JP2021159588A - Bath device - Google Patents

Abstract

To provide a technique capable of washing a tank even after a microbubble supply operation is interrupted.SOLUTION: A bath device includes a bathtub, a circuit, a circulation pump, a tank, a pressure pump, a gas introduction part, a microbubble discharge nozzle, a supply channel, a water supply valve, and a control device. The control device executes a microbubble supply operation. The control device starts the microbubble supply operation upon receiving a first start instruction, and terminates the microbubble supply operation when an operation termination condition is satisfied. The control device brings the water supply valve into an open state upon receiving an interruption instruction before the operation termination condition is satisfied after starting the microbubble supply operation, and executes a tank washing operation of driving the pressure pump and supplying water supplied from a water supply source to the tank.SELECTED DRAWING: Figure 6

Description

The technique disclosed herein relates to a bath device.

Patent Document 1 describes a bathtub, a circulation path for circulating water in the bathtub, a circulation pump provided in the circulation path, a tank provided in the circulation path for dissolving gas in water, and a circulation path. A pressure pump installed on the upstream side of the tank, a gas introduction part that is connected to the tank and can introduce gas into the tank, a fine bubble discharge nozzle attached to the bathtub, and one end as a water supply source. A bath device including a water supply channel which is connected and the other end of which is connected to a circulation path, a water supply valve which is provided in the water supply channel and opens and closes the water supply channel, and a control device are disclosed. .. The control device drives a circulation pump and a pressurizing pump while the water supply valve is closed, and ejects water from the tank to the bathtub via a fine bubble discharge nozzle, and a water supply valve. Is configured to be able to execute a gas introduction operation for introducing gas from the gas introduction unit into the tank and a fine bubble supply operation for executing the operation when the pressure pump is stopped and the pressure pump is stopped. The control device is configured to start the fine bubble supply operation when receiving the first start instruction instructing the start of the fine bubble supply operation, and to end the fine bubble supply operation when the operation end condition is satisfied. ing.

Japanese Unexamined Patent Publication No. 2009-18118

In the bath device of Patent Document 1, the control device executes a tank cleaning operation of supplying water supplied from the water supply source to the tank when the operation end condition is satisfied. However, in the bath device of Patent Document 1, no consideration is given to the situation where the execution of the fine bubble supply operation is interrupted before the operation end condition is satisfied. If the bath device does not perform the tank cleaning operation after interrupting the fine bubble supply operation, the water supplied from the bathtub will remain in the tank. The water supplied from the bathtub contains more foreign matter than the water supplied from the water source. If the water containing foreign matter remains in the tank, there is a risk that germs will grow in the water in the tank. When the fine bubble supply operation is executed after the germs have propagated in the water in the tank, the water in which the germs have propagated is ejected into the bathtub. Therefore, there is a demand for a technique capable of keeping the inside of the tank clean even when the operation of supplying fine bubbles is interrupted.

The present invention provides a technique capable of keeping the inside of a tank clean even when the operation of supplying fine bubbles is interrupted.

The bath device of one embodiment disclosed by the present specification is provided in a bathtub, a circulation path for circulating water in the bathtub, a circulation pump provided in the circulation path, and the circulation path. , A tank that dissolves gas in water, a pressurizing pump provided on the upstream side of the tank in the circulation path, and a gas introduction unit that is connected to the tank and can introduce gas into the tank. A water supply channel having a fine bubble discharge nozzle attached to the bathtub, one end connected to the water supply source, and the other end connected to the circulation path, and the water supply channel provided in the water supply channel. A water supply valve that opens and closes and a control device are provided, and the control device drives the circulation pump and the pressurizing pump in a state where the water supply valve is closed, and draws water from the tank. In a state where the water supply operation of ejecting water to the bathtub through the fine bubble discharge nozzle and the water supply valve are in the closed state and the pressurizing pump is stopped, the gas introduction unit to the tank. It is configured to be able to execute the gas introduction operation for introducing gas into the gas and the fine bubble supply operation for executing the gas introduction operation, and when the first start instruction for instructing the start of the fine bubble supply operation is received, the fine bubble supply operation is performed. When the operation is started and the operation end condition is satisfied, the fine bubble supply operation is terminated. The operation end condition is such that the number of executions of the water supply operation and the gas introduction operation reaches a predetermined number of times. Or, a predetermined time has elapsed from the start of the fine bubble supply operation, and the fine bubble supply operation is performed after the fine bubble supply operation is started and before the operation end condition is satisfied. When receiving the interruption instruction for instructing the interruption, the water supply valve is opened, the pressurizing pump is driven, and the tank cleaning operation for supplying the water supplied from the water supply source to the tank is executed. It is configured to do.

According to the above configuration, the control device performs a tank cleaning operation when the fine bubble supply operation is interrupted. Therefore, even if the fine bubble supply operation is interrupted, the water in the tank is replaced with clean water supplied from the water supply source. Therefore, even if the fine bubble supply operation is interrupted, the inside of the tank can be kept clean.

The wall of the bathtub is a first discharge port connected to a circulation path, and the amount of water discharged from the first discharge port is water having a component perpendicular to the wall where the first discharge port is installed. The amount is larger than the amount of water of the component parallel to the wall where the first discharge port is installed, the first discharge port and the second discharge port connected to the circulation path, and discharge from the second discharge port. The amount of water produced is such that the amount of water of the component parallel to the wall where the second discharge port is installed is larger than the amount of water of the component perpendicular to the wall where the second discharge port is installed. An exit and may be provided. In the water supply operation, the water discharged from the tank to the bathtub is discharged into the bathtub through the first discharge port, and in the tank cleaning operation, the water discharged from the tank to the bathtub passes through the second discharge port. , May be discharged into the bathtub.

In the water supply operation, the water sucked from the bathtub into the circulation path is discharged into the bathtub through the circulation path and the tank. Therefore, the temperature of the water discharged into the bathtub is almost the same as the temperature of the water in the bathtub. Therefore, in the water supply operation, even if the water discharged from the first discharge port directly hits the bather, it is unlikely to cause discomfort to the bather. On the other hand, in the tank cleaning operation, the water supplied from the water supply source is discharged into the bathtub through the circulation path and the tank. In this case, for example, when the water supplied from the water supply source to the circulation path is not heated, the temperature of the water discharged into the bathtub and the temperature of the water in the bathtub can be significantly different. In such a situation, if the water discharged into the bathtub hits the bather directly, it may cause discomfort to the bather. According to the above configuration, in the tank cleaning operation executed after the fine bubble supply operation is interrupted, the water discharged from the tank to the bathtub is discharged into the bathtub through the second discharge port. Therefore, in the tank cleaning operation, it is possible to prevent the water discharged from the tank into the bathtub from directly hitting the bather. As a result, the comfort of the user who uses the bath device can be improved.

The bath device is further provided in the circulation path, and may be provided with a heating device for heating the water in the circulation path. The control device is configured to be able to perform a reheating operation that heats the water in the bathtub by driving the circulation pump and the heating device when the water supply valve is closed and the pressurizing pump is stopped. It may be configured to start the reheating operation when receiving the second start instruction instructing the start of the reheating operation. The interruption instruction may include a second start instruction received after the fine bubble supply operation is started and before the operation end condition is satisfied. When the control device receives the interruption instruction by the second start instruction after starting the fine bubble supply operation and before the operation end condition is satisfied, the control device executes the reheating operation before the tank cleaning operation and follows up. It may be configured to perform the tank cleaning operation after the burning operation is completed.

When the control device receives the interruption instruction by the second start instruction after starting the fine bubble supply operation and before the operation end condition is satisfied, the control device must execute the reheating operation and the tank cleaning operation. In this case, a configuration is conceivable in which the reheating operation is executed after the tank cleaning operation is executed. According to such a configuration, the reheating operation is not started until the tank cleaning operation is completed. In this case, the reheating operation desired by the bather is not immediately performed, which causes discomfort to the bather. According to the above configuration, the reheating operation desired by the bather is immediately performed, so that the bather does not feel uncomfortable. Therefore, the comfort of the user who uses the bath device can be improved.

It is a figure which shows the structure of the bath system which concerns on Example (water supply state). It is a figure which shows the structure of the bath system which concerns on Example (air introduction state). It is a figure which shows the structure of the bath system which concerns on Example (reheating state). It is a figure which shows the structure of the bath system which concerns on Example (tank cleaning state). It is a figure which shows typically the circulation connector which concerns on Example. It is a flowchart which shows the operation process which concerns on Example. It is a flowchart which shows the fine bubble supply operation process which concerns on Example.

(Example)
(Configuration of bath system 2)
The bath system 2 will be described with reference to FIGS. 1 to 4. The bath system 2 includes a heat source unit 10, a fine bubble generation unit 50, a bathtub 130, and a control device 150. The heat source unit 10 is connected to the water supply source 200 and the fine bubble generation unit 50. The fine bubble generation unit 50 is connected to the heat source unit 10 and the bathtub 130. In the following, a case where water flows in the direction of the arrow shown in FIG. 1 will be described as an example.

(Structure of heat source unit 10)
The heat source unit 10 is a unit for heating the water flowing through the water channel in the heat source unit 10 and supplying the heated water to the bathtub 130. The heat source unit 10 includes a heat source machine 12, a water supply channel 20, a first return channel 22, a second return channel 23, and a first outgoing channel 24.

The upstream end of the first return water channel 22 is connected to the fine bubble generation unit 50 (specifically, the third return water channel 60), and the downstream end is connected to the heat source side switching valve 28. The upstream end of the second return channel 23 is connected to the heat source side switching valve 28, and the downstream end is connected to the heat source machine 12. A circulation pump 30 and a water flow switch 32 are provided in the second return water channel 23. The circulation pump 30 is provided on the upstream side of the water flow switch 32, and sends out water on the upstream side of the circulation pump 30 to the downstream side. The water flow switch 32 detects that water is passing through the second return water channel 23. The heat source machine 12 is, for example, a gas heat source machine that heats water passing through the heat source machine 12.

The upstream end of the water supply channel 20 is connected to a water supply source 200 such as a city water supply, and the downstream end of the water supply channel 20 is connected to a heat source side switching valve 28. A hot water filling valve 26 is provided in the water supply channel 20. The hot water filling valve 26 opens and closes the water supply channel 20. The heat source side switching valve 28 has a first switching state (states in FIGS. 1 to 3) in which the first return water channel 22, the second return water channel 23, and the water supply channel 20 communicate with each other, and the second return water channel 23. It is possible to switch between the second switching state (the state shown in FIG. 4) in which the water supply channel 20 communicates.

The upstream end of the first going water channel 24 is connected to the heat source machine 12, and the downstream end is connected to the fine bubble generation unit 50 (specifically, the second going water channel 68).

(Structure of fine bubble generation unit 50)
The fine bubble generation unit 50 includes a tank 52, a third return channel 60, a second outlet channel 68, a water supply channel 74, a communication channel 66, a jet channel 64, a fourth return channel 62, and a third. The outbound water channel 70 and the air introduction channel 100 are provided.

The tank 52 can store water inside. Inside the tank 52, a low water level electrode 52a and a high water level electrode 52b for detecting the water level in the tank 52 are installed. The water level detected by the low water level electrode 52a (hereinafter referred to as "lower limit water level") is lower than the water level detected by the high water level electrode 52b (hereinafter referred to as "upper limit water level"). When the low water level electrode 52a and the high water level electrode 52b come into contact with the water surface of the water stored in the tank 52, they output an ON signal to the control device 150. The tank 52 is used to generate air-dissolved pressurized water in which air is pressurized and dissolved in water.

The upstream end of the third return channel 60 is connected to the communication channel 66, and the downstream end is connected to the heat source unit 10 (specifically, the first return channel 22). The communication channel 66 connects the first switching valve 80 and the second switching valve 82. One end of the fourth return water channel 62 is connected to the first switching valve 80, and the other end is connected to the bathtub 130 (specifically, the circulation connector 132). The upstream end of the ejection water channel 64 is connected to the lower part of the tank 52, and the downstream end is connected to the first switching valve 80. The ejection water channel 64 is provided with a check valve 84 that prevents water from flowing from the first switching valve 80 side to the tank 52 side. The first switching valve 80 has a first communication state (state in FIG. 1) in which the ejection channel 64 and the fourth return channel 62 communicate with each other, and a second communication state in which the ejection channel 64 and the communication channel 66 communicate with each other (state in FIG. 1). The state of FIGS. 2 and 4) and the third communication state (state of FIG. 3) in which the fourth return channel 62, the ejection channel 64, and the communication channel 66 communicate with each other can be switched.

The upstream end of the second going water channel 68 is connected to the heat source unit 10 (specifically, the first going water channel 24), and the downstream end is connected to the second switching valve 82. One end of the third going water channel 70 is connected to the bathtub 130 (specifically, the circulation connector 132), and the other end is connected to the second switching valve 82. The second switching valve 82 has a fourth communication state (states of FIGS. 1 and 4) in which the third communication channel 70 and the communication channel 66 communicate with each other, and a fifth communication state in which the second communication channel 68 and the third communication channel 70 communicate with each other. It is possible to switch between the communication state (the state of FIGS. 2 and 3).

The second outbound channel 68 and the tank 52 are connected by a water supply channel 74. The water supply water channel 74 is provided with a water supply control valve 86 and a pressure pump 88. The water supply control valve 86 opens and closes the water supply water channel 74. The water supply control valve 86 is provided on the upstream side of the pressurizing pump 88. The pressurizing pump 88 pressurizes the water in the water supply channel 74 and sends it out to the downstream side. In the following, the state of the bath system 2 when the heat source side switching valve 28 is in the first switching state, the first switching valve 80 is in the first communication state, and the second switching valve 82 is in the fourth communication state. (The state shown in FIG. 1) is referred to as a "water supply state", the heat source side switching valve 28 is in the first switching state, the first switching valve 80 is in the second communication state, and the second switching valve 82 is in the second switching state. The state of the bath system 2 (the state shown in FIG. 2) in the case of 5 communication states is called an "air introduction state", the heat source side switching valve 28 is in the first switching state, and the first switching valve 80 is in the third communication state. The state of the bath system 2 (state in FIG. 3) when the second switching valve 82 is in the fifth communication state is called the "reheating state", and the heat source side switching valve 28 is in the second switching state. The state of the bath system 2 (state in FIG. 4) when the first switching valve 80 is in the second communication state and the second switching valve 82 is in the fourth communication state is "tank cleaning state". Is called.

The upstream end side of the air introduction path 100 is open to the atmosphere, and the downstream end is connected to the tank 52. The air introduction path 100 introduces air into the tank 52. An air control valve 102 is provided in the air introduction path 100. The air control valve 102 opens and closes the air introduction path 100.

(Structure of circulation connector 132)
Subsequently, the circulation connector 132 connected to the wall portion 130a of the bathtub 130 will be described with reference to FIGS. 5A to 5C. 5 (a) to 5 (c) are views schematically showing a cross section of the circulation connector 132. The arrows in FIGS. 5A to 5C indicate the flow of water. FIG. 5A shows the flow of water when the bath system 2 is in the water supply state (state of FIG. 1), and FIG. 5B shows the flow of water when the bath system 2 is in the reheating state (state of FIG. 3). 5 (c) shows the flow of water when the bath system 2 is in the air introduction state (state of FIG. 2) or the tank cleaning state (state of FIG. 4). In the following, the vertical direction of FIG. 5 is referred to as a vertical direction, and the horizontal direction of FIG. 5 is referred to as a front-rear direction.

The circulation connector 132 includes an upper water channel 136 and a lower water channel 138. The upper channel 136 communicates with the fourth return channel 62, and the lower channel 138 communicates with the third outgoing channel 70. The upper water channel 136 is branched into a first discharge path 136a and a first suction path 136b. The first discharge path 136a communicates with the first discharge port 134a provided on the front surface 132a of the circulation connector 132. The water discharged from the first discharge port 134a is discharged in front of the wall portion 130a of the bathtub 130, that is, in the direction perpendicular to the wall portion 130a. The first discharge path 136a is provided with a check valve 140a for preventing the flow of water from the front side to the rear side, and a fine bubble discharge nozzle 142. The check valve 140a is provided in front of the fine bubble discharge nozzle 142. The fine bubble discharge nozzle 142 depressurizes the water passing through the fine bubble discharge nozzle 142. The first suction path 136b communicates with the first suction port 134b provided on the front surface 132a of the circulation connector 132. The first suction path 136b is provided with a check valve 140b that prevents the flow of water from the rear side to the front side.

The lower water channel 138 is branched into a second discharge channel 138a and a second suction channel 138b. The second suction path 138b communicates with the second suction port 134c provided on the front surface 132a of the circulation connector 132. The second suction path 138b is provided with a check valve 140c that prevents the flow of water from the rear side to the front side. The second discharge path 138a communicates with the second discharge port 134d provided on the lower surface 132b of the circulation connector 132. The water discharged from the second discharge port 134d is discharged downward, that is, in a direction parallel to the wall portion 130a. The second discharge path 138a is provided with a check valve 140d that prevents the flow of water from the lower side to the upper side.

(Configuration of control device 150)
The control device 150 shown in FIGS. 1 to 4 controls the operation of each component of the heat source unit 10 and the fine bubble generation unit 50. The control device 150 is configured to be able to communicate with the remote controller 154 that can be operated by the user. The control device 150 includes a memory 152. The control device 150 can execute a reheating operation, a fine bubble supply operation, and the like according to the operation of the remote controller 154 by the user.

(Operation processing; Fig. 6)
Subsequently, the operation process executed by the control device 150 of the bath system 2 will be described. The control device 150 executes a reheating operation, a fine bubble supply operation (air introduction operation and water supply operation), and a tank cleaning operation in the operation process. The control device 150 starts the process of FIG. 6 when the power of the bath system 2 is turned on. In the initial state of FIG. 6, the heat source side switching valve 28, the first switching valve 80, and the second switching valve 82 are in the first switching state, the third communication state, and the fifth communication state, respectively (see FIG. 3). ). The drive of the circulation pump 30 and the pressurizing pump 88 is stopped, and the hot water filling valve 26, the water supply control valve 86, and the air control valve 102 are in the closed state.

In S10, the control device 150 monitors the reception of the reheating start instruction signal from the remote control 154. The reheating start instruction signal is transmitted from the remote controller 154 when an operation for instructing the execution of the reheating operation by the user is executed on the remote controller 154. When the reheating start instruction signal is received from the remote controller 154, the control device 150 determines YES in S10, and the process proceeds to S12.

In S12, the control device 150 executes the reheating operation. The reheating operation is performed when the heat source side switching valve 28 is in the first switching state, the first switching valve 80 is in the third communication state, and the second switching valve 82 is in the fifth communication state (FIG. 3). In the reheating state), the water in the bathtub 130 is heated by the heat source machine 12. The control device 150 drives the circulation pump 30 and the heat source machine 12. As a result, as shown in FIGS. 3 and 5 (b), the water in the bathtub 130 becomes the circulation connector 132 (specifically, the first suction port 134b, the first suction passage 136b, and the upper water passage 136). , 4th return channel 62, 1st switching valve 80, communication channel 66, 3rd return channel 60, 1st return channel 22, heat source side switching valve 28, supply to heat source machine 12 via 2nd return channel 23 Will be done. Then, the water heated by the heat source machine 12 is the first going water channel 24, the second going water channel 68, the second switching valve 82, the third going water channel 70, and the circulation connector 132 (specifically, the lower water channel 138, the first). It is supplied to the bathtub 130 via the two discharge paths 138a and the second discharge port 134d).

In S14, the control device 150 monitors that the first operation time has elapsed since the reheating operation was started. When the first operation time elapses after the reheating operation is started, the control device 150 determines YES in S14 and ends the process of FIG. When the control device 150 determines YES in S14, the control device 150 stops the drive of the heat source machine 12 and the circulation pump 30. As a result, the reheating operation is completed. In the modified example, the control device 150 may determine YES in S14 when the temperature in the bathtub 130 reaches the set temperature.

Further, in S20, the control device 150 monitors the reception of the fine bubble start instruction signal from the remote controller 154 at the same time as the monitoring of S10. The fine bubble start instruction signal is transmitted from the remote control 154 when an operation for instructing the execution of the fine bubble supply operation by the user is executed on the remote control 154. When the control device 150 receives the fine bubble start instruction signal from the remote controller 154, the control device 150 determines YES in S20, and the process proceeds to S22.

In S22, the control device 150 executes the fine bubble supply operation process shown in FIG. 7. The fine bubble supply operation process is a process for executing a fine bubble supply operation including an air introduction operation and a water supply operation. In S50 of FIG. 7, the control device 150 executes the air introduction operation. The control device 150 switches the air control valve 102 to the open state, maintains the heat source side switching valve 28 in the first switching state, switches the first switching valve 80 to the second communication state, and switches the second switching valve 82 to the fifth communication state. The communication state is maintained, and the water supply control valve 86 is maintained in the closed state. As a result, the bath system 2 is put into the air introduction state (see FIG. 2). In S50 after passing through S72, which will be described later, the control device 150 switches the second switching valve 82 to the fifth communication state. The control device 150 then drives the circulation pump 30. As a result, as shown in FIGS. 2 and 5 (c), water is sucked out from the tank 52 and air is introduced into the tank 52 through the air introduction path 100. The water sucked out from the tank 52 is the ejection water channel 64, the first switching valve 80, the communication water channel 66, the third return water channel 60, the first return water channel 22, the heat source side switching valve 28, the second return water channel 23, and the heat source machine. 12, 1st going water channel 24, 2nd going water channel 68, 2nd switching valve 82, 3rd going water channel 70, and circulation connector 132 (specifically, lower water channel 138, 2nd discharge channel 138a, and 1st 2 It is discharged to the tub 130 via the discharge port 134d).

In S52, the control device 150 monitors that the water level of the tank 52 becomes lower than the lower limit water level. When the water level of the tank 52 becomes lower than the lower limit water level, the control device 150 determines YES in S52, and the process proceeds to S60. When the control device 150 determines YES in S52, the control device 150 switches the air control valve 102 to the closed state. As a result, the air introduction operation is completed.

Further, the control device 150 monitors the reception of the instruction signal from the remote controller 154 in S54 at the same time as the monitoring of S52. The instruction signal is either a reheating start instruction signal requesting the execution of the reheating operation or a fine bubble end instruction signal instructing the end of the fine bubble supply operation. As for the fine bubble end instruction signal, when the user executes an operation for instructing the end of the fine bubble supply operation to the remote controller 154, or the user executes an operation for turning off the power of the remote controller 154 to the remote controller 154. If so, it is transmitted from the remote controller 154. When the instruction signal is received, the control device 150 determines YES in S54, and the process proceeds to S80.

Further, in S60, the control device 150 starts the water supply operation. The control device 150 maintains the heat source side switching valve 28 in the first switching state, switches the first switching valve 80 to the first communication state, switches the second switching valve 82 to the fourth communication state, and switches the water supply control valve 86 to the fourth communication state. Switch to the open state. As a result, the bath system 2 is in the water supply state (see FIG. 1). The control device 150 then drives the pressurizing pump 88. As a result, as shown in FIGS. 1 and 5 (a), the water in the bathtub 130 becomes the circulation connector 132 (specifically, the second suction port 134c, the second suction passage 138b, and the lower water passage 138). 3rd going waterway 70, 2nd switching valve 82, communication waterway 66, 3rd return waterway 60, 1st return waterway 22, heat source side switching valve 28, 2nd return waterway 23, heat source machine 12, 1st going waterway 24, It is supplied to the tank 52 via the second outbound water channel 68 and the water supply water channel 74. At this time, the water pressurized by the pressurizing pump 88 is supplied from the water supply channel 74 to the tank 52. Inside the tank 52, air is pressurized and dissolved in water. Then, the air-dissolved pressurized water is supplied from the tank 52 to the ejection water channel 64, the first switching valve 80, the fourth return water channel 62, and the circulation connector 132 (specifically, the upper water channel 136, the first discharge channel 136a, and the first. It is supplied to the bathtub 130 via the discharge port 134a). The air-dissolved pressurized water is depressurized to below atmospheric pressure when passing through the fine bubble discharge nozzle 142 in the circulation connector 132, and is increased to atmospheric pressure when ejected to the bathtub 130, and the water in the bathtub 130 is increased. Fine bubbles are generated in.

In S62, the control device 150 monitors that the water level of the tank 52 becomes equal to or higher than the upper limit water level. When the water level of the tank 52 becomes equal to or higher than the upper limit water level, the control device 150 determines YES in S62, and the process proceeds to S70. When the control device 150 determines YES in S62, the water supply control valve 86 is switched to the closed state, and the circulation pump 30 and the pressurizing pump 88 are stopped. As a result, the water supply operation is completed.

Further, the control device 150 monitors the reception of the instruction signal from the remote controller 154 in S64 at the same time as the monitoring of S62. When the instruction signal is received from the remote controller 154, the control device 150 determines YES in S64, and the process proceeds to S80.

In S70, the control device 150 increases the number of cycles by one. The number of cycles is the number of times the air introduction operation and the water supply operation are executed.

In S72, the control device 150 determines whether or not the current number of cycles has reached a predetermined number of times (for example, 5 times). When the number of cycles reaches a predetermined number, the control device 150 determines YES in S72, ends the process of FIG. 7, and proceeds to the process of S30 of FIG. On the other hand, when the number of cycles has not reached the predetermined number of cycles, the control device 150 determines NO in S72, and the process returns to S50.

Further, when the control device 150 determines YES in S54 or YES in S64, the control device 150 determines in S80 whether or not the instruction signal is a reheating start instruction signal. When the instruction signal is the reheating start instruction signal, the control device 150 determines YES in S80, and the process proceeds to S82. On the other hand, when the instruction signal is not a reheating instruction signal, the control device 150 determines NO in S80, ends the process of FIG. 7, and proceeds to the process of S30 of FIG.

In S82, the control device 150 executes the reheating operation.

In S84, the control device 150 monitors that the first operation time has elapsed since the reheating operation was started. When the first operation time elapses after the reheating operation is started, the control device 150 determines YES in S84, ends the process of FIG. 7, and proceeds to the process of S30 of FIG.

Returning to FIG. 6, the control device 150 starts the tank cleaning operation in S30. The tank cleaning operation is an operation for replacing the water in the tank 52 with clean water supplied from the water supply source 200. The control device 150 switches the heat source side switching valve 28 to the second switching state, switches the first switching valve 80 to the second communication state, switches the second switching valve 82 to the fourth communication state, and opens the hot water filling valve 26. The state is switched, and the water supply control valve 86 is switched to the open state. As a result, the bath system 2 is put into the tank cleaning state (see FIG. 4). The control device 150 then drives the pressurizing pump 88. As a result, as shown in FIGS. 4 and 5 (c), the water supplied from the water supply source 200 is the water supply channel 20, the second return channel 23, the heat source machine 12, the first outbound channel 24, and the second outbound channel. 68, It is supplied to the tank 52 via the water supply channel 74. The water discharged from the tank 52 is the ejection water channel 64, the first switching valve 80, the communication water channel 66, the second switching valve 82, the third outlet water channel 70, and the circulation connector 132 (specifically, the lower water channel 138, It is discharged to the bathtub 130 via the second discharge path 138a and the second discharge port 134d). As described above, when the fine bubble supply operation is normally completed (YES in S72 of FIG. 6) and when the fine bubble supply operation is interrupted (YES in S54 or YES in S64), the control device 150 is used. , In either case, the tank cleaning operation is performed.

In S32, the control device 150 monitors that the second operation time has elapsed since the tank cleaning operation was started. The second operation time is set to the time required for the water in the tank 52 to be replaced by the water supplied from the water supply source 200. When the second operation time elapses after the tank cleaning operation is started, the control device 150 determines YES in S32 and ends the process of FIG. When the tank cleaning operation is completed, the control device 150 switches the heat source side switching valve 28 to the first switching state, switches the first switching valve 80 to the third communication state, and switches the second switching valve 82 to the fifth switching state. The communication state is switched, the hot water filling valve 26 is switched to the closed state, and the water supply control valve 86 is switched to the closed state.

(Effect of this example)
As described above, the control device 150 of the bath system 2 enables the fine bubble supply operation (FIG. 7) to execute the water supply operation (S60 in FIG. 7) and the air introduction operation (S50 in FIG. 7). It is configured. When the control device 150 receives the fine bubble start instruction signal instructing the start of the fine bubble supply operation (YES in S20 of FIG. 6), the control device 150 has the number of cycles of the fine bubble supply operation (that is, the air introduction operation and the water supply operation). It is configured to execute the fine bubble supply operation until the number of times of execution reaches a predetermined number of times (for example, 5 times). When the control device 150 receives an instruction signal (YES in S64 or S84 of FIG. 7) after starting the fine bubble supply operation and before the number of cycles reaches a predetermined number of times, the control device 150 performs a tank cleaning operation (FIG. 6). S30) is configured to be executed. According to the above configuration, the control device 150 executes the tank cleaning operation when the fine bubble supply operation is interrupted. Therefore, even when the fine bubble supply operation is interrupted, the water in the tank 52 is replaced with clean water supplied from the water supply source 200. Therefore, even when the fine bubble supply operation is interrupted, the inside of the tank 52 can be kept clean.

Further, as shown in FIG. 5A, in the water supply operation, the water discharged from the tank 52 to the bathtub 130 is discharged into the bathtub 130 through the first discharge port 134a. Further, as shown in FIG. 5C, in the tank cleaning operation, the water discharged from the tank 52 to the bathtub 130 is discharged into the bathtub 130 through the second discharge port 134d. According to the above configuration, in the tank cleaning operation executed after the fine bubble supply operation is interrupted, it is possible to prevent the water discharged from the tank 52 to the bathtub 130 from directly hitting the bather. As a result, the comfort of the user who uses the bath system 2 can be improved.

Further, the control device 150 is configured to start the reheating operation when receiving the reheating start instruction signal. Then, when the control device 150 receives the reheating start instruction signal after starting the fine bubble supply operation and before the number of cycles (that is, the number of executions of the air introduction operation and the water supply operation) reaches a predetermined number of times. , The reheating operation is executed before the tank cleaning operation (S82, S84 in FIG. 7), and the tank cleaning operation is executed after the reheating operation is completed (S30 in FIG. 6). According to such a configuration, the reheating operation desired by the bather is immediately performed, so that the bather does not feel uncomfortable. Therefore, the comfort of the user who uses the bath system 2 can be improved.

(Correspondence)
The bath system 2 is an example of a "bath device". 1st return channel 22, 2nd return channel 23, 1st outgoing channel 24, 3rd return channel 60, 2nd outgoing channel 68, spouting channel 64, communication channel 66, water supply channel 74, 4th return channel 62, and , The third going waterway 70 is an example of a “circulation channel”. The hot water filling valve 26 is an example of a “water supply valve”. The number of cycles is an example of "the number of executions of gas introduction operation and water supply operation". The instruction signal, the reheating start instruction signal, and the fine bubble end instruction signal are examples of the "interruption instruction". The fine bubble start instruction signal and the reheating start instruction signal are examples of the "first start instruction" and the "second start instruction", respectively. Air is an example of a "gas". The air introduction path 100 and the air control valve 102 are examples of the “gas introduction unit”. The air introduction operation is an example of the "gas introduction operation". The heat source machine 12 is an example of a “heating device”.

Although each embodiment has been described in detail above, these are merely examples and do not limit the scope of claims. The techniques described in the claims include various modifications and modifications of the specific examples illustrated above.

(First Modification Example) In the fine bubble supply operation process of FIG. 7, the control device 150 determines whether or not a predetermined time has elapsed since the start of the fine bubble supply operation process instead of S70 and S72. May be good. In this modification, when the control device 150 determines that a predetermined time has elapsed since the start of the fine bubble supply operation process, the process of FIG. 7 is terminated, and the process proceeds to S30 of FIG. On the other hand, when it is determined that the predetermined time has not elapsed since the control device 150 started the fine bubble supply operation process, the process returns to S50.

(Second modification) In the tank cleaning operation (S30 in FIG. 6), the control device 150 switches the heat source side switching valve 28 to the second switching state, switches the first switching valve 80 to the first communication state, and second. The switching valve 82 may be switched to the fourth communication state, the hot water filling valve 26 may be switched to the open state, and the water supply control valve 86 may be switched to the open state. In this modification, the water discharged from the tank 52 to the bathtub 130 during the tank cleaning operation is discharged into the bathtub 130 through the first discharge port 134a of the circulation connector 132.

(Third Modification Example) S80 to S84 in FIG. 7 may be executed after a YES is determined in S32 in FIG. In this modification, when the control device 150 receives the reheating start instruction signal during the execution of the fine bubble supply operation, the control device 150 executes the reheating operation after executing the tank cleaning operation.

(Fourth Deformation Example) In the above embodiment, the heat source unit 10 and the fine bubble generation unit 50 are integrally configured, but even if the heat source unit 10 and the fine bubble generation unit 50 are separately configured. good. In this modification, the control device 150 has a remote controller for instructing the reheating operation executed by the heat source unit 10 and a remote controller for instructing the fine bubble supply operation executed by the fine bubble generation unit 50. It is configured to be communicable.

(Fifth Modified Example) In the above embodiment, air is introduced into the tank 52. In the modified example, a gas such as carbon dioxide, hydrogen, or oxygen may be introduced into the tank 52 instead of air. In this case, a tank filled with gas may be arranged at the upstream end of the air introduction path 100.

(Sixth modification) The "gas introduction section" is not limited to the air introduction path 100 and the air control valve 102, but may be an air pump or the like connected to the air introduction path 100 and the air introduction path 100. good.

The technical elements described herein or in the drawings exhibit their technical usefulness alone or in various combinations, and are not limited to the combinations described in the claims at the time of filing. In addition, the techniques illustrated in the present specification or drawings can achieve a plurality of purposes at the same time, and achieving one of the purposes itself has technical usefulness.

2: Bath system 10: Heat source unit 12: Heat source machine 20: Water supply channel 22: First return channel 23: Second return channel 24: First outlet channel 26: Hot water filling valve 28: Heat source side switching valve 30: Circulation pump 32 : Water flow switch 50: Fine bubble generation unit 52: Tank 52a: Low water level electrode 52b: High water level electrode 60: Third return water channel 62: Fourth return water channel 64: Ejection water channel 66: Communication water channel 68: Second outbound water channel 70: Third going water channel 74: Water supply water channel 80: First switching valve 82: Second switching valve 84: Check valve 86: Water supply control valve 88: Pressurizing pump 100: Air introduction path 102: Air control valve 130: Bathtub 130a : Wall 132: Circulation connector 132a: Front 132b: Bottom 134a: First discharge port 134b: First suction port 134c: Second suction port 134d: Second discharge port 136: Upper water channel 136a: First discharge path 136b: First suction passage 138: Lower water passage 138a: Second discharge passage 138b: Second suction passage 140a to 140d: Non-stop portion 142: Fine bubble discharge nozzle 150: Control device 152: Memory 154: Remote control 200: Water supply source

Claims (3)

With a bathtub
The circulation path that circulates the water in the bathtub and
The circulation pump provided in the circulation path and
A tank provided in the circulation path that dissolves gas in water,
A pressurizing pump provided on the upstream side of the circulation path with respect to the tank,
A gas introduction unit that is connected to the tank and can introduce gas into the tank,
A fine bubble discharge nozzle attached to the bathtub and
One end is connected to the water supply source and the other end is connected to the circulation path.
A water supply valve provided in the water supply channel to open and close the water supply channel,
Equipped with a control device,
The control device is
A water supply operation in which the circulation pump and the pressurizing pump are driven in a state where the water supply valve is closed and water from the tank is ejected to the bathtub via the fine bubble discharge nozzle.
A gas introduction operation in which a gas is introduced from the gas introduction unit into the tank while the water supply valve is in the closed state and the pressurizing pump is stopped.
It is configured to be able to perform a fine bubble supply operation
When the first start instruction for instructing the start of the fine bubble supply operation is received, the fine bubble supply operation is started, and when the operation end condition is satisfied, the fine bubble supply operation is terminated. Ori,
The operation end condition is that the number of executions of the water supply operation and the gas introduction operation reaches a predetermined number of times, or a predetermined time elapses after the start of the fine bubble supply operation.
When the interruption instruction for instructing the interruption of the fine bubble supply operation is received after the start of the fine bubble supply operation and before the operation end condition is satisfied, the water supply valve is opened and the water supply valve is opened. A bath device configured to drive a pressurizing pump to perform a tank cleaning operation of supplying water supplied from the water supply source to the tank. On the wall of the bathtub
The amount of water discharged from the first discharge port in the first discharge port connected to the circulation path is the amount of water having a component perpendicular to the wall portion on which the first discharge port is installed. The first discharge port, which is larger than the amount of water of the component parallel to the wall where the first discharge port is installed,
The amount of water discharged from the second discharge port in the second discharge port connected to the circulation path is the amount of water having a component parallel to the wall portion on which the second discharge port is installed. The second discharge port, which is larger than the amount of water of the component perpendicular to the wall portion on which the second discharge port is installed, is provided.
In the water supply operation, the water discharged from the tank to the bathtub is discharged into the bathtub through the first discharge port.
The bath device according to claim 1, wherein in the tank cleaning operation, the water discharged from the tank to the bathtub is discharged into the bathtub through the second discharge port. The bath device further
It is provided in the circulation path and is provided with a heating device for heating the water in the circulation path.
The control device is
When the water supply valve is in the closed state and the pressurizing pump is stopped, the circulation pump and the heating device can be driven to perform a reheating operation for heating the water in the bathtub. Is composed of
When the second start instruction for instructing the start of the reheating operation is received, the reheating operation is started.
The interruption instruction includes the second start instruction received after the start of the fine bubble supply operation and before the operation end condition is satisfied.
The control device is
When the interruption instruction by the second start instruction is received after the start of the fine bubble supply operation and before the operation end condition is satisfied, the reheating operation is executed before the tank cleaning operation. The bath device according to claim 1 or 2, wherein the tank cleaning operation is executed after the reheating operation is completed.

Images