JP3672611B2 - Bath water circulation device having an electrolysis sterilizer - Google Patents

Description

[0001]
[Industrial application fields]
The present invention relates to a bath water apparatus, and more particularly to a bath water sterilizer in a bath water cleaning apparatus.
[0002]
[Prior art]
A device has been developed in which bath water in a bathtub is purified, sterilized and circulated by a circulation pump, and the purified bath water is sent again into the bathtub.
Purification and sterilization using these devices is performed using an ultraviolet sterilizer or high-pressure discharge type ozone generator that sterilizes by passing the bath water through a sterilization tank with a built-in ultraviolet lamp after processing in a filtration tank made of activated carbon, barley stone, etc. Ozone was sterilized by generating ozone and mixing the ozone into bath water to sterilize.
[0003]
The conventional bath water apparatus not only removes stains of the bath water as described above, but also provides a bath water apparatus that can perform bathing comfortably for 24 hours by simultaneously performing sterilization and heat insulation.
[0004]
[Problems to be solved by the invention]
However, when performing sterilization using an ozone sterilizer, ozone is insoluble in water, so high-concentration ozone must be used, and unreacted ozone remaining in the bath water may diverge from the bath. Therefore, there has been a problem that an expensive exhaust ozone treatment device has to be installed.
[0005]
In addition, in a sterilizer using an ultraviolet lamp, not only does it take a long time to sterilize and purify bath water, but it always has to be sterilized. Had to be cleaned. In addition, since these devices cannot remove sweat, fat, etc. generated from the human body, when sweat, fat, etc. are brought into the bath water, they cause a strange odor in the bath water, which is extremely uncomfortable. there were.
[0006]
An object of the present invention is to provide an apparatus for bathing in a comfortable environment for bathers by improving the drawbacks of the prior art as described above.
[0007]
[Means for Solving the Problems]
That is, the present invention provides a bath water circulating apparatus provided with a circulation pump that circulates bath water, a purification filter that purifies bath water, and a heater that heats bath water. Electrolytic sterilization apparatus that electrolyzes electrolysis with a diaphragm and electrolyzes bath water to generate chlorine for sterilization, a salt addition unit that adds salt to the electrolytic sterilization apparatus, and a salt content were added Energization control means for controlling energization of the electrolytic sterilization apparatus to electrolyze the bath water to generate a predetermined amount of chlorine for sterilization, and timer means for energizing the electrolytic sterilization apparatus and generating chlorine for a certain period of time And an electrolysis sterilization start command means for instructing the start of the timer means, and a salt addition control means for controlling the supply of salt from the salt addition unit in response to the command of the electrolysis sterilization start command means. It solved the problem by the bath water circulating device having an electrolytic sterilizer, characterized in that the.
The present invention also provides an electrolysis sterilization method in which bath water in a bathtub is pumped by a circulation pump, circulated through a circulation path, cleaned, heat-treated, and returned to the bathtub, and electrolyzed with water-free membranes after the cleaning process. The operation of the electrolytic sterilization apparatus is controlled to generate a predetermined amount of chlorine for electrolysis by electrolyzing the bath water in which the salt content is added to the bath water taken in by the electrolytic sterilization apparatus, and generating a predetermined amount of chlorine for sterilization. The energization control means to perform, the electrolytic sterilization start command means to start sterilization at the start time set to perform the electrolytic sterilization in a predetermined time zone, and the normal bath water circulation operation is continued after the sterilization ends The problem was solved by using a bath water circulation device having an electrolytic sterilization device characterized by the following.
The present invention also provides an electrolytic sterilization time adjusting means for allowing the electrolytic sterilization time set by the timer means to be set to an arbitrary length, and an adjusted time storage means for storing the adjusted electrolytic sterilization time. The problem has been solved by providing a bath water circulation device having an electrolytic sterilization device characterized in that.
The present invention also provides an electrolytic sterilization time adjusting means for allowing the electrolytic sterilization time set by the timer means to be set to an arbitrary length, and an adjusted time storage means for storing the adjusted electrolytic sterilization time. The salt addition amount storage means for calculating and storing the salt addition amount corresponding to the electrolytic sterilization time set by the electrolytic sterilization time adjustment means, and the salt addition amount data stored in the salt addition amount storage means The problem has been solved by providing a bath water circulation device having an electrolytic sterilization device characterized in that a salt addition control means for controlling the amount of salt added is further provided.
Further, the present invention provides a clock means for issuing an electrolytic sterilization start command by the electrolytic sterilization start command means at an arbitrary time, a time setting means for setting the clock means at an arbitrary time, and a set time. Setting time storage means for storing, electrolytic sterilization time adjusting means for allowing the electrolysis sterilization time of the timer means to be set to an arbitrary length, and adjustment time storage means for storing the adjusted electrolytic sterilization time The problem has been solved by providing a bath water circulation device having an electrolytic sterilization device characterized in that and are further provided.
The present invention also provides a clock means for performing electrolytic sterilization at an arbitrary time, and a start time setting means and an end time setting means for setting a time for starting and ending the electrolytic sterilization based on the clock means. Sterilization start time storage means and sterilization end time time storage means for storing the set start time and end time, and sterilization start time and sterilization stored in the sterilization start time storage means and sterilization end time storage means In response to the sterilization start signal and the sterilization end signal based on the end time, the apparatus has an electrolytic sterilization device further provided with a salt addition control means for controlling the salt addition timing from the salt addition unit The problem was solved by using a bath water circulation system.
The present invention further provides a dewatering filter for adsorbing residual chlorine components generated by sterilization by the electrolyzer and remaining in the bath water, and further comprising a dewatering filter and a bath water circulation apparatus having an electrolyzer The problem was solved.
[0008]
【Example】
The function and basic structure of claim 1 in the present invention will be described with reference to FIGS.
In the external view of the present invention (FIG. 1), the bath water circulation device A is provided with an operation switch for selecting, confirming, changing, etc. various functions and a display device 9 constituted by a liquid crystal panel on the front surface of the main body device. ing.
The user operates the operation switches and keys to set the temperature. Further, the current time, bath water temperature, and the like are displayed on the liquid crystal panel.
[0009]
The basic configuration of the internal structure of the present invention is as shown in FIG. 2, and the entire configuration for explaining the flow of bath water which is the functional basis is shown in FIG. The bathtub 1 and the pre-filter 2a for sucking in the bath water in the bathtub and removing hair, the purification filter portion 2b for cleaning the bath water, the circulation pump 3 for circulating the bath water, and the bath water The heating heater 5 that heats the water, the electrolytic sterilization device 7 that sterilizes the bath water, the salt addition unit 23, and the jet nozzle 25 that is a discharge port for returning the purified and sterilized bath water to the bathtub again.
[0010]
The inside of the electrolytic sterilizer 7 is a cathode chamber in which the outer side of the anode chamber formed by sandwiching two anode cases on the outer surface and sandwiching the anode plates is joined by two cathode cases holding the cathode plates. It is formed as an electrolytic cell having a double closed chamber electrode chamber structure.
When the electrolysis sterilizer 7 is energized, a current flows through the anode plate and the cathode plate, the bath water is electrolyzed, chlorine ions are generated, and the bath water is sterilized and deodorized efficiently.
[0011]
The embodiment of claim 1 of the present invention will be described with reference to the flowchart of FIG. The bath water circulator A is first turned on by the power switch 10 of the bath water circulator main body A in S1 and starts operation. In S2, when the power is turned on, the circulation pump controller 3a instructs the drive of the circulation pump 3, and the bath water of the bath water device is circulated.
[0012]
In S3, a flow rate sensor 4 is installed to check whether the purification filter 2 or the piping for circulating the bath water is clogged with dust or dirt, and detects the flow rate. Whether the flow rate detected by the flow rate sensor 4 is appropriate is confirmed at T1, and if normal, the process proceeds to YES, and if the flow rate is insufficient, the process proceeds to S6 with NO.
[0013]
In S6, the user confirms that an abnormality has occurred and displays it on the display device 9 constituted by the liquid crystal panel installed in the bath water circulation device in S7, or the user has confirmed that an abnormality has occurred in the flow rate by a warning buzzer or the like. To warn.
[0014]
If the flow rate is appropriate, the process goes to S4 and heating by the heater 5 is performed. In S5, the temperature of the bath water is detected by the temperature sensor 6 provided in the pipe. When the temperature is lower than the temperature set by the temperature setting key 6a, a signal is sent from the heating control relay switch 5a, and the heater 5 switch is turned on. Put in and heat.
When the temperature of the bath water is high, the heater 5 is turned off to adjust the temperature.
[0015]
If the temperature of the bath water exceeds the set range, it is confirmed that an abnormality has occurred in S6 due to abnormal heating of the heater, etc., and a warning is issued in S7 as in the case of an abnormal flow rate. If it is within the proper temperature range of the bath water, the program proceeds to the electrolytic sterilization routine.
[0016]
The electrolytic sterilization routine is performed according to the flow shown in FIG.
In S9, the control valve 22 for controlling the supply amount of the salt addition unit 23 is opened at the start of the electrolytic sterilization, and appropriate amounts of salt and saline are added to the electrolytic sterilizer 7 in S10. In S11, a constant current is supplied to the electrolytic sterilizer 7, and the bath water is electrolyzed by the anode and cathode electrode plates of the electrolytic sterilizer 7.
When salt is added, the salt is decomposed into chloride ions and sodium ions in the electrolysis sterilizer, and the salt components do not flow into the bath water, and each ion component volatilizes, so there is no effect on the human body. .
[0017]
In S12, the current flowing through the electrode plate is detected by the current sensor 8, and it is determined whether or not the current value is appropriate at T5.
If more than a predetermined current flows due to electric leakage or the like, the process goes to S15 to confirm that an abnormality has occurred, and energization is stopped in S16.
Next, in S17, a warning is displayed on the display device 9 in the same manner as the flow rate abnormality and the heater abnormality.
[0018]
The amount of current used is a current in a range that does not affect the human body at all. However, when an abnormality occurs in a device such as an electric leakage, the energization is stopped before warning display for safety.
When an abnormality such as an electric leakage is confirmed at T6 and the abnormality is canceled, the program returns to S9 and the same operation is repeated.
When electrolytic sterilization is started in S13, the program returns to the main routine.
The operation of the bath water circulation apparatus is continued until the power switch 10 of the bath water circulation apparatus main body A is turned off at T3.
[0019]
Next, the function of the embodiment of claim 2 will be described with reference to FIG.
The basic configuration of the present invention includes a purification filter 2 for purifying bath water, a heater 5 for heating bath water, a circulation pump 3 for circulating bath water, an electrolytic sterilizer 7 for sterilizing bath water, and a salt content. An addition unit 23 and a control valve 22 for controlling the addition of salt are configured.
Here, a timer device 15 for controlling the electrolytic sterilization time and an electrolytic start command switch 12 for instructing the start of electrolytic sterilization are provided.
[0020]
The basic operation of the bath water circulation of the present invention is the same as that shown in FIG. 5, so the description of the basic flow portion in the main unit A is omitted, and the operation of the present invention is illustrated by the flowchart of FIG. explain.
[0021]
In S18, the routine proceeds to an electrolytic sterilization routine. At T7, when the user performs sterilization at an arbitrary time, the electrolytic sterilization start switch is turned on. In S19, in response to the input signal of the start switch of the electrolytic sterilizer 7, the salt addition control valve 22 including the electromagnetic valve of the salt addition unit 23 is opened.
[0022]
When the control valve 22 that has received the input signal is opened, a certain amount of salt is added and supplied to the electrolytic sterilizer 7 from the salt adding unit 23 that stores salt and saline. In step S21, the control valve 23a is closed to adjust the amount of salt to be added.
In S22, a timer built in the apparatus is activated in accordance with the operation of the electrolytic sterilization start switch, and the operation time is measured in S24.
When the timer device is actuated, in S24, a signal for energization is sent from the energization control relay switch 11 to the electrolytic sterilization device 7, and energization is started.
[0023]
When energization is started, the bath water is electrolyzed by each electrode plate of the electrolytic cell provided inside the electrolytic sterilizer 7, chlorine is generated, the chlorine is mixed with the bath water, supplied to the bathtub, and sterilized. Is done.
In S25, the current flowing through the electrode plate is detected by the current sensor or the leakage sensor 8, and in order to prevent a leakage accident, if the current flows more than a predetermined current value, the occurrence of abnormality is confirmed in S28, and in S29. Make a warning.
[0024]
When the current value is normal within the appropriate range at T8, the process goes to T9, the timer 15 measures a preset time required for electrolytic sterilization, and detects whether the time has elapsed.
When the set time is reached, the energization for electrolytic sterilization is stopped in S26, and when the set time is not reached, the process goes to S23 again and the electrolytic sterilization is continued along with the measurement of time.
[0025]
When the energization is stopped in S26, the program S27 returns to the flow of FIG. The bath water circulation device is continuously operated until the operation of the device is selected at T3 even after the end of the electrolytic sterilization.
[0026]
Next, the function of the embodiment of claim 3 will be described with reference to FIG. The basic flow of bath water is the same as FIG. The basic operation of this apparatus is the flow shown in FIG. 5, and since the contents have already been described, the description thereof is omitted. The operation of the present invention will be described with reference to the flowchart of FIG.
[0027]
In S31, the routine proceeds to an electrolytic sterilization routine. In T11, it is confirmed whether or not a change in the time (timer) adjustment of electrolytic sterilization is performed.
If it has already been set or there is no change, NO is selected and the program is transferred to T13.
[0028]
When the time is extended to increase the amount of electrolytic sterilization, or when the time is shortened because the bath water is not so dirty, an arbitrary time is input by the sterilization time change key 13 in S32. The input time is displayed on the display device 9 in S33.
[0029]
When the sterilization time changed and adjusted in S33 is displayed, the user confirms the time displayed on the display device 9, and operates the enter key in T12.
When the sterilization time is determined by the confirmation, the sterilization time is stored in the change time memory unit (RAM) 14 in S34.
[0030]
At T13, a sterilization start command is issued based on the sterilization time stored in the change time memory 14. When the sterilization is not performed, the program goes to S43, returns to the main routine, and the operation of circulation and purification of the bath water circulator without performing the sterilization process is performed.
[0031]
When performing sterilization at T13, the electrolytic sterilization start switch 12 is operated. When the switch is operated, the control valve 22 of the salt content adding unit 23 is opened to add salt to the electrolytic sterilizer 7 in S35, and a certain amount of salt necessary for chlorine generation is supplied in S36.
When a single salt is supplied in S36, the control valve 22 is closed in S37, and the supply of salt is stopped.
[0032]
Next, a timer operates based on the sterilization time stored in S38, and in S39, measurement is performed until the time set in S34 comes.
In S40, an electric current is passed through the electrolytic sterilizer 7 during the timer operation, and the electrolytic sterilization is performed. In S41, the current value is detected by the current sensor 8.
[0033]
If no abnormality due to electric leakage or the like has occurred at T14, it is determined at T15 whether the set time stored in S34 has come. When the set time is not reached, the process returns to S39 and the electrolytic sterilization is continued.
[0034]
When the time set in T15 is reached, the relay switch is turned off in S42, and energization to the electrolyzer is stopped. Electrolysis sterilization ends when the energization is stopped.
In S43, the program returns to the flowchart of FIG.
[0035]
If an abnormality occurs in the current value at T14, the energization is stopped in S45, and the abnormality content is displayed on the display device 9 or a warning sound is generated in S46 to warn the user that the abnormality has occurred. To do.
When the abnormality that has occurred is canceled along with the warning in S46, the process proceeds to T13, and the sterilization process is confirmed again.
[0036]
Next, the function of the embodiment of claim 4 will be described with reference to FIG. The basic flow of bath water is the same as FIG. The basic operation of this apparatus is the flow shown in FIG. 5, and since the contents have already been described, a description thereof will be omitted. The operation of the present invention will be described with reference to the flowchart of FIG.
[0037]
The process proceeds to S347 electrolytic sterilization routine. At T17, confirmation is made as to whether or not to change the time (timer) adjustment for electrolytic sterilization.
If it has already been set or there is no change, NO is selected and the program is transferred to T13.
[0038]
When the time is extended to increase the amount of electrolytic sterilization, or when the time is shortened because the bath water is not so dirty, an arbitrary time is input by the sterilization time change key 13 in S48. The input time is displayed on the display device 9 in S49.
[0039]
When the sterilization time adjusted in S348 is displayed, the user confirms the time displayed on the display device 9, and operates the enter key in T18.
When the sterilization time is determined by the confirmation, the sterilization time is stored in the change time memory unit (RAM) 14 in S50.
[0040]
In S51, the amount of salt to be added is calculated corresponding to the time stored in S50.
In S52, the calculated addition amount for electrolytic sterilization is stored in a storage memory (RAM). At T19, a sterilization start command is issued based on the sterilization time stored in the change time storage memory 14.
When sterilization is not performed, the program goes to S61, returns to the main routine, and the operation of circulation and purification of the bath water circulator without sterilization is performed.
[0041]
When sterilization is performed at T19, the electrolytic sterilization start switch 12 is operated. When the switch is operated, the control valve 22 of the salt content adding unit 23 is opened to add salt to the electrolytic sterilizer 7 in S53, and in S54, the optimum amount of salt stored in S36 for chlorine generation. Is added.
When the salt for generating chlorine is supplied in S54, the control valve 22 is closed in S55, and the supply of salt is stopped.
[0042]
Next, a timer operates based on the sterilization time stored in S56, and in S57, measurement is performed until the time set and stored in S50 comes.
In S58, an electric current is passed through the electrolytic sterilizer 7 during the timer operation, and electrolytic sterilization is performed.
[0043]
In S59, the current value is detected by the current sensor 8.
If no abnormality due to leakage or the like has occurred at T20, it is determined at T21 whether the set time stored in S50 has come. When the set time is not reached, the process returns to S57 and the electrolytic sterilization is continued.
[0044]
When the time set in T21 is reached, the relay switch is turned off in S60, and energization to the electrolyzer is stopped. Electrolysis sterilization ends when the energization is stopped. In S61, the program returns to the flowchart of FIG.
[0045]
If an abnormality occurs in the current value at T20, the energization is stopped in S63, and the abnormality content is displayed on the display device 9 in S64 or a warning sound is generated to warn the user that the abnormality has occurred. To do.
When the abnormality that has occurred is canceled along with the warning in S64, the process proceeds to T22, and the sterilization work is confirmed again.
[0046]
Next, the function of the embodiment of claim 5 will be described with reference to FIG. The basic flow of bath water is the same as FIG. The basic operation of this apparatus will be described with reference to the flowchart of FIG. When the power source 10 of the bath water circulation device is turned on in S65, the main unit A is driven. At the same time when the power is turned on, the clock 17 built in the device is turned on and the clock function is started. In S67, the clock 17 displays information such as time corresponding to the situation at the time of insertion on the display device 9.
[0047]
The user confirms the display, and if the time is incorrect at T23, the clock is reset to the correct time by the clock setting key 16 at S81, and the clock 17 is set in a normal state. Next, at T24, when the user's desired sterilization start time has already been set, the user proceeds to the next step as it is, and when setting a new time, the user inputs the internal clock setting key 16 to enter S68. Set with. The time is displayed on the display device 9 of the bath water circulating apparatus in S69, and the user sets it while confirming the display.
[0048]
In T25, it is confirmed whether or not the start time is to be confirmed. If it is confirmed, YES is selected, and if it is set again, NO is selected.
When confirmed, the sterilization start time is stored in the electrolytic sterilization time storage memory unit (RAM) 18 in S70.
[0049]
In S71, the time of the clock reset in S81 is measured. The measurement here means that a clock built in the apparatus is driven in the same way as a normal alarm clock. In S72, the operation of the circulating pump, the heater, etc. of the bath water circulator is started.
[0050]
In T26, it is confirmed whether the electrolysis start time of the electrolytic sterilizer 7 has come. This means that the time measurement by the built-in clock in S71 is the same as the set time set in S68, and if it is the same, the program shifts to S76.
[0051]
In S76, the timer 15 is activated with the start of electrolytic sterilization. This timer 15 is for controlling the time of electrolytic sterilization. When the timer 15 is activated, the timer time is measured in S77.
[0052]
In S78, the electrolysis sterilizer 7 is energized and sterilization starts. In T27, a current value for energizing the electrolytic sterilizer 7 is measured to determine whether the current is appropriate.
When the current value is normal, the process goes to T28 as it is and determines whether the time set in the timer 15 has elapsed.
[0053]
When the measured value in S77 becomes equal to the set predetermined time, the process goes to S79, the energization to the electrolytic sterilizer 7 is stopped, and the electrolytic sterilization ends in S80.
When the operation of the bath water circulation device is continued, the program returns to S72, and the operation for bath water circulation and heating is performed until the next electrolytic sterilization start time comes.
[0054]
When the power source of the main body A is turned off to end the operation of the bath water circulation device at T29, all the devices are stopped.
However, the built-in clock device can be provided with a small storage battery or the like to measure the accurate time.
[0055]
The function of the sixth embodiment of the present invention will be described with reference to FIG. The basic flow of bath water is the same as FIG. The basic operation of this apparatus will be described with reference to the flowchart of FIG. In S85, the bath water circulator is turned on. Next, at T31, a determination is made regarding the time setting for electrolytic sterilization. If the time has already been set for the clock 17 in the apparatus, the program shifts to the operation of the bath water circulation apparatus in S91.
[0056]
The start and end times of electrolytic sterilization are displayed on the display device 9, and the user confirms the displayed time and performs the resetting operation.
When it is not set or when setting a new time, NO is selected here, and the electrolytic sterilization time is set.
[0057]
In S86, the start time for electrolytic sterilization is set first. The start time corresponds to the clock 15 built in the main body A and is input by the start time setting key 19. When the start time is set in S86, the start time set in S87 is stored in the start time storage memory unit 18. The storage memory unit 18 is composed of a RAM or the like so that it can be rewritten.
[0058]
Once the start time is set, the end time is set in S88. The adjustment of the end time is for the user to arbitrarily set the length of the sterilization time.
If the bath water is very dirty, the sterilization time can be extended and the bath water can be cleaned. The end time is set by operating the end time setting key 20 in the same manner as the start time.
[0059]
When the end time is set in S88, the end time is stored in the end time storage memory unit 21 in S89. The set time is displayed on the display device 9, and the user checks whether there is any change.
[0060]
In T32, it is confirmed whether there is a change in the set time. If there is no change or the like, NO is selected and the set time is confirmed in S90. When the set time is fixed, the operation of the bath water circulation device is started in S91.
When the operation is started, it is determined in T33 whether or not the electrolytic sterilization start time set in S86 has come.
[0061]
When the set start time is reached, the process goes to S92, the control valve 22 of the salt addition unit 23 is opened to add salt to the electrolytic sterilizer 7, and a certain amount necessary for chlorine generation in S93. Of salt is supplied. When salt for one time is supplied in S93, the control valve 22 is closed in S94, and the supply of salt is stopped.
[0062]
Next, in S95, the program sends a signal to the electrolytic sterilizer 7 to start electrolytic sterilization.
The electrolytic sterilization is performed until the end time set in S88, and it is determined whether the end time is reached in T34.
When the end time is reached, the relay switch 7a is turned off and the energization is stopped. Although the electrolytic sterilization ends in S96, the program returns to S91 and continues the normal bath water circulation operation until the next electrolytic sterilization start time comes.
[0063]
An embodiment of claim 7 of the present invention will be described based on the functional block diagram of FIG. The basic configuration of the present invention includes a purification filter 2 for cleaning the bathtub 1 and the bath water, a circulation pump 3 for circulating the bath water, a heater 5 for heating the bath water, and sterilizing the bath water. The electrolytic sterilization device 7 and the salt content adding unit 23 for increasing the electrolysis efficiency in the electrolytic sterilization device 7 are configured.
[0064]
The purification filter 2b is composed of a normal filter 26 for removing dirt from the bath water and a dechlorination filter 27 for removing trihalomethane in the bath water.
[0065]
In the bath water circulation device, when the operation is started, the electrolysis sterilization device 7 starts sterilization of the bath water. The bath water is electrolyzed by the electrolytic sterilization apparatus 7 and chlorine generated along with the electrolysis is mixed into the bath water. The mixed bath water is jetted into the bathtub 1 as bath water, mixed with the bath water in the bathtub, and chlorinated in the bath water.
Chlorine components mixed in the bath water remove proteins and urine components that cause off-flavors and produce clean and safe bath water.
[0066]
The normal filter 26 in the purification filter 2 is for removing normal dirt, and the chlorine removal filter 27 is for removing residual chlorine in the bathtub after electrolytic sterilization and removing chlorine odor during bathing. belongs to. This dechlorination filter is composed of calcium sulfite, nickel peroxide, activated carbon and the like, and effectively removes trihalomethane generated in the bath water.
[0067]
【The invention's effect】
As described above, in claim 1, by using the apparatus using the present invention, the deodorizing effect is high. Conventionally, when a strange odor is generated from the bath water, the bath water must be replaced, etc. The work is eliminated and the economic effect is demonstrated.
Electrolytic sterilization is effective even when the sterilization time is short compared to ultraviolet sterilization and ozone sterilization, and since it is efficient, sterilization can be performed only when rapid sterilization is required or when a person does not take a bath.
In the present invention, these electrolytic sterilization effects can be performed more efficiently, so that salts such as salt and saline can be added and supplied to the electrolytic sterilization device to increase the efficiency of chlorine generation and effectively perform the electrolytic sterilization.
Further, in the invention of claim 2, since the start time of the electrolytic sterilization can be arbitrarily operated and set, quick sterilization can be performed in the case where a bad odor is generated or the bath water is mistakenly soiled, and the sterilization time. Efficient sterilization can be performed by adding salt corresponding to the above.
The invention of claim 3 can arbitrarily set the length of time for electrolytic sterilization, can perform sterilization treatment corresponding to the degree of contamination of the bath water, and is supplied with salt at the start of sterilization, so that efficient sterilization is possible. Yes.
Further, the invention of claim 4 can arbitrarily set the length of time for electrolytic sterilization, and calculates the amount of salt to be supplied corresponding to the sterilization time so as to optimize the amount of bath water. Can be sterilized according to the degree.
In the invention of claim 5, since the start time of electrolytic sterilization is linked with a clock built in the main body, and the adjustment of the electrolytic sterilization time can be performed, the sterilization corresponding to the number of bathers in each household can be performed. It can be done.
In the invention of claim 6, since the start time and end time of electrolytic sterilization can be arbitrarily set, not only can the sterilization be performed during a bathing time such as midnight, but also the time when the bath water becomes dirty or dirty. In accordance with the degree of sterilization, sterilization can be performed very efficiently in order to appropriately control the sterilization time and to control the amount of salt added for generating chlorine.
In the invention of claim 7, by providing a dechlorination filter in addition to the purification filter in the apparatus of claims 1 to 6, the chlorine odor and trihalomethane in the bath water can be removed, corresponding to chlorine sterilization. It is a safe device.
[Brief description of the drawings]
FIG. 1 is an external view showing an embodiment of the present invention.
FIG. 2 is an external view showing the inside of an apparatus according to an embodiment of the present invention.
FIG. 3 is a control block diagram showing an embodiment of the present invention.
FIG. 4 is a functional block diagram showing an embodiment of the present invention.
FIG. 5 is a flow chart of bath water circulation showing one embodiment of the present invention.
FIG. 6 is an electrolytic sterilization flowchart showing one embodiment of the present invention.
FIG. 7 is a functional block diagram showing an embodiment of claim 2 of the present invention.
FIG. 8 is an electrolytic sterilization flowchart showing one embodiment of claim 2 of the present invention.
FIG. 9 is a functional block diagram showing an embodiment of claim 3 of the present invention;
FIG. 10 is a flowchart showing one embodiment of claim 3 of the present invention.
FIG. 11 is a functional block diagram showing an embodiment of claim 4 of the present invention;
FIG. 12 is a flowchart showing one embodiment of claim 4 of the present invention.
FIG. 13 is a block diagram showing an embodiment of claim 5 of the present invention;
FIG. 14 is a flowchart showing one embodiment of claim 5 of the present invention.
FIG. 15 is a functional block diagram showing an embodiment of claim 6 of the present invention;
FIG. 16 is a flowchart showing one embodiment of claim 6 of the present invention;
FIG. 17 is a functional block diagram showing an embodiment of claim 7 of the present invention;
[Explanation of symbols]
A: bath water circulation device, B: control unit (CPU), 1: bathtub, 2: purification filter, 2a: prefilter 3: circulation pump, 3a: circulation pump control means, 4: flow sensor, 5: heater, 5a : Heating control means, 6: temperature sensor, 6a: temperature setting key, 6b: temperature storage section, 6c: temperature comparison section means, 7: electrolytic sterilization device,
8: current sensor, 9: liquid crystal display device, 10: bath water circulation device power switch, 11: energization control means (relay switch), 12: electrolytic sterilization start command switch, 13: sterilization time (timer) change key, 14: change Time memory (RAM),
15: timer, 16: clock (internal clock) setting key, 17: clock means internal clock, 18: sterilization start time storage memory (RAM), 19: start time setting key, 20: end time setting key, 21: end time Storage memory (RAM), 22: Control valve for salt addition control, 23: Salt addition unit, 24: Addition amount storage memory unit (RAM)
25: Jet nozzle, 26: Normal filter part, 27: Dechlorination filter part

Claims (7)

Electrolysis that electrolyzes bath water after cleaning with a diaphragm in a bath water circulation device equipped with a circulation pump that circulates bath water, a purification filter that purifies bath water, and a heater that heats bath water Electrolytic sterilization device that takes in the sterilization device and electrolyzes the bath water to generate chlorine for sterilization, electrolyzes the salt water addition unit for adding salt to the electrolysis sterilization device, and the bath water to which salt is added Energizing control means for controlling energization of the electrolysis sterilizer to generate a predetermined amount of chlorine for sterilization, timer means for energizing the electrolysis sterilizer and generating chlorine for a certain period of time, Electrolytic sterilization start command means for instructing start and salinity addition control means for controlling supply of salt from the salt addition unit in response to a command from the electrolytic sterilization start command means are provided. Bath water circulating device having a solution sterilizer. In the bath water circulation device that pumps up bath water in the bathtub with a circulation pump and circulates it through the circulation path to return to the bathtub after cleaning treatment and heat retention, the bath water after cleaning treatment is taken into an electrolysis sterilizer that electrolyzes with a diaphragm, Energization control means for energizing and controlling the operation of the electrolyzer to electrolyze the bath water obtained by adding salt to the bath water taken in by the electrolyzer and generating a predetermined amount of chlorine for sterilization Electrolytic sterilization start command means for starting sterilization at a start time set so as to perform electrolytic sterilization in a predetermined time zone, and normal bath water circulation operation after sterilization is finished. A bath water circulation device having a sterilization device. 2. The electrolytic sterilization time adjusting means for enabling the electrolytic sterilization time set by the timer means to be set to an arbitrary length, and the adjusted time storage means for storing the adjusted electrolytic sterilization time. A bath water circulation device having an electrolytic sterilization device, further comprising: 2. The electrolytic sterilization time adjusting means for enabling the electrolytic sterilization time set by the timer means to be set to an arbitrary length, and the adjusted time storage means for storing the adjusted electrolytic sterilization time. The salt addition amount storage means for calculating and storing the salt addition amount corresponding to the electrolytic sterilization time set by the electrolytic sterilization time adjustment means, and the salt addition amount data stored in the salt addition amount storage means A bath water circulation device having an electrolytic sterilization device, further comprising: a salt addition control means for controlling a salt addition amount based on the salt addition control means. In Claim 1, the clock means for issuing the electrolytic sterilization start command by the electrolytic sterilization start command means at an arbitrary time, the time setting means for setting the clock means at an arbitrary time, and the set time Setting time storage means for storing, electrolytic sterilization time adjusting means for allowing the electrolysis sterilization time of the timer means to be set to an arbitrary length, and adjustment time storage means for storing the adjusted electrolytic sterilization time A bath water circulation device having an electrolytic sterilization device, further comprising: 2. A clock means for performing electrolytic sterilization at an arbitrary time according to claim 1, and a start time setting means and an end time setting means for setting a time for starting and ending the electrolytic sterilization based on the clock means. Sterilization start time storage means and sterilization end time time storage means for storing the set start time and end time, and sterilization start time and sterilization stored in the sterilization start time storage means and sterilization end time storage means In response to the sterilization start signal and the sterilization end signal based on the end time, the apparatus has an electrolytic sterilization device further provided with a salt addition control means for controlling the salt addition timing from the salt addition unit Bath water circulation device. The dechlorination filter according to claim 1, 2, 3, 4, 5, or 6, further comprising a dechlorination filter for adsorbing residual chlorine components generated by sterilization by the electrolytic sterilizer and remaining in the bath water. A bath water circulation device having an electrolytic sterilization device.

Images