JP3710860B2 - Bath system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a bath system that automatically purifies and remedies hot water in a bathtub and replenishes insufficient hot water in the bathtub.
[0002]
[Prior art]
The conventional bath system circulates hot and cold water in a bathtub through a circulation path, collects dirt such as dirt in the hot water with a filter or sterilizer provided in the circulation path, and collects germs that propagate in the hot water. Sterilized and returned to the bath. Further, the temperature of the circulating hot water is detected, and when the temperature of the hot water is lower than the set temperature, the hot water is heated by a heat exchanger provided in the circulation path and the temperature is raised to the set temperature. I was allowed to warm.
[0003]
The filter uses glass beads or the like as a filtering material, and is filtered with glass beads filled with small dust such as dirt by passing hot water. Further, a germicidal lamp such as an ultraviolet lamp is enclosed in the sterilizer, and germs are sterilized by irradiating ultraviolet rays while passing hot water through the sterilizer.
[0004]
In addition, in the case of bath systems for large baths used in hotels, public facilities, hospitals, etc., the heating water of a large boiler for hot water supply that supplies hot water to various facilities in the facility is used as a heat source for heating the heat exchanger. When the temperature of the hot water in the bathtub rises to a set temperature, the temperature adjustment is performed by stopping the circulation of the hot water and stopping the heat exchange.
[0005]
[Problems to be solved by the invention]
As described above, in the case of a conventional bath system for a large public bath, a large boiler is required. Also, in order to compensate for the decrease in hot water temperature due to the memorial service and hot water supply to external equipment and the heat loss due to natural heat dissipation, the boiler needs to be repeatedly ignited and extinguished, but precise adjustment of temperature is difficult with large boilers. There was a problem that the temperature of the hot water in the bathtub could not be adjusted accurately.
[0006]
In addition, since the temperature of the hot water supplied from the boiler to the outside is not stable, the hot water boiled in the boiler and the cold water are mixed when the water level of the hot water in the bathtub is lowered, so Even when trying to make and replenish the bathtub, there was a problem that it was difficult to accurately adjust the temperature of the mixed water.
[0007]
Furthermore, there is a problem that the fuel consumption is extremely large and uneconomical because large boilers frequently repeat ignition and extinguishing and the heating efficiency of the boiler itself is low.
[0008]
The present invention was made in order to solve the above problems, and while using the heated water of a water heating device that supplies heated water to various facilities in the facility as a heat source for hot water heating, It is an object of the present invention to provide a bath system capable of achieving stable remembrance, replenishment of hot water, fuel use efficiency and heating efficiency.
[0009]
[Means for Solving the Problems]
  The present invention employs the following means in order to solve the above problems.
  That is, the invention according to claim 1 is a hot water circulation path for sucking hot water in a bathtub with a circulation pump and returning it to the bathtub again, a filter or sterilizer for purifying the hot water in the bathtub circulating in the hot water circulation path, The hot water purification type additional device provided with a heat exchanger for heating the hot water circulating in the hot water circulation path and the temperature-controlled heating water discharged from a plurality of hot water supply devices are joined together to add the hot water purification type additional device. A hot water heating apparatus having a heated water circulation path for supplying heated water after heat exchange to the hot water supply apparatus and sucking the heated water after the heat exchange with a circulation pump and returning it to each hot water supply apparatus. Supplying water to the bath with water at a predetermined temperature obtained by mixing the heated water of the water heating device and the clean water when the water level is detected and compared with the set water level. The hot water purification The memorial device detects the temperature of hot water in the bathtub circulating in the hot water circulation path and the temperature of heated hot water supplied to the heat exchanger, and when the temperature of the hot water in the bathtub reaches a set temperature, or When the temperature of the heated water supplied to the heat exchanger falls below a predetermined temperature, the heat exchange by the heat exchanger is stopped and the hot water in the bathtub is stopped.When the hot water circulating through the hot water circulation path is heated by the heat exchanger, the circulating flow rate of the hot water circulating through the hot water circulation path is reduced, and when the hot water circulating through the hot water circulation path by the heat exchanger is not heated. Increase the circulation flow rate of hot water circulating through the hot water circulation pathIt is characterized by doing so.
[0010]
When it is set as such a structure, the hot water of a bathtub can be traced with the heating hot water supplied from the hot water heating apparatus provided with the several hot-water supply apparatus. Moreover, when the water level of the hot water of a bathtub falls, the tap water adjusted to predetermined temperature from a tap water supply apparatus can be supplied to a bathtub.
[0011]
The invention according to claim 2 is characterized in that, in the invention according to claim 1, the hot water heating device changes the number of operating hot water supply devices according to the flow rate of the heated hot water. .
[0012]
In such a configuration, since the number of operating hot water supply devices changes according to the flow rate of heated hot water, useless ignition is eliminated and fuel consumption can be reduced.
[0013]
The invention according to claim 3 is the invention according to claim 1 or 2, wherein the water heating device branches the heated water refluxed after the heat exchange to the hot water inlet side of the heat exchanger. A bypass pipe for feeding and a flow path regulating valve for variably controlling the branch flow rate of the heated clean water to the bypass pipe, and branch to the bypass pipe when the temperature of the heated clean water after the heat exchange is high Increase the flow rate to reduce the reflux flow rate of the heated hot water to the hot water supply device, and when the temperature of the heated hot water after the heat exchange is low, reduce the branch flow rate to the bypass pipe to the hot water supply device Control is performed to increase the reflux flow rate of heated water.
[0014]
When it is set as such a structure, the calorie | heat amount of heating water can be used effectively and a heating efficiency improves.
[0015]
Further, the invention according to claim 4 is characterized in that, in the invention according to claim 3, the flow path regulating valve is a heat-sensitive valve using a thermo wax element.
[0016]
In such a configuration, no dedicated control means or circuit for changing the flow dividing ratio of the flow path adjustment valve is required, so that the configuration of the apparatus can be simplified.
[0017]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below with reference to the drawings.
FIG. 1 shows an example of a bath system according to the present invention.
As shown in the figure, the bath system of the present invention includes a bathtub 1, a hot water purification type remedy device 3, a drinking water heating device 200, and a hot water supply device 400.
A purification and purifying device 3 is connected to the bathtub 1, and the hot water 2 in the bathtub 1 is circulated through the purification and purifying device 3 to purify and follow the hot water 2. The hot water purifying pursuit apparatus 3 is connected to the water heating device 200 via the heat exchanger 35, and the hot water 2 in the bathtub 1 is heated by the heated water supplied from the water heating device 200. In addition, purification is performed by introducing the heated water into the filters 18 and 24 and the filter device 7.
[0018]
Moreover, since the water level of the hot water 2 in the bathtub 1 is lowered by its use, it is necessary to supply new hot water to a desired water level. Therefore, in order to realize this, the water level is detected by the water level sensor 406 provided in the bathtub 1, and if the water level is lowered, the heated water from the return pipe 215 and the check valve 402 and the water supply are supplied. Water from the pipe 223 and the check valve 401 is mixed by the mixing valve 403 of the hot water supply device 400 to adjust to a desired temperature, and the temperature-adjusted water is supplied via the supply valve 404 and the water supply pipe 405. The bathtub 1 is replenished.
[0019]
Further, the diversion ratio of the flow path adjustment valve 218 is varied according to the temperature of the heated water after the heat exchange, and when the temperature of the heated water after the heat exchange is high, the branch flow rate to the bypass pipe 219 is changed. When the heating water recirculation flow rate to the hot water supply devices 201 to 203 is increased and the temperature of the heated hot water after heat exchange is low, the branch flow rate to the bypass pipe 219 is reduced to reduce the hot water supply device. Control is performed to increase the reflux flow rate of heated water to 201-203.
[0020]
As the mixing valve 403 and the flow path adjustment valve 218, it is simplest to use a heat-sensitive type that uses a thermowax element that can automatically change the diversion ratio depending on the temperature. The diversion ratio may be variably controlled by a motor.
[0021]
Hereinafter, the details of the structure of each of the hot water purification type remedy device 3, the hot water heating device 200, and the hot water supply device 400 constituting the bath system of the present invention will be described in order.
[0022]
In FIG. 2, the example of a structure of the said hot water purification type memorial device is shown.
In the figure, 1 is a bathtub, 2 is hot water, and 3 is a hot water purifying remedy device of the present invention. The hot water 2 stored in the bathtub 1 reaches the branch part a through the return pipe 4, the circulating hot water sensor 5, the check valve 6, and the filter device 7, and the first circulation pump 12 and the Branched into a flow path to the second circulation pump 14 via the one flow path switching valve 11, and further, a circulation flow path via the first filter 18 and the first sterilizer 21, a second filter 24 and a second sterilization It is branched into a circulation flow path via the vessel 27.
[0023]
The filter device 7 removes large debris such as hair, and a filter 8 such as a mesh for removing large debris such as hair is provided therein. Further, a second drain pipe 10 and a second drain valve 9 for draining the washing water to the outside are provided at the lower part of the filter device 7.
[0024]
The 1st filter 18 and the 2nd filter 24 remove small dusts, such as dirt, and the glass beads 20 and 26 for filtering hot water are accommodated in the inside. In addition, air tops 19 and 25 for introducing air when draining hot water accumulated in the filters are provided on the upper portions of the filters 18 and 24, respectively.
[0025]
The sterilizers 21 and 27 sterilize the germs that propagate in the hot water. The sterilizers 22 and 28 such as ultraviolet lamps are stored in the sterilizers 21 and 27, and the hot water passing through the sterilizers 21 and 27 is irradiated with ultraviolet rays. It is configured to sterilize by irradiation.
[0026]
The flow paths from the first sterilizer 21 and the second filter 24 are merged by the merge pipe 31 and reach the merge section b via the follow-up switching valve 33. In addition, the merging pipe 31 and the forward pipe 36 are connected in the merging portion b, and a circulation path for returning hot water to the bathtub 1 is configured.
[0027]
The return pipe 4 and the forward pipe 36 are constituted by large-diameter pipes, and the pipe from the branch part a to the junction part b is constituted by a pipe having a smaller diameter than the return pipe 4 and the forward pipe 36. The amount of flowing water is regulated by the pressure loss of the merging pipe 31.
[0028]
A bypass pipe 32 is connected to the junction b in parallel with the junction pipe 31. A bypass valve 34 is provided in the middle, and the bypass valve 34 is opened so that the flow rate regulated by the merging pipe 31 is released and the circulation flow rate is increased.
[0029]
Further, in the flow path from the branch part a to the second circulation pump 14, a first flow path switching valve 11 constituted by a three-way valve for switching to the flow path to the merge pipe 31 is also provided in the second circulation. A second flow path switching valve 16 comprising a three-way valve for switching the flow path from the pump 14 to the filter device 7 and the second filter 24 is further provided at the inlet to the first filter 18 and the second filter 24. A first drainage switching valve 17 and a second drainage switching valve 23 each comprising a direction valve are provided.
[0030]
A cleaning valve 30 is provided in the flow path connecting the outlet of the first sterilizer 21 and the inlet of the first filter 18. Further, a first drain pipe 29 is branched from the first drain switching valve 17 and the second drain switching valve 23 to discharge the wash water to the outside. On the outlet side of the first circulation pump 12 and the second circulation pump 14, a first flowing water switch 13 and a second flowing water switch 15 are provided for detecting flowing water from the respective pumps.
[0031]
Furthermore, the merging pipe 31 is provided with a follow-up switching valve 33 for switching to either the flow path to the heat exchanger 35 or the flow path to the merging point b. The heat exchanger 35 is composed of two flow paths for allowing the hot water 2 and the clean water in the bathtub 1 to pass through, and heats the hot water 2 from the heated hot water passing through the clean water pipe 37 through the heat exchanger 35. The hot water in the bathtub 1 is heated.
[0032]
Reference numeral 38 denotes an upper water temperature sensor that monitors the temperature of the upper water flowing through the upper water pipe 37. When the temperature of the clean water passing through the clean water pipe 37 is not more than a predetermined temperature, the hot water circulating through the heat exchanger 35 is switched by the heat exchanger 35 to the side of the junction b, assuming that the circulating hot water cannot be heated. It is provided to control so as not to pass through the heat exchanger 35.
[0033]
A water supply introduction pipe 39 is branched from the water supply pipe 37, and includes a check valve 40, a vacuum breaker valve 41 for preventing a reverse flow of sewage, a water supply introduction valve 42, and check valves 43, 44. Thus, it is configured so that clean water can be introduced into the lower portions of the first filter 18 and the second filter 24.
[0034]
As described above, the circulation channel is provided with two branch channels consisting of the circulation pumps 12 and 14 and the filters 18 and 24, respectively. The capacity of each pump and filter can be reduced as compared with an apparatus constituted by only one circulation pump and one filter. For this reason, since the pressure loss by a filter becomes small, durability improves and it can comprise a long life and a small hot water purifying pursuit apparatus.
[0035]
FIG. 3 is a block diagram showing a configuration of an electric circuit of the hot water purifying pursuit apparatus. In the figure, reference numeral 100 denotes a control unit, which includes a CPU 101, A / D converters 102 and 103 connected to the CPU 101, a RAM 106 for temporarily storing data and various information, a control program for controlling the operation of the entire apparatus, and various controls. A ROM 107 storing data and an EEPROM 125 for storing measured time such as operation time, failure warning data, and the like are provided. Reference numeral 108 denotes an I / O device for an interface between the built-in analog circuit and the CPU.
[0036]
The A / D converters 102 and 103 detect the hot water temperature sensor 5 that detects the water temperature of the hot water 2 in the bathtub 1 that flows in from the return pipe, and the temperature of the hot water that flows in the upper water pipe 37 of the heat exchanger 25. The upper water temperature sensor 38 is connected.
[0037]
The I / O device 108 includes a first pump driving circuit 109, a second pump 110, a first germicidal lamp driving circuit 111, a second germicidal lamp driving circuit 112, and driving valve driving circuits for driving each switching valve and on / off valve. 113, the 1st flowing water detection circuit 114, and the 2nd flowing water detection circuit 115 are connected.
[0038]
The first circulation pump 109 has a first circulation pump, the second circulation pump drive circuit 110 has a first circulation pump 14, the first sterilization lamp drive circuit 111 has a first sterilization lamp 22, and a second sterilization lamp drive circuit. 112, the second sterilizing lamp 28, the driving valve driving circuit 113, various driving valves, the first flowing water detection circuit, the first flowing water switch 13, and the second flowing water detection circuit 115, the second flowing water switch. It is connected.
[0039]
The first germicidal lamp driving circuit 111 and the second germicidal lamp driving circuit 112 turn on the first and second germicidal lamps 22 and 28 according to a signal from the I / O 108 and monitor the driving current of each germicidal lamp. When disconnection is detected, a signal is sent to the CPU 101 via the I / O 108. In addition, the I / O 108 is provided with a transmission / reception circuit 116 for performing communication with the external remote control unit 120.
[0040]
The controller 100 is operated by the external remote controller controller 120.
The external remote controller 120 is provided with a CPU 121, a RAM 123, a ROM 124 in which a program for operating the CPU 121 is stored, and an I / O device 122 for an interface between the built-in analog circuit and the CPU.
[0041]
The I / O device 122 includes an input circuit 126 for the operation switch 132, a temperature setting circuit 127 for the temperature setting switch 133 for setting the reheating temperature of the hot water 2 in the bathtub 1, a set temperature, various failure alarms, and the like. A display circuit 128 for driving the display device 134 for informing information, an input circuit 129 for the cleaning switch 135 for cleaning the filters 18 and 24 or changing the cleaning start time, and an alarm after the replacement of the first germicidal lamp 22 An input circuit 130 for resetting the reset switch 136 and an input circuit 131 for resetting the reset switch 137 after resetting the second germicidal lamp 27 are connected.
[0042]
FIG. 4 is an external view of the display panel unit of the external remote controller 120.
The display panel unit 134 of the external remote control device 120 is cleaning the 7-segment LED indicators 138 and 139 for displaying the set temperature, the detected temperature, the alarm information code, etc. with two-digit numbers and symbols, and the filter. Is provided with an LED 141 indicating that the temperature is being memorized up to the set temperature, and an operation switch 132 that emits light during operation. Further, a cleaning switch 135 for arbitrarily cleaning the filter and a set temperature switch 133 for changing the set temperature are provided. It should be noted that reset buttons 1 and 2 for returning all settings to the initial state are provided inside the opening / closing lid of the switch unit.
[0043]
When the operation switch 132 is in the light emission state, that is, during the filtration / retreating operation, the filter can be arbitrarily cleaned by pressing the cleaning switch 135. The washing switch 135 also serves as a washing time switching switch. When the washing switch 135 is pressed when the operation is stopped, the washing start cycle of the filter is changed from 4 hours to 2 hours, or conversely, from 2 hours to 4 hours. It can be changed arbitrarily.
[0044]
Proceeding, various operations in the hot water and water purifying filtration apparatus will be described.
The various operations described below are controlled by the control unit 100 while receiving necessary commands from the external remote controller 120 shown in FIG.
[0045]
First, the operation when pursuing while purifying hot water in the bathtub will be described with reference to the operation explanatory diagram of FIG. In addition, in FIG. 5, a dotted line shows the circulation flow path of the hot water 2 (sewage) of the bathtub 1, and a broken line shows the flow path of clean water.
[0046]
FIG. 5 shows a state in which the hot water 2 in the bathtub 1 is being purified while pursuing, and the control unit 100 causes the first flow path switching valve 11 to move from the first port 50 to the second port 51. In the flow path, the second flow path switching valve 16 flows from the first port 53 to the second port 54, and the first drainage switching valve 17 flows from the first port 56 to the second port 57. The second drainage switching valve 23 is in the flow path from the second port 60 to the third port 61, the memory switching valve 33 is in the flow path from the first port 62 to the second port 63, Each has been switched.
[0047]
The flowing water from the first circulation pump 12 and the second circulation pump 14 reaches the branch part a from the return pipe 4, and in the branch part a, the circulation flow path of the first circulation pump 12, that is, the first filter 18 and the first filter 18. The circuit is branched into a circulation path to the sterilizer 21 and a circulation path of the second circulation pump 14, that is, a circulation path to the first filter 24 and the second sterilizer 27. The branch part a divides the flowing water from the return pipe 4 having a large diameter almost evenly and flows it to each circulation path. The divided circulation paths are joined by a branch pipe 31 having a smaller diameter than the return pipe 4. Because they come together, the amount of flowing water is drastically reduced due to the pressure loss due to the difference in pipe diameter. In a state in which the amount of flowing water is drastically reduced, the hot water 2 is heated by receiving heat from the hot water flowing in the hot water 37 in the heat exchanger 35, and the heated hot water is supplied to the bathtub 1 through the return pipe 36. The hot water 2 in the bathtub 1 is heated by being refluxed.
[0048]
Thus, by reducing the amount of circulating water with the diversion pipe 31 having a small pipe diameter, the heat exchange efficiency per unit flow rate in the heat exchanger 35 is improved, and the temperature of the hot water 2 returned to the bathtub 1 is efficiently increased. Can rise. For this reason, since the hot hot water to be recirculated and the low temperature hot water in the bathtub are efficiently stirred by convection, it can be efficiently boiled up to the set temperature.
[0049]
Further, since the circulation flow rate is reduced, it becomes possible to sufficiently irradiate the ultraviolet rays for sterilization with respect to the hot water passing through the first and second sterilizers 21 and 27, and sterilize efficiently. Can do.
[0050]
Next, an operation when only purifying is performed without memorialization will be described with reference to an operation explanatory diagram of FIG. In addition, in FIG. 6, a dotted line shows the circulation flow path of the hot water 2 (sewage) of the bathtub 1, and a broken line shows the flow path of clean water.
[0051]
FIG. 6 shows the circulation when the temperature of the hot water 2 in the bathtub 1 detected by the circulating water temperature sensor 5 reaches the set temperature, or when the temperature of the water detected by the water temperature sensor 38 falls below a predetermined temperature. It represents the state of running water. When the temperature of the bathtub 1 reaches the set temperature, the control unit 100 stops heating the hot water 2, increases the circulating water flow amount, sends a large amount of hot water 2 to the filters 18, 24, and reduces the filtration amount. The hot water 2 is purified by increasing it.
[0052]
At this time, since the flow rate of the hot water passing through the first and second sterilizers 21 and 27 is increased, the ultraviolet irradiation time per unit flow rate is decreased, and the sterilization ability is decreased. That is, in this case, it concentrates on removing impurities such as dust contained in the hot water in the bathtub 1 to compensate for the purifying ability at the time of memorialization with a small circulating flow rate.
[0053]
When the temperature of the hot water 2 in the bathtub 1 reaches a set temperature, or when the water temperature falls below a predetermined temperature, the control unit 100 drives the memory switching valve 33 to switch from the first port 62 to the third port. It switches to the flow path to 64, bypasses the heat exchanger 35, and stops the heating of the hot water 2.
[0054]
Further, the bypass valve 34 is opened, and hot water whose flow rate is regulated by the merging pipe 31 having a small pipe diameter is bypassed by the bypass valve 34, thereby increasing the flow rate and returning the hot water 2 from the large diameter forward pipe 36. Increase the filtration capacity. As an example, the flow rate at this time is 60 liters / minute.
[0055]
Moreover, when the temperature of the upper water which flows through the upper water pipe 37 becomes 60 degrees C or less, for example, the hot water 2 cannot be heated and the flow path of the remnant switching valve 37 is switched to the junction part b side.
[0056]
When the hot water is purified as shown in FIGS. 5 and 6, filtered impurities such as dust accumulate in the first and second filters 18 and 24, and the filtering capacity decreases with time. Come. In addition, a large amount of hair accumulates in the filter device 7, resulting in problems such as a decrease in the amount of circulating water. For this reason, it is necessary to wash | clean the filters 18 and 24 and the filter apparatus 7 for every predetermined time. This cleaning operation will be described with reference to FIGS.
[0057]
7 shows a flow path setting state when the first filter 18 is washed, FIG. 8 shows a flow path setting state when the second filter 24 is washed, and FIG. 9 shows a flow path setting state when the filter device 7 is washed. Respectively. The first circulation pump 12 is responsible for cleaning the first and second filters 18, 24, and the second circulation pump 14 is responsible for cleaning the filter device 7. The cleaning of the filters 18 and 24 and the filter device 7 is performed every time a chasing or filtering operation is performed for a predetermined time (for example, 4 hours). In each drawing, the dotted path is a flow path for each cleaning.
[0058]
Glass beads 20 and 26 are housed in the first and second filters 18 and 24 as filter materials, and impurities such as dust that has been filtered and clogged are accumulated in the gaps between the glass beads 20 and 26. Therefore, hot water is introduced from the opposite direction of the filters 18 and 24, the glass beads are stirred from below, and dust and the like are discharged to the outside. At this time, if the cleaning flow rate is too large, the glass beads in the filters 18 and 24 are discharged to the outside, so the cleaning flow rate must be set to such an extent that the glass beads are not discharged to the outside.
[0059]
Therefore, when the first and second filters 18 and 24 are cleaned, only the first circulation pump 12 is used, and the flow rate is reduced due to the pressure loss of the circulation path, so that the filter is cleaned. The flow rate at this time is, for example, about 18 liters / minute.
[0060]
First, the cleaning of the first filter 18 in FIG. 7 will be described.
The first flow path switching valve 11 is switched from the second port 51 to the second port 52, and the second drainage switching valve 23 is closed in all directions. Further, the first drainage switching valve 17 is switched from the second port 57 to the third port 58, the cleaning valve 30 is opened, the tracking switching valve 33 is closed in all directions, and the bypass valve 34 is closed. Set the flow path.
[0061]
When the first circulation pump 12 is driven, the hot water 2 sucked from the return pipe 4 is passed through the first drain pipe 29 from the reverse direction of the first filter 18 as shown by the dotted line in FIG. Drained to the outside. At this time, the glass beads are swung up in the reverse direction to separate dust and the like and are discharged to the outside through the first drain pipe 29. Since this circulation channel is configured to have a smaller diameter than the return pipe 4, the suction flow rate of the pump 12 is regulated to such an extent that the glass beads 20 are not discharged to the outside.
[0062]
Next, cleaning of the second filter 24 in FIG. 8 will be described.
When the cleaning of the first filter 18 is finished, the second drainage switching valve 23 is switched from the first port 59 to the third port 61, the flow path in all directions of the first drainage switching valve 17 is closed, and the second drainage switching valve 17 is closed. A cleaning circuit for the filter 24 is constructed. And the 1st circulation pump 12 is driven, and the hot water 2 is discharged | emitted from the 1st drainage pipe 29 through the flow path shown with the dotted line of FIG.
[0063]
Next, cleaning of the filter 8 in FIG. 9 will be described.
The filter 8 of the filter device 7 is for removing large debris such as hair contained in the hot water 2 of the bathtub 1. In particular, when a large number of people take a bath, a large amount of garbage is captured and the flow of water is hindered. Therefore, it is necessary to periodically discharge large garbage captured by the filter 8 to the outside. Therefore, in order to remove the dust accumulated in the filter 8, hot water 2 in the bathtub 1 is introduced from the opposite side of the filter 8 by a pump and washed.
[0064]
Now, the removal of dust accumulated in the filter 8 can be effectively discharged as the amount of ejection at the beginning of water flow increases. However, when the hot water 2 of the bathtub 1 is sucked by a pump, the piping from the bathtub 1 is long. It takes time to suck in the required amount of water, and the initial ejection amount is insufficient. For this reason, even if a large-capacity pump is used, it is difficult to increase the purification efficiency. Therefore, in the present invention, in order to compensate for an insufficient amount of hot water 2 in the bathtub 1 in the cleaning of the filter 8, the hot water stored in the filters 18 and 24 is also sucked to increase the initial amount of spray, and the reverse of the filter 8. Purify by jetting from the side.
[0065]
First, the flow path of the first flow path switching valve 11 is switched from the third port 52 to the second port 51, and the second flow path switching valve 16 is switched from the first port 53 to the third port. Switch to 55. Further, the second drain valve 9 is opened, the flow path of the second drain switching valve 23 is closed in all directions, the cleaning valve 30 is opened, and the memory switching valve 33 is changed from the first port to the third port. And the bypass valve 34 is opened to set the flow path.
[0066]
When the second circulation pump 14 is driven, the hot water stored in the filters 18 and 24 and the hot water 2 of the bathtub 1 sucked from the forward pipe 36 are flown as indicated by the dotted line in FIG. It is introduced from the reverse side of the filter device 7, applies water pressure from the back side of the filter 8, and discharges it together with dust from the second drain pipe 10.
[0067]
As described above, when the filter device 7 is cleaned, not only the hot water 2 of the bathtub 1 but also the hot water of the filters 18 and 24 are used to compensate for the shortage of the initial ejection amount, and further, the hot water from the forward pipe 36 is used. In order to suck the water efficiently, hot water is sucked not only from the merging pipe 31 but also from the bypass pipe 32 to obtain the amount of water for washing the filter device 7.
[0068]
19 and 25 are air tops, which introduce air into the filter as the hot water in the filters 18 and 24 decreases, that is, the internal pressure of the filter decreases. It is something to do.
[0069]
Now, the hot water purifying remedy apparatus 3 removes debris in the hot water with the first and second filters 18 and 24 and is sterilized with the sterilizers 21 and 27. While circulating hot water 2, germs attached to the glass beads 20, 26 in the filters 18, 24 propagate and return to the bathtub 1 while being sterilized by the germicidal lamps 22, 28. Breed. For this reason, even if sterilization is performed by the sterilizers 21 and 27, it becomes an equilibrium state with a certain number of bacteria, and it is difficult to perform complete sterilization. Therefore, it is necessary to periodically sterilize the germs in the first and second filters 18 and 24 and the piping on the way and discharge them to the outside to prevent the germs from breeding.
[0070]
This sterilization operation will be described with reference to FIG.
This sterilization is performed by introducing high temperature heated water supplied from the water pipe 37 into the filters 18 and 24 and sterilizing at high temperature, and discharging the mixed water of dead sterilized bacteria to the outside. Done. In FIG. 10, a dotted line is a flow path at that time.
[0071]
First, the first flow path switching valve 11 is switched to the flow path from the first port 50 to the second port 51, and the second flow path switching valve 16 is flowed from the first port 53 to the second port 54. Switch to the road. Further, the first drainage switching valve 17 is switched to the flow path from the second port 57 to the third port 58 and the second drainage switching valve 23 is switched to the flow path from the first port 61 to the third port 59. Then, the second drain valve 9, the washing valve 30, and the bypass valve 34 are closed, and the memory switching valve 33 is closed in all directions.
[0072]
Subsequently, when the clean water introduction valve 42 is opened, high temperature clean water flowing through the clean water pipe 37 is introduced into the filters 18 and 24 via the check valve 40, the vacuum breaker valve 41, and the check valves 43 and 44. It is discharged to the outside through the first drain pipe 29.
[0073]
The temperature of the water flowing through the water supply pipe 37 is 60 ° C. to 70 ° C., and the water supply introduction valve 42 is opened for a predetermined time or more necessary for sterilization, and the high temperature water is passed through the filters 18 and 24. The internal glass beads 20 and 26 are agitated by high temperature clean water introduced from the opposite side of the filters 18 and 24, and the adhering germs are sterilized. At the same time, dead bodies of germs are discharged to the outside by the inflow pressure of clean water. Is done.
[0074]
The check valves 40, 43, and 44 and the vacuum breaker valve 41 are edge cutting means provided to prevent sewage from mixing into the clean water.
[0075]
Next, a series of processing operations from FIG. 5 to FIG. 10 will be described with reference to the flowcharts of FIG. 11 and FIG.
[0076]
In step S1, the 1st circulation pump 12 and the 2nd circulation pump 14 are driven, and circulation of hot water 2 of bathtub 1, ie, filtration of hot water, is started.
[0077]
In step S2, lighting of the germicidal lamps 22 and 28 is started. That is, sterilization of the hot water 2 is started.
[0078]
In step S3, it is determined whether or not the measured value of the first filtration integration time has been cleared. If yes, then continue with step S4, otherwise, go to step S5.
[0079]
In step S4, integration of the first filtration integration time, that is, the time during which the circulation pump is driven, is started. This first filtration integration time is for cleaning the filter after 4 hours have elapsed since the start of the filtration operation.
[0080]
It should be noted that the accumulated cleaning start time can be changed from 4 hours to 2 hours, or conversely from 2 hours to 4 hours, by pressing the cleaning switch 135 (see FIG. 4) while the operation is stopped. This is to restore the filtration capacity by arbitrarily changing the washing time of the filter depending on the degree of contamination of hot water in a large-capacity bathtub for business use.
[0081]
In step S5, it is determined whether or not the measured value of the first filtration integration time has been cleared. If yes, then continue with step S6, otherwise continue with step S7.
[0082]
In step S6, integration of the second filtration integration time, that is, the time during which the circulation pump is driven is started. This second filtration integration time is for performing sterilization washing with high-temperature water in the filter and the circulation path after 24 hours have elapsed since the start of the filtration operation.
[0083]
In step S7, it is determined whether or not the temperature of the heated water flowing through the water pipe 37 detected by the water temperature sensor 38 is, for example, 60 ° C. or higher. If it is 60 ° C. or higher, the process proceeds to step S8 on the assumption that hot water 2 in the bathtub 1 can be chased, and if it is less than 60 ° C., the process proceeds to step S11 on the assumption that chasing is impossible.
[0084]
In step S8, it is determined whether the temperature of the hot water detected by the circulating water temperature sensor 5 is equal to or lower than a set temperature. If the temperature is equal to or higher than the set temperature, it is determined that the chasing is unnecessary, and the process proceeds to step S11. If the temperature is lower than the set temperature, the process proceeds to step S9 so as to perform chasing.
[0085]
In step S9, the bypass valve 30 is closed as in the flow path indicated by the dotted line in FIG. 5 to allow the circulating water to flow into the merging pipe 31, and the flow rate is reduced to 36 liters / minute due to the pressure loss.
[0086]
In step S <b> 10, the flow path of the follow-up switching valve 33 is switched to the flow path from the first port 62 to the second port 63, and the circulating hot water 2 is passed through the heat exchanger 35. And in this heat exchanger 35, the temperature of the hot water 2 in the bathtub 1 is raised by exchanging heat with the hot water flowing through the water pipe 37 and returning to the bathtub 1.
[0087]
In step S11, the bypass valve 30 is opened as in the flow path indicated by the dotted line in FIG. 6 so that the hot water 2 is returned to the outgoing pipe 36 in parallel with the merging pipe 31, and the circulation flow rate is increased to 60 liters / minute. As a result, the amount of filtration and purification of the hot water 2 in the bathtub 1 is increased, and dust and the like are efficiently recovered.
[0088]
Then, in step S12, the heat exchanger 35 is bypassed by switching the flow path of the renewal switching valve 33 from the first port to the third port, and setting is made so as not to recycle the circulating water.
[0089]
In step S13, it is determined whether 4 hours (or 2 hours) have elapsed as the first filtration integration time. When 4 hours (or 2 hours) have passed, the process proceeds to step S15, and the process proceeds to the washing operation of the filter.
[0090]
In step S14, it is determined whether 24 hours have passed as the second filtration integration time. When 24 hours have elapsed, the process proceeds to step S20, and the process proceeds to a sterilization operation such as a filter using high temperature water.
[0091]
Steps S15 to S19 represent the cleaning operations of the filters 18, 24 and the filter device 7.
[0092]
First, in step S15, the operations of the first circulation pump 12 and the second circulation pump 14 are stopped. That is, the circulation of the hot water 2 by the memorial operation and the purification operation is stopped.
[0093]
Subsequently, in step S16, the germicidal lamps 22 and 28 are turned off.
[0094]
In step S17, the first filter 18 and the second filter 24 are cleaned as in the flow path shown by the dotted lines in FIGS. The cleaning flow rate at this time is, for example, 18 liters / minute.
[0095]
In step S18, large dust such as hair accumulated in the filter 8 of the filter device 7 is removed as in the flow path indicated by the dotted line in FIG. In order to compensate for the initial flow rate for cleaning, hot water stored in the first filter 18 and the second filter 24 is introduced into the filter device 7 together with hot water introduced from the forward pipe 36, and purification is performed.
[0096]
In step S19, the integrated value of the first filtration time is cleared, and the process returns to step S1.
[0097]
Subsequently, the sterilization operation of a filter or the like with high-temperature clean water from step S20 to step S23 will be described.
[0098]
First, in step S20, the operations of the first circulation pump 12 and the second circulation pump 14 are stopped. That is, the circulation of the hot water 2 by the memorial operation and the purification operation is stopped.
[0099]
Subsequently, the ultraviolet germicidal lamps 22, 28 are turned off in step S21.
[0100]
Next, in step S22, the filters 18 and 24 are sterilized with high-temperature water as shown by the broken line in FIG. The temperature of the water to be introduced for sterilization is 60 ° C. or more, water is passed for about 1 minute to sterilize, and the water is discharged to the outside together with dead bodies of various bacteria. Since the dead bodies of germs are discharged to the outside, the dead bodies do not become a new breeding source of germs.
[0101]
In step S23, the integrated value of the second filtration time is cleared, and the process returns to step S1.
[0102]
In the hot water purifying memorial device, the germs that propagate on the filters 18 and 24 are sterilized with high-temperature clean water, but this sterilization with clean water is incomplete unless exposed to high temperatures for a predetermined time or longer. Become. Therefore, the sterilization process using high temperature clean water will be described in detail with reference to the flowchart of FIG.
[0103]
The sterilization with the high temperature clean water is performed by introducing clean water above a predetermined temperature into the filter for a predetermined time and discharging the clean water after sterilization to the outside. If the water temperature falls below a predetermined temperature before the predetermined time elapses during sterilization, the sterilization operation of the filter is stopped and the temperature of the water is recovered. In this case, the water is passed again for a predetermined sterilization time.
[0104]
First, in step S30, it is determined whether or not the accumulated time of filtration, that is, hot water circulation has passed 24 hours. In the case of YES, it progresses to the sterilization process after step S31.
[0105]
In step S31, it is determined whether or not the temperature of the water passing through the water pipe 37 detected by the water temperature sensor 38 is 60 ° C. or higher. If it is 60 degreeC or more, it will progress to step S32, and if it is less than 60 degreeC, it will wait until the water temperature rises to 60 degreeC or more.
[0106]
In step S32, the circulation pumps 12 and 14 are stopped to introduce clean water.
[0107]
In step S33, the flow path is switched as shown by a dotted line in FIG. 10, the clean water introduction valve 42 is opened, high temperature clean water heated to the filters 18 and 24 is introduced, and the clean water after cleansing is first. Both the dead bodies of germs are discharged from the drain pipe 29 to the outside.
[0108]
In step S34, it is determined whether the detected temperature from the water temperature sensor 38 has dropped below 60 ° C. during the introduction of the water. If it is less than 60 ° C., the process proceeds to step S35, and if it is 60 ° C. or more, the process proceeds to step S38.
[0109]
In step S35, it is determined that the temperature of the clean water is not suitable for sterilization, and the clean water introduction valve 42 is closed.
[0110]
In step S36, the water supply introduction time is cleared. This is because sterilization is completed by always introducing clean water above a predetermined temperature for a predetermined time.
[0111]
In step S37, since the sterilization of the filter was interrupted in step S35, switching to the circulation path of FIG. 5 to FIG. 6 was resumed, and purification and renewal of hot water was resumed. Wait until it returns to.
[0112]
In step S38, it is determined whether or not a predetermined time has elapsed after the introduction of clean water. If clean water is continuously introduced for a predetermined time, the process proceeds to step S39. As this predetermined time for introducing clean water and sterilizing, about 5 to 10 minutes are assumed, for example.
[0113]
In step S39, the filtration circulation integration time, that is, data indicating that 24 hours have elapsed is cleared, and the process returns to step S30 to repeat the above operation.
[0114]
As described above, in the present invention, sterilization is always completed by introducing clean water at a predetermined temperature or higher into the filters 18 and 24 continuously for a predetermined time, and the propagation of germs in the hot water 2 is prevented. .
[0115]
Next, a control operation for appropriately notifying the bather when various troubles and failures occur in the hot water purifying pursuit apparatus will be described.
[0116]
First, the abnormality detection operation of the germicidal lamps 22 and 28 will be described with reference to the flowchart of FIG.
While using the sterilizing lamps 22 and 28, the sterilizing ability may be reduced due to disconnection or the like. Therefore, in the present invention, when the life of the germicidal lamp is approaching, a notification is given to prompt replacement, and a notification is given to replace it as soon as it is disconnected.
[0117]
In step S40, it is determined whether the apparatus is in operation. If it is not in operation, the process proceeds to step S41, and the alarm operation due to the disconnection of the germicidal lamps 22 and 28 or the near end of the service life is stopped. This is often used continuously for 24 hours in a commercial bathtub, and when stopping operation, maintenance such as periodic inspection and cleaning is usually performed, and it is necessary to notify when operation stops Because there is no.
[0118]
In step S42, integration of the lighting time of the germicidal lamps 22 and 28 is started.
[0119]
In step S43, the first and second germicidal lamp drive circuits 111 and 112 (see FIG. 3) detect the current values of the respective germicidal lamps 22 and 28, and check for disconnection. If disconnection occurs, the I / O 108 is detected. A disconnection signal is sent to the CPU 101 and the CPU 101 recognizes the disconnection.
[0120]
Subsequently, in step S44, the CPU 101 determines whether the disconnected germicidal lamp is the first germicidal lamp 22, the second germicidal lamp 28, or both, and the disconnected germicidal lamp. Are stored in the RAM 106 and the EEPROM 125.
[0121]
In step S45, the broken germicidal lamp is notified. The disconnection notification is performed by displaying a failure code such as “10” on the displays 138 and 139 of the external remote control device 120. At this time, if the first germicidal lamp 22 is disconnected, the indicator 139 blinks. If the second germicidal lamp 28 is disconnected, the indicator 138 is blinked, and both germicide lights are disconnected. When it is, both the indicators 138 and 139 are blinked.
[0122]
In addition, for the notification of the disconnection, an arbitrary display lamp such as the cleaning lamp 140 is used. If the first germicidal lamp is disconnected, the lamp blinks once every predetermined period, and the second germicidal lamp is disconnected. In such a case, it is possible to use a method in which the lamp blinks twice every predetermined period, and when both germicidal lamps are disconnected, the lamp blinks three times every predetermined period.
[0123]
In step S46, it is determined whether each of the first germicidal lamp 22 and the second germicidal lamp 28 has been lit for a predetermined lifetime.
[0124]
In step S47, the germicidal lamp that has been lit for a predetermined lifetime is stored in the RAM 106 and the EEPROM 125. Although this lifetime varies depending on the germicidal lamp, for example, 1000 hours is set, and when 1000 hours have passed, notification is made so as to prompt replacement even when the germicidal lamp is not disconnected.
[0125]
In step S48, it is determined whether a disconnection alarm has been issued. If a disconnection alarm has been issued, the disconnection alarm is given priority for notification.
[0126]
In step S49, it is notified that the life of the germicidal lamp is approaching. This notification is performed by displaying a failure code such as “11” on the indicators 138 and 139 of the remote control device. In order to notify the germicidal lamp that has reached the end of its life, the corresponding indicator or indicator lamp blinks, as in the case of the disconnection display described above.
[0127]
In accordance with the disconnection alarm or the life alarm, the user appropriately replaces the corresponding germicidal lamp, and after the replacement, the corresponding reset switches 136 and 137 of the external remote controller 120 are appropriately pressed to cancel the alarm.
[0128]
Next, the failure detection operation of the circulation pumps 12 and 14 will be described with reference to the flowchart of FIG.
When a failure occurs in the circulation pump, troubles such as the inability to perform pursuit and purification occur because the circulation of hot water stops. In the conventional apparatus of this type, it is common to provide a running water switch or the like in the circulation flow path, detect circulating running water, determine whether the pump is stopped, and issue an alarm.
[0129]
However, there are sometimes accidents in which the contact of the relay circuit that drives the circulation pump is stuck and the circulation pump remains driven even though the stop command for the circulation pump is issued. It cannot be detected by the conventional method.
[0130]
In particular, in the case of the hot water purifying type remedy device, since the hot water in the bathtub 1 is heated in the heat exchanger 35, the circulation pumps 12 and 14 are driven even though the operation is stopped. There is a risk that the heat will be released from the exchanger 35 and the temperature of the hot water 2 in the bathtub 1 will rise above the set temperature. Further, when the pump is driven at the time of cleaning or sterilizing the filters 18 and 24, there is a risk that the pump life may be reduced due to the circulation pump being driven in the closed circuit. Therefore, in the present invention, such a problem is eliminated by performing processing as shown in the flowchart of FIG.
[0131]
15 will be described. In step S50, it is determined whether or not a stop command is issued to the circulation pumps 12 and 14. When the stop command for the circulation pump is issued, the process proceeds to the failure detection mode in step S51 and subsequent steps.
[0132]
In step S51, it is confirmed by the flowing water switches 13 and 15 whether or not the circulation pumps 12 and 14 that should not operate originally are operating due to contact fixing of the relay circuit or the like.
[0133]
In step S52, the circulating pump that is operating is stored in the RAM 123 and the EEPROM 125.
[0134]
In step S53, considering the temperature rise of the hot water 2 in the bathtub 1 or the life reduction of the circulation pump, each switching valve is operated so as to form a circulation path as shown in FIG. By switching to the flow path from the first port 62 to the third port 64, the heat exchanger 35 is bypassed, and the temperature rise of the hot water 2 in the bathtub 1 is prevented.
[0135]
In step S54, it is confirmed whether an operation command has been issued. When the operation command is issued, the process proceeds to step S55, and when it is not issued, the process proceeds to step S57.
[0136]
In step S55, the circulating pump in operation is notified by contact fixing of the relay or the like. For this failure notification, a failure code such as “12” is displayed on the displays 138 and 139 of the external remote control device 120. Further, in the same manner as in the case of the disconnection display or the life display described above, the corresponding indicator or display lamp blinks to determine whether or not the first circulation pump 12 and the second circulation pump 14 have failed.
[0137]
In step S56, the CPU 101 issues an operation stop command to forcibly stop the operations of the circulation pumps 12, 14, the germicidal lamps 22, 28, the switching valve, and the like.
[0138]
In step S57, the CPU 101 reconfirms from the running water switches 13 and 15 whether or not there is an operating circulation pump. This is because the contact of the relay contact is temporary, the contact is restored after a certain time, and the operation of the circulating pump may stop, so that it is confirmed whether it has stopped or not stopped.
[0139]
In step S58, the circulating pump that has stopped operating and the circulating pump that is operating are stored in the RAM 106 and the EEPROM 125.
[0140]
In step S59, it is confirmed whether all the circulation pumps have been stopped. If all the circulation pumps are not stopped, the process proceeds to step S54, and the operations from step S54 to step S58 are repeated. On the other hand, if all the circulation pumps are stopped, the process proceeds to step S60.
[0141]
In step S60, the alarm stored in the RAM 106 and the EEPROM 125 that all the circulation pumps have returned to the stopped state is deleted.
[0142]
In step S61, the chase switching valve 33 is switched to the flow path toward the heat exchanger 35, and is shifted to a state where chase is possible. The reason for shifting to the state in which this is possible is to circulate the heated running water as a freeze prevention when the outside air temperature decreases.
[0143]
The processing operation for failure detection has been described above, but in the case of the present invention, priority is provided to the failure codes displayed on the external remote control device 120. That is, the fault code indicating the occurrence of poor circulation of hot water due to the failure of the circulation pumps 12 and 14 is displayed with priority over an alarm such as disconnection of the germicidal lamps 22 and 28. This is because bathing is possible even if the germicidal lamps 22 and 28 are out of order, but if the circulation pumps 12 and 14 are out of order, the basic function as a memory device is impaired.
[0144]
Next, a water heating apparatus for supplying hot water for heating to the heat exchanger 35 of the hot water purifying apparatus 3 will be described with reference to FIGS.
[0145]
Supply of clean water to the heat exchanger 25 of the hot water purifying pursuit apparatus 3 is performed by supplying hot water heated by, for example, an oil boiler or a gas hot water supply device, and the hot water after heat exchange is discarded outside. It is also possible to circulate hot water discharged from an oil boiler, a gas hot water supply device, or the like. However, in view of the fact that the present invention is intended for large business baths with large capacities, as shown in FIG. 16, a plurality of (for example, about 2 to 8) hot water supply devices are provided side by side, and required hot water is provided. The water heating apparatus 200 configured to automatically increase / decrease the number of hot water supply devices to be operated according to the flow rate and the heat retention temperature was used.
[0146]
That is, FIG. 16 is provided with three hot water supply apparatuses 201 to 203, and the first hot water supply apparatus 201 includes a heat exchanger 207 and a burner 211 for heating the heat exchanger 207. . The inlet end of the heat exchanger 235 is connected to the inlet pipe 204 via the incoming water amount sensor 206 and the incoming water temperature sensor 205, and the outlet end of the heat exchanger 207 is the outlet hot water pipe 210 via the outlet water temperature sensor 208 and the water flow valve 209. It is connected to the. In addition, fuel is supplied to the burner 211 via a fuel main valve 212 and a fuel proportional valve 213.
[0147]
The second hot water supply device 202 and the third hot water supply device 203 have the same configuration as the first hot water supply device 201. In addition, in the example of this FIG. 16, although the three hot-water supply apparatuses were installed side by side, the number of installation is determined according to the maximum amount of water to be used.
[0148]
The water intake pipes 204 of the hot water supply apparatuses 201 to 203 are respectively connected to the water supply pipe 224, and clean water is supplied through the water supply pipe 224, the water supply pipe 223, the check valve 222, and the water supply pump 221. On the other hand, the hot water pipes 210 of the hot water supply apparatuses 201 to 203 are respectively connected to the hot water supply pipe 226, and the hot water heated by the hot water supply apparatuses through the hot water supply pipe 226, the check valve 214, and the return pipe 215 is purified. It is supplied to the water pipe 37 of the heat exchanger 35 of the type tracking device 3.
[0149]
The clean water supplied to the hot water purifying pursuit apparatus 3 through the return pipe 215 is returned to the hot water supply apparatuses 201 to 203 from the forward pipe 216 and the recovery pipe 220 via the water supply pipe 224 again. That is, the hot water supply pipe 226, the return pipe 215, the hot water pipe 37 of the heat exchanger 35 of the hot water purifying pursuit apparatus 3, the forward pipe 216, and the recovery pipe 220 constitute a circulation path of clean water. This circulation path is circulated by a circulation pump 217.
[0150]
The water supply pump 221 supplies clean water stored in a water receiving tank or the like to the circulation path at a predetermined pressure, and a pressure drop that occurs when the clean water in the circulation path is taken out from the faucet 227 or the like. Depending on the situation, an appropriate amount of clean water is supplied to the circulation path. Further, check valves 214 and 225 are provided in the circulation path to prevent backflow.
[0151]
Reference numeral 219 denotes a bypass pipe that connects the forward pipe 216 and the return pipe 215, and a flow path adjustment valve 218 that adjusts the flow rate returning to the recovery pipe 220 and the flow rate returning to the return pipe 215 from the bypass pipe 219 is provided at the branch point. ing.
[0152]
In addition, each hot water supply device has a maximum effective amount of hot water that can be heated to a predetermined temperature and discharged, and the hot water supply device as a whole has a number of hot water supply devices sufficient to satisfy the required maximum amount of hot water. . For example, if the maximum effective amount of hot water for a single hot water supply device is 10 liters / minute and the required maximum amount of hot water for the entire water heating device is 30 liters / minute, three hot water supply devices are provided as shown. Will be.
[0153]
In addition, the circulation flow rate of clean water circulated by the circulation pump 217 includes three hot water supply devices in order to prevent the three hot water supply devices 201 to 203 from simultaneously burning and increasing the amount of fuel used. Circulate at such a flow rate that one or two of them operate. Since this circulating heated water only circulates in the circulation path, it may be heated to the extent that it compensates for the loss due to heat dissipation.
[0154]
When tap water is discharged from the faucet 227 or the like, the pressure loss in the circulation path is released and the flow rate restriction is released, so that new tap water is supplied to the water supply pump according to the amount of hot water discharged to the outside. The number of hot water supply devices that are replenished by the heat pump 221 and that corresponds to the hot water flow rate at this time is operated.
[0155]
FIG. 17 is a block diagram of an electric circuit of the water heating device 200.
The main control device 300 controls the operation of the entire device, and is connected to the control units 301 to 303 of the hot water supply devices 201 to 203 and the external remote control device 304. The main control device 300 receives detection data such as the temperature and the amount of water sent from the control units 301 to 303, and gives an operation command to the control units 301 to 303. Based on this operation command, each control unit 301 to 303 gives a drive command to the water flow valve 209, the fuel main valve 212, the fuel proportional valve 213, and the like of each hot water supply device.
[0156]
FIG. 18 is a detailed block diagram of the main controller 300 and the external remote controller 304.
The main control device 300 includes a CPU 310, an I / O device 311 for interface, a RAM 312 for temporarily storing data and various information, a ROM 313 storing a control program and various control data for controlling the entire operation, and a failure warning. An EEPROM 314 for storing data and the like is provided. Further, the I / O device 311 is connected with transmission / reception devices 315 to 317 for transmitting / receiving data to / from each of the control units 301 to 303 and a transmission / reception circuit 318 for performing communication with the external remote control device 304. ing.
[0157]
The external remote control unit 304 is provided with a CPU 320, an I / O device 321, a RAM 322, and a ROM 323 that stores a program for operating the CPU 121. Further, the I / O device 321 is notified of information such as a start circuit 324 for the operation switch 327, a temperature setting circuit 325 for the temperature setting switch 328 for setting the temperature of the clean water, a set temperature, various failure alarms, and the like. A display circuit 326 for driving the display device 329 is connected.
[0158]
FIG. 19 is a detailed block diagram of the control unit 301 (302, 303) of the hot water supply apparatus 201 (202, 203).
The control unit 301 (302, 303) includes a CPU 330, an I / O device 331, A / D converters 332, 333 connected to the CPU 101, a RAM 334 for temporarily storing data and various information, and a control for controlling operations. A ROM 335 in which programs and various control data are stored is provided. The A / D converters 332 and 333 include an incoming water temperature sensor 205 that detects the temperature of clean water flowing into the heat exchanger 207 from the incoming water pipe 204, and a heated water that is discharged from the heat exchanger 207 to the hot water outlet pipe 210. A hot water temperature sensor 208 for detecting the temperature of the clean water is connected.
[0159]
The I / O device 331 includes a water valve driving circuit 336 for driving the water valve 209, a fuel main valve driving circuit 337 for driving the fuel main valve 212, a fuel proportional valve driving circuit 338 for driving the fuel proportional valve 213, A waveform shaping circuit 339 for converting a flow rate signal to the heat exchanger 207 detected by the incoming water sensor 206 into a waveform signal suitable for control, and a transmission / reception circuit 340 for transmitting / receiving data to / from the main controller 300 are connected. Yes.
[0160]
Next, the operation of the water heating apparatus 200 configured as described above will be described in detail.
First, main controller 300 issues an operation command to first hot water supply apparatus 201. The control part 301 of the 1st hot water supply apparatus 201 opens the water flow valve 209 by this operation command. Then, the clean water enters the heat exchanger 207 through the water supply pipe 224 and the water inlet pipe 204 and is discharged from the hot water outlet pipe 210. This inflow of clean water is detected by the incoming water amount sensor 206, and the operation proceeds to the ignition operation of the burner 211, and the detected incoming water amount is transmitted to the main controller 300.
[0161]
Main controller 300 calculates the number of hot water supply devices to be operated based on the amount of incoming water sent from first hot water supply device 201. For example, when the maximum effective hot water discharge amount of one hot water supply device is 10 liters / minute and the incoming water amount is 30 liters / minute, it is determined that it is necessary to drive three hot water supply devices, and the second hot water supply device 202, An operation command is also transmitted to the third hot water supply device 203. Thereby, the 2nd hot-water supply apparatus 202 and the 3rd hot-water supply apparatus 203 also start operation.
[0162]
A set temperature is transmitted from the main control device 300 to the control units 301 to 303 of each hot water supply device, and each control unit stores the set temperature in the RAM 334 and stores the detected incoming water temperature, incoming water amount, outgoing hot water temperature and the like. Based on the set temperature, the amount of fuel supplied to each burner 211 is calculated, and the opening of each fuel proportional valve 213 is adjusted to heat the clean water. The hot water of each hot water supply apparatus heated to the set temperature is discharged from the hot water supply pipe 210, and the hot water supply pipe 226, the return pipe 215, the upper water pipe 37 and the forward pipe 216 of the heat exchanger 35 of the hot water purification type pursuit apparatus 3. It circulates through the circulation path of the circulation pump 217 and the recovery pipe 220.
[0163]
Now, when the circulating water is heated to the set temperature, each of the hot water supply apparatuses 201 to 203 stops combustion and enters a standby state. However, since the circulation amount by the circulation pump 217 is kept substantially constant, the main control is performed. The device 300 continues to issue commands to open the water flow valve 209 to the control units 301 to 303 of each hot water supply device. For this reason, the water that has been heated to the set temperature circulates through each heat exchanger 207, but by passing through this heat exchanger, a large amount of heat from the water is released to the outside. As a result, the temperature of clean water drops within a short time.
[0164]
As a result, each burner 211 is repeatedly ignited and stopped frequently, fuel consumption for heating increases, and hot water always passes through the heat exchanger, so that corrosion or the like is likely to occur in the heat exchanger. Become. Therefore, in the present invention, the bypass pipe 219 and the flow path adjustment valve 218 are provided in the circulation flow path so that the circulated clean water is bypassed to the return pipe 215 in accordance with the temperature of the circulated clean water.
[0165]
As shown in FIG. 20, the flow path adjusting valve 218 includes a thermo wax element 350 enclosing wax that expands and contracts by heat, a heat sensitive part 351 incorporating the thermo wax element 350, and a pressing spring 355. Two valve bodies 353 and 354 for adjusting the partial flow rate are formed on the outer periphery of the heat sensitive part 351. For example, the thermo-wax element 350 that expands and contracts in the range of 55 ° C. to 75 ° C. is used, the set temperature of the hot water supply device is set to 65 ° C., and the temperature at which the heat sensitive unit 351 senses heat exceeds 65 ° C. Then, the adjustment screw 356 is adjusted so that the thermal part 351 moves upward, and when the temperature is lower than 65 ° C., the thermal part 351 moves downward.
[0166]
When the heat sensitive part 351 is warmed by the clean water passing through the valve, the thermo wax element 350 expands, and the protruding pin 352 at the tip pushes the adjusting screw 356, and the heat sensitive part 351 is moved upward against the pressing spring 355. Push up. On the other hand, when the temperature of the clean water decreases, the thermo wax element 350 contracts and the protruding pin 352 retracts, and the heat-sensitive portion 351 is pushed downward by the pressing spring 355.
[0167]
Accordingly, if the temperature of the clean water rises, the valve body 354 side opens and the flow rate in the A direction increases, and if the temperature of the clean water decreases, the valve body 353 side opens and the flow rate in the B direction increases. Furthermore, when the temperature of the clean water is high enough to stop the combustion of all the hot water supply apparatuses 201 to 203, most of the circulated clean water is bypassed by the flow path adjustment valve 218, and the flow rate on the recovery pipe 220 side. Decrease. For this reason, at the time of high temperature, the heat of the clean water is not released from the heat exchanger 207 to the outside, and the temperature of the heated clean water is not suddenly decreased.
[0168]
The above point will be described in more detail. When the temperature of the hot water rises due to heating by the hot water supply devices 201 to 203, the amount of the hot water returned to the hot water supply devices 201 to 203 is reduced by the action of the flow path adjustment valve 218. The main control unit 300 calculates the total flow rate from the incoming water amount sensor 206 of each hot water supply device, and when the total incoming water amount is reduced to less than 10 liters / minute, the water flow valves 209 of the second and third hot water supply devices 202 and 203 are used. Is closed, the second and third hot water supply devices 202 and 203 are stopped, and only the first hot water supply device 201 is heated.
[0169]
In the first hot water supply apparatus 201, in order to constantly detect the temperature and amount of the circulated fresh water with the incoming water temperature sensor 205 and the incoming water amount sensor 206, the temperature of the upper water reaches the set temperature and the combustion is stopped. However, the water valve 209 is left open without closing.
[0170]
When the temperature of the circulated water decreases over time, the flow path adjustment valve 218 increases the amount of reflux in the B direction. When the amount of water detected by the incoming water amount sensor 206 of the first hot water supply apparatus 201 becomes 10 liters / minute or more, the second hot water supply apparatus 202 is operated. Further, when the amount of hot water discharged increases due to the external hot water discharge and the total water amount detected by the first and second hot water supply devices 201 and 202 increases to 20 liters / minute or more, the third hot water supply device 203 is also operated. In this way, clean water can be efficiently heated while minimizing fuel consumption.
[0171]
FIG. 21 is a block diagram of an electric circuit of the hot water supply device 400.
A water level setting unit 451 that sets the water level of the hot water 2 in the bathtub 1, a water level detection unit 452 that detects the water level of the hot water in the bathtub 1 from the output signal of the water level sensor 406, a replenishment that drives the replenishment valve 404. The water level of the hot water 2 in the bathtub 1 detected by the water level detection unit 452 and the water level set in the water level setting unit 451 are compared in the water level comparison control unit 453, and the water level of the hot water 2 is set. When it is lower than the water level, the replenishing valve driving unit 454 is driven to open the replenishing valve 404, and control is performed so that the water having a predetermined mixing temperature is replenished to the bathtub 1 through the water replenishing pipe 405.
[0172]
【The invention's effect】
  As described above, when the invention according to claim 1 is used, the hot water circulation path for sucking hot water in the bathtub by the circulation pump and returning it to the bathtub again, and the filtration for purifying the hot water in the bathtub circulating in the hot water circulation path A hot water purification-type remedy device provided with a heat exchanger for heating hot water circulating in the hot water circulation path and a temperature-adjusted heated hot water discharged from a plurality of hot water supply devices. A hot water heating apparatus having a heated water circulation path for supplying the heated hot water after the heat exchange to the respective hot water supply devices again by a circulation pump, The water level of hot water is detected and compared with the set water level. When the water level is lower than the set water level, the bathtub is replenished with water at a predetermined temperature obtained by mixing the heated water and the clean water of the clean water heating device. A water supply device, The hot water purification pursuit apparatus detects the temperature of the hot water in the bathtub circulating in the hot water circulation path and the temperature of the heated hot water supplied to the heat exchanger, and the temperature of the hot water in the bathtub reaches the set temperature. Or when the temperature of the heated water supplied to the heat exchanger falls below a predetermined temperature, the heat exchange by the heat exchanger is stopped and the hot water in the bathtub is stopped.When the hot water circulating through the hot water circulation path is heated by the heat exchanger, the circulating flow rate of the hot water circulating through the hot water circulation path is reduced, and when the hot water circulating through the hot water circulation path by the heat exchanger is not heated. To increase the circulation flow rate of hot water circulating through the hot water circulation pathAs a result, it is possible to stably carry out replenishment and replenishment of clean water using a clean water heating device including a plurality of hot water supply devices. For this reason, while being able to provide a comfortable bathing environment, it becomes possible to aim at the effective use of the water heating device which supplies heating water to various facilities.In addition, the circulation flow rate can be reduced when the heat exchanger is used to improve the heat exchange efficiency of the heat exchanger, and the circulation flow rate can be increased during non-heating to improve the purification efficiency by the filter. Can do. For this reason, it becomes possible to perform a memorial and purification in a well-balanced manner, maintaining the temperature of hot water at an appropriate temperature, and providing a clean bathing environment. Moreover, since the heat exchange efficiency is improved, it is possible to reduce the size of the hot water supply device that supplies heated water to the heat exchanger and to reduce the amount of fuel used.
[0173]
According to the second aspect of the present invention, since the water heating device changes the number of operating hot water supply devices in accordance with the flow rate of the heated hot water, there is no hot water supply device that is ignited wastefully, and the fuel Consumption can be reduced. For this reason, the efficiency of fuel use can be improved.
[0174]
According to the invention of claim 3, the water supply heating device branches the heated water recirculated after the heat exchange to the hot water inlet side of the heat exchanger and supplies the bypass pipe, and the bypass pipe And a flow path regulating valve that variably controls the branch flow rate of the heated water to be heated, and when the temperature of the heated water after the heat exchange is high, the branch flow rate to the bypass pipe is increased to the hot water supply device. The reflux flow rate of the heated clean water is reduced, and when the heated clean water temperature after the heat exchange is low, the branch flow rate to the bypass pipe is reduced to increase the reflux flow rate of the heated clean water to the hot water supply device. Since it did in this way, the calorie | heat amount of heating water can be used effectively and the improvement of a heating efficiency can be aimed at.
[0175]
Furthermore, according to the invention described in claim 4, since the flow path adjustment valve is composed of a thermosensitive valve using a thermowax element, a dedicated control means or circuit for changing the diversion ratio of the flow path adjustment valve is provided. I don't need anything. For this reason, simplification and cost reduction of the apparatus can be achieved.
[Brief description of the drawings]
FIG. 1 is a diagram showing an example of a bath system according to the present invention.
FIG. 2 is a diagram showing a configuration of a hot and cold purifying memorial device 3;
FIG. 3 is a block diagram showing a configuration of an electric circuit of the hot water purifying memorial device 3;
4 is an external view of a display panel unit of the external remote control device 120. FIG.
FIG. 5 is a flow path diagram when performing pursuit while purifying hot water in a bathtub.
FIG. 6 is a flow chart in the case where only purification is performed without memorialization.
FIG. 7 is a flow path diagram when the first filter 18 is washed.
FIG. 8 is a flow path diagram during cleaning of the second filter 24;
FIG. 9 is a flow path diagram during cleaning of the filter device 7;
FIG. 10 is a flow path diagram during sterilization of the filters 18, 24 with high-temperature clean water.
FIG. 11 is a flowchart of the overall processing operation of the hot and cold purification type remedy device 3;
FIG. 12 is a flowchart (continuation of FIG. 11) of the overall processing operation of the hot and cold purifying apparatus 3;
13 is a flowchart of the sterilization operation of the filters 18, 24. FIG.
14 is a flowchart of an abnormality detection operation for germicidal lamps 22 and 28. FIG.
FIG. 15 is a flowchart of a failure detection operation of the circulation pumps 12 and 14;
16 is a diagram showing a configuration of a water heating device 200. FIG.
17 is a block diagram of an electric circuit of the water heating device 200. FIG.
18 is a detailed block diagram of main controller 300 and external remote controller 304. FIG.
FIG. 19 is a detailed block diagram of control unit 301 (301, 302) of hot water supply apparatus 201 (202, 203).
20 is a cross-sectional view showing the structure of the flow path adjustment valve 218. FIG.
FIG. 21 is a block diagram of an electric circuit of the hot water supply device 400. FIG.
[Explanation of symbols]
1 Bathtub
2 hot water
3 Hot water purification type memorial device
7 Filter device
13 First running water switch
12 First circulation pump
14 Second circulation pump
15 Second running water switch
18 First filter
21 First sterilizer
24 Second filter
27 Second sterilizer
35 Heat exchanger
200 Water heater
201-203 hot water supply device
204 Inlet pipe
205 Water temperature sensor
206 Water volume sensor
207 heat exchanger
208 Hot water temperature sensor
209 Water valve
210 Hot water pipe
211 burner
215 Return pipe
216 Outward pipe
217 Circulation pump
218 Flow path adjustment valve
219 Bypass pipe
220 Recovery tube
221 Water supply pump
223 Water supply pipe
224 water supply pipe
226 Hot water supply pipe
350 Thermo wax element
400 Water supply device
403 Mixing valve
404 Supply valve
405 Water supply pipe

Claims (4)

Hot water circulation path for sucking hot water in the bathtub and returning to the bathtub again, a filter or sterilizer for purifying the hot water in the bathtub circulating in the hot water circulation path, and heating the hot water circulating in the hot water circulation path A hot water purifying memorial device equipped with a heat exchanger,
Heated hot water whose temperature is adjusted and discharged from a plurality of hot water supply devices are joined and supplied to the heat exchanger of the hot water purifying purifier, and the heated hot water after heat exchange is sucked by a circulation pump. A water heater with a heated water circulation path that recirculates to each water heater;
The water level of the hot water in the bathtub is detected and compared with a set water level. When the water level is lower than the set water level, the water at a predetermined temperature obtained by mixing the heated water and the clean water of the clean water heating device is supplied to the bathtub. It consists of a water supply device that supplies water,
The hot water purification type remedy device detects the temperature of hot water in a bathtub circulating in the hot water circulation path and the temperature of heated hot water supplied to the heat exchanger,
When the temperature of the hot water in the bathtub reaches a set temperature, or when the temperature of heated hot water supplied to the heat exchanger decreases below a predetermined temperature, the heat exchange by the heat exchanger is stopped to Stop the memorial of hot water in the bathtub ,
When heating the hot water circulating through the hot water circulation path by the heat exchanger, the circulation flow rate of hot water circulating through the hot water circulation path is reduced,
A bath system characterized by increasing the circulating flow rate of hot water circulating through the hot water circulation path when the hot water circulating through the hot water circulation path by the heat exchanger is not heated . The bath system according to claim 1, wherein the hot water heating device changes the number of operating hot water supply devices according to a flow rate of hot water discharged from the heated hot water. The water heating device is
A bypass pipe for branching and feeding the heated water refluxed after the heat exchange to the hot water inlet side of the heat exchanger;
A flow path adjustment valve that variably controls the branch flow rate of heated water to the bypass pipe,
When the temperature of the heated water after the heat exchange is high, increase the branch flow rate to the bypass pipe to reduce the reflux flow rate of the heated water to the hot water supply device,
The control is performed such that when the temperature of the heated water after the heat exchange is low, the branch flow rate to the bypass pipe is reduced and the reflux flow rate of the heated water to the hot water supply device is increased. The bath system according to 1 or 2. The bath system according to claim 3, wherein the flow path adjustment valve is a heat-sensitive valve using a thermo wax element.

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