JP3675114B2 - Bath water purifier - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a bathtub water cleaning apparatus that performs cleaning processing such as filtration on bath water in a bathtub and keeps it constantly clean.
[0002]
[Prior art]
In recent years, bath water in a bathtub is sucked up by a circulation pump, and the dirt of the bath water is filtered by a filtration device and the bath water is heated by a heater to keep the bath water in the bathtub always clean and at a suitable temperature for 24 hours. A bath water cleaning device has been developed to make it possible to take a bath at any time and is now widely used.
[0003]
As what is conventionally used as a bathtub water purification apparatus as mentioned above, there exists a thing as shown in FIG. This is formed by connecting the bathtub water cleaning device main body 4 and the inside of the bathtub 1 with a suction flow path 3 and a discharge flow path 9. Here, in the bathtub water purification apparatus main body 4, a circulation pump 6, a filtration tank 5, and a heater 7 are provided, and between the circulation pump 6 and the filtration tank 5 and between the filtration tank 5 and the heater 7. Each is provided with a filtration tank channel 21 and a heater channel 22. The circulation pump 6 is connected to the suction flow path 3, and the heater 7 is connected to the discharge flow path 9. A prefilter 10 is provided at the opening in the bathtub of the suction flow path 3, and a nozzle 11 is provided at the opening in the bathtub of the discharge flow path 9. Here, the pre-filter 10 is provided with a sponge as a filtering material, and the filtration tank 5 is provided with a fiber ball as a filtering material and a cleaning bacterium for biodegradation.
[0004]
When the bathtub water purification apparatus as described above is activated, the bath water 2 in the bathtub passes through the prefilter 10 and is introduced into the suction flow path 3 by the action of the circulation pump 6. At this time, the dirt in the bath water 2 having a particle diameter of about 1 to 10 μm or more is removed by a sponge which is a filtering material of the pre-filter 10. The bath water 2 introduced into the suction flow path 3 passes through the circulation pump 6, passes through the filtration tank flow path 21, and is introduced into the filtration tank 5. In the bath water 2 introduced into the filtration tank 5, dirt having a particle size of about 1 to 10 μm or more that has not been removed by the pre-filter 10 is removed by a fiber ball as a filtering material, and the particle size is 0.001 μm or less. The very fine dirt and the dirt dissolved in the bath water 2 are removed by the purification action of the biodegradable cleaning bacteria. The bath water 2 purified in this way is introduced into the heater 7 via the heater flow path 22 and heated in the heater 7. The bath water 2 heated by the heater 7 is sent to the discharge flow path 9 and ejected from the nozzle 11 into the bathtub 1. The bath water 2 spouted from the nozzle 11 stirs the bath water 2 in the bathtub 1 so that the bath water 2 does not stagnate in a part of the bathtub 1 and the bath water 2 in the bathtub 1 is used as a bath water purifier. It can be circulated universally.
[0005]
[Problems to be solved by the invention]
However, the dirt in bath water 2 is not only sand, mud, hair, and dirt, but also chemicals that dissolve in bath water such as soap, cosmetics, and kneading agents, secretions from the body, or insoluble matters in tap water, It is composed of various substances such as general bacteria, and its size varies. Among these stains, the stain having a particle size of about 1 to 10 μm or more, the extremely fine stain having a particle size of 0.001 μm or less, and the stain dissolved in the bath water 2 are as shown in FIG. Although it could be removed by the conventional bath water cleaning apparatus shown, those having a particle size of 0.001 to 10 μm could not be removed. Therefore, particulate bacteria having a particle diameter of 0.001 to 10 μm and colloidal dirt remain in the bath water 2, causing the bath water 2 to become cloudy.
[0006]
In the conventional bathtub water cleaning apparatus shown in FIG. 19, when the filter medium in the filter tank 5 is clogged and colloidal dirt cannot pass through, the colloidal particle size is 0.001 to 10 μm. In order to remove the dirt of bacterial particles having a particle size of 0.001 to 10 μm, the organic matter containing colloidal dirt in the bath water 2 is removed from the filtration tank 5. The bacteria have been reduced by decomposition by the organism-cleaning bacteria, and have been sterilized by chlorine or ozone. However, in order to remove the colloidal dirt in the bath water 2 with the filter medium in the filter tank 5, the filter medium in the filter tank 5 needs to be clogged to some extent as described above. When removing dirt with the filter medium in the filtration tank 5 and when organic substances are decomposed by the biological purification bacteria in the filtration tank 5 to reduce the growth of bacteria, a bath water cleaning device is installed. Immediately after the replacement of the filter medium, the colloidal dirt cannot be removed in the filtration tank 5, and the colloidal dirt is removed in the filter tank 5 only after the dirt adheres to the filter medium and causes some clogging. In addition, the contamination of the colloidal organic matter can be decomposed by the biocleaning bacteria, so that until then, the bathing water 2 has to be endured or the bathing water 2 must be replaced. It was free et al. Further, when sterilizing with chlorine or ozone, if the sterilizing action is too strong, the biologically purified bacteria in the filter tank 5 will be sterilized. Therefore, in the case of chlorine sterilization, the chlorine concentration is 0.2 ppm. In the case of ozone sterilization, the ozone concentration must be suppressed to 0.1 ppm or less in consideration of the influence on the human body. In the case of sterilization by ultraviolet rays, the sterilization ability is low due to reflection by water. These were quite unacceptable as auxiliary sterilization means.
[0007]
Therefore, it is conceivable to use a microfiltration filter that removes dirt having a particle diameter of 0.001 to 10 μm in order to filter the bath water 2, but if the bath water 2 is passed through the microfiltration filter, the flow of the bath water 2 is reduced. Therefore, the amount of the bath water 2 circulating in the apparatus is reduced and the cleaning efficiency of the bath water 2 is deteriorated, and the bath water 2 ejected from the discharge passage 9 into the bathtub 1 is reduced. The flow rate of water is also reduced, and the effect of the jetted bath water 2 stirring the bath water 2 in the bathtub 1 is reduced, so that the bath water 2 stagnates in a part of the bathtub 1 and There is also a risk that the water purifier cannot be circulated evenly. In order to solve this problem, a considerable amount of work must be given when the bath water 2 is circulated, and the burden on the circulation pump 6 becomes large. In addition, since the microfiltration filter is quickly clogged, it is necessary to stop the operation of the bathtub water purification device and replace expensive filter media each time, which is time-consuming and expensive. When the filter is clogged, it becomes difficult for the bath water 2 to circulate in the bathtub water cleaning device, and a great burden is placed on the circulation pump 6.
[0008]
The present invention has been made in view of the above points, and filters particulate bacteria and colloidal dirt having a particle diameter of 0.001 to 10 μm using a microfiltration filter. The purpose is to provide a bathtub water cleaning device that can reliably perform the cleaning function immediately after installation and can circulate the bath water in the bathtub uniformly to the bathtub water cleaning device and is easy to maintain. It is what.
[0009]
[Means for Solving the Problems]
The invention according to claim 1 of the present invention is a bathtub water cleaning device for cleaning while circulating the bath water 2 in the bathtub 1 using the circulation pump 6, wherein the bathtub 1 is disposed upstream of the circulation pump 6. A suction passage 3 for sucking the bath water 2 therein, and a discharge passage 9 for discharging the cleaned bath water 2 on the downstream side of the circulation pump 6. An introduction port for the microfiltration filter 12 is provided from the discharge passage 9. A microfiltration filter introduction flow path 16 for sending the bath water 2 to 31 is provided by branching from the discharge flow path 9, and the bath water 2 filtered in the microfiltration filter 12 is sucked from the outlet 32 of the microfiltration filter 12. The microfiltration filter lead-out channel 17 to be sent to the passage 3 is provided between the lead-out port 32 of the microfiltration filter 12 and the suction channel 3.
[0010]
Ma Vomiting A switching valve 26 capable of adjusting the flow rate is provided at a branch point between the outlet passage 9 and the microfiltration filter introduction passage 16.
Ma Vomiting A microfiltration filter cleaning channel 19 for sending the bath water 2 from the outlet channel 9 to the cleaning water inlet 33 of the microfiltration filter 12 is branched from the discharge channel 9 and switched to a branch point from the discharge channel 9. In addition to providing the valve 27, the drainage flow path 18 for draining the bath water 2 that has passed through the microfiltration filter 12 and used for cleaning from the cleaning water discharge port 34 of the microfiltration filter 12 to the outside of the bath water purifier is microfiltered. It is characterized by being connected to the cleaning water discharge port 34 of the filter 12.
[0011]
Claims of the invention 2 The invention described in claim 1 In addition to the above configuration, a microfiltration filter circulation washing channel 20 for sending the bath water 2 used for cleaning the microfiltration filter 12 to the suction channel 3 is branched from the drainage channel 18 and switched to the branch point. The valve 28 is provided.
Claims of the invention 3 The invention described in claim 1 Or 2 In addition to the configuration described above, air is mixed into the microfiltration filter cleaning flow path 19 with an air pump 15 or an ejector.
[0012]
Claims of the invention 4 The invention described in claim 3 In addition to the above structure, the microfiltration filter cleaning flow path 33 is provided with an air pump 15 or an ejector.
Claims of the invention 5 The invention described in claim 1 Thru 4 In addition to any of the configurations, the switching valve 27 provided at the branch point between the discharge flow path 9 and the microfiltration filter cleaning flow path 19, and the branch point between the drainage flow path 18 and the microfiltration filter circulation cleaning flow path 20 The provided switching valve 28 is constituted by a mechanical timer powered by running water.
[0013]
Claims of the invention 6 The invention described in claim 1 to claim 1 5 In addition to any of the configurations, the microfiltration filter 12 is installed outside the bathtub water purifier main body.
[0014]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below.
FIG. 1 shows an example of an embodiment of the present invention. In the example of the embodiment of the present invention shown in FIG. 1, the bath water cleaning device is provided with a circulation pump 6, a heater 7, a normal filter 13, a chlorine generation (input) device 14, and a microfiltration filter 12. It is. Further, a suction flow path 3 is provided between the bathtub 1 and the circulation pump 6, and the inside of the bathtub 1 and the circulation pump 6 are connected to each other, and between the chlorine generation (input) device 14 and the inside of the bathtub 1. Is provided with a discharge passage 9, which connects the chlorine generation (input) device 14 and the inside of the bathtub 1. A prefilter 10 is provided at the opening in the bathtub 1 of the suction flow path 3. Further, a heater flow path 24 is provided between the circulation pump 6 and the heater 7, a normal filter flow path 25 is provided between the heater 7 and the normal filter 13, and the normal filter 13 and the chlorine generation (input) device 14 are connected. Between them, a chlorine generating (feeding) device flow path 25 is provided. Further, a microfiltration filter introduction flow channel 16 for sending the bath water 2 from the discharge flow channel 9 to the introduction port 31 of the microfiltration filter 12 is provided to be branched from the discharge flow channel 9 and is filtered in the microfiltration filter 12. A microfiltration filter outlet channel 17 is provided between the outlet port 32 of the microfiltration filter 12 and the suction channel 3 so that the bath water 2 is sent from the outlet 32 of the microfiltration filter 12 to the suction channel 3. A switching valve 26 capable of adjusting the flow rate is provided at a branch point between the discharge flow path 9 and the fine filtration filter introduction flow path 16, and a valve 29 is provided in the fine filtration filter lead-out flow path 17. In addition, a fine filtration filter cleaning channel 19 for sending the bath water 2 from the discharge channel 9 to the cleaning water inlet 33 of the microfiltration filter 12 is provided to be branched from the discharge channel 9. A switching valve 27 is provided at the branch point of the water and drains the bath water 2 used for washing after passing through the microfiltration filter 12 from the washing water discharge port 34 of the microfiltration filter 12 to the outside of the bath water purifier. The drainage flow path 18 is provided so as to be connected to the washing water discharge port 34 of the microfiltration filter 12. Further, a microfiltration filter circulation cleaning channel 20 for sending the bath water 2 used for cleaning the microfiltration filter 12 to the suction channel 3 is provided to be branched from the drainage channel 18, and a switching valve is provided at the branch point. 28 is provided. The microfiltration filter cleaning flow path 33 is provided with an air pump 15 (which may be an ejector). A switching valve 27 provided at a branch point between the discharge flow path 9 and the precision filtration filter washing flow path 19 and a branch point between the drainage flow path 18 and the precision filtration filter circulation washing flow path 20 are provided. The switching valve 28 is constituted by a mechanical timer powered by running water.
[0015]
Here, the pre-filter 10 is provided with a sponge as a filtering material, and can filter dirt having a diameter of 1 to 10 μm or more. Further, the normal filter 13 is provided with a fiber ball or the like as a filtering material, and can filter dirt having a diameter of 1 to 10 μm or more.
Here, the microfiltration filter 12 can filter particulate dirt having a diameter of 0.001 to 10 μm in the bath water 2. FIG. 12 shows an example of the microfiltration filter 12. This is a form called a hollow fiber module, which uses a filtration membrane 35 formed of a hollow fiber membrane as a filter material, and includes a filtration membrane 35 formed of a hollow fiber membrane in a box-type filter container 38. It is made up of. The inside of the filter container 38 is separated by a filtration membrane 35 formed of a hollow fiber membrane, and a stock solution chamber 36 and a filtrate chamber 37 are formed. Holes that open from the stock solution chamber 36 to the outside are formed in three places. These are the introduction port 31, the cleaning water injection port 33, and the cleaning water discharge port 34, respectively. In addition, one hole that opens from the filtrate chamber 37 to the outside is formed, and serves as the outlet 32 described above. Here, the inlet 31 and the outlet 32 are formed on opposite sides of the filtration membrane 35, and the cleaning water inlet 33 and the cleaning water outlet 34 are formed on a straight line across the stock solution chamber 36. It is something. The microfiltration filter 12 used in the present invention is not limited to the hollow fiber module described above, and various types of microfiltration filters such as a tubular module, a pleat module, a spiral module, and a plate (flat membrane) module can be used. It can be used.
[0016]
Here, the circulation pump 6, the heater 7, the normal filter 13, the chlorine generation (input) device 14, and the microfiltration filter 12 are housed in the bathtub water purifier main body 4 installed outside the bathtub 1. is there.
FIG. 2 shows a circulation path of the bath water 2 when the bath water 2 in the bathtub 1 is circulated and cleaned using the bathtub water cleaning apparatus shown in FIG. Here, the switching valve 26 is adjusted so that the bath water 12 sent from the chlorine generation (input) device 14 can be sent to both the direction of the bathtub 1 of the discharge passage 9 and the microfiltration filter outlet passage 16. The switching valve 27 is adjusted so that the bath water 2 sent from the switching valve 26 side of the discharge passage 9 can be sent only in the direction of the bathtub 1 of the discharge passage 9. The switching valve 28 is configured so that the bath water 2 sent from the washing water discharge port 34 of the microfiltration filter 12 to the drainage flow path 18 flows into both the drainage side of the washing water discharge port 34 and the circulation washing flow path 20. The valve 29 is adjusted so as not to be sent, and the valve 29 is in an open state.
[0017]
When the bathtub water cleaning device is activated in the above-described state, the bath water 2 in the bathtub 2 passes through the prefilter 10 and is sent to the suction flow path 3 by the action of the circulation pump 6. At this time, the hair and the like in the bath water 2 and large dirt of 1 to 10 μm or more are removed by the sponge provided in the pre-filter 10. The bath water 2 sent to the suction flow path 3 passes through the circulation pump 6, is sent to the heater 7 via the heater flow path 23, and is heated in the heater 7. The bath water 2 sent to the heater 7 is usually sent to the normal filter 13 via the filter flow path 24, and the diameter 1 that could not be removed by the pre-filter 10 by a filter medium such as a fiber ball provided in the normal filter 13. Particulate dirt of 10 μm or more is removed. Usually, the bath water 2 sent to the filter 13 is sent to the chlorine generation (introduction) device 14 via the chlorine generation (introduction) device flow path 25 and supplied with chlorine for sterilization. The bath water 2 sent to the chlorine generation (input) device 14 is sent to the discharge passage 9. The bath water 2 sent to the discharge flow path 9 is divided at the switching valve 26 into one sent to the direction of the bathtub 1 of the discharge flow path 9 and one sent to the microfiltration filter outlet flow path 16. The bath water 2 sent in the switching valve 26 in the direction of the bathtub 1 of the discharge channel 9 is discharged into the bathtub 1 from the opening in the bathtub 1 of the discharge channel 9, and the bath in the bathtub 1 is driven by the discharged momentum. Water 2 is agitated. Further, the bath water 2 sent to the microfiltration filter outlet flow channel 16 in the switching valve 26 is sent from the inlet 31 of the microfiltration filter 12 to the stock solution chamber 36 in the microfiltration filter 12, and a filtration membrane formed of a hollow fiber membrane. It passes through 35 and is sent to the filtrate chamber 37. Here, when the bath water 2 passes through the filtration membrane 35 formed of a hollow fiber membrane, particulate dirt having a diameter of 0.001 to 10 μm that has not been removed by the pre-filter 10 in the bath water 2 is removed. is there. The bath water 2 sent to the stock solution chamber 37 is sent from the outlet 32 to the outside of the microfiltration filter 12, and again through the microfiltration filter outlet channel 17. Inhalation It is sent to the flow path 3. From the microfiltration filter outlet channel 17 Inhalation Bath water 2 sent to channel 3 is from bathtub 1 Inhalation Together with the bath water 2 sent to the flow path 3, it circulates in the bathtub water cleaning device again as described above, and in the process from the microfiltration filter outlet flow path 17 Inhalation From bath water 2 and bathtub 1 sent to channel 3 Inhalation The bath water 2 sent to the flow path 3 is mixed.
[0018]
When the bath water 2 is circulated and cleaned as shown in FIG. 2 using the bath water cleaning apparatus shown in FIG. 1 as described above, the microfiltration filter 12 has a diameter of 0.001 to 10 μm. By removing particulate bacteria and colloidal dirt, it is possible to prevent white turbidity of the bath water 2 immediately after the installation of the bath water purifier or immediately after the replacement of the filter medium. Since it becomes difficult to clog, it is possible to reduce the trouble of replacing the filter medium, and even if the microfiltration filter 12 is clogged, it is possible to secure a sufficient flow rate of the bath water 2 circulating in the bath water purifier. The flow rate of the bath water 2 sent from the discharge flow path 9 into the bathtub 1 can be secured, so that a great burden is not imposed on the circulation pump 6, and even if the microfiltration filter 12 is clogged, Discharge flow Since the flow rate of the bath water 2 sent into the bathtub 1 from 9 can be secured, the bath water 2 in the bathtub 1 is stirred by the flow rate of the bath water 2 sent into the bathtub 1 from the discharge channel 9, and the bath 1 is bathed in the bath 1. The water 2 does not stagnate in part, and the bath water 2 in the bathtub 1 can be circulated in the bathtub water purifier uniformly. In addition, the positive pressure of the circulation pump 6 is applied to the inlet 31 of the microfiltration filter 12 from the microfiltration filter introduction channel 16 provided by branching from the discharge channel 9, and the microfiltration filter connected to the suction channel 3. Since the suction force of the circulation pump 6 acts from the outlet channel 17 to the outlet port 32 of the microfiltration filter 12, the pressure difference between the inlet port 31 and the outlet port 32 of the microfiltration filter 12 can be increased. The flow rate of the bath water 2 passing through the filtration filter 12 can be increased, the purification ability of the microfiltration filter 12 can be increased, and the purification ability of the bathtub water purifier can be improved. Furthermore, since the bath water 2 purified by the microfiltration filter 12 is reliably mixed with the bath water 2 circulating in the bath water cleaning device in the process of circulating in the bath water cleaning device, Only the bath water 2 that has passed does not stagnate inside the bathtub 1, and the degree of mixing of the bath water 2 that has passed through the microfiltration filter inside the bathtub 1 can be made favorable.
[0019]
Here, the switching valve 26 is capable of adjusting the flow rate as described above, and the flow rate of the bath water 2 sent from the switching valve 26 toward the bathtub 1 of the discharge flow path 9 and the microfiltration filter introduced from the switching valve 26. The ratio of the flow rate of the bath water 2 sent to the flow path 16 can be arbitrarily changed. Since the switching valve 26 capable of adjusting the flow rate is provided at the branch point between the discharge flow channel 9 and the microfiltration filter introduction flow channel 16 as described above, the switching valve 26 is used when the bath water 2 in the bathtub 1 is largely cloudy. The switching valve 26 is adjusted so that the ratio of the flow rate of the bath water 2 sent to the microfiltration filter introduction flow path 16 is increased, so that the bath water 2 in the bathtub 1 has little or no cloudiness. If there is not, the switching valve 26 is adjusted so that the ratio of the flow rate of the bath water 2 sent from the switching valve 26 to the microfiltration filter introduction flow path 16 is reduced or the bath water 2 is not sent to the microfiltration filter introduction flow path 16. For example, the ratio of the flow rate of the bath water 2 sent to the microfiltration filter introduction flow path 16 can be arbitrarily changed depending on the degree of contamination of the bath water 2 in the bath 1. Microfiltration filter regardless of dirt Always without such through a constant bath water 2, in which it can reduce clogging of the microfiltration filter 12. Moreover, the ratio of the flow rate of the bath water 2 sent from the switching valve 26 to the microfiltration filter introduction flow path 16 can be increased to rapidly purify the bath water 2 in the bathtub 1.
[0020]
FIG. 3 shows the path of the bath water 2 when the filtration membrane 35 of the microfiltration filter 12 is washed using the bathtub water cleaning apparatus shown in FIG. Here, the switching valve 26 is adjusted so that the bath water 2 sent from the chlorine generation (input) device 14 can be sent only in the direction in the bathtub 1 of the discharge flow path 9, and The switching valve 27 is adjusted so that the bath water 2 sent from the switching valve 26 side of the discharge channel 9 can be sent only to the microfiltration filter cleaning channel 19. The bath water 2 sent from the washing water discharge port 34 of the microfiltration filter 12 to the drainage flow path 18 is adjusted so that all the bath water 2 can be sent to the drainage side of the drainage flow path 18. The valve 29 is preferably in a closed state.
[0021]
When the bathtub water purification apparatus is activated in the state as described above, the bath water 2 in the bathtub 1 is sent to the switching valve 26 as in the case of FIG. 2 is sent to the bathtub 1 side of the discharge flow path 9, and all the bath water 2 sent to the switching valve 27 is sent to the microfiltration filter washing flow path 19. The bath water 2 sent to the microfiltration filter cleaning flow path 19 is sent from the cleaning water inlet 33 of the microfiltration filter 12 to the stock solution chamber 36 in the microfiltration filter 12. The bath water 2 sent to the stock solution chamber 36 is cleaned by removing the dirt adhering to the filtration membrane 35 of the microfiltration filter 12 by the impact force due to the flow velocity, and the cleaning water discharge port 34 of the microfiltration filter 12 together with the removed dirt. To the discharge channel 18. All the dirt removed from the bath water 2 and the filtration membrane 35 sent to the discharge channel 18 is discharged out of the bath water purifier.
[0022]
When the bath water 2 is circulated as shown in FIG. 2 and the bath water 2 is circulated and cleaned as shown in FIG. 2 using the bath water purifier shown in FIG. 1, dirt adheres to the filtration membrane 35 of the microfiltration filter 12. There is a risk that clogging may occur and the purification capacity of the bath water purifier may be reduced. However, when the filter membrane 35 of the microfiltration filter 12 is contaminated and clogged, the switching valves 26 and 27 are clogged. , 28 can be used to clean the filtration membrane 35 of the microfiltration filter 12 as shown in FIG. 3, so that the purification capability of the microfiltration filter 12 can be recovered, and the microfiltration filter 12 can be purified. The ability can be maintained for a long time. Furthermore, the dirt in the bath water 2 removed by the microfiltration filter 12 can be reliably thrown out of the bath water purifier through the drainage flow path 18. Here, when bubbles are mixed into the bath water 2 sent to the stock solution chamber 36 in the microfiltration filter 12 by the air pump 15 (or ejector), vibrations of the bubbles in the stock solution chamber 36 cause the filter membrane 35 of the microfiltration filter 12 to be filtered. The effect of removing attached dirt can be further increased.
[0023]
FIG. 4 shows a path of the bath water 2 when the filtration membrane 35 of the microfiltration filter 12 is circulated and washed using the bathtub water cleaning apparatus shown in FIG. Here, the switching valve 26 is adjusted so that the bath water 2 sent from the chlorine generating (feeding) device 14 can be sent only in the direction of the bathtub 1 of the discharge passage 9. The valve 27 is adjusted so that the bath water 2 sent from the switching valve 26 side of the discharge flow path 9 can be sent only to the microfiltration filter cleaning flow path 19, and the switching valve 28 is precision. The bath water 2 sent from the washing water discharge port 34 of the filtration filter 12 to the drainage flow path 18 is adjusted so that all the bath water 2 can be sent to the circulation washing flow path 20. The valve 29 is preferably in a closed state.
[0024]
When the bathtub water cleaning device is started in the above-described state, the bath water 2 in the bathtub 1 is cleaned by removing the dirt adhering to the filtration membrane 35 of the microfiltration filter 12 as in the case of FIG. After being sent to the switching valve 28 of the drainage flow path 18 from the cleaning water discharge port 34 of the microfiltration filter 12 together with the removed dirt, all are sent to the circulation cleaning flow path 20. When the bath water 2 sent to the circulation cleaning channel 20 reaches the connection position between the ring cleaning channel 20 and the suction channel 3, it is sent again to the circulation pump 6 side of the suction channel 3 by the action of the circulation pump 6. The filtration membrane 35 of the microfiltration filter 12 is washed while circulating in the bathtub water purification device. When the cleaning of the filtration membrane 35 of the microfiltration filter 12 is completed, the switching valve 28 is used to drain all the bath water 2 sent from the cleaning water discharge port 34 of the microfiltration filter 12 to the drainage flow path 18. The flow path of the bath water 2 is adjusted as shown in FIG. 3 by adjusting the flow rate so that it can be sent to the bath water 2 and the filtration membrane 35 of the microfiltration filter 12 circulated in the bath water purifier. In addition to discharging the dirt adhering to the outside of the bath water purifier through the drainage flow path 18, the flow path in which the dirt adhering to the filtration membrane 35 of the microfiltration filter 12 was circulated is rinsed.
[0025]
When the filtration membrane 35 of the microfiltration filter 12 is circulated and washed as shown in FIG. 4 using the bath water cleaning apparatus shown in FIG. 1 as described above, the bath used when the filtration membrane 35 of the microfiltration filter 12 is circulated and washed. Since the circulation path of the water 2 can be shortened, the load applied to the circulation pump 6 is reduced, and the flow rate of the bath water 2 per unit time can be increased, so that the filtration membrane 35 is used as a bath when washing the filtration membrane 35 of the microfiltration filter 12. The impact force received from the convection of the water 2 can be increased, and the cleaning power of the filtration membrane 35 of the microfiltration filter 12 can be improved. Even if the cleaning time of the filtration membrane 35 of the microfiltration filter 12 is lengthened, the bath water 2 drained by the cleaning is the bath water 2 circulating in the bath water purifier and the filtration membrane 35 of the microfiltration filter 12. Only the bath water 2 for rinsing the flow path in which the dirt adhering to the circulation was circulated, the drainage of the bath water 2 at the time of washing is reduced, and the filtration membrane 35 of the microfiltration filter 12 Can be sufficiently washed. Further, as described above, the bath water 2 used for cleaning the filtration membrane 35 of the microfiltration filter 12 is not sent into the bathtub 1 but is discharged out of the bath water purifier. The bath water 2 that circulates in the gasification apparatus and cleans the filter membrane 35 of the microfiltration filter 12 is heated by the heater 7 to a high temperature of 70 to 75 ° C. necessary for heat sterilization, or by the chlorine generation (input) apparatus 14. Chlorine can be added to the bath water 2 until the chlorine concentration reaches about 1 ppm. By doing so, bacteria attached to the sterilization and microfiltration filter in the bath water purifier can be obtained. Sterilization can be performed reliably.
[0026]
Further, just before the switching valves 27 and 28 are adjusted as described above, the air pump 15 (or ejector) is operated to send bubbles into the bath water 2. The bath water 2 mixed with bubbles is circulated in the bath water purifier to wash the filtration membrane 35 of the microfiltration filter 12, thereby washing the filtration membrane 35 of the microfiltration filter 12 with the bath water 2. In addition to the impact caused by the flow velocity of the bath water 2 in the stock solution chamber 36, it can be performed by the vibration of bubbles in the stock solution chamber 36. The cleaning ability of 35 can be improved. After the filtration membrane 35 of the microfiltration filter 12 is washed in this way and the filtration membrane 35 is sufficiently washed, the bath water 2 is circulated in the bath water purifier without mixing bubbles in the bath water 2 described above. In the same manner as when the filtration membrane 35 of the microfiltration filter 12 is washed, all the bath water 2 sent from the washing water discharge port 34 of the microfiltration filter 12 to the drainage flow path 18 is drained. By adjusting so that it can be sent to the drain side of the channel 18, the flow path of the bath water 2 is made as shown in FIG. 3, and the bath water 2 and the microfiltration filter circulated in the bath water purifier In addition to discharging the dirt adhering to the filtration membrane 35 of the twelve through the drainage flow path 18 to the outside of the bath water purifier, the passage in which the dirt adhering to the filtration membrane 35 of the microfiltration filter 12 was circulated is provided. Rinse.
[0027]
FIG. 5 shows a case where the bath water 2 in the bathtub 1 is cleaned without using the microfiltration filter 12 using the bath water cleaning apparatus shown in FIG. 1 and the filtration membrane 35 of the microfiltration filter 12 is washed. The path of bath water 2 and bubbles is shown. Here, the switching valve 26 is adjusted so that the bath water 2 sent from the chlorine generation (input) device 14 can be sent only in the direction in the bathtub 1 of the discharge flow path 9, and The switching valve 27 is adjusted so that the bath water 2 sent from the switching valve 26 side of the discharge passage 9 can be sent only to the inside of the bathtub 1 of the discharge passage 9, and the switching valve 28. Is adjusted so that all of the bath water 2 sent from the washing water discharge port 34 of the microfiltration filter 12 to the drainage flow path 18 can be sent to the circulation washing flow path 20. The valve 29 is preferably in a closed state. Further, before adjusting the switching valves 26, 27, and 28 as described above, the switching valve 27 is adjusted in advance so that the bath water 2 is sent to the microfiltration filter washing flow path 19 and the switching valve 28. Is adjusted so that the bath water 2 is sent to the drainage side of the drainage flow path 18 and the bathtub water purifier is activated, so that the fine filtration filter cleaning flow path 19 and the stock solution chamber 36 of the fine filtration filter 12 are activated. The bath water 2 is retained in the drainage flow path 18.
[0028]
When the bathtub water cleaning device is started in the above state and air bubbles are sent into the microfiltration filter cleaning flow path 19 by the air pump 15, the bath water 2 in the bathtub 1 is the same as in the case of FIG. After being sent to the position of the switching valve 27 of the discharge flow path 9, all are sent in the direction in the bathtub 1 of the discharge flow path 9. Also, the bubbles sent into the microfiltration filter cleaning flow path 19 by the air pump 15 are sent from the cleaning water inlet 31 of the microfiltration filter 12 to the stock solution chamber 36 in the microfiltration filter 12, and are caused by the bubbles vibrating in the stock solution chamber 36. The dirt attached to the filtration membrane 35 of the microfiltration filter 12 is removed and washed. Bubbles sent to the stock solution chamber 36 in the microfiltration filter 12 are sent from the washing water discharge port 34 of the microfiltration filter 12 to the drainage flow path 18 and sent out of the bathtub water purifier.
[0029]
As described above, the bath water purification apparatus shown in FIG. 1 is used to clean the bath water 2 in the bathtub 1 without using the microfiltration filter 12 as shown in FIG. By washing 35, bubbles are sent by the air pump 15 to the microfiltration filter cleaning flow path 19, the stock solution chamber 36 of the microfiltration filter 12, and the bath water 2 staying in the drainage flow path 18. Since the filter membrane 35 of the microfiltration filter 12 can be washed by the vibration of bubbles in the filter, the amount of the bath water 2 drained out of the bath water purifier is reduced when the filter membrane 35 of the microfiltration filter 12 is washed. In addition, the filter membrane 35 of the microfiltration filter 12 can be washed and at the same time the bath water in the bathtub 1 can be circulated and purified by the bath water purifier, so the bathing time zone is removed. Etc. to clean the filtration membrane 35 of the microfiltration filter 12, in which the washing time and timing of the filtration membrane 35 of the microfiltration filter 12 can eliminate the need or care.
[0030]
FIG. 6 shows another example of the embodiment of the present invention. The bathtub water cleaning apparatus shown in FIG. 6 has the same configuration as the bathtub water cleaning apparatus shown in FIG. 1 except that the circulation cleaning flow path 20 and the switching valve 28 are not provided, and the valve 30 is provided in the drain flow path 18. It is what has.
FIG. 7 shows a circulation path of the bath water 2 when the bath water 2 in the bathtub 1 is circulated and cleaned using the bath water cleaning apparatus shown in FIG. Here, the switching valve 26 is adjusted so that the bath water 12 sent from the chlorine generation (input) device 14 can be sent to both the direction of the bathtub 1 of the discharge passage 9 and the microfiltration filter outlet passage 16. The switching valve 27 is adjusted so that the bath water 2 sent from the switching valve 26 side of the discharge passage 9 can be sent only in the direction of the bathtub 1 of the discharge passage 9. 30 is in a closed state, and valve 29 is in an open state.
[0031]
When the bathtub water purification device is activated in the state as described above, the bath water 2 circulates through the same path as the case where the bathtub water purification device shown in FIG. 1 is activated in the state shown in FIG. The same effect as that obtained when the apparatus is activated in the state shown in FIG. 2 can be obtained. FIG. 8 shows the path of the bath water 2 when the filtration membrane 35 of the microfiltration filter 12 is washed using the bathtub water cleaning apparatus shown in FIG. Here, the switching valve 26 is adjusted so that the bath water 2 sent from the chlorine generation (input) device 14 can be sent only in the direction in the bathtub 1 of the discharge flow path 9, and The switching valve 27 is adjusted so that the bath water 2 sent from the switching valve 26 side of the discharge passage 9 can be sent only to the microfiltration filter washing passage 19, and the valve 30 is opened. It is in a state of being. The valve 29 is preferably in a closed state.
[0032]
When the bathtub water purification device is activated in the above-described state, the bath water 2 circulates in the same path as the case where the bathtub water purification device shown in FIG. 1 is activated in the state shown in FIG. The same effect as that obtained when the apparatus is activated in the state shown in FIG. 3 can be obtained. Further, when the bathtub water cleaning device is started in the above-described state and air bubbles are mixed into the microfiltration filter cleaning flow path 19 by the air pump 15, the bath water 2 and the bubbles are generated by the bath water cleaning device shown in FIG. 3 is activated in the state shown in FIG. 3 and circulates in the same path as when air bubbles are mixed into the microfiltration filter cleaning flow path 19 by the air pump 15, and the bathtub water cleaning apparatus shown in FIG. 1 is in the state shown in FIG. The same effect as when air bubbles are mixed into the microfiltration filter cleaning flow path 19 by the air pump 15 while being activated can be obtained.
[0033]
FIG. 9 shows a case where the bath water 2 in the bathtub 1 is cleaned without using the microfiltration filter 12 and the filtration membrane 35 of the microfiltration filter 12 is washed using the bath water cleaning apparatus shown in FIG. The path of bath water 2 and bubbles is shown. Here, the switching valve 26 is adjusted so that the bath water 2 sent from the chlorine generation (input) device 14 can be sent only in the direction in the bathtub 1 of the discharge flow path 9, and The switching valve 27 is adjusted so that the bath water 2 sent from the switching valve 26 side of the discharge flow path 9 can be sent only to the inside of the bathtub 1 of the discharge flow path 9. It is in an open state. The valve 29 is preferably in a closed state. Further, before adjusting the switching valves 26 and 27 as described above, the switching valve 27 is adjusted in advance so that the bath water 2 is sent to the microfiltration filter washing flow path 19, and bath water By starting the cleaning device, bath water remains in the microfiltration filter cleaning flow path 19, the stock solution chamber 36 of the microfiltration filter 12, and the drainage flow path 18.
[0034]
When the bathtub water cleaning device is activated in the above state and air bubbles are mixed into the microfiltration filter cleaning flow path 19 by the air pump 15, the bath water 2 and the bubbles are the same as the bath water cleaning device shown in FIG. 1 and the air pump 15 circulates in the same path as when air bubbles are mixed into the microfiltration filter cleaning flow path 19 to start the bath water purifier shown in FIG. 1 in the state shown in FIG. At the same time, the same effect as that obtained when air bubbles are mixed into the microfiltration filter cleaning flow path 19 by the air pump 15 can be obtained.
10 and 11 show another example of the embodiment of the present invention. The bathtub water cleaning apparatus shown in FIG. 10 is the same as the bathtub water cleaning apparatus shown in FIG. 1 except that the microfiltration filter 12 contains a circulation pump 6, a heater 7, a normal filter 13, a chlorine generation (input) device 14, and the like. It is provided in the in-tub block 39 in the bathtub 1 in which the pre-filter 10 and the discharge port of the discharge flow path 9 and the like are housed. Further, the bathtub water cleaning apparatus shown in FIG. 11 is the same as that shown in FIG. 10 in the bathtub water cleaning apparatus shown in FIG. 6, except that the microfiltration filter 12 is a circulation pump 6, a heater 7, a normal filter 13, and chlorine generation. (Input) Not provided in the bathtub water purifier main body 4 in which the device 14 or the like is accommodated, but provided in the bathtub inner block 39 in the bathtub 1 containing the prefilter 10 and the discharge port of the discharge flow path 9. It is what has been.
[0035]
As described above, the microfiltration filter 12 is not arranged in the bathtub water purifier main body 4 but is provided in the bathtub inner block 39 installed in the bathtub 1, thereby cleaning the bathtub water installed outside the bathtub 1. The main body 4 can be made compact, and the microfiltration filter 12 can be provided on the block 39 in the bathtub, so that the microfiltration filter 12 can be easily maintained.
[0036]
In the above embodiment of the present invention, the switching valves 27 and 28 are adjusted to switch the bath water purifier from normal operation to cleaning of the filtration membrane 35 of the microfiltration filter 12, and further to the microfiltration filter 12. When switching to the drainage of the bath water 2 used for cleaning the filtration membrane 35 and returning to the normal operation of the bathtub water cleaning device, etc., the switching valves 27 and 28 are controlled by a timer to be constant. The switching valves 27 and 28 can be automatically adjusted after a time. In that case, a solenoid valve or the like can be used as the switching valves 27 and 28. In this case, however, a power source for the solenoid valve is required and electrical insulation is required. Therefore, as the switching valves 27 and 28, a mechanical timer that mechanically counts the flow rate of the bath water 2 and automatically and mechanically switches the flow path of the bath water 2 using the running water as power when a constant flow rate flows. Can be used.
[0037]
Examples of mechanical timers used in the embodiment of the present invention are schematically shown in FIGS.
13 and 14 show a switching valve 27 provided at a branch point between the discharge passage 9 and the microfiltration filter passage 16. Here, in the vicinity of the branch point between the discharge passage 9 and the microfiltration filter passage 16, spherical valves 40a and 40b are provided on the bathtub 1 side of the microfiltration filter passage 16 and the discharge passage 9, respectively. The valves 40a and 40b are formed by narrowing the insides of the microfiltration filter channel 16 and the discharge channel 9 on the bathtub 1 side, and the valves 40a and 42b are in contact with the valve seats 42a and 42b by flowing water pressure. It consists of balls 41a and 41b for closing, and the balls 41a and 41b are arranged closer to the branch points of the respective flow paths than the valve seats 42a and 42b. An impeller 43a is disposed on the opposite side of the branch point of each flow path of the spherical valve 40a provided in the microfiltration filter flow path 16. The impeller 43a is pivotally supported by a blade shaft 49, and the blade shaft 49 is provided so as to protrude outside the fine filtration filter flow path 16, and a speed reduction wheel train is provided at a portion provided so as to protrude outside the fine filtration filter flow path 16. 46a is provided. The reduction gear train 46 a is fitted with another reduction gear train 45 a, and the other reduction gear train 45 a is provided on the camshaft 44. The cam shaft 44 is provided through the microfiltration filter flow path 16, and an operation dial 54 is provided at one end opposite to the side where the reduction gear train 45a is provided, and a disc-shaped cam 47 is provided at the other end. A cam shaft 44 is provided at the center of the disk. Here, the rotational input of the impeller 43a is transmitted while the shaft rotational speed is gradually decelerated through the reduction gear trains 45a and 46a, and is output to the rotation of the cam 47. A cam groove portion 48 that opens outwardly in a concave shape is provided on the periphery of the cam 47, and the cam groove portion 48 is fitted to a protruding piece 49 that protrudes at a substantially central position of the rod-shaped control rod 52. is there. The control rod 52 protrudes inside the discharge flow path 9 and the microfiltration filter flow path 16 and is provided so as to be movable in the axial direction. Extrusion portions 53a and 53b are provided at both ends thereof, and the extrusion portion 53a. , 53b, the balls 41a, 41b are arranged on substantially the extension line of the shaft of the control rod 52 in the vicinity. The control rod 52 has a spring locking piece 50 projecting slightly from the protruding piece 49 toward the microfiltration filter flow path 16, and the spring 51 is arranged between the spring locking piece 50 and the microfiltration filter flow path 16. The elastic force of the spring 51 acts on the control rod 52 toward the discharge channel 9 in the axial direction. Here, the cam 47 has a shape as shown in FIGS. As shown in FIG. 18A, the cam groove portion 48 formed in the cam 47 has a primary cam groove portion 48a that is a quarter portion of the entire outer periphery of the cam 47, and a secondary portion that is continuous with the secondary portion. The cam groove portion 48b and the remaining half portion are formed as an intermediate cam groove portion 48d. As shown in FIG. 18B, the primary cam groove portion 48a and the secondary cam groove portion 48b are formed so as to be shifted outwardly on the opposite sides with respect to the disc of the cam 47, and the primary cam groove portion 48a. The connecting portion of the secondary cam groove 48b is provided so that the switching cam groove 48c is perpendicular to the primary cam groove 48a and the secondary cam groove 48b as shown in FIG. Further, as shown in FIG. 18 (d), the intermediate cam groove portion 48d is provided obliquely with respect to the circumference of the cam 47 so as to smoothly connect the displacement between the primary cam groove portion 48a and the secondary cam groove portion 48b.
[0038]
15 to 17 show a switching valve 28 provided at a branch point between the drainage flow path 18 and the circulation cleaning flow path 20. In this device, spherical valves 40a and 40b are provided on the drain side of the circulation washing channel 20 and the drainage channel 18 near the branch point of the drainage channel 18 and the circulation washing channel 20, respectively. Although the structure is substantially the same as that of the valve 27, the impeller 43 a and the reduction wheels 45 a and 46 a are provided in the circulation washing channel 20, and the impeller 43 b and the reduction wheel 45 b are also provided on the drain side of the drainage channel 18. 46b, and in addition to the rotational input of the impeller 43a, the rotational input of the impeller 43b is also transmitted through the reduction wheel trains 45b and 46b with the shaft rotational speed reduced and output to the rotation of the cam 47. It is different in a certain way.
[0039]
In the bathtub water cleaning apparatus shown in FIG. 1, when the switching valve 27 circulates and cleans the bath water 2 of the bathtub 1 as shown in FIG. 2, the secondary cam groove 48b has a protruding piece as shown in FIG. 49. In this state, the spherical valve 40b on the bathtub 1 side of the discharge passage 9 is in a state in which the extruded piece 53b presses the ball 41b away from the valve seat 42b and the spherical valve 40b is opened. In the spherical valve 40a on the microfiltration filter cleaning flow path 16 side, the extruded piece 53a is not in contact with the ball 41a, and the ball 41a is in contact with the valve seat 42a by the flow pressure of the bath water 2, and the spherical valve 40a is Closed. When the microfiltration filter 12 is circulated and washed as shown in FIG. 4, the switching valve 27 rotates the operation dial 54 to rotate the cam 47 so that the projecting piece 49 and the primary cam groove 48a are fitted. 14 to state. In this state, contrary to the state shown in FIG. 13, the spherical valve 40a on the side of the microfiltration filter cleaning channel 16 is in a state where the extruded piece 53a presses the ball 41a away from the valve seat 42a and the spherical valve 40a is opened. The spherical valve 40b on the bathtub 1 side of the discharge flow path 9 is such that the extruded piece 53b is not in contact with the ball 41b, and the ball 41b is in contact with the valve seat 42b due to the fluid pressure of the bath water 2, and the spherical valve 40b is Closed. In this state, the bath water flows into the microfiltration filter cleaning flow path 16, and the impeller 43a is rotated by the flow pressure. The rotational input of the impeller 43a is output to the rotational motion of the cam 47 through the reduction gear trains 45a and 46a as described above. At this time, the cam 47 rotates so that the fitting portion with the protruding piece 49 moves from the primary cam groove portion 48a to the switching cam groove portion 48c. When the bath water 2 having a constant flow rate flows from the state of FIG. 14 to the microfiltration filter cleaning flow path 16, the fitting portion of the cam 47 with the protruding piece 49 moves from the primary cam groove portion 48a to the switching cam groove portion 48c, and the spring. The elastic rod 51 moves the control rod 52 in the axial direction in the direction of the bathtub 1 of the discharge flow path 9, and the fitting portion of the cam 47 with the protruding piece 49 moves from the switching cam groove portion 48c to the secondary cam groove portion 48b. Then, the state returns to the state of FIG.
[0040]
Further, in the bathtub water cleaning apparatus shown in FIG. 1, the switching valve 28 is configured such that when the bath water 2 in the bathtub 1 is circulated and cleaned as shown in FIG. In this state, the balls 41a and 41b of the spherical valves 40a and 40b and the extruded pieces 53a and 53b of the control rod 52 are provided on both the drainage side of the drainage channel 18 and the circulation cleaning channel 20. The balls 41a and 41b are in contact with the valve seats 42a and 42b and the spherical valves 40a and 40b are closed due to the flow pressure of the bath water 2. When circulating and washing the microfiltration filter 12 as shown in FIG. 4, in addition to setting the switching valve 27 to the state shown in FIG. 47 is rotated to a state shown in FIG. 16 where the protruding piece 49 and the primary cam groove 48a are fitted. In this state, the spherical valve 40a of the circulation cleaning channel 20 is in a state in which the extruded piece 53a presses the ball 41a away from the valve seat 42a, and the spherical valve 40a is opened. In the spherical valve 40b, the extruded piece 53b is not in contact with the ball 41b, and the ball 41b is in contact with the valve seat 42b due to the fluid pressure of the bath water 2 so that the spherical valve 40b is closed. In this state, the bath water 2 flows into the circulation washing channel 20 and the impeller 43a on the circulation washing channel 20 side is rotated by the fluid pressure. The rotational input of the impeller 43a is output to the rotational motion of the cam 47 through the reduction gear trains 45a and 46a as described above. At this time, the cam 47 rotates so that the fitting portion with the protruding piece 49 moves from the primary cam groove portion 48a to the switching cam groove portion 48c. When the bath water 2 having a constant flow rate flows from the state shown in FIG. 16 to the circulation cleaning flow path 20, the fitting portion of the cam 47 with the protruding piece 49 moves from the primary cam groove portion 48a to the switching cam groove portion 48c, and the spring 51 The control rod 52 is moved in the axial direction in the direction of the drainage side of the drainage flow path 18 by the elastic force, and the fitting portion of the cam 47 with the protruding piece 49 is moved from the switching cam groove 48c to the secondary cam groove 48b. As shown in FIG. 17, the spherical valve 40b on the drain side of the drainage flow path 18 is in a state where the extruded piece 53b presses the ball 41b away from the valve seat 42b, and the spherical valve 40b is opened. In the spherical valve 40a, the extruded piece 53a is not in contact with the ball 41a, and the ball 41a comes into contact with the valve seat 42a due to the fluid pressure of the bath water 2 and the spherical valve 40a is closed. In this state, the bath water 2 flows to the drainage side of the drainage channel 18, and the impeller 43 b on the drainage side of the drainage channel 18 is rotated by the fluid pressure. The rotational input of the impeller 43b is output to the rotational motion of the cam 47 through the reduction gear trains 45b and 46b as described above. At this time, the switching valve 27 is still in a state in which the bath water 2 is sent only to the microfiltration filter washing flow path as shown in FIG. 13, and has not been switched to the state as shown in FIG. It has been adjusted. When the bath water 2 having a constant flow rate flows from the state of FIG. 17 to the drainage side of the drainage channel 18, the fitting portion of the cam 47 with the projecting piece 47 moves from the secondary cam groove portion 48b to the intermediate cam groove portion 48d. Returning to the state of FIG. At the same time, the switching valve 27 is also switched from the state shown in FIG. 13 to the state shown in FIG. 18 so that the bath water 2 is sent only in the direction of the bathtub 1 of the discharge passage 9. It is what.
[0041]
When the switching valves 27 and 28 are configured as described above, in the bathtub water cleaning apparatus shown in FIG. 1, when the mechanical timer is operated when circulatingly cleaning the bath water 2 of the bathtub 1 as shown in FIG. When the bath water 2 having a constant flow rate circulates, the switching valve 28 is switched and the flow path of the bath water 2 is automatically switched as shown in FIG. 3 to drain the bath water 2 and rinse the flow path. In this state, when a constant flow rate further flows, the switching valve 27 and the switching valve 28 are simultaneously switched, and the flow path of the bath water 2 circulates and cleans the bath water 2 without using the microfiltration filter 12. Is automatically switched to.
[0042]
Moreover, what was comprised with the mechanical timer similar to the above as the switching valve 27 of the bathtub water purification apparatus shown in FIG. 6 is used, and a mechanical timer is operated when wash | cleaning the microfiltration filter 12 as shown in FIG. Then, after the bath water 2 having a constant flow rate flows, the switching valve 27 is switched, and the flow path of the bath water 2 is automatically changed to a flow path that circulates and cleans the bath water 2 without using the microfiltration filter 12. It will be switched.
[0043]
As described above, by using the switching valves 27 and 28 constituted by mechanical timers, a power source for timer operation of the switching valves 27 and 28 becomes unnecessary, and there is no need to provide electrical insulation. As shown in the embodiment of the present invention, the switching valves 27 and 28 can be provided in the in-tub block 39 in the bathtub 2, and the user can clean the microfiltration filter 12 by switching the mechanical timer. The operation of the bath water cleaning device can be automatically and easily switched from the state to the drainage of the bath water 2 used for washing, and further to the cycle cleaning of the bath water 2 in the bath 1 It is.
[0044]
【The invention's effect】
As described above, the invention described in claim 1 of the present invention is a bath water cleaning device for cleaning while circulating bath water in a bathtub using a circulation pump, and in the bathtub on the upstream side of the circulation pump. Provided with a suction flow channel for sucking in the bath water and a discharge flow channel for discharging the cleaned bath water downstream of the circulation pump, and sending the bath water from the discharge flow channel to the introduction port of the fine filtration filter The introduction flow path is branched from the discharge flow path, and the microfiltration filter lead-out path for sending the bath water filtered in the microfiltration filter from the microfiltration filter lead-out port to the suction flow path is provided. Since it is provided between the suction flow passage and the suction flow path, particulate bacteria having a diameter of 0.001 to 10 μm and colloidal dirt are removed by a microfiltration filter, and immediately after the installation of the bath water cleaning device, or a filter medium. Exchange of Immediately after the bath water can be prevented from becoming clouded, and even if the microfiltration filter is clogged, a sufficient flow rate of the bath water circulating through the bath water purifier can be secured, and the water is sent from the discharge channel into the bath. Therefore, even if the microfiltration filter is clogged, the bath water sent from the discharge channel into the bathtub 1 can be secured. The bath water 2 in the bathtub is stirred by the flow rate of the bath water sent from the discharge flow path into the bathtub, so that the bath water does not stagnate in the bathtub, and the bath water in the bathtub Can be circulated in the bathtub water purifier uniformly. In addition, a positive pressure of the circulation pump is applied to the inlet of the microfiltration filter from the microfiltration filter introduction channel provided by branching from the discharge channel, and microfiltration is performed from the microfiltration filter outlet channel connected to the suction channel. Since the suction force of the circulation pump acts on the filter outlet, the pressure difference between the inlet and outlet of the microfiltration filter can be increased, and therefore the flow rate of the bath water passing through the microfiltration filter can be increased. The purification capability of the microfiltration filter can be increased, and the purification capability of the bathtub water purification device can be improved. Furthermore, since the bath water purified by the microfiltration filter is reliably mixed with the bath water circulating in the bath water purifier in the process of circulating in the bath water purifier, the bath that has passed through the microfiltration filter. Only water does not stagnate inside the bathtub, and the degree of mixing of the bath water that has passed through the microfiltration filter inside the bathtub can be improved.
[0045]
Ma The Since a switching valve capable of adjusting the flow rate is provided at the branch point between the discharge flow path and the microfiltration filter introduction flow path, when the bath water in the bathtub 1 has a lot of cloudy dirt, the switching valve is changed to the microfiltration filter introduction flow path. Adjust the selector valve so that the ratio of the flow rate of the bath water to be sent is large, and if there is very little or no cloudy dirt in the bath water in the bathtub, from the selector valve to the microfiltration filter introduction flow path Adjust the switching valve so that the ratio of the flow rate of the bath water to be sent is small or not sent at all, and the flow rate of the bath water sent to the microfiltration filter introduction flow path due to the soiling condition of the bath water in the bath The ratio can be changed arbitrarily, so that it is not always possible to pass a certain amount of bath water through the microfiltration filter regardless of the degree of contamination of the bath water in the bathtub, and clogging of the microfiltration filter can be reduced. . Moreover, the ratio of the flow rate of the bath water sent from the switching valve to the microfiltration filter introduction channel can be increased to rapidly purify the bath water in the bathtub.
[0046]
Ma The A microfiltration filter cleaning channel that sends bath water from the discharge channel to the cleaning water inlet of the microfiltration filter is branched from the discharge channel, a switching valve is provided at the branch point from the discharge channel, and microfiltration is performed. A drainage channel for draining the bath water used for washing after passing through the filter from the washing water discharge port of the microfiltration filter to the outside of the bath water purifier is connected to the washing water discharge port of the microfiltration filter. Therefore, when dirt is attached to the filter membrane of the microfiltration filter and clogging occurs, the microfiltration filter can be washed by adjusting the switching valve, and thus the purification ability of the microfiltration filter is restored. Therefore, the purification ability of the microfiltration filter can be maintained for a long time. Furthermore, the dirt in the bath water removed by the microfiltration filter can be reliably thrown out of the bath water purifier through the drainage flow path.
[0047]
Claims of the invention 2 The invention described in claim 1 In addition to the above configuration, a microfiltration filter circulation washing channel that sends the bath water used for cleaning the microfiltration filter to the suction channel is branched from the drainage channel, and a switching valve is provided at the branch point. By adjusting the switching valve, the microfiltration filter can be circulated and washed with the bath water circulating in the bath water cleaning device, and the circulation path of the bath water when washing the filtration membrane of the microfiltration filter can be shortened, so that the circulation is possible. Since the load on the pump is reduced and the flow rate of the bath water per unit time can be increased, the impact force that the filtration membrane receives from the convection of the bath water 2 when washing the filtration membrane of the microfiltration filter can be increased. It is possible to improve the cleaning power of the filtration membrane of the microfiltration filter. Even if the cleaning time of the microfiltration filter is increased, the bath water drained by the cleaning circulates the bath water circulating in the bath water purifier and the dirt attached to the filter membrane of the microfiltration filter. This is only bath water for rinsing the flow path, and drains the bath water at the time of washing, and the filtration membrane of the microfiltration filter can be sufficiently washed. In addition, as described above, the bath water used for cleaning the filter membrane of the microfiltration filter is not sent to the bathtub, but is discharged outside the bathtub water purifier. The bath water that circulates and cleans the filter membrane of the microfiltration filter is heated to a high temperature of 70 to 75 ° C. necessary for heat sterilization by a heater, or the chlorine concentration in this bath water is about 1 ppm by a chlorine generator (input) device. Chlorine can be added until it becomes, and by doing so, it is possible to reliably sterilize the tub water purification device and bacteria attached to the microfiltration filter. is there.
[0048]
Claims of the invention 3 The invention described in claim 1 Or 2 In addition to the above configuration, air is mixed into the microfiltration filter cleaning flow path with an air pump or an ejector. Therefore, when the microfiltration filter is cleaned, in addition to the impact force that the filtration membrane receives from the flow rate of the bath water, Since the dirt adhered to the filter membrane of the microfiltration filter is removed, the cleaning effect of the microfiltration filter can be increased.
[0049]
Claims of the invention 4 The invention described in claim 3 In this configuration, since the air filter or ejector is provided in the microfiltration filter cleaning flow path, air bubbles are sent into the microfiltration filter cleaning flow path, the raw liquid chamber of the microfiltration filter, and the bath water staying in the drainage flow path by the air pump. The filter membrane of the microfiltration filter can be cleaned by the vibration of bubbles in the stock solution chamber, and the amount of bath water drained out of the bath water purifier can be reduced when cleaning the filter membrane of the microfiltration filter. It is possible to wash the filtration membrane of the microfiltration filter and at the same time circulate and clean the bath water in the bathtub with the bath water cleaning device. It is possible to eliminate the need to care about the cleaning time and timing of the filtration membrane of the microfiltration filter, such as performing cleaning.
[0050]
Claims of the invention 5 The invention described in claim 1 Thru 4 In addition to any of the configurations described above, a switching valve provided at the branch point between the discharge flow path and the microfiltration filter cleaning flow path, and a switching valve provided at the branch point between the drainage flow path and the microfiltration filter circulation cleaning flow path Is configured with a mechanical timer powered by running water, which eliminates the need for a power supply for timer operation of the switching valve, and allows the switching valve to be provided in the bathtub block in the bathtub without the need for electrical insulation. By setting the mechanical timer to be switched by the user, bath water purification such as switching from the washing state of the microfiltration filter to the drainage of the bath water used for washing, and switching to the bath water circulation cleaning in the bathtub, etc. It is possible to automatically and easily switch the operation of the converter.
[0051]
Claims of the invention 6 The invention described in claim 1 to claim 1 5 In addition to any of the above configurations, the microfiltration filter is installed outside the bathtub water purification apparatus main body, so that the microfiltration filter is a block in the bathtub installed in the bathtub, and the discharge port of the prefilter and the discharge channel is provided. It can be installed in the block inside the bathtub so that the main body of the bath water purifier can be made compact and the microfiltration filter can be installed in the block in the bathtub, making maintenance of the microfiltration filter easy. Is something that can be done.
[Brief description of the drawings]
FIG. 1 is a schematic view showing an example of an embodiment of the present invention.
FIG. 2 is a schematic view showing an example of a state of use of the bathtub water cleaning apparatus shown in FIG.
FIG. 3 is a schematic view showing another example of the state of use of the bathtub water cleaning apparatus shown in FIG. 1;
FIG. 4 is a schematic view showing still another example of the state of use of the bathtub water cleaning apparatus shown in FIG. 1;
FIG. 5 is a schematic view showing still another example of the state of use of the bathtub water cleaning apparatus shown in FIG. 1;
FIG. 6 is a schematic view showing another example of the embodiment of the present invention.
7 is a schematic view showing an example of a state of use of the bathtub water cleaning apparatus shown in FIG.
FIG. 8 is a schematic view showing another example of a state of use of the bathtub water cleaning apparatus shown in FIG. 6;
FIG. 9 is a schematic view showing still another example of a form of use of the bathtub water cleaning apparatus shown in FIG. 6;
FIG. 10 is a schematic view showing still another example of the embodiment of the present invention.
FIG. 11 is a schematic view showing still another example of the embodiment of the present invention.
FIG. 12 is a cross-sectional view showing an example of a microfiltration filter used in the present invention.
FIG. 13 is a cross-sectional view of an example of a mechanical timer used in the practice of the present invention.
FIG. 14 is a cross-sectional view showing another operation of the mechanical timer same as above.
FIG. 15 is a cross-sectional view showing another example of a mechanical timer used in the present invention.
FIG. 16 is a cross-sectional view showing another operation of the mechanical timer same as above.
FIG. 17 is a cross-sectional view showing still another operation of the mechanical timer.
18A to 18D show examples of cams used in the mechanical timer used in the embodiment of the present invention. FIG. 18A is a front view, and FIG. AA sectional drawing, (c) is a side view of C part of (a), (d) is a side view of B part of (a).
FIG. 19 is a schematic sectional view showing a conventional bathtub water cleaning device.
[Explanation of symbols]
1 Bathtub
2 bath water
3 Suction channel
6 Circulation pump
9 Discharge flow path
12 Microfiltration filter
15 Air pump
16 Microfiltration filter introduction flow path
17 Microfiltration filter outlet flow path
18 Drainage channel
19 Microfiltration filter cleaning flow path
20 Microfiltration filter circulation cleaning flow path
26 Switching valve
27 Switching valve
28 Switching valve
31 Introduction port
32 outlet
33 Washing water inlet
34 Wash water outlet

Claims (6)

A bath water cleaning device for purifying while circulating bath water in a bathtub using a circulation pump, an intake flow path for sucking bath water in the bath upstream of the circulation pump, and a downstream side of the circulation pump In addition to providing a discharge channel that discharges the cleaned bath water in the process, a microfiltration filter introduction channel that sends bath water from the discharge channel to the introduction port of the microfiltration filter is branched from the discharge channel and microfiltration is performed. A microfiltration filter outlet channel that sends the bath water filtered in the filter from the outlet port of the microfiltration filter to the suction channel is provided between the outlet port of the microfiltration filter and the suction channel, and the discharge channel and the microfilter A switching valve that can adjust the flow rate is provided at the branch point with the filter introduction flow path, and a fine filtration filter cleaning flow path that sends bath water from the discharge flow path to the washing water inlet of the fine filtration filter is provided by branching from the discharge flow path. From its discharge flow path A switching valve is provided at the branch point, and the drainage flow path for draining the bath water used for washing after passing through the microfiltration filter from the washing water discharge port of the microfiltration filter to the outside of the bathtub water cleaning device A bathtub water cleaning device characterized by being connected to a cleaning water discharge port . A microfiltration filter circulation cleaning channel for sending bath water used for cleaning the microfiltration filter to the suction channel is provided by branching from the drainage channel, and a switching valve is provided at the branching point. Item 2. A bath water purifier according to Item 1. The bathtub water cleaning apparatus according to claim 1 or 2, wherein air is mixed into the microfiltration filter cleaning flow path by an air pump or an ejector . 4. The bathtub water cleaning apparatus according to claim 3, wherein the microfiltration filter cleaning flow path is provided with an air pump or an ejector . A switching valve provided at the branch point between the discharge flow path and the microfiltration filter cleaning flow path and a switching valve provided at the branch point between the drainage flow path and the microfiltration filter circulation cleaning flow path are mechanically driven by running water. The bath water purifier according to any one of claims 1 to 4 , wherein the bath water purifier is constituted by a timer . Bath water cleaning apparatus according to any one of claims 1 to 5, characterized in that installed microfiltration filter out bathtub water cleaning apparatus.

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