JP2003290768A - Apparatus for preventing adhesion of urinary calculus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an apparatus 1 for preventing adhesion of urinary calculi which is capable of easily maintaining a stable sterilization effect and makes it possible to obtain a cleaning effect as well by forming reformed water by electrolysis using a first intermediate electrode 12 made of ferrite and a second intermediate electrode 22 made of magnesium. <P>SOLUTION: The reformed water containing various oxygen active specifies (OH, H<SB>2</SB>O<SB>2</SB>, O<SB>2</SB><SP>-</SP>, etc.), and having the sterilization effect is formed by electrolysis of water in a first electrolytic chamber 10 in which the first intermediate ferritic electrode 12 is disposed. The reformed water containing Mg(OH)<SB>2</SB>and having the alkaline cleaning effect is formed in a second electrolytic chamber 20 in which the second intermediate electrode 22 made of magnesium is disposed. Such reformed water is made to flow out to a toilet 6 based on a specified rule. As a result, the apparatus 1 for preventing adhesion of the urinary calculi which is capable of stably maintaining the sterilization effect and makes it possible to obtain the cleaning effect as well can be obtained by the easy means of electrolyzing the water. <P>COPYRIGHT: (C)2004,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a structure of a urinary stone adhesion preventing device for suppressing adherence of urine stones, which is the main cause of colored stains on the toilet bowl, to the toilet bowl.

[0002]

BACKGROUND OF THE INVENTION One of the main causes of colored stains on toilet bowls is adhesion of urine stones. In urinary stones, urea in urine is decomposed into ammonia by bacteria and its pH rises to become alkaline, whereby calcium ions (Ca ²⁺ ) and phosphate ions (PO ₄ ^2- ) in urine react with each other. And calcium phosphate (Ca
PO ₄ ) is precipitated together with organic matter. Therefore, sterilization is an effective method for preventing urinary stones from adhering to the toilet bowl.

Conventionally, as a sterilizing method for toilet bowls, hypochlorous acid (HOC) is used by spraying chemicals or electrolyzing tap water.
1) was generated and sprayed.

[0004]

However, in the method of spraying a drug, since it is necessary to regularly supply the drug to the drug sprayer, the drug replenishing work is complicated and the running cost is consumed because the drug is consumed. There was a problem that it would be huge.

Further, the method of spraying hypochlorous acid (HOCl) generated by electrolysis can suppress maintenance costs and running costs, but it is possible to reduce chlorine ion concentration in feed water (for example, tap water). There is a problem that the concentration of hypochlorous acid (HOCl) generated in conjunction changes, that is, the bactericidal effect varies, so that the bactericidal effect cannot be stably maintained.

Further, although the above-mentioned two methods have a sterilizing effect, they have no effect of removing dirt adhering to the toilet bowl, so once urine stones adhere to the toilet bowl, it cannot be removed, that is, a separate detergent or the like. There was also a problem that cleaning was required.

The present invention has been made in view of the above problems, and by using reformed water obtained by electrolysis by a ferrite electrode and a magnesium electrode,
An object of the present invention is to provide a urinary stone adhesion preventing device which can easily and stably maintain a bactericidal effect and can also obtain a cleaning effect.

[0008]

In order to achieve the above object, the present invention employs the following technical means. The urinary stone adhesion preventive device according to claim 1 of the present invention is a toilet bowl, an electrolytic cell divided into a first electrolysis chamber and a second electrolysis chamber with an electrolytic membrane through which ions can pass, and a first electrolysis chamber. A first electrode formed of a noble metal or a noble metal alloy disposed in the chamber, a second electrode formed of a noble metal or a noble metal alloy disposed in the second electrolysis chamber, between the first and second electrodes and the first electrolysis A first intermediate electrode formed of ferrite arranged in the chamber, a second intermediate electrode formed of magnesium arranged between the first and second electrodes and in the second electrolysis chamber, and first and second Control means for applying a voltage to the electrodes, a first conduit for introducing water into the first electrolysis chamber, a second conduit for introducing water into the second electrolysis chamber, and water in the first electrolysis chamber to the toilet side. A first water discharge pipe for flowing out and a second water discharge pipe for discharging water in the second electrolysis chamber to the toilet side,
The control means applies a voltage to the first and second electrodes to reform the water in the first and second electrolysis chambers by electrolysis, respectively, and the reformed water is transformed into first and second water in response to a cleaning request. (2) It was configured to flow out to the toilet side via a water discharge pipe.

According to the first aspect of the invention, when a voltage is applied to the first and second electrodes, electrons are taken from the water in the vicinity of the high potential voltage electrode side surface of the first intermediate electrode in the first electrolysis chamber. Various oxygen-active species (eg, hydrogen peroxide, hydroxy radicals, superoxide anions, etc.) are produced. A bactericidal effect can be obtained by the oxidizing power of these oxygen active species. On the other hand, in the second electrolysis chamber, magnesium ions (Mg ²⁺ ) are transferred from the surface of the second intermediate electrode on the high potential voltage electrode side.
Is dissolved in water and the water in the second electrolysis chamber is reformed to be alkaline. The surface-active action of this reformed water removes dirt on the toilet bowl surface. Therefore, it is possible to realize a urinary stone adhesion preventing device that can stably maintain the sterilizing effect and at the same time remove dirt on the surface of the toilet bowl. Since the first intermediate electrode is made of ferrite, it is possible to generate oxygen active species with high efficiency.

Further, by separating one electrolytic cell by an electrolytic membrane through which ions can pass, two kinds of electrolytic chambers, that is, a first electrolytic chamber and a second electrolytic chamber are formed without increasing the number of electrodes connected to a power source. Therefore, the wiring to the electrodes can be simplified and the urine stone adherence preventing device can be downsized.

Since a water discharge pipe is provided in each of the first and second electrolysis chambers to discharge the reformed water in the electrolysis chambers to the toilet bowl.
It is possible to freely select the type of reforming water to be discharged from the urine stone adhesion preventing device to the toilet bowl, as required.

Further, since the first intermediate electrode made of ferrite and the second intermediate electrode made of magnesium are not directly connected to the voltage applying means, ferrite,
Alternatively, when magnesium is consumed and each intermediate electrode is replaced, the electrode replacement work can be easily performed.

In the urinary stone adhesion preventing apparatus according to the second aspect of the present invention, the voltage applying means applies a high potential voltage to the first electrode and a low potential voltage to the first electrode in a first conduction mode. , A second conduction mode in which a low potential voltage is applied to the first electrode and a high potential voltage is applied to the first electrode is alternately switched.

According to the second aspect of the present invention, when electrolysis proceeds in the first and second electrolysis chambers by applying a voltage to the first and second electrodes, the first and second intermediate electrodes are consumed. Both surfaces of each intermediate electrode can be consumed, and the life of each intermediate electrode can be extended.

That is, in the first electrolysis chamber,
Surface of the first intermediate electrode on the side of the low potential voltage electrode
Exposed to hydrogen gas produced by electrolysis of water
Deteriorated. On the other hand, in the second electrolysis chamber, the second intermediate electrode
On the surface of the high potential voltage electrode side of Mg (OH)₂Is deposited,
Due to this deposited material, Mg on the surface of the second intermediate electrode^{2 +}
Dissolution of the ions becomes uneven, and the turtle appears on the surface of the second intermediate electrode.
Cracking or roughening (unevenness) occurs. This state
Continuing, peeling of minute magnesium pieces from the electrode surface
Occurs and the life of the electrode is shortened. Therefore, the first and second
Switch the polarity of the voltage applied to the electrodes, and repeat it.
By returning it, both front and back surfaces of the first intermediate electrode are deteriorated.
At the same time, make both front and back surfaces of the second intermediate electrode rough.
Therefore, it is possible to extend the life of the first and second intermediate electrodes.
You can

In this case, if the durations of the first energization mode and the second energization mode are set equal to each other, as in the urinary stone adherence prevention device according to the fifth aspect, the first and second intermediate electrodes can be connected. It is possible to extend the service lives of the first and second intermediate electrodes by ensuring that the degrees of wear on the front and back surfaces are equal.

A urinary stone adherence prevention device according to a third aspect of the present invention is a toilet bowl, and a pair of third electrodes made of a noble metal or a noble metal alloy and a ferrite formed between the third electrodes. A first electrolytic cell having one intermediate electrode; a pair of fourth electrodes made of a noble metal or a noble metal alloy; and a second electrode made of magnesium arranged between the fourth electrodes.
A second electrolyzer provided with an intermediate electrode; a control means for applying a voltage to the pair of third electrodes and a voltage to the pair of fourth electrodes; and a first water conduit for flowing water into the first electrolyzer. A second water conduit for inflowing water into the second electrolyzer, a first water discharge pipe for outflowing water from the inside of the first electrolyzer to the toilet side, and a second discharge pipe for outflowing water from the inside of the second electrolyzer to the toilet side. A water pipe, and the control means applies a voltage to the pair of third electrodes and a voltage to the pair of fourth electrodes to reform the water in the first and second electrolytic cells by electrolysis, respectively. The modified water is made to flow out to the toilet side through the first and second water discharge pipes in response to a cleaning request.

According to the third aspect of the invention, when a voltage is applied to the third and fourth electrodes, electrons are taken from the water in the vicinity of the high potential voltage electrode side surface of the first intermediate electrode in the first electrolytic cell. Various oxygen-active species (eg, hydrogen peroxide, hydroxy radicals, superoxide anions, etc.) are produced. A bactericidal effect can be obtained by the oxidizing power of these oxygen active species. On the other hand, in the second electrolytic cell, magnesium ions (Mg ²⁺ ) are transferred from the surface of the second intermediate electrode on the high potential voltage electrode side.
Is dissolved in water and the water in the second electrolytic cell is reformed to be alkaline. The surface-active action of this reformed water removes dirt on the toilet bowl surface. Therefore, it is possible to realize a urinary stone adhesion preventing device that can stably maintain the sterilizing effect and at the same time remove dirt on the surface of the toilet bowl. Since the first intermediate electrode is made of ferrite, it is possible to generate oxygen active species with high efficiency.

Since the first and second electrolytic cells are respectively provided with water discharge pipes for flowing the reformed water in the electrolytic cells to the toilet bowl,
It is possible to freely select the type of reforming water to be discharged from the urine stone adhesion preventing device to the toilet bowl, as required.

Since the first intermediate electrode made of ferrite and the second intermediate electrode made of magnesium are not directly connected to the voltage applying means, the ferrite,
Alternatively, when magnesium is consumed and each intermediate electrode is replaced, the electrode replacement work can be easily performed.

In the urinary stone adhesion preventing apparatus according to claim 4 of the present invention, the voltage applying means applies a high potential voltage to one of the pair of third electrodes of the first electrolysis cell and to the other. The first conduction mode in which a low potential voltage is applied and the second conduction mode in which a low potential voltage is applied to one of them and a high potential voltage is applied to the other are alternately switched, and a pair of fourth electrolysis cells of the second electrolytic cell are provided. A first energization mode in which a high potential voltage is applied to one of the electrodes and a low potential voltage is applied to the other, and a second energization in which a low potential voltage is applied to one of the electrodes and a high potential voltage is applied to the other The mode is switched alternately.

According to the fourth aspect of the present invention, by applying a voltage to the pair of third electrodes and a voltage to the pair of fourth electrodes, electrolysis proceeds in the first and second electrolytic cells to cause the first intermediate electrode. Although the second intermediate electrode is consumed, both surfaces of each intermediate electrode can be consumed almost evenly, and the life of each intermediate electrode can be extended.

That is, in the first electrolytic cell,
Surface of the first intermediate electrode on the side of the low potential voltage electrode
Exposed to hydrogen gas produced by electrolysis of water
Deteriorated. On the other hand, in the second electrolytic cell, the second intermediate electrode
On the surface of the high potential voltage electrode side of Mg (OH)₂Is deposited,
Due to this deposited material, Mg on the surface of the second intermediate electrode^{2 +}
Dissolution of the ions becomes uneven, and the turtle appears on the surface of the second intermediate electrode.
Cracking or roughening (unevenness) occurs. This state
Continuing, peeling of minute magnesium pieces from the electrode surface
Occurs and the life of the electrode is shortened. Therefore, a pair of third
Polarity of voltage application to the electrodes and voltage application to the pair of fourth electrodes
, And then repeat it one by one,
Both the front and back surfaces of the intermediate electrode are deteriorated, and the second intermediate electrode
Since it is possible to make both front and back surfaces rough,
The life of the second intermediate electrode can be extended.

In this case, if the durations of the first energization mode and the second energization mode are set equal to each other, as in the urinary stone adherence prevention device according to the fifth aspect, the first and second intermediate electrodes can be connected. It is possible to extend the service lives of the first and second intermediate electrodes by ensuring that the degrees of wear on the front and back surfaces are equal.

The urinary stone adherence prevention device according to claim 6 of the present invention is provided in the middle of the first water conduit and is provided in the middle of the second water conduit and first valve means for opening and closing the first water conduit. Second valve means for opening and closing the second water pipe, third valve means provided in the middle of the first water discharge pipe for opening and closing the first water discharge pipe, and opening and closing the second water discharge pipe provided in the middle of the second water discharge pipe And a fourth valve means for controlling the opening and closing of these first to fourth valve means. Thereby, the outflow of water from the first and second electrolysis chambers or the first and second electrolysis tanks to the toilet bowl,
Also, the water can be easily and reliably supplied to the first and second electrolysis chambers or the first and second electrolyzers at any timing.

According to a seventh aspect of the present invention, in the urinary stone adhesion preventing device, the first to fourth valve means are electromagnetic valves, and the electromagnetic valves are driven by the control means. Thereby, the outflow of water from the first and second electrolysis chambers or the first and second electrolysis tanks to the toilet bowl, and the supply of water to the first and second electrolysis chambers or the first and second electrolysis tanks. It can be performed easily and surely at any timing.

[0027]

BEST MODE FOR CARRYING OUT THE INVENTION A urinary stone adhesion preventing device according to the present invention will be described below with reference to the drawings.

(First Embodiment) FIG. 1 shows a first embodiment of the present invention.
It is explanatory drawing which shows the structure of the urine stone adhesion prevention apparatus 1 by embodiment of this.

As shown in FIG. 1, the urinary stone adherence prevention apparatus 1 is roughly divided into an electrolytic cell 2 divided into a first electrolytic chamber 10 and a second electrolytic chamber 20 by an electrolytic membrane 3, and both electrolytic chambers 10. , 20
A control device 4 for applying a voltage to the first electrode 11 and the second electrode 21 provided therein, and first and second water conduits 13, 23 for allowing pressurized water to flow into both electrolysis chambers 10, 20; First,
1st, 2nd which intercepts or connects the 2nd water conduits 13 and 23
Electromagnetic valves 14 and 24, first and second water discharge pipes 15 and 25 for causing water in both electrolysis chambers 10 and 20 to flow out, and third that shuts off or connects the first and second water discharge pipes 15 and 25, The fourth solenoid valves 16 and 26 are provided.

The electrolytic cell 2 is made of a material resistant to acids and alkalis, such as plastic or stainless steel. In addition, the electrolytic cell 2 includes a first electrolytic chamber 10 and a second electrolytic chamber 2 with an electrolytic membrane 3 through which ions can pass.
As shown in FIG. 1, the first electrolysis chamber 10 and the second electrolysis chamber 20 are Pt- which are noble metal alloys.
The first electrode 11 and the second electrode 21 made of Ti alloy are arranged so as to face each other. Further, a first intermediate electrode made of ferrite is arranged between the first and second electrodes 11 and 21 and in the first electrolytic chamber 10. Further, between the first and second electrodes 11 and 21 and in the second electrolytic chamber 20,
A second intermediate electrode formed of magnesium is arranged. As the above-mentioned electrolytic membrane 3, for example, a composite of a porous membrane made of polytetrachloroethylene and a non-woven fabric made of polyethylene terephthalate is used. Ions can pass through the electrolytic membrane 3. In other words, although a current flows between the first and second electrodes 11 and 21 in the electrolytic bath 2, the first and second electrolytic chambers 1
The electrolysis products at 0 and 20 cannot pass.

First water pipe 13 for injecting pressurized water into the first electrolysis chamber, and pressurized water into the second electrolysis chamber flow into the upper portions of the first and second electrolysis chambers 10 and 20. The second water guiding pipes 23 to be connected are respectively connected, and the first water guiding pipes 13 and 23 are connected in the middle of the first and second water guiding pipes 13 and 23, respectively.
First and second electromagnetic valves 14 and 24, which are second switching means, are provided, respectively. In addition, each water conduit 13, 23
Is connected to a water supply pipe (not shown) or an industrial water pipe (not shown). In addition, the first and second solenoid valves 1
Nos. 4 and 24 are in a cutoff state when not energized and in a communication state when energized.

On the other hand, below the first electrolysis chamber 10 and the second electrolysis chamber 20, the first water discharge pipe 1 for letting out the water in the first electrolysis chamber is provided.
5. Second discharge pipes 25 for discharging water in the second electrolysis chamber are connected respectively, and third and fourth switching means for shutting off or communicating the water discharge pipes 15, 25 in the middle of the water discharge pipes 15, 25. The third and fourth electromagnetic valves 16 and 26 are respectively provided. In addition, as shown in FIG. 1, the water discharge pipes 15 and 25 are connected together above the toilet bowl 6 as a unit in the middle. Further, the third and fourth solenoid valves 16 and 26 are in a cutoff state when not energized and in a communication state when energized.

Further, first and second water level sensors 17 and 27 for detecting the water levels in the first and second electrolysis chambers 10 and 20 are installed above the first and second electrolysis chambers 10 and 20, respectively. Has been done. The output signals of the first and second water level sensors 17 and 27 are low level when the water levels in the first and second electrolysis chambers 10 and 20 are above a predetermined value, and the first and second electrolysis chambers 10 and 20 are low. When the water level inside is less than the specified value, the level is high.

Next, the structure of the control device 4 which is a voltage applying means for applying a voltage to the first electrode 11 and the second electrode 21 will be described. FIG. 2 shows an electric circuit configuration diagram of the control device 4 of the urinary stone adhesion preventing device 1 according to the first embodiment of the present invention.

As shown in FIG. 2, the control device 4 is connected to an AC power source 8 of 100 V, for example, via a main switch 7. The control device 4 includes a converter 41 that converts AC power from the 100V AC power supply 8 into DC having a predetermined voltage.
And a power supply unit 42 which is supplied with DC power from the conversion unit 41 to apply a voltage to the first and second electrodes 11, 21 and drives the first to fourth electromagnetic valves 14, 24, 16, 26, and The control unit 43 operates by the DC power from the unit 41 and outputs a voltage application signal and a solenoid valve drive signal to the power supply unit 42. That is, the power supply unit 42 applies a voltage to the first and second electrodes 11 and 21 based on the voltage application signal and the solenoid valve drive signal from the control unit 43, and at the same time, the first to fourth solenoid valves 14, 24 and 16 are provided. , 26 are driven.

In the urinary stone adhesion preventive apparatus 1 according to the first embodiment of the present invention, the conversion unit 41 supplies a direct current 36V to the power supply unit 42 and a direct current 5V to the control unit 43.

The power supply unit 42 applies 36 V as a high potential voltage to one electrode of the first electrode 11 and the second electrode 21 and applies 0 V as a low potential voltage to the other electrode. In addition, the first to fourth solenoid valves 14, 24, 16, 26
Is driven with a direct current of 36V.

The control section 43 has a first
A first energization mode in which 36 V as a high potential voltage is applied to the electrode 11 and 0 V as a low potential voltage is applied to the second electrode 21, and 0 V as a low potential voltage is applied to the first electrode 11 and the second electrode 21 is applied. The voltage application signal is output so as to alternately repeat the second conduction mode in which 36 V is applied as the high potential voltage. Further, the energization time in the first energization mode and the energization time in the second energization mode are set to be equal to each other, and in the urine stone adherence prevention device 1 according to the first embodiment of the present invention, each is set to 3 seconds. It is set. Further, the control section 43 is connected to the toilet use sensor 5 that detects that the toilet 6 is used.
The toilet use sensor 5 is composed of, for example, an infrared sensor, and detects that there is a person in the immediate vicinity of the toilet 6, that is, the toilet 6 is in use. First of the present invention
The output signal level of the toilet use sensor 5 of the urinary stone adherence prevention device 1 according to the embodiment is high when the toilet 6 is in use and low when the toilet 6 is not in use. The control unit 43 starts operation based on the output signal from the toilet use sensor 5, and outputs a voltage application signal and a solenoid valve drive signal to the power supply unit 42 according to a predetermined rule. Further, the control unit 43 has the first and second
First and second for detecting the water level in the electrolysis chambers 10 and 20
Water level sensors 17 and 27 are connected.

The main switch 7 of the urinary stone adhesion preventing device 1 is normally closed except when it is not used for a long period of time.

Next, the operation of the urinary stone adhesion preventing device 1 according to the first embodiment of the present invention will be described based on the time chart of the operation of each part of the urine stone adhesion preventing device 1 shown in FIG.

FIG. 3 shows the first to fourth solenoid valves 14 and 2 in the urinary stone adhesion preventing apparatus 1 according to the first embodiment of the present invention.
4 is a time chart of the output signal levels of the first, second water level sensors 17, 27, and the toilet use sensor 5, and 4, 16, 26, the first and second electrodes 11, 21 are energized. That is, in FIGS. 3A to 3D, the first to fourth solenoid valves 1 are shown.
4, 24, 16 and 26 show energized states. FIG. 3E shows a voltage application state to the first and second electrodes 11 and 21. 3 (f) to 3 (h), the first and second water level sensors 1 are shown.
7 and 27 show the output signal levels of the toilet use sensor 5.
In FIGS. 3A to 3H, the vertical axis represents the energized state (ON,
OFF) or the output signal level (H, L), and the horizontal axis represents time (t).

When a person stands in front of the toilet bowl 6, the output signal level of the toilet bowl use sensor 5 changes from L to H, as shown in FIG. 3 (h). As a result, the control unit 43 of the control device 4 starts operating.

First, when a person leaves the toilet bowl 6 and the output signal level of the toilet bowl use sensor 5 changes from H to L, the controller 4 causes the fourth solenoid valve 26 to operate, as shown in FIG. 3 (d). The second water discharge pipe 25 is energized and communicates. As a result, the reformed water in the second electrolysis chamber 20 flows out to the toilet 6 through the second water discharge pipe 25. The reforming water in the second electrolysis chamber 20 is Mg
It is alkaline containing (OH) ₂ , and its surface activating action removes dirt on the toilet bowl 6. Here, the energization time t1 to the fourth solenoid valve 26 is set so that the entire amount of the reforming water in the second electrolysis chamber 20 flows out. When the time t1 has passed and the power supply to the fourth solenoid valve 26 is stopped, the second water discharge pipe 25 is cut off again. When the reformed water in the second electrolysis chamber 20 flows out, the output signal level of the second water level sensor 27 changes from H to L, as shown in FIG.

Next, as shown in FIG. 3 (c), the third solenoid valve 16 is energized to connect the first water discharge pipe 15. As a result, the reformed water in the first electrolysis chamber 10 flows out to the toilet 6 through the first water discharge pipe 15. The reforming water in the first electrolysis chamber 10 is
It contains various oxygen active species generated by ferrite electrolysis, and the sterilizing action thereof sterilizes the inside of the toilet bowl 6. Here, the energization time t2 to the third solenoid valve 16 is set so that the entire reforming water in the first electrolysis chamber 10 flows out.
When the time t2 has elapsed and the energization of the third solenoid valve 16 is stopped, the first water discharge pipe 15 is cut off again. When the reformed water in the first electrolysis chamber 10 flows out, the output signal level of the first water level sensor 17 changes from H to L, as shown in FIG.

Next, as shown in FIGS. 3 (a) and 3 (b),
The first and second solenoid valves 13 and 23 are energized to connect the first and second water conduits 13 and 23. This allows water from a water pipe (not shown) or industrial water pipe (not shown) to
It flows into the first and second electrolysis chambers 10 and 20 through the first and second water conduits 13 and 23. Then, the first and second electrolysis chambers 1
The water level in 0 and 20 becomes a predetermined level, and as shown in FIG.
As shown in (g), the first and second water level sensors 17, 27
When the output signal of changes from L to H,
The energization of the second solenoid valves 13 and 23 is stopped and the first and second solenoid valves are stopped.
The water conduits 13 and 23 are cut off to stop the flow of water into the electrolysis chambers 10 and 20.

Next, the control device 4 operates as shown in FIGS. 3 (f) and 3 (g).
It is detected by the output signals of the first and second water level sensors 17 and 27 shown in FIG. 2 that both of the electrolysis chambers 10 and 20 are filled with water, and as shown in FIG. 2 electrodes 1
The voltage application to Nos. 1 and 21 is started.

That is, the control unit 43 applies a voltage to the power supply unit 42 to the first and second electrodes 11 and 21 of the electrolytic cell 2, that is, the first conduction mode for 3 seconds and the second conduction mode for 3 seconds. A voltage application signal is output so as to alternately repeat and. As a result, the first electrode 11 is set in the first energization mode.
When 36 V as a high potential voltage and 0 V as a low potential voltage are applied to the second electrode 21 for 3 seconds, then, as a second conduction mode, 0 V as a low potential voltage is applied to the first electrode 11.
36 V as a high potential voltage is applied to the second electrode 21 for 3 seconds, and this is repeated alternately. At this time, in the first and second electrodes 11 and 21, the first and second intermediate electrodes 12 and 22, the potential difference between two adjacent electrodes is 7.2 V (36 V / 36 V /
5).

As a result, in the electrolytic cell 2, the first and second electrodes 11 and 21, the first and second intermediate electrodes 12 and 2,
2, the electrolysis proceeds. Note that FIG. 1 shows the first energization mode, that is, 36 V for the first electrode 11 and the second electrode 21.
Shows that 0V is applied. In the electrolytic cell 2, as shown in FIG. 1, the first electrode 1 to which 36V is applied
1 acts as a + pole, and the second electrode 21 to which 0 V is applied acts as a − pole. At the same time, in the first and second intermediate electrodes 11 and 12, the surfaces 12a and 22a on the first electrode 11 side act as a negative pole, and the surfaces 12b and 22b on the second electrode 21 side act as a positive pole. Therefore, in the first electrolysis chamber 10, hydrogen gas is generated in the vicinity of the first electrode 11 side surface 12a of the first intermediate electrode 12, which is the negative electrode, and at the same time, the first intermediate electrode 1 that is the positive electrode is generated.
Various active species of oxygen in the vicinity of the second electrode 21 side surface 12b of the _{2 (OH, H 2 O 2} , O 2 - , etc.) is generated. The oxidizing power of these oxygen active species exerts a bactericidal effect. That is, the first
The water in the electrolysis chamber 10 becomes reforming water having a sterilizing effect. On the other hand, in the second electrolysis chamber 20, Mg ²⁺ ions are eluted from the surface 22b of the second intermediate electrode 22, which is the + electrode, on the side of the second electrode 21, and OH— generated by electrolysis of the Mg ²⁺ ions and water
And causes a reaction as shown in (Chemical Formula 1) below,
(OH) ₂ is produced. This Mg (OH) ₂ is dissolved in water and the water in the second electrolysis chamber 20 is reformed to be alkaline.
Since this reformed water has a surface active effect, it exhibits a cleaning effect.

[0049]

[Chemical formula 1] Mg ²⁺ + OH- → Mg (OH) _{2 Since} the first electrolysis chamber 10 and the second electrolysis chamber 20 are separated by the electrolytic membrane 3, a current flows between the first and second electrodes 11 and 21. The products in 10 and 20 (various oxygen active species, Mg (OH) ₂ ) are not mixed.

When the first energization mode progresses due to the voltage application, the surface 12a of the first intermediate electrode 12 on the first electrode 11 side is exposed to hydrogen gas and deteriorates. In addition, the Mg (OH) 2 generated on the surface 22 b of the second intermediate electrode 22 on the second electrode 21 side.
₂ begins to precipitate. When the amount of Mg (OH) ₂ deposited is large, the elution of Mg ²⁺ ions from the surface 22b of the second intermediate electrode 22 on the side of the second electrode 21 becomes non-uniform, resulting in cracks on the surface 22b or formation of the surface 22b. It becomes rough and uneven. If this state continues, peeling of fine magnesium pieces from the surface 22b occurs and the life of the second intermediate electrode 22 is shortened. Therefore, when Mg (OH) ₂ starts to precipitate on the surface 22b, that is, when the first energization mode has passed for 3 seconds, the mode is switched to the second energization mode, and Mg ²⁺ ions are generated from the surface 22a opposite to the surface 22b. By dissolving Mg (OH) ₂ that has started to precipitate on the surface 22b in water and restoring the surface 22b, the surfaces 22a and 22b of the second intermediate electrode 22 are prevented from being roughened and the life is extended. can do. Also, regarding the first intermediate electrode 12, by switching to the second energization mode, the surfaces 12a and 12b of the first intermediate electrode 12 are evenly deteriorated and consumed, and the life can be extended.

By the way, in the urinary stone adhesion preventing apparatus 1 according to the first embodiment of the present invention, a magnesium casting material is used as the second intermediate electrode 22, and in the case of the casting material, Mg (OH) ₂ is formed on the electrode surface. Since the time until the start of precipitation is about 3 seconds, the energization time in the first energization mode and the second energization mode is set to 3 seconds. A method of manufacturing a magnesium material for forming the second intermediate electrode 22 (for example, forging,
Mg (OH) _{2 on the} electrode surface
The time until the start of precipitation also differs. Therefore, by setting the energization time in the first energization mode and the second energization mode to be optimal according to the method for producing the magnesium material used as the intermediate electrode 5, the second intermediate electrode 22 is always provided.
Roughness of the surfaces 22a and 22b can be prevented and the life can be extended.

The first and second intermediate electrodes 12 and 22 are
Deteriorated by hydrogen gas or Mg ²⁺By elution of ions
It is consumed and requires regular replacement. The present invention
In the urinary stone adhesion preventing device 1 according to one embodiment,
The first and second intermediate electrodes 12 and 22 are the first electrode 11 and the second intermediate electrode.
It is electrically connected to the control device 4 like the two electrodes 21.
Since it is not available, its replacement work can be carried out easily.
It

The voltage application time to the first and second electrodes 11 and 21 while alternately switching the first energization mode and the second energization mode is a predetermined time (the urine stone adhesion preventing apparatus according to the first embodiment of the present invention. After 30 minutes (1), the control device 4 stops the voltage application to the first and second electrodes 11 and 21. Further, when the toilet bowl 6 is used and the output signal level of the toilet bowl usage sensor 5 changes from L to H before 30 minutes have passed, the control unit 43 detects it and detects the first and second electrodes 1.
The voltage application to Nos. 1 and 21 is stopped, and the next operation is newly started.

In the urinary stone adhesion preventing apparatus 1 according to the first embodiment of the present invention described above, the first electrolytic chamber 10 and the second electrolytic chamber 20 are separated by the electrolytic membrane 3 through which ions can pass. A partitioned electrolysis tank 2, a first electrode 11 formed of a noble metal or a noble metal alloy in the first electrolysis chamber 10, and a second electrode 11 formed of a noble metal or noble metal alloy in the second electrolysis chamber 20. Between the electrode and 21, the first and second electrodes 11 and 21, and between the first intermediate electrode 12 formed of ferrite and disposed in the first electrolysis chamber 10, between the first and second electrodes 11 and 21, and between the second electrode A second intermediate electrode 22 made of magnesium disposed in the electrolysis chamber 20, and first and second electrodes 11 and 21.
A control device 4 which is a voltage applying means for applying a voltage to the first electrolysis chamber 10 and a first water conduit 1 for injecting pressurized water into the first electrolysis chamber 10.
3 and a second that allows pressurized water to flow into the second electrolysis chamber 20
The water conduit 23, the first solenoid valve 14 that is a first switching means that is provided in the middle of the first water conduit 13 and that blocks or communicates with the first water conduit 13, and the first solenoid valve 14 that is provided in the middle of the second water conduit 23 The second electromagnetic valve 24, which is a second switching unit that shuts off or connects the second water conduit 23, the first water discharge pipe 15 that causes the water in the first electrolysis chamber 10 to flow out, and the water in the second electrolysis chamber 20. In the middle of the second water discharge pipe 25, the second water discharge pipe 25 to be discharged, the third solenoid valve 16 which is a third switching means which is provided in the middle of the first water discharge pipe 15 and blocks or communicates with the first water discharge pipe 15. And a fourth electromagnetic valve 26, which is a fourth switching means for shutting off or communicating with the second water discharge pipe 25, and the first and second electrodes 1 and 2.
A voltage is applied to the first and the second electrolysis chambers 10 and 10.
Each of the water inside is reformed by electrolysis,
It is configured to flow out to the toilet bowl 6 via the second water discharge pipes 15 and 16. Further, the control device 4 applies the high potential voltage to the first electrode 11 and the low potential voltage to the second electrode 21, and the first conduction mode, and applies the low potential voltage to the first electrode 11 and the second potential mode. Second for applying a high potential voltage to the electrode 12
The configuration is such that the energization mode is switched alternately.

As a result, in the first electrolysis chamber 10,
Various active oxygen species by electrolysis _{(OH, H 2 O 2,} O 2 -
Etc.) are produced and the water is reformed. A bactericidal effect can be obtained by the oxidizing power of these oxygen active species. Further, since various oxygen active species are generated irrespective of the chlorine concentration in tap water, etc., the bactericidal effect can always be stably maintained. On the other hand, in the second electrolytic chamber 20, Mg (OH)
₂ is produced and the water is reformed to be alkaline. The surface-active action of this reformed water can remove dirt on the toilet bowl surface.
That is, the reformed water having a bactericidal effect and the reformed water having a cleaning effect can be simultaneously generated by an easy means of electrolyzing water, so that the bactericidal effect can be stably maintained and the cleaning can be performed. It is possible to realize the urinary stone adherence prevention device 1 that also provides the effect.

Further, by separating one electrolytic cell 2 by an electrolytic membrane 3 through which ions can pass, two kinds of electrolytic chambers, that is, a first electrolytic chamber 10 and an electrolytic chamber directly connected to the control device 4 are not increased. The second electrolysis chamber 20 is formed. Therefore, the number of electrodes can be reduced, the wiring can be simplified, the cost can be reduced, and the urine stone adhesion preventing apparatus 1 can be downsized.

Further, the first and second water discharge pipes 15 and 25 for letting out the reforming water generated in the first and second electrolysis chambers 10 and 20.
Also, since the third and fourth electromagnetic valves 16 and 26 for switching between shutoff or communication of the water discharge pipes 15 and 25 are provided to allow both reforming water to flow out independently, the urinary stone adhesion preventing device 1
It is possible to freely select the type of reforming water to be flown out of the tank as required.

Further, since the first intermediate electrode 12 made of ferrite and the second intermediate electrode 22 made of magnesium are not directly connected to the control device 4, ferrite or magnesium is consumed and each intermediate electrode is consumed. 1
When 2 and 22 are replaced, the electrode replacement work can be easily performed.

When voltage is applied to the first and second electrodes 11 and 21, the first energization mode and the second energization mode are alternately switched, so that both surfaces 12a and 12b of the intermediate electrodes 12 and 22 are 22a and 22b can be consumed almost uniformly, and the life of each intermediate electrode 12 and 22 can be extended.

In the urinary stone adhesion preventive apparatus 1 according to the first embodiment of the present invention described above, the number of the intermediate electrodes 12 and 22 is two, but the number is not limited to two. You don't have to. For example, it may be three at a time. Moreover, the number of the intermediate electrodes 12 and 22 may not be the same but may be different. Furthermore, a plurality of intermediate electrodes 1
If 2 and 22 are fixed to spacers made of an electrically insulating material to form a unit, and each intermediate electrode 12 and 22 is made into one part, the workability when replacing each intermediate electrode 12 and 22 can be improved. it can.

Further, in the urinary stone adhesion preventing apparatus 1 according to the first embodiment of the present invention described above, the first electrode 1
Although the first and second electrodes 21 are formed of Pt-Ti alloy,
The first electrode 11 may be made of ferrite and the second electrode 21 may be made of magnesium. This allows
Since the total area of the ferrite electrode and the magnesium electrode can be increased, the reforming water can be generated in a short time in the electrolytic cell 2 having a small capacity. In this case, each intermediate electrode 12,
At least one of 22 may be omitted. This allows
The electrolytic cell 2 can be downsized.

Further, in the urinary stone adhesion preventing apparatus 1 according to the first embodiment of the present invention described above, the first electrode 11
May be made of ferrite, or the second electrode 21 may be made of magnesium. As a result, the total area of the ferrite electrode or the magnesium electrode can be increased, so that the reforming water can be generated in a short time in the electrolytic cell 2 having a small capacity.

The first electrode 11 is made of ferrite and the first intermediate electrode 12 is omitted, or the second electrode 21 is made of magnesium and the second intermediate electrode 22 is formed.
May be omitted. Thereby, the electrolytic cell 2 can be downsized.

Further, the first electrode 11 and the second electrode 21
May be formed from a noble metal such as Pt instead of the Pt—Ti alloy that is a noble metal alloy. By this, both electrodes 1
It is possible to eliminate the need for replacement of 1 and 21.

Further, the operation of the urinary stone adhesion preventing apparatus 1 according to the first embodiment of the present invention is not limited to the contents shown in the time chart of FIG. 3, and may be changed as necessary. For example, in the time chart of FIG. 3, when the use of the toilet bowl 6 is finished, that is, when the output signal level of the toilet bowl use sensor 5 changes from H to L, the reforming water is caused to flow out from each electrolytic chamber 10, 20. However, during use of the toilet bowl 6, that is, after a predetermined time (for example, 5 seconds) after the output signal level of the toilet bowl usage sensor 5 changes from L to H,
The reforming water may flow out from each of the electrolysis chambers 10 and 20. In addition, the order of outflow of the reforming water from the electrolysis chambers 10 and 20 is
First, the first electrolysis chamber 10 and then the second electrolysis chamber are used, but this may be reversed. Further, the reformed water is not caused to flow out from both electrolysis chambers 10 and 20 each time the toilet bowl 6 is used, but the reformed water is caused to flow out from either one of the electrolysis chambers 10 and 20 when the toilet bowl 6 is used once. Next time, each electrolysis room 10, 2
It may be discharged from the other side of 0 and this may be repeated alternately.

In addition, in the urinary stone adhesion preventing apparatus 1 according to the first embodiment of the present invention, the power source of the control unit 4 is set to 100.
Although the AC power source 8 is V, another power source, for example, 2
An AC power supply of 00V or a DC power supply such as a storage battery may be used.

Further, the first and second electromagnetic valves 14, 24 in the urinary stone adhesion preventing apparatus 1 according to the first embodiment of the present invention.
At least one of the above may be eliminated, and a mechanical float valve (when the float moves following the fluctuation of the water level, the passage is opened and closed in conjunction with it) may be provided instead. In this case, the water level sensor in the electrolysis chamber provided with the mechanical float valve can be eliminated.

(Second Embodiment) Next, a urinary stone adhesion preventing apparatus 1 according to a second embodiment of the present invention will be described.

FIG. 4 is an explanatory view showing the structure of the urinary stone adhesion preventing apparatus 1 according to the second embodiment of the present invention.

In the urine stone adhesion preventing apparatus 1 according to the second embodiment of the present invention, the first and second electrolytic chambers 10 and 20 of the urine stone adhesion preventing apparatus 1 according to the first embodiment are shown in FIG. As shown, it is divided into two independent electrolytic cells, that is, a first electrolytic cell 10A and a second electrolytic cell 20A.

In the first and second electrolytic cells 10A and 20A, a pair of third electrodes 11A and 11B made of Pt-Ti alloy which is a noble metal alloy, and Pt which is a noble metal alloy.
A pair of fourth electrodes 21A and 2 made of -Ti alloy
1B are arranged respectively. And the third electrode 1
A first intermediate electrode 12 made of ferrite is arranged between 1A and 11B, and also a fourth electrode 21A, 21B.
In between, a second intermediate electrode 22 made of magnesium
Are arranged.

The structure other than the first and second electrolytic cells 10A and 20A, the third electrodes 11A and 11B, and the fourth electrodes 21A and 21B is the same as that of the urinary stone adhesion preventing apparatus 1 according to the first embodiment. Therefore, the same effect as that of the urinary stone adhesion preventing device 1 according to the first embodiment can be obtained.

Further, in the urinary stone adhesion preventing apparatus 1 according to the second embodiment, the first electrolytic cell 10A for generating various oxygen active species and the second electrolytic cell for generating Mg (OH) ₂ are used. Since the tank 20A is formed separately, the first and second electrolytic tanks 10A and 20A in the urine stone adhesion preventing device 1 are formed.
The degree of freedom in designing the arrangement of A can be improved.

In the urinary stone adhesion preventing apparatus 1 according to the second embodiment of the present invention described above, at least one of the pair of third electrodes 11A and 11B is made of ferrite and the pair of fourth electrodes 21A is formed. , 21B may be formed of magnesium. As a result, the total area of the ferrite electrode and the magnesium electrode can be increased, so that the electrolytic cells 10A, 20A having a small capacity can be obtained.
Thus, reformed water can be generated in a short time. In this case, at least one of the intermediate electrodes 12 and 22 may be omitted. As a result, at least one of the electrolytic cells 10A and 20A can be downsized.

Further, in the urinary stone adhesion preventing apparatus 1 according to the second embodiment of the present invention described above, at least one of the pair of third electrodes 11A and 11B is formed of ferrite or the pair of fourth electrodes. At least one of 21A and 21B may be formed of magnesium. As a result, the total area of the ferrite electrode or the magnesium electrode can be increased, so that the first electrolytic cell 10A having a small capacity can be obtained.
Alternatively, the reforming water can be generated in a short time by the second electrolytic cell 20A.

Further, at least one of the pair of third electrodes 11A and 11B is made of ferrite and the first intermediate electrode 12 is omitted, or the pair of fourth electrodes 21A and 2B is formed.
At least one of 1B may be formed of magnesium and the second intermediate electrode 22 may be omitted. As a result, the first electrolytic cell 10A or the second electrolytic cell 20A can be downsized.

Further, the pair of third electrodes 11A and 11B and the pair of fourth electrodes 21A and 21B may be formed of a noble metal such as Pt instead of the noble metal alloy Pt—Ti alloy. Also by this, each electrode 11A, 11B, 21
It is not necessary to replace A and 21B.

Further, in the urinary stone adhesion preventing apparatus 1 according to the second embodiment of the present invention described above, Mg (O
The second electrolytic cell 20A for producing H) ₂ may be omitted. In this case, the toilet bowl can be kept clean by the sterilizing effect of the modified water containing various oxygen active species generated in the first electrolytic cell 10A, and the urine stone adhesion preventing apparatus 1 can be downsized. .

[Brief description of drawings]

FIG. 1 is an explanatory diagram showing a configuration of a urinary stone adhesion preventing device 1 according to a first embodiment of the present invention.

FIG. 2 is an explanatory diagram showing an electric circuit configuration of a control device 4 of the urinary stone adhesion preventing device 1 according to the first embodiment of the present invention.

3A to 3D are first to fourth solenoid valves 14 and 2;
It is a time chart of the energization state of 4, 16, and 26.
(E) is a time chart of a voltage application state to the first and second electrodes 11 and 21. (F) to (h) are time charts of the output signal levels of the first and second water level sensors 17, 27 and the toilet use sensor 5.

FIG. 4 is an explanatory diagram showing a configuration of a urinary stone adhesion preventing device 1 according to a second embodiment of the present invention.

[Explanation of symbols]

1 Urine stone adhesion prevention device 2 electrolysis tank 3 Electrolyte membrane 4 Control device (control means) 41 Converter 42 power supply 43 Control unit 5 Toilet sensor 6 toilet bowl 7 Main switch 8 AC power supply 10 First electrolysis chamber 10A first electrolyzer 11 First electrode 11A Third electrode 12 First intermediate electrode 13 First water conduit 14 First solenoid valve (first valve means) 15 First discharge pipe 16 Third solenoid valve (third valve means) 17 First water level sensor 20 Second electrolysis chamber 20A second electrolyzer 21 Second electrode 21A Fourth electrode 22 Second intermediate electrode 23 Second water conduit 24 Second solenoid valve (second valve means) 25 Second water discharge pipe 26 Fourth solenoid valve (fourth valve means) 27 Second water level sensor

   ─────────────────────────────────────────────────── ─── Continued front page    F-term (reference) 2D038 AA02                 4D061 DA02 DB01 DB09 EA02 EB02                       EB04 EB12 EB20 EB28 EB30                       EB31 EB39 GC14

Claims (7)

[Claims] 1. A toilet bowl, and an electrolytic cell divided into a first electrolysis chamber and a second electrolysis chamber with an electrolytic membrane through which ions can pass.
A first electrode formed of a noble metal or a noble metal alloy disposed in the first electrolysis chamber, a second electrode formed of a noble metal or a noble metal alloy disposed in the second electrolysis chamber, and the first and second electrodes A first intermediate electrode made of ferrite arranged between the electrodes and in the first electrolysis chamber, and a second intermediate electrode made of magnesium arranged between the first and second electrodes and in the second electrolysis chamber. An intermediate electrode, a control means for applying a voltage to the first and second electrodes, a first water conduit for introducing water into the first electrolysis chamber, and a second for introducing water into the second electrolysis chamber
The control means includes a water conduit, a first water discharge pipe for flowing water in the first electrolysis chamber to the toilet bowl side, and a second water discharge pipe for flowing water in the second electrolysis chamber to the toilet bowl side. , A voltage is applied to the first and second electrodes to electrolyze the water in the first and second electrolysis chambers, respectively, and the reformed water is supplied to the first and second electrolysis chambers in response to a cleaning request. 2. A urinary stone adherence prevention device, characterized in that it is discharged to the toilet side through a water discharge pipe. 2. The control means applies a high potential voltage to the first electrode and a low potential voltage to the first electrode, and a low potential voltage to the first electrode. The urine stone adherence prevention device according to claim 1, wherein the second energization mode in which a high potential voltage is applied to the first electrode is alternately switched. 3. A toilet bowl, a first electrolytic cell provided with a pair of third electrodes made of a noble metal or a noble metal alloy, and a first intermediate electrode made of ferrite arranged between the third electrodes, and a noble metal or A second electrolysis tank including a pair of fourth electrodes formed of a noble metal alloy and a second intermediate electrode formed of magnesium arranged between the fourth electrodes, and applying a voltage to the pair of third electrodes. Control means for applying a voltage to the pair of fourth electrodes, a first water conduit for introducing water into the first electrolyzer, a second water conduit for introducing water into the second electrolyzer, and the first The control means includes a first water discharge pipe for flowing water from the inside of the electrolysis tank to the toilet bowl side, and a second water discharge pipe for flowing water from the inside of the second electrolysis tank to the toilet bowl side. A voltage is applied to the three electrodes and to the pair of fourth electrodes A voltage is applied to reform the water in the first and second electrolyzers by electrolysis, respectively, and the reformed water is reformed in response to a cleaning request through the first and second discharge pipes. A urinary stone adhesion prevention device characterized by being discharged to the side. 4. The first controlling means applies a high potential voltage to one of the pair of third electrodes provided in the first electrolytic cell and a low potential voltage to the other of the third electrodes.
The energization mode and the second energization mode in which a low potential voltage is applied to one of the two and a high potential voltage is applied to the other are alternately switched, and the pair of fourth electrodes provided in the second electrolytic cell are provided. , A first conduction mode in which a high potential voltage is applied to one of them and a low potential voltage is applied to the other,
The urinary stone adherence prevention device according to claim 3, wherein the second energization mode in which a low potential voltage is applied to one side and a high potential voltage is applied to the other side is alternately switched. 5. The urinary stone adhesion preventing device according to claim 2, wherein the durations of the first energization mode and the second energization mode are made equal to each other. 6. A first valve means provided in the middle of the first water conduit to open and close the first water conduit, and a second valve provided in the middle of the second water conduit to open and close the second water conduit. Means, third valve means provided in the middle of the first water discharge pipe to open and close the first water discharge pipe, and fourth valve means provided in the middle of the second water discharge pipe to open and close the second water discharge pipe. The urinary stone adhesion preventing device according to any one of claims 1 to 5, characterized in that the first to fourth valve means are controlled to be opened and closed by the control means. 7. The first to fourth valve means are solenoid valves,
7. The urinary stone adhesion preventing device according to claim 6, wherein the solenoid valve is driven by the control means.