub water between the bathtub and the heating device via the bathtub water circulation circuit;
A bubble generator for generating bubbles in the bathtub water flowing through the bathtub water circulation circuit in a state where the bathtub water circulation pump is operated to supply bubbles into the bathtub,
A water flow detecting means for detecting a water flow in the bathtub water circulation circuit;
When a request for supplying air bubbles into the bathtub is generated and a water flow generated by operating the bathtub water circulation pump based on the request is detected by the water flow detection means, the heating device, the bathtub First operating means for operating a water circulation pump and the bubble generating device;
When the request is generated and the water flow is not detected by the water flow detecting means even if the bathtub water circulation pump is operated based on the request, the bath water circulation pump and the bubbles are generated with the heating device stopped. Second operating means for operating the device,
The heating device is a heat exchanger that heats bathtub water in the bathtub water circulation circuit using hot water stored in a hot water storage tank,
A hot water storage type hot water supply apparatus configured to generate fine bubbles with the bubble generating device in a state where the heating device is stopped when high-temperature water in the hot water storage tank cannot be used by the heating device. A heating device for heating the bathtub water stored in the bathtub;
A bathtub water circulation circuit connecting the bathtub and the heating device;
A bathtub water circulation pump for circulating bathtub water between the bathtub and the heating device via the bathtub water circulation circuit;
A bubble generator for generating bubbles in the bathtub water flowing through the bathtub water circulation circuit in a state where the bathtub water circulation pump is operated to supply bubbles into the bathtub,
A water flow detecting means for detecting a water flow in the bathtub water circulation circuit,
The bubble generating device is an ejector that introduces air from the outside using the water flow of the bathtub water flowing through the bathtub water circulation circuit and mixes the air into the bathtub water as bubbles,
  A hot water storage type hot water heater configured to operate the bubble generating device when a water flow in the bathtub water circulation circuit is detected by the water flow detecting means in a state where a request for supplying bubbles into the bathtub is not generated. Temperature detecting means for detecting the temperature of the bathtub water flowing through the bathtub water circulation circuit,
The hot water storage hot water supply according to claim 1 or 2 , wherein the first operating means is configured to stop the heating device when the temperature of the bath water detected by the temperature detecting means is equal to or higher than a predetermined high temperature determination value. Machine. Temperature detecting means for detecting the temperature of the bathtub water flowing through the bathtub water circulation circuit,
When the temperature of the bath water detected by the temperature detecting means is less than a predetermined low temperature determination value, the second operating means controls the heating device so that the temperature becomes equal to or higher than the low temperature determination value. The hot water storage type water heater according to any one of claims 1 , 2, and 4 . The bubble generating device is an ejector that introduces air from the outside using the water flow of the bathtub water flowing through the bathtub water circulation circuit and mixes the air into the bathtub water as bubbles,
3. The bubble generating device is configured to operate when a water flow in the bathtub water circulation circuit is detected by the water flow detection means in a state where a request for supplying bubbles into the bathtub is not generated. Hot water storage water heater. The heating device is a heat exchanger that heats bathtub water in the bathtub water circulation circuit using hot water stored in a hot water storage tank,
The hot water in the hot water tank when it is not possible to utilize by the heating device, hot water storage type hot-water supply according to claim 1 comprising a structure for generating micro-bubbles by the bubble generating device in a state of stopping the heating device Machine. The operation unit according to any one of claims 1 to 7 , further comprising an operation unit capable of performing a selection operation as to whether or not to activate the heating device when generating fine bubbles by the bubble generation device. Hot water storage water heater. The hot water storage type hot water supply device according to any one of claims 1 to 8 , wherein the heating capacity when the bath water is heated by the heating device can be switched to a plurality of stages.

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