JP2004150759A - Bathtub hot water supply device and washing water pouring device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a bathtub hot water supply device and a washing water pouring device preventing the large amount of water leak caused by freezing water remaining in a backflow preventive device due to drainage. <P>SOLUTION: The bathtub hot water supply device 1 comprises a hot water supply part 2 for heating water used for feeding hot water and a reheating part 5 for reheating water inside a bathtub 3. The backflow preventive device 50 is provided between a hot water circuit 11 (a clean water circuit) provided with the hot water supply part 2 and a bathtub circulation circuit 22 (a water circuit for miscellaneous use) provided with the reheating part 5. The backflow preventive device 50 opens and closes an overflow port 52 according to a difference in the water feed pressure of water fed from the hot water circuit 11 side to the bathtub circulation circuit 22 side. A freezing preventive heater 88 is arranged near the backflow preventive device 50. The bathtub hot water supply device 1 restrains the function of preventing water leak from the overflow port 52 by prohibiting the supply of hot water into a bathtub 3 for a predetermined period of time. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
TECHNICAL FIELD The present invention relates to a bathtub hot water supply device provided with a backflow prevention device between a water supply circuit through which clean water flows and a water flow circuit through which miscellaneous water flows, and a washing water injection device.
[0002]
[Prior art]
2. Description of the Related Art Some bathtub hot water supply devices and washing water injection devices of the related art include a water supply circuit for supplying clean water and used for hot water supply and the like, and a miscellaneous water circuit for flowing miscellaneous water such as hot water in the bathtub. In a bathtub hot water supply device or a washing water injection device having such a configuration, it is necessary to prevent reverse flow of miscellaneous water from the miscellaneous water circuit side to the clean water circuit side in order to prevent mixed water from mixing with clean water. there were. Therefore, in the related art, a backflow prevention device as disclosed in, for example, the following Patent Document 1 and Patent Document 2 is provided between the miscellaneous water circuit and the water supply circuit.
[0003]
[Patent Document 1]
JP-A-7-103358
[Patent Document 2]
JP-A-2000-304144
[0004]
The backflow prevention device is provided with a pressure introducing portion for introducing the pressure on the primary side and the secondary side, an overflow port communicating with the pressure introducing portion on the secondary side, and a pressure difference between the primary side and the secondary side. It has an operating diaphragm and spool. The backflow prevention device closes the overflow port when the pressure on the primary side is higher than the pressure on the secondary side, and allows water flow from the primary side to the secondary side. Conversely, when the pressure on the secondary side becomes higher than the pressure on the primary side, the backflow prevention device opens the overflow port to open the secondary side, so that the secondary water is reduced to the primary side. To prevent backflow to
[0005]
[Problems to be solved by the invention]
In a bathtub hot water supply device and a washing water injection device of the related art, when it is assumed that the user will not use the device for a long period of time, such as when he is away, drainage for discharging hot water from the piping is performed. If water is discharged in a low-temperature environment such as in winter, the water remaining inside the backflow prevention device freezes, and the overflow port is rarely left open. There is.
[0006]
As described above, in the backflow prevention device, the overflow port may be left open due to freezing of hot water remaining inside. In this case, even if the power is turned on to activate the bathtub hot water supply device and the washing water injection device, and the water pressure acts on the primary pressure introduction portion, the backflow prevention device does not operate due to freezing, and the water flows to the miscellaneous water side. There is a problem that a large amount of water leakage occurs with the supply of water.
[0007]
Accordingly, an object of the present invention is to provide a bathtub hot water supply apparatus and a washing water injection apparatus that do not cause a large amount of water leakage due to freezing of hot water remaining in the backflow prevention apparatus due to drainage or the like.
[0008]
[Means for Solving the Problems]
The invention according to claim 1, which is provided in view of the above-described problem, includes a water supply pipe that supplies water from the outside, a water supply circuit that heats water supplied through the water supply pipe, and a water supply circuit. A bathtub circulation circuit capable of supplying clean water to the bathtub and circulating and heating the miscellaneous water in the bathtub is provided, and an overflow port is closed between the hot water supply circuit and the bathtub circulation circuit by a water supply pressure of the clean water. A bathtub hot water supply device provided with a backflow prevention device that opens an overflow port when the water supply pressure decreases, and prevents miscellaneous water in the bathtub and the bathtub circulation circuit from flowing back to the water supply side. The present invention is a bathtub water heater characterized in that a function of prohibiting the supply of clean water to the bathtub circulation circuit side for a predetermined time after power-on of the bathtub water heater is limited.
[0009]
The bathtub hot water supply device of the present invention, between the hot water supply circuit and the bathtub circulation circuit, closes the overflow port with the supply pressure of clean water supplied from the outside, and opens the overflow port when the water supply pressure decreases. And a backflow prevention device for preventing backflow of miscellaneous water flowing in the bathtub circulation circuit. Therefore, in the bathtub hot water supply apparatus of the present invention, miscellaneous water in the bathtub and the bathtub circulation circuit does not enter the water supply side.
[0010]
If the power supply to the bathtub hot water supply is cut off after draining is completed and the device is left in a low-temperature environment, the hot water remaining in the backflow prevention device rarely freezes, and the backflow prevention device opens the overflow port. May be left as it is. In this state, if the power is turned on to start the bath water heater and water is supplied from the water supply pipe side or the hot water supply circuit side, a large amount of leakage may occur at the overflow port as described above.
[0011]
Therefore, in the bathtub hot water supply device of the present invention, a function restriction is imposed on prohibiting the supply of clean water to the bathtub circulation circuit for a predetermined time after the power is turned on. Therefore, even if the bathtub hot water supply device of the present invention is started in a state where the overflow port is opened due to the freezing of hot water remaining in the backflow prevention device, the supply of clean water is not performed and no water leakage occurs.
[0012]
On the other hand, in the bathtub hot water supply device of the present invention, when the power is turned on, the water supply reaches the frozen portion of the backflow prevention device or its vicinity due to the water supply pressure. Therefore, in the bathtub hot water supply device of the present invention, a predetermined time has elapsed since the power was turned on even when the overflow port was kept open due to freezing of the hot water remaining inside the backflow prevention device when the power was turned on. Around that time, that is, when the function restriction ends, the frozen portion of the backflow prevention device is thawed by the water supplied to or near the frozen portion by the water supply pressure, and the overflow port is closed by the water supply pressure. Therefore, according to the above-described configuration, even when the backflow prevention device keeps the overflow port open due to freezing of hot water remaining inside when the power of the bathtub hot water supply device is turned on, a large amount of water leakage accompanying this occurs. Can be reliably prevented. Further, as will be described later, if a heater is arranged near the backflow prevention device, the frozen portion of the backflow prevention device can be thawed more reliably, and a large amount of water leakage from the overflow port can be more reliably prevented. Can be prevented.
[0013]
The invention according to claim 4 comprises a water supply pipe for supplying clean water from the outside, and a washing water injection circuit for injecting miscellaneous water in the bathtub into the washing machine by performing a predetermined pumping operation. Between the pipe and the washing water supply circuit, the overflow port is closed by the water supply pressure and the overflow port is opened when the water supply pressure is reduced, so that miscellaneous water in the bathtub flows back to the water supply pipe side. A washing and pouring device provided with a backflow prevention device for preventing the water from flowing from the water supply pipe side to the washing and pouring circuit side for a predetermined time after power-on to the washing and pouring device. And a washing water injection device.
[0014]
The washing water injection device of the present invention is provided with a washing water injection circuit that draws out hot water in the bathtub and injects water into the washing machine. The washing water injection circuit is a flowing water circuit through which miscellaneous water flows, similarly to the bathtub circulation circuit described above. In the washing water injection device of the present invention, since the backflow prevention valve is provided between the washing water injection circuit through which miscellaneous water flows and the water supply pipe through which clean water flows, mixing of miscellaneous water into the water supply pipe does not occur. .
[0015]
Further, in the laundry water injection device of the present invention, a function restriction is imposed on prohibiting the supply of clean water to the bathtub circulation circuit and the laundry water injection circuit for a predetermined time after the power is turned on. Therefore, in the laundry water injection device of the present invention, water leakage does not occur even when the power of the laundry water injection device is turned on while the overflow port remains open due to freezing of hot water remaining in the backflow prevention device at the time of drainage or the like. .
[0016]
On the other hand, in the laundry water injection device of the present invention, the water supply reaches the frozen portion of the backflow prevention device or its vicinity due to the water supply pressure during the function restriction. Therefore, in the washing water injection device of the present invention, even when the overflow port remains open due to freezing of hot water remaining in the backflow prevention device due to drainage or the like when the power is turned on, when the function restriction is completed. The freezing portion of the backflow prevention device is thawed by the water supplied to or near the frozen portion by the feedwater pressure, and the overflow port is closed by the feedwater pressure. Therefore, according to the above-described configuration, even when the power of the washing water injection device is turned on in a state where the overflow port is opened due to freezing of hot water remaining inside at the time of draining or the like, a large amount of water is not leaked, I can start a water injection device. Further, as described later, if a heater is arranged near the backflow prevention device, the frozen portion of the backflow prevention device can be thawed more reliably, and a large amount of water leakage from the overflow port can be reliably prevented. Can be.
[0017]
In the present invention, the "water supply pipe" refers to water supplied from the outside or water supplied by heating, for example, a pipe for supplying water from the outside, or water supplied from the outside. And a hot water supply pipe for heating and supplying hot water.
[0018]
Further, in the above-described bathtub hot water supply device or washing water injection device, a heater for preventing freezing of the backflow prevention device is installed near the backflow prevention device. It may be characterized in that it operates until the elapse or the ambient temperature near the heater reaches a predetermined temperature. (Claims 2 and 5)
[0019]
According to this configuration, it is possible to reliably thaw frozen hot water remaining in the backflow prevention device due to drainage or the like. Therefore, according to the present invention, malfunction of the backflow prevention device due to freezing of hot water remaining in the backflow prevention device can be prevented, and a large amount of water leakage at the overflow port can be reliably prevented.
[0020]
Further, the above-described bathtub hot water supply device or washing water injection device may be characterized in that the function restriction is released when the outside air temperature when the power is turned on is equal to or higher than a predetermined temperature. (Claims 3 and 6)
[0021]
According to this configuration, when the outside air temperature is already equal to or higher than the predetermined temperature when the power is turned on, it is not necessary to perform the function limitation when it is assumed that the backflow prevention device does not freeze. That is, according to the above configuration, when it is assumed that the outside air temperature is high and water leakage due to freezing of the backflow prevention device does not occur, the operation can be immediately shifted to the next operation without limiting the function.
[0022]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be further described.
FIG. 1 is a piping diagram of a bathtub water heater according to one embodiment of the present invention. FIG. 2 is a flowchart showing a control flow in the bathtub hot water supply apparatus shown in FIG.
[0023]
In FIG. 1, reference numeral 1 denotes a bathtub hot water supply apparatus of the present embodiment. The bathtub hot water supply device 1 has a hot water supply unit 2 for supplying hot water to the sink and other hot water, and a reheating unit 5 for reheating the hot water in the bathtub 3.
[0024]
Hot water supply unit 2 has the same configuration as a known hot water supply device, and has a high-temperature hot water circuit 11 connected to hot water supply heat exchanger 10 and a bypass circuit 12 that bypasses hot water supply heat exchanger 10. Then, the amount of bypass water flowing through the bypass circuit 12 is adjusted by the bypass water amount control valve 15, and the temperature of the hot water is adjusted by mixing the high temperature hot water flowing through the high temperature hot water circuit 11 and the cold water flowing through the bypass circuit 12. Further, a water amount control valve 18 and a temperature sensor 20 are provided on the downstream side of the mixing portion of the high-temperature hot water circuit 11 and the bypass circuit 12, and the temperature detected by the temperature sensor 20 is supplied to the bypass water amount control valve 15 and the like. The total amount of water is adjusted by the water amount adjusting valve 18 while being fed back.
[0025]
The high-temperature hot water circuit 11 is provided with a water amount sensor 14 and a temperature sensor 19, the opening of the proportional control valve 17 is adjusted so that the temperature of the high-temperature hot water becomes approximately 80 ° C., and the supply amount of the fuel gas is adjusted. Is done.
[0026]
The reheating unit 5 has a bathtub circulation circuit 22 for circulating hot water in the bathtub 3 and the reheating heat exchanger 21. That is, the bathtub circulation circuit 22 has an outgoing waterway 23 for feeding hot water from the reheating heat exchanger 21 to the bathtub 3 and a return waterway 24 for returning hotwater from the bathtub 3 to the reheating heat exchanger 21 side. A water level sensor 25, a circulating pump 26, a water flow switch 27, and a hot water temperature sensor 28 are provided in the return water passage 24. Here, the water level sensor 25 detects the water level in the bathtub 3, and the hot water temperature sensor 28 detects the water temperature in the bathtub.
[0027]
Hot water supply unit 2 and reheating unit 5 are connected by dropping water channel 30. The drop water channel 30 is branched from the downstream side of the portion of the hot water supply unit 2 where the temperature sensor 20 is mounted, and is connected to the return water channel 24 of the additional heating unit 5. Further, a water amount sensor 33 and a pouring solenoid valve 32 are connected to a connecting portion between the drop water channel 30 and the return water channel 24, and two check valves 34, 35 are further provided downstream in series. Each of the two check valves 34 and 35 is attached in a direction that allows a water flow from the hot water supply unit 2 side to the additional heating unit 5 side and prevents reverse flow.
[0028]
Further, a check valve 50 is provided between the check valves 34 and 35. The backflow prevention device 50 is provided with a pressure detection port 51 to which the water supply branch pipe 36 branched from the water inlet side of the high-temperature hot water circuit 11 is connected, and an overflow port 52.
The backflow prevention device 50 is configured so that the pressure on the drop water channel 30 side, that is, the primary pressure acting from the test port 51 (primary side) and the secondary pressure acting from the check valve 35 side (secondary side). A diaphragm is provided that operates based on the pressure difference. More specifically, the backflow prevention device 50 closes the overflow port 52 when the primary pressure is higher than the secondary pressure, and directly connects the primary and secondary sides. Therefore, the primary pressure of the test port 51 is higher than the pressure of the water supply circuit side, and when the pouring solenoid valve 32 is opened, the water flow from the primary water supply circuit side to the water supply circuit side secondary side is permitted. .
[0029]
Conversely, when the pressure on the secondary side, which is a water circuit, becomes higher than the primary pressure, which is a water circuit, the overflow port 52 is opened, and the secondary side, which is a water circuit, and the primary side, which is a water circuit, are forcibly shut off. .
[0030]
As described above, the backflow prevention device 50 is configured such that the pressure of the hot water supplied from the check valve 34 side through the drop water channel 30, and more specifically, the pressure acting on the pressure detection port 51 via the water supply branch pipe 36, When the water pressure on the downstream side of the check valve 35, which is a miscellaneous water side, is higher than that of the check valve 35, hot water flows from the check valve 34 toward the check valve 35. Conversely, when the pressure on the secondary side becomes higher than the pressure on the primary side, the backflow prevention device 50 opens the overflow port 52 to open the secondary side to the atmosphere, and the water flowing in the return-side channel 24 drops. It prevents backflow to the water channel 30 (water supply side).
[0031]
In the present embodiment, a can body heater 81, a first water inlet heater 82, a second water inlet heater 83, a hot water heater 85, a bath pump heater 86, and a freeze prevention heater 88 are provided as electric heaters for preventing freezing. I have.
[0032]
Describing each heater, in the present embodiment, a can heater 81 is provided in the hot water supply unit 2 on the hot water supply side.
Further, a first water inlet heater 82 is provided near a water supply port of the water tap 87. Further, a second water inlet heater 83 is provided near the water amount sensor 14 provided on the water inlet side of the high temperature hot water circuit 11.
Further, a tapping heater 85 is provided in the vicinity of the water amount control valve 18.
[0033]
The bath pump heater 86 is provided near the bath water circulation pump 26 of the bath / heating unit. Further, the anti-freezing heater 88 is installed near the backflow prevention device 50.
[0034]
The above-described heat exchangers 10 and 21 of the hot water supply unit 2 and the additional heating unit 5 are disposed in independent combustion cases 37 and 38, respectively, and are supplied by independent supply fans 40 and 41, respectively.
The path of the gas supplied to the burners 47 and 48 is also independent after the original solenoid valve 43. The hot water supply burner 47 of the hot water supply unit 2 is proportionally controlled by the proportional control valve 17, and the reheating unit 5 is supplied with gas to the reheating burner 48 via the electromagnetic valve 45.
[0035]
In addition to the above-described configuration, the bathtub hot water supply device 1 is provided with an air temperature detection sensor 90 for detecting an outside air temperature.
[0036]
The bathtub hot water supply device 1 includes a control device 60 into which a control program for performing drive control similar to that of a known heat source device is input. In addition to the control program, a program for limiting functions, which is an operation unique to bathtub water heater 1 of the present embodiment, is input to control device 60. Hereinafter, the function restriction, which is an operation unique to the bathtub water heater 1 of the present embodiment, will be described in detail.
[0037]
The user closes the water stopcock (not shown) provided in the water supply pipe, stops the water supply into the bathtub hot water supply device 1 and further opens the water drainage plug when leaving the house for a long time. Then, the supply of electric power to the bathtub hot water supply device 1 is stopped. Here, if the device is further exposed to a low temperature, the hot water remaining in the backflow prevention device 50 freezes, and the overflow port 52 may rarely remain open. In this case, if the power is turned on and water is supplied to start the bathtub hot water supply device 1 and the pouring solenoid valve 32 is opened, a large amount of hot water leaks from the overflow port 52.
[0038]
Therefore, in the bathtub hot water supply apparatus 1 of the present embodiment, the control device 60 starts function restriction in accordance with the control flow shown in FIG. More specifically, the control device 60 detects the outside temperature t by the temperature detection sensor 90 in step 2 immediately after the power is supplied to the bathtub hot water supply device 1 in step 1. Here, when it is assumed that the outside air temperature t is higher than the predetermined temperature T and the backflow prevention device 50 is not frozen, the control device 60 advances the control flow to step 7.
[0039]
On the other hand, if the outside air temperature t is lower than the predetermined temperature T in Step 2 and there is a possibility that the backflow prevention device 50 is frozen, the control device 60 advances the control flow to Step 3. In step 3, control device 60 prohibits the opening operation of pouring electromagnetic valve 32. More specifically, in this embodiment, since pouring electromagnetic valve 32 is a normally closed electromagnetic valve, control device 60 shuts off the power supply to pouring electromagnetic valve 32 and maintains the closed state. Even if the user issues a request for pouring water to bathtub 3 to control device 60 via a remote controller (not shown) for operating bathtub hot water supply device 1, control device 60 transmits this request. cancel. As a result, water is prevented from entering the check valve 50 from the check valve 34 side, and leakage from the overflow port 52 is prevented. On the other hand, a small amount of clean water enters the backflow prevention device 50 from the measurement port 51 due to the supply pressure of clean water flowing from the water tap 87. The frozen portion of the backflow prevention device 50 is gradually thawed by the tap water that has entered from the test port 51. That is, the tap water supplied from the outside flows through the pipe on the water inlet side of the high-temperature hot water circuit 11 and the water supply branch pipe 36 branched from the pipe, and usually has a water temperature of about 10 ° C. even in winter. Therefore, the frozen portion of the backflow prevention device 50 can be gradually thawed by the tap water entering from the test port 51.
[0040]
Subsequently, in order to more reliably thaw the frozen portion of the check ring 50, the control device 60 energizes the freeze prevention heater 88 installed near the check ring 50 in step 4, and the control device 60 supplies electricity to the check ring. The heating of the device 50 is started. In step 5, when it is confirmed that a predetermined time (A minutes) has elapsed from the start of heating of the backflow prevention device 50 by the antifreeze heater 88, the control device 60 advances the control flow to step 6, and the control device 60 proceeds to step 6. The energization to 88 is stopped, and the heating of the backflow prevention device 50 ends. When the energization of the freeze prevention heater 88 is stopped in step 6, the control device 60 cancels the prohibition of the opening operation of the pouring electromagnetic valve 32 in step 7, and based on a control program similar to a known heat source device. The drive control of the bathtub water heater 1 is started.
[0041]
In the bathtub hot water supply apparatus 1 of the present embodiment, the outside temperature t is lower than the predetermined temperature T, and the overflow port 52 of the backflow prevention device 50 is opened by freezing of the hot water remaining in the backflow prevention device 50 at the time of drainage. When there is a possibility that the function is left, the above-described function restriction is performed. Therefore, in the bathtub hot water supply device 1, even if the backflow prevention device 50 keeps the overflow port 52 open due to freezing when the power is turned on, the frozen portion is gradually thawed by the tap water entering from the pressure detection port 51. Will be done. Furthermore, since the bathtub hot water supply apparatus 1 heats the backflow prevention device 50 by the antifreeze heater 88, the frozen portion of the backflow prevention device 50 is reliably thawed. Therefore, in the bathtub hot water supply apparatus 1 of the present embodiment, hot water is supplied to the backflow prevention device 50 after the backflow prevention device 50 can perform a normal operation. Therefore, the bathtub hot water supply device 1 causes water leakage in the overflow port 52 even if the hot water remaining in the backflow prevention device 50 freezes due to drainage or the like and is started with the overflow port 52 opened. Absent.
[0042]
In addition, the bathtub hot water supply apparatus 1 does not perform the function restriction described above when the outside air temperature t is higher than the predetermined temperature T, cancels the prohibition of the opening operation of the pouring electromagnetic valve 32 immediately after the power is turned on, and releases the known heat source. Drive control of the bathtub hot water supply device 1 is started by a control program similar to that of the device. Therefore, according to the above-described configuration, hot water is immediately supplied to the bathtub 3 and the bathtub circulation circuit 22 when the backflow prevention device 50 is not expected to freeze even if hot water remains at the time of drainage. Can be.
[0043]
Subsequently, a second embodiment of the present invention will be described in detail with reference to the drawings. Note that the present embodiment has a configuration similar to that of the above-described first embodiment, and thus common portions are denoted by the same reference numerals, and detailed description thereof will be omitted.
FIG. 3 is a piping system diagram of the laundry water injection device according to one embodiment of the present invention. The washing water supply device 100 of the present embodiment has substantially the same piping system as the bathtub hot water supply device 1 of the above embodiment, but has a washing water injection circuit 102 for pouring water into the washing machine 101. to differ greatly. The washing water injection circuit 102 includes a three-way valve 103, a filter 105, a water flow switch 106, and a safety valve 107.
[0044]
That is, as shown in FIG. 3, the washing water injection circuit 102 is provided with a three-way valve 103 provided in a part of the outgoing water passage 23 from the reheating unit 5 to the bathtub 3 of the washing water injection device 100, and a part thereof is branched. It is. That is, the three-way valve 103 is provided in the outgoing water passage 23 and is connected to one connection port of the filter 105. The other connection port of the filter 105 is connected to a faucet tap 108 via a water flow switch 106.
[0045]
The flow path connecting the filter 105 and the water flow switch 106 is branched midway, and is connected to the hot water supply unit 2 of the washing water injection device 100 via two check valves 34 and 35. That is, the water supply branch pipe 36 branched from the water inlet side of the high temperature hot water circuit 11 is connected to the check valve 34 via the water injection solenoid valve 110 and the governor 111. In the present embodiment, the pouring solenoid valve 32 and the water pouring solenoid valve 110 are always open and are closed by energizing. The pressure detection port 51 of the check valve 50 is connected to a pressure detection pipe 115 that is branched in the middle of the water supply branch pipe 36 and upstream of the governor 111. Further, a drop water channel 30 branched from a hot water outlet side of the high temperature hot water circuit 11 is connected to a check valve 34 side via a check valve 112 and a pouring solenoid valve 32.
[0046]
Further, a safety valve 113 is provided between the check valves 34 and 35 and the water injection solenoid valves 110 and 32. On the other hand, another safety valve 107 is attached to the filter 105, and the discharge side is connected between the three-way valve 103 and the bathtub 3.
[0047]
In the laundry water injection device 100 of the present embodiment, the remaining water in the bathtub 3, tap water, and hot water heated from tap water can be individually supplied from the faucet tap 108.
That is, when the water in the bathtub 3 is to be reheated, the three-way valve 103 is switched as shown in FIG. 3 (a), the reheating unit 5 of the washing water injection device 100 and the bathtub 3 are communicated, and the filter 105 side (miscellaneous). The water faucet 108 side) is shielded. As a result, the hot water circulates only between the bathtub 3 and the reheating unit 5.
[0048]
On the other hand, when tap water is discharged from the faucet faucet 108, the three-way valve 103 is switched as shown in FIG. 3 (b) to communicate with the filter 105 side (the faucet faucet 108 side) and shield the bathtub 3 side. I do.
Then, in this state, the water injection solenoid valve 110 is opened. As a result, tap water flows from the hot water supply unit 2 side, and reaches the check valves 34 and 35 via the governor 111 and the water injection solenoid valve 110. Then, the clean water flows into the water flow switch 106 and is discharged from the faucet faucet 108.
[0049]
Also, in the case where hot water heated from tap water is discharged from the faucet tap 108, the three-way valve 103 is switched as shown in FIG. 3 (b) to communicate with the filter 105 side (the faucet tap 108 side). Shield the three sides.
Then, in this state, the pouring solenoid valve 32 is opened. As a result, hot water flows from the hot water supply unit 2 side, and reaches the check valves 34 and 35 via the check valve 112 and the pouring solenoid valve 32. This hot water flows into the water flow switch 106 and is discharged from the faucet tap 108.
[0050]
When the remaining hot water in the bathtub 3 is to be discharged from the faucet faucet 108, the three-way valve 103 is switched as shown in FIG. 3 (b), and the filter 105 side (the faucet faucet 108 side) is communicated. Shield the side.
Then, in this state, the circulation pump 26 of the reheating unit 5 is started. As a result, the remaining hot water in the bathtub 3 is sucked into the circulation pump 26 and discharged to the outgoing-side water passage 23 via the additional heating heat exchanger 21 of the additional heating unit 5. Then, the hot water flows from the outgoing water channel 23 to the filter 105 via the three-way valve 103, and is further discharged from the miscellaneous faucet 108 via the water flow switch 106. When the remaining hot water in the bathtub 3 is discharged from the faucet faucet 108, the circulation pump 26 is temporarily stopped in a state where the water flow switch 106 detects the water flow, and the three-way valve 103 is temporarily turned off as shown in FIG. It is desirable to switch to a state where all three sides communicate with each other, and in this state, open the pouring solenoid valve 32 and introduce hot water heated to clean water into the filter 105. When the hot water is introduced into the bathtub 3 through the filter 105 in this manner, the hair and grime attached to the filter 105 are pushed back to the bathtub 3 side, and the mixing of hair and grime into the hot water discharged from the faucet faucet 108 can be prevented.
[0051]
The washing water supply device 100 of the present embodiment includes a control device 120 similar to the bathtub hot water supply device 1 described above. A program for restricting functions, which is an operation unique to the laundry water injection device 100 of the present embodiment, is input to the control device 120. Hereinafter, the operation immediately after the power supply of the laundry water injection device 100 of the present embodiment is turned on will be described in detail with reference to the flowchart shown in FIG.
[0052]
In the laundry water injection device 100 of the present embodiment, when the power of the laundry water injection device 100 is turned on in step 1, the control device 120 detects the outside air temperature t by the air temperature detection sensor 90 in step 2. Here, when the outside air temperature t is higher than the predetermined temperature T, the control device 120 determines that the backflow prevention device 50 is not frozen, and advances the control flow to step S8.
[0053]
If the outside air temperature t is lower than the predetermined temperature T in step 2, the hot water remaining in the backflow prevention device 50 at the time of drainage is frozen, and the overflow port 52 of the backflow prevention device 50 remains open. There is a concern that a large amount of water leakage may be caused by this. Therefore, control device 120 advances the control flow to step 3, prohibits the opening operation of pouring electromagnetic valve 32 and pouring electromagnetic valve 110, stops the supply of clean water to washing water injection circuit 102 side, and causes overflow port 52 To prevent water leakage from More specifically, in step 3, the control device 120 closes the pouring solenoid valve 32 and the water pouring solenoid valve 110, prohibits water flow to the check valve 34 side, and prevents water leakage from the overflow port 52. To prevent. On the other hand, a small amount of clean water infiltrates the backflow prevention device 50 from the test port 51 through the test tube 115 due to the supply pressure of clean water supplied from the outside. Therefore, the frozen portion of the backflow prevention device 50 is gradually thawed by the tap water that has entered through the test port 51.
[0054]
Subsequently, in order to more reliably thaw the frozen portion of the backflow prevention device 50, the control device 120 supplies power to the antifreeze heater 88 near the backflow prevention device 50 in step 4 and also controls the inside of the washing water injection device 100. Electric power is also supplied to the can body heater 81, the first water inlet heater 82, the second water inlet heater 83, the hot water heater 85, and the bath pump heater 86 to heat each part.
[0055]
In step 5, when it is confirmed that a predetermined time (minute A) has elapsed from the start of heating of the backflow prevention device 50 by the antifreeze heater 88, the control device 120 advances the control flow to step 6. The control device 120 detects the ambient temperature d near the backflow prevention device 50 in step 6. Here, if the ambient temperature d is higher than the predetermined temperature D, the control flow proceeds to step S7.
[0056]
On the other hand, if the ambient temperature d in the vicinity of the backflow prevention device 50 is lower than the predetermined temperature D in step 6, the control device 120 advances the control flow to step 6a, and controls the heater Continue heating. When a predetermined time (B minutes) has elapsed since the start of heating by each heater, the control device 120 advances the control flow to step 7, and stops the heating by each heater.
[0057]
When the power supply to each heater is stopped in step 7, the control device 120 releases the prohibition of the opening operation of the pouring solenoid valve 32 and the pouring solenoid valve 110, and the control of the washing and pouring device 100 by the same control program as the known heat source device. Start drive control.
[0058]
In the case where the outside temperature t is lower than the predetermined temperature T, the overflow port 52 may remain open due to the freezing of the hot water remaining in the backflow prevention device 50 in the laundry water injection device 100 of the present embodiment. Only the above-mentioned function restriction is performed. Therefore, according to the above-described configuration, when it is assumed that malfunction of the backflow prevention device 50 due to freezing does not occur, tap water can be supplied from the faucet tap 108 immediately.
[0059]
Further, in the washing water injection device 100, when the outside air temperature t is lower than the predetermined temperature T and the backflow prevention device 50 is assumed to be frozen, the antifreeze heater 88 is energized, and the backflow prevention device 50 is maintained for a predetermined time. Is to be heated. Further, in the washing water injection device 100, when the backflow prevention device 50 is heated by the heater 88 for a predetermined time and the ambient temperature d is lower than the predetermined temperature D, the backflow prevention device 50 is continuously heated, whereby the backflow prevention device 50 is heated. Thawing of the frozen portion of the prevention device 50 is further ensured. Therefore, in the washing water injection device 100 of the present embodiment, hot water is supplied to the backflow prevention device 50 after the frozen state of the backflow prevention device 50 is surely released. Therefore, according to the above-described configuration, even when the backflow prevention device 50 is frozen in a state where the overflow port 52 is opened when the power is turned on due to drainage or the like, the washing water is injected without causing water leakage from the overflow port 52. The device 100 can be started.
[0060]
Since the bathtub hot water supply device 1 and the washing water injection device 100 of the above embodiment have a configuration in which the antifreeze heater 88 is arranged near the backflow prevention device 50, the frozen portion of the backflow prevention device 50 is quickly and efficiently thawed, Water leakage from the overflow port 52 due to freezing of the backflow prevention device 50 can be reliably prevented.
[0061]
Although the bath tub hot water supply device 1 and the washing water injection device 100 of the above embodiment each have the anti-freezing heater 88, the present invention is not limited to this, and has a configuration without the anti-freezing heater 88. Is also good. That is, the above-described bath tub hot water supply device 1 and the washing water injection device 100 are configured to defrost the frozen portion with the tap water slightly entering from the pressure detection port 51 of the backflow prevention device 50 by the feed water pressure while the functions are restricted. It is also possible. Further, since the bathtub hot water supply device 1 and the laundry water injection device 100 have the burners 47 and 48 as heat sources inside, the frozen portion is thawed by the heat generated by the operation of the burners 47 and 48. Is also possible.
[0062]
In the washing water injection device 100 of the above-described embodiment, the anti-freezing heater 88 is operated for a predetermined time while the function is restricted, and at the time when the predetermined time has elapsed, the anti-freezing device 88 is controlled according to the ambient temperature d near the backflow prevention device 50. Although the embodiment in which the heating is continued is illustrated, the present invention is not limited to this. More specifically, the bathtub hot water supply device 1 and the washing water injection device 100 may perform heating by the antifreeze device 88 according to the ambient temperature d near the backflow prevention device 50. Further, the bathtub hot water supply device 1 operates the anti-freezing heater 88 for a predetermined time according to the outside air temperature, similarly to the above-mentioned washing water injection device 100, and further according to the ambient temperature d near the backflow prevention device 50 at this time. A configuration in which heating is performed by the antifreezing device 88 may be employed.
[0063]
【The invention's effect】
According to the first to third aspects of the present invention, it is possible to prevent a large amount of water leakage due to freezing of the backflow prevention device with the overflow port opened with the drainage or the like.
[0064]
Further, according to the invention as set forth in claims 4 to 6, the function of prohibiting the supply of hot or cold water to the bath tub for a predetermined time after the power is turned on is restricted, thereby reliably preventing water leakage from the overflow port. Can be.
[Brief description of the drawings]
FIG. 1 is a piping system diagram of a bathtub hot water supply apparatus according to one embodiment of the present invention.
FIG. 2 is a flowchart showing a control flow in the bathtub hot water supply apparatus shown in FIG.
FIG. 3 is a piping system diagram of the laundry water injection device according to one embodiment of the present invention.
FIG. 4 is a flowchart showing a control flow in the washing and pouring device shown in FIG. 3;
[Explanation of symbols]
1 Bathtub water heater
3 bathtub
11 Hot water circuit (water supply circuit)
22 Bathtub circulation circuit (miscellaneous water circuit)
23 Outbound waterway
24 Return-side waterway
30 Drop Waterway
32 Pouring solenoid valve
34 Check valve
35 Check valve
36 Water supply branch pipe
50 Backflow prevention device
51 Inspection port
52 overflow port
60 control device
88 Freezing prevention heater
90 Temperature detection sensor
100 washing water injection device
102 Laundry pouring circuit
110 Water injection solenoid valve
115 Test tube
120 control device

Claims (6)

A water supply pipe for supplying clean water from outside, a hot water supply circuit for heating the clean water introduced through the water supply pipe, a clean water supply from the hot water supply circuit to the bathtub, and circulation and heating of miscellaneous water in the bathtub. A possible bathtub circulation circuit, wherein between the hot water supply circuit and the bathtub circulation circuit, the overflow port is closed by the water supply pressure, and the overflow port is opened when the water supply pressure drops, And a back tub water heater provided with a backflow prevention device for preventing backwater flowing in the bath tub circulation circuit from flowing back to the water supply side. A bath tub hot water supply device, wherein a function of prohibiting supply of clean water to a circuit side is restricted. In the vicinity of the backflow prevention device, a heater for preventing freezing of the backflow prevention device is installed, and the heater is turned on for a predetermined time after the power is supplied to the bathtub hot water supply device, or the ambient temperature near the heater becomes a predetermined temperature. The bathtub hot-water supply device according to claim 1, wherein the hot-water supply device operates until the temperature of the bathtub is reached. The bathtub hot water supply apparatus according to claim 1 or 2, wherein the function restriction is released when the outside air temperature at the time of turning on the power is equal to or higher than a predetermined temperature. A water supply pipe for supplying clean water from the outside, and a washing water injection circuit for injecting miscellaneous water in the bathtub into the washing machine by performing a predetermined pumping operation, between the water supply pipe and the washing water injection circuit. A backflow prevention device is provided for closing the overflow port by the supply pressure of clean water, opening the overflow port when the supply water pressure decreases, and preventing miscellaneous water in the bathtub from flowing back to the water supply pipe side. Washing water injection device, wherein a function of prohibiting supply of clean water from the water supply pipe side to the laundry water injection circuit side for a predetermined time from power-on to the laundry water injection device is limited. apparatus. In the vicinity of the backflow prevention device, a heater for preventing freezing of the backflow prevention device is installed, and the heater is turned on for a predetermined time after the power is supplied to the bathtub hot water supply device, or the ambient temperature near the heater becomes a predetermined temperature. 5. The washing and pouring device according to claim 4, wherein the device is operated until the temperature of the washing water is reached. The washing water injection device according to claim 4 or 5, wherein the function restriction is released when the outside air temperature at the time of turning on the power is equal to or higher than a predetermined temperature.

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