JP2013202539A - Acid water generator and toilet device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an acid water generator and a toilet device capable of more surely obtaining acid water having desired pH, or prolonging a service life.SOLUTION: An acid water generator is the acid water generator for generating acid water, and includes: an electrolysis system for generating the acid water by electrolysis; and a cation exchange resin system arranged in series with the electrolysis system more on the downstream side than the electrolysis system, for generating the acid water by a cation exchange resin.

Description

  Aspects of the present invention generally relate to an acidic water generator and a toilet device.

For example, there are cases in which sterilization is necessary in devices and equipment around water. Alternatively, it may be necessary to remove scale.
For example, when the bowl surface of a urinal or urinal is washed with washing water and the residual water remaining on the bowl surface evaporates and the bowl surface dries, scales may adhere to the bowl surface. If scale adheres to the bowl surface, the bowl surface becomes dirty. Moreover, since the scale adheres firmly to the bowl surface, it is difficult to remove the scale. Therefore, there is a need for a technique for suppressing the generation of scale or a technique that can easily remove the scale even when the scale adheres to the bowl surface. Furthermore, the scale of the silicic acid component adheres more firmly to the glaze surface of the toilet bowl than the scale of calcium or magnesium. Therefore, a technique that can easily remove the scale of the silicate component is desired.

  On the other hand, as a result of examination by the present inventors, a metal ion that suppresses the polymerization of soluble silicic acid in the residual water remaining on the surface of the toilet bowl after toilet bowl washing is included in acidic water having a bactericidal action, It has been found that the generation of scales that adhere firmly to the toilet surface can be suppressed by adding to the toilet bowl. In order to generate acidic water containing metal ions, it is first necessary to generate acidic water. As an apparatus which produces | generates acidic water, there exists an apparatus which produces | generates acidic water in a polar chamber by electrolysis of the water in an electrolytic cell, for example (patent document 1).

  However, when acidic water is generated in an electrolytic cell as described in Patent Document 1, there is a problem that the pH (potential Hydrogen) of acidic water is largely attributed to water components such as tap water. Specifically, when tap water having a relatively low cation (mineral component) concentration is electrolyzed in an electrolytic cell, a desired and sufficient pH may not be obtained.

  On the other hand, a cation exchange resin is mentioned as one of the methods which produces | generates the acidic water which has a desired pH, without being largely attributed to the component of tap water. However, with regard to the cation exchange resin, there is a concern that the size of the device may be increased in consideration of extending the life of the device. On the other hand, if the size of the device is reduced, the life of the device is shortened, and therefore the replacement frequency of the cation exchange resin is increased. For this reason, there is a problem that the usability is deteriorated for the user.

Japanese Patent Laid-Open No. 9-78658

  The present invention has been made on the basis of recognition of such problems, and it is possible to provide an acidic water generating device and a toilet device that can more reliably obtain acidic water having a desired pH, or can achieve a longer life. The purpose is to provide.

  1st invention is the acidic water production | generation apparatus which produces | generates acidic water, Comprising: The electrolysis system which produces | generates acidic water by electrolysis, and arrange | positions in series with the said electrolysis system downstream from the said electrolysis system And a cation exchange resin system that generates acidic water using a cation exchange resin.

  According to this acidic water generator, the cation exchange resin system is arranged in series with the electrolysis system on the downstream side of the electrolysis system. The dependence of the cation exchange resin system on the water quality is lower than the dependence of the electrolysis system on the water quality. Therefore, even when the supplied water has a water quality such that the electrolysis in the electrolysis system cannot produce the desired low pH acidic water, the cation exchange resin system allows the desired low pH acidic water to be produced. That is, it is possible to generate acidic water having a higher bactericidal action.

  That is, the electrolysis system provided on the upstream side of the cation exchange resin system discharges cations, collects anions, and supplies them to the cation exchange resin system. Therefore, the anion concentration is relatively increased in the water supplied to the cation exchange resin system. Then, the concentration of anions as counter ions with respect to the cations increases, so that the amount of cations that can be exchanged in the ion exchange resin increases. Thereby, it is possible to generate acidic water having a low pH that cannot be obtained by only one of the electrolysis system and the cation exchange resin system.

  Moreover, since acidic water is produced | generated using an electrolysis system and a cation exchange resin system, the load concerning a cation exchange resin system can be reduced. Thereby, the enlargement of a cation exchange resin system can be suppressed, extending the lifetime of a cation exchange resin system. In addition, the frequency of maintenance such as replacing only the ion exchange resin can be reduced.

  Furthermore, when the acidic water generated by the electrolysis system is bypassed to the downstream side of the cation exchange resin system, it is possible to generate acidic water at a desired pH while further extending the lifetime of the cation exchange resin system. Can be achieved.

  Moreover, 2nd invention is an acidic water production | generation apparatus which produces | generates acidic water, Comprising: It arrange | positions in parallel with the electrolysis system which produces | generates acidic water by electrolysis, and the said electrolysis system, By cation exchange resin A cation exchange resin system that generates acidic water, and the acidic water generated by the electrolysis system and the acidic water generated by the cation exchange resin system are the electrolysis system and the cation exchange resin system. It is an acidic water production | generation apparatus characterized by merging in the downstream of an ion exchange resin system.

  According to this acidic water generator, the cation exchange resin system is arranged in parallel with the electrolysis system. Therefore, compared with the case where acidic water is generated using only the cation exchange resin system, the life of the cation exchange resin system can be extended, and the frequency of maintenance can be reduced. In addition, even when the supplied water has a water quality such that the electrolysis in the electrolysis system cannot produce the desired low pH acidic water, the acidic water is produced only by using the electrolysis system. In comparison, the desired low pH acidic water can be produced.

  In addition, by changing the water flow rate of the water flow leading to the electrolysis system and the water flow leading to the cation exchange resin system, acidic water having a desired pH can be generated while changing the water flow rate. The service life of the replacement resin system can be further extended. And the optimal acidic water production | generation apparatus according to the water quality condition of the installation place can be provided.

  Moreover, 3rd invention is the acidic water production | generation apparatus of any one of 1st and 2nd invention, and the spraying means which sprays the acidic water produced | generated by the said acidic water production | generation apparatus at least on the surface of the bowl of a toilet bowl. The alkaline water generated by the electrolysis system is directly discharged to the drain pipe of the toilet.

  According to this toilet apparatus, alkaline water does not contact the surface of the bowl of the toilet bowl. Therefore, it can suppress that alkaline water reduces the bactericidal action of acidic water.

  Moreover, 4th invention is the acidic water production | generation apparatus of any one of 1st and 2nd invention, and the spray means which sprays the acidic water produced | generated by the said acidic water production | generation apparatus at least on the surface of the bowl of a toilet bowl. The spray means sprays the acidic water after washing the toilet bowl, and the alkaline water generated by the electrolysis system is applied to the surface of the bowl at the time of washing the toilet bowl or before washing the toilet bowl. A toilet device that is discharged.

  According to this toilet device, since alkaline water is discharged to the surface of the bowl of the toilet bowl, the alkaline water can be discharged with a simpler structure rather than a complicated structure such as discharging to the drain pipe of the toilet bowl. . Further, the alkaline water discharged to the surface of the bowl is discharged to the toilet drain pipe by washing the toilet with neutral tap water. Therefore, when acidic water is sprayed on the surface of the bowl of a toilet bowl, it can suppress that the bactericidal action of acidic water reduces.

  Further, a fifth invention further comprises a metal ion water addition system in which the metal is gradually dissolved using the acid water generated by the acid water generator in the third or fourth invention, and the spraying means includes: The toilet device is characterized by spraying acidic water containing the metal ions.

  According to this toilet device, acidic water having a relatively low pH can be generated by the acidic water generator. Therefore, the metal can be gradually dissolved. Thereby, even when it has the water quality which cannot produce | generate the acidic water of desired low pH by the electrolysis in an electrolysis system, acidic water with a comparatively high metal ion density | concentration can be produced | generated. Therefore, with a simple system, polymerization of silicic acid can be suppressed and generation of scale can be suppressed. Further, the generated scale can be easily removed.

  ADVANTAGE OF THE INVENTION According to the aspect of this invention, the acidic water production | generation apparatus and toilet apparatus which can obtain the acidic water which has desired pH more reliably, or can achieve lifetime improvement are provided.

It is a block diagram showing the principal part structure of the acidic water production | generation apparatus concerning embodiment of this invention. It is typical sectional drawing which illustrates the electrolytic cell and flow-path switching valve of this embodiment. It is a typical sectional view which illustrates the cation exchange resin system concerning this embodiment. It is a block diagram showing the principal part structure of the modification of an acidic water generating apparatus in this embodiment. It is a block diagram showing the principal part structure of the other modification of an acidic water generating apparatus in this embodiment. It is a graph which illustrates an example of transition of the cation concentration of the water which passed the electrolytic cell and cation exchange resin system of this embodiment. It is a graph which illustrates an example of transition of pH of water which passed the electrolytic cell and cation exchange resin system of this embodiment. It is a graph explaining an example of the synergistic effect of an electrolytic cell and a cation exchange resin system. It is a schematic diagram showing the toilet apparatus concerning embodiment of this invention. It is a block diagram showing the principal part structure of the toilet apparatus concerning this embodiment. It is a block diagram showing the principal part structure of the modification of the toilet apparatus concerning this embodiment. It is a block diagram showing the principal part structure of the other modification of the toilet apparatus concerning this embodiment. It is a cross-sectional schematic diagram which illustrates the metal ion water addition system of this embodiment. It is a timing chart which illustrates the example of operation of the toilet device concerning this embodiment.

Embodiments of the present invention will be described below with reference to the drawings. In addition, in each drawing, the same code | symbol is attached | subjected to the same component and detailed description is abbreviate | omitted suitably.
FIG. 1 is a block diagram showing a main configuration of an acidic water generator according to an embodiment of the present invention.

  The acidic water generator 405 according to the present embodiment includes a flow path 21, an electrolytic cell (electrolysis system) 420, a flow path switching valve 431, and a cation exchange resin system 460. The flow path 21 can guide the water supplied from the water supply source 30. The electrolytic cell 420 is provided on the upstream side of the flow path 21 and can generate acidic water and alkaline water by electrolysis of water. The cation exchange resin system 460 is arranged in series with the electrolytic cell 420 on the downstream side of the electrolytic cell 420. The cation exchange resin system 460 exchanges cations with hydrogen ions by passing water, and releases hydrogen ions to generate acidic water.

  The flow path switching valve 431 is provided on the downstream side of the electrolytic cell 420 and on the upstream side of the cation exchange resin system 460. The flow path switching valve 431 performs opening / closing and switching of water supply to the cation exchange resin system 460 and the drainage side. The flow path 21 includes a first flow path 21a that guides water, solution, and the like to the cation exchange resin system 460 by a flow path switching valve 431, and a second flow path 21b that guides water, solution, and the like to the drain side. Fork.

FIG. 2 is a schematic cross-sectional view illustrating the electrolytic cell and the flow path switching valve of this embodiment.
As shown in FIG. 2, the electrolytic cell 420 of the present embodiment includes an anode plate 424 and a cathode plate 425 therein, and the anode plate 424 and the cathode plate are controlled by controlling energization from a control unit (not shown), for example. The tap water flowing through the space (flow path) between 425 and 425 can be electrolyzed. At this time, acid (H ⁺ ) is consumed in the cathode plate 425, and the pH increases in the vicinity of the cathode plate 425. That is, alkaline water is generated in the vicinity of the cathode plate 425. On the other hand, alkali (OH ⁻ ) is consumed in the anode plate 424, and the pH decreases in the vicinity of the anode plate 424. That is, acidic water is generated near the anode plate 424.

  For example, by control from a control unit (not shown), the flow path switching valve 431 mainly opens and closes the flow path that guides acidic water to the cation exchange resin system 460, or mainly opens the flow path that guides alkaline water to the drain side. Open and close. That is, the flow path switching valve 431 guides not only the acidic water but also the alkaline water in an amount smaller than the amount of acidic water led to the cation exchange resin system 460 to the cation exchange resin system 460. On the other hand, the flow path switching valve 431 guides not only alkaline water but also acidic water having a smaller amount than alkaline water led to the drain side to the drain side.

FIG. 3 is a schematic cross-sectional view illustrating a cation exchange resin system according to this embodiment.
As illustrated in FIG. 3, the cation exchange resin system 460 of the present embodiment includes a housing 461 and a cation exchange resin 463 provided inside the housing 461. The cation exchange resin 463 exchanges the cation contained in the water or the solution supplied from the electrolytic cell 420 via the flow path switching valve 431 with the hydrogen ion that it has, and releases the hydrogen ion. In this way, the cation exchange resin system 460 exchanges the cation introduced from the electrolytic cell 420 with the hydrogen ion, generates acidic water, and discharges it downstream.

  Returning to FIG. 1, in the acidic water generator 405 according to this embodiment, water supplied from the water supply source 30 to the electrolytic cell 420 is guided to the electrolytic cell 420. In the electrolytic cell 420, acidic water and alkaline water are generated by electrolysis of water. Acidic water and alkaline water generated in the electrolytic cell 420 are respectively guided to flow channel switching valves 431 provided on the downstream side of the electrolytic cell 420 through different flow paths. The flow path switching valve 431 guides the acidic water supplied from the electrolytic cell 420 to the cation exchange resin system 460 provided on the downstream side of the flow path switching valve 431. On the other hand, the flow path switching valve 431 causes the alkaline water supplied from the electrolytic bath 420 to flow into the sewage as drainage.

  In order to suppress the generation of scale such as calcium carbonate in the electrolytic cell 420, polarity reversal (pole change (PC)) for switching the anode plate 424 and the cathode plate 425 may be performed. Then, when the flow path switching valve 431 is not provided, the flow paths for guiding acidic water and alkaline water are interchanged with each other, and the alkaline water is guided to the cation exchange resin system 460. Therefore, the flow path switching valve 431 has a function of switching the flow path to guide the acidic water to the cation exchange resin system 460 when polarity inversion is performed in the electrolytic cell 420.

  Here, the pH of the acidic water produced by the electrolytic cell 420 is largely attributed to water components such as tap water. Specifically, the tap water resistance value having a relatively low cation (mineral component) concentration is higher than the tap water resistance value having a relatively high cation concentration. Therefore, the current value flowing in tap water having a relatively low cation concentration is lower than the current value flowing in tap water having a relatively high cation concentration. According to this, when tap water having a relatively low cation concentration is electrolyzed by the electrolytic cell 420, a desired and sufficient pH may not be obtained.

  On the other hand, according to this embodiment, the cation exchange resin system 460 is provided on the downstream side of the electrolytic cell 420. The dependence of the cation exchange resin system 460 on the water quality is lower than the dependence of the electrolytic cell 420 on the water quality. Therefore, even when the water supplied from the water supply source 30 has a water quality such that the electrolysis in the electrolytic cell 420 cannot produce acidic water having a desired low pH, the cation exchange resin system 460 allows the desired water to be generated. Low pH acidic water, that is, acidic water having higher bactericidal action can be produced.

  More specifically, the electrolytic cell 420 provided on the upstream side of the cation exchange resin system 460 discharges cations contained in the alkaline water and collects the anions contained in the acidic water to collect the cation exchange resin. Supply to system 460. Therefore, in the water supplied to the cation exchange resin system 460, the anion concentration is relatively increased. Then, the concentration of anions as counter ions with respect to the cations increases, so that the amount of cations that can be exchanged in the ion exchange resin increases. Thereby, it is possible to generate acidic water having a low pH that cannot be obtained by only one of the electrolytic cell 420 and the cation exchange resin system 460.

  Moreover, since acidic water is produced | generated using the electrolytic cell 420 and the cation exchange resin system 460, the load concerning the cation exchange resin system 460 can be reduced. That is, since the water whose pH is lowered to some extent in the electrolytic bath 420 is passed through the cation exchange resin system 460, the load on the cation exchange resin system 460 can be reduced. In other words, since the cation contained in the alkaline water is discharged by the electrolytic cell 420, the amount of hydrogen ions exchanged with the cation in the cation exchange resin system 460 can be suppressed. Thereby, the enlargement of the cation exchange resin system 460 can be suppressed while extending the life of the cation exchange resin system 460. In addition, the frequency of maintenance such as replacing only the ion exchange resin can be reduced.

Next, a modification of the acidic water generator according to this embodiment will be described with reference to the drawings.
FIG. 4 is a block diagram illustrating a main configuration of a modified example of the acidic water generator according to the present embodiment.

In the acidic water generating apparatus 406 of this modification, the flow path 21 includes a first flow path 21a that guides water, a solution, and the like to the cation exchange resin system 460 by the flow path switching valve 432, and water and a solution to the drain side. The second flow path 21b that guides water and the like and the bypass flow path 21c that guides water and solutions to the downstream side of the cation exchange resin system 460 without guiding water and solutions to the cation exchange resin system 460 are branched. Is done. That is, the flow path switching valve 432 according to the present modification opens / closes and switches water supply to the cation exchange resin system 460, the drainage side, or the downstream side of the cation exchange resin system 460.
About other principal part structure, it is the same as that of the principal part structure of the acidic water production | generation apparatus 405 mentioned regarding FIGS. 1-3.

According to this modification, the flow path switching valve 432 has, for example, a flow rate of water guided to the first flow path 21a and a flow volume of water guided to the bypass flow path 21c based on a current value flowing through the electrolytic cell 420, The ratio of water (water flow rate) can be changed. For example, when the value of the current flowing through the electrolytic cell 420 is relatively high, the flow path switching valve 432 has a relatively small flow rate of water guided to the first flow path 21a (cation exchange resin system 460). Set to. On the other hand, when the value of the current flowing through the electrolytic cell 420 is relatively low, the flow path switching valve 432 has a relatively large flow rate of water led to the first flow path 21a (cation exchange resin system 460). Set to. The operation of the flow path switching valve 432 is controlled by, for example, a control unit (not shown).
According to this, while being able to produce | generate acidic water of desired pH, the lifetime improvement of the cation exchange resin system 460 can be achieved further.

FIG. 5 is a block diagram illustrating a main configuration of another modification of the acidic water generator in the present embodiment.
In the acidic water generators 405 and 406 described above with reference to FIGS. 1 to 4, the electrolytic cell 420 and the cation exchange resin system 460 are arranged in series with each other, whereas in the acidic water generator 407 of the present modification, As shown in FIG. 5, the electrolytic cell 420 and the cation exchange resin system 460 are arranged in parallel with each other.

A first flow path switching valve 433 is provided downstream of the water supply source 30 and upstream of the electrolytic cell 420 and the cation exchange resin system 460. A second flow path switching valve 434 is provided on the downstream side of the electrolytic cell 420.
The first flow path switching valve 433 opens / closes and switches the water supply to the electrolytic cell 420 and the cation exchange resin system 460.
The second flow path switching valve 434 corresponds to the flow path switching valve 431 described above with reference to FIGS. 1 to 3, and guides the acidic water supplied from the electrolytic cell 420 to the downstream side. On the other hand, the second flow path switching valve 434 causes the alkaline water supplied from the electrolytic cell 420 to flow into the sewage as waste water.

The water guided to the cation exchange resin system 460 by the first flow path switching valve 433 passes through the cation exchange resin system 460 to become acidic water, and then flows downstream from the second flow path switching valve 434. Merges with the guided acidic water.
About other principal part structure and the flow of water, it is the same as that of the principal part structure and flow of water of the acidic water production | generation apparatus 405 mentioned above regarding FIGS.

  According to the present modification, the first flow path switching valve 433 is configured such that the flow rate of water led to the electrolytic cell 420 and the flow rate of water led to the cation exchange resin system 460 based on the current value flowing through the electrolytic cell 420, for example. The ratio can be changed. For example, when the value of the current flowing through the electrolytic cell 420 is relatively high, the first flow path switching valve 433 sets the flow rate of water led to the cation exchange resin system 460 to a relatively small flow rate. On the other hand, when the value of the current flowing through the electrolytic cell 420 is relatively low, the first flow path switching valve 433 sets the flow rate of water led to the cation exchange resin system 460 to a relatively high flow rate. The operation of the first flow path switching valve 433 is controlled by, for example, a control unit (not shown).

  According to this, compared with the case where acidic water is generated using only the cation exchange resin system 460, the life of the cation exchange resin system 460 can be extended, and the frequency of maintenance can be reduced. it can. Further, even when the water supplied from the water supply source 30 has a water quality such that the electrolysis in the electrolytic cell 420 cannot produce acidic water having a desired low pH, the acidic water is obtained using only the electrolytic cell 420. Compared with the case where it produces | generates, the desired low pH acidic water can be produced | generated.

  Further, by changing the setting of the ratio of the flow rate of water led to the electrolytic cell 420 and the flow rate of water led to the cation exchange resin system 460, acidic water having a desired pH can be generated, and cation can be generated. The service life of the replacement resin system 460 can be further extended. And the optimal acidic water production | generation apparatus 407 according to the water quality condition of the installation place can be provided.

Next, an example of the result of the study conducted by the inventor will be described with reference to the drawings.
FIG. 6 is a graph illustrating an example of the transition of the cation concentration of water that has passed through the electrolytic cell and the cation exchange resin system of this embodiment.
This inventor examined the transition of the cation density | concentration of the water which passed the electrolytic cell 420 and the cation exchange resin system 460 using the acidic water production | generation apparatus 405 mentioned above regarding FIGS. An example of the examination result is as shown in FIG.

That is, first, the cation of water supplied from the water supply source 30 includes calcium ions (Ca ²⁺ ), magnesium ions (Mg ²⁺ ), sodium ions (Na ⁺ ), and potassium ions (K ⁺ ). Their cation concentration is 20 ppm (parts per million).
Subsequently, the water supplied to the electrolytic cell 420 is electrolyzed. Alkaline water generated by electrolysis in the electrolytic cell 420 flows into sewage as waste water, so that cations contained in the alkaline water are discharged from the acidic water generator 405. Therefore, the cation concentration of the water electrolyzed by the electrolytic cell 420 is reduced from 20 ppm to 9.5 ppm. That is, the reduction amount of the cation concentration at this time is substantially the same as the discharge amount of the cation from the acidic water generator 405.

  Subsequently, cations contained in the water supplied to the cation exchange resin system 460 are exchanged with hydrogen ions. Therefore, the cation concentration of the water that has passed through the cation exchange resin system 460 is reduced from 9.5 ppm to 0.3 ppm. That is, the reduction amount of the cation concentration at this time is substantially the same as the exchange amount of the cation and the hydrogen ion in the cation exchange resin system 460.

  According to an example of the result of this study, before passing through the cation exchange resin system 460, the electrolytic cell 420 discharges the cation contained in the alkaline water, so that the cation concentration is reduced by about half. That is, the amount of cation exchange in the cation exchange resin system 460 is approximately halved. Therefore, the lifetime of the cation exchange resin system 460 can be approximately doubled.

FIG. 7 is a graph illustrating an example of the pH transition of water that has passed through the electrolytic cell and the cation exchange resin system of this embodiment.
This inventor examined the transition of the pH of the water which passed the electrolytic cell 420 and the cation exchange resin system 460 using the acidic water production | generation apparatus 405 mentioned above regarding FIGS. An example of the examination result is as shown in FIG.

That is, first, the pH of the water supplied from the water supply source 30 is pH 7.9 in the region A, pH 7.0 in the region B, and pH 6.9 in the region C. Region A, region B, and region C represent arbitrary regions in Japan.
Subsequently, the water supplied to the electrolytic cell 420 is electrolyzed. The pH of the acidic water generated by electrolysis in the electrolytic cell 420 is from pH 7.9 to pH 6.0 in region A, from pH 7.0 to pH 5.5 in region B, and from pH 6.9 to pH 3.4 in region C. To reduce. Here, as shown in FIG. 7, one of the target values of pH in the present study by the present inventor is “pH 4 or less”. Then, the pH in the region A and the region B has not yet achieved the target value “pH 4 or less”.

  Subsequently, cations contained in the water supplied to the cation exchange resin system 460 are exchanged with hydrogen ions. The pH of the acidic water that has passed through the cation exchange resin system 460 is from pH 6.0 to pH 3.0 in region A, from pH 5.5 to pH 3.4 in region B, and from pH 3.4 to pH 3.0 in region C. To reduce.

  According to an example of the result of this study, after electrolysis of water in the electrolytic cell 420, water supplied from the water supply source 30 is passed through the cation exchange resin system 460, so that Even if the water quality is such that the decomposition cannot produce acidic water having a desired low pH (pH 4 or lower in this study), the cation exchange resin system 460 may produce acidic water having a desired low pH. it can.

FIG. 8 is a graph illustrating an example of a synergistic effect between the electrolytic cell and the cation exchange resin system.
This inventor examined the synergistic effect of the electrolytic cell 420 and the cation exchange resin system 460 using the acidic water production | generation apparatus 405 mentioned above regarding FIGS. An example of the examination result is as shown in FIG.

That is, first, the cation concentration and the anion concentration of water supplied from the water supply source 30 are each about 20 ppm. The pH of the water supplied from the water supply source 30 is pH 6.9.
Next, the cation concentration of the water passed through only the cation exchange resin system 460 is reduced to about 0 ppm. On the other hand, since anions are not exchanged in the cation exchange resin system 460, the anion concentration is maintained at about 20 ppm. Moreover, the pH of the water which passed only the cation exchange resin system 460 is pH 3.4.

  Next, the cation concentration of the water electrolyzed by the electrolytic cell 420 is reduced from about 20 ppm to about 10 ppm because alkaline water is drained. On the other hand, the anion concentration of the water electrolytically decomposed by the electrolytic cell 420 is relatively increased and increased from about 20 ppm to about 40 ppm because cations are discharged and the anions are collected. The pH of the water electrolyzed by the electrolytic cell 420 is pH 3.4.

  Next, after electrolyzing water in the electrolytic cell 420, the cation concentration of water passed through the cation exchange resin system 460 is reduced to about 0 ppm as described above with reference to FIG. On the other hand, the anion concentration is relatively increased because cations are discharged. Then, the concentration of anions as counter ions with respect to the cations increases, so that the amount of cations that can be exchanged in the ion exchange resin increases. In other words, as the anion concentration increases, the proportion (capacity) in which cations can exist increases. Then, the release of hydrogen ions is promoted. Thereby, it is possible to generate acidic water having a low pH that cannot be obtained by only one of the electrolytic cell 420 and the cation exchange resin system 460. According to an example of the results of this study, the pH of the water passed through the cation exchange resin system 460 after electrolysis of water in the electrolytic cell 420 is pH 3.0.

Next, another embodiment of the present invention will be described.
FIG. 9 is a schematic diagram illustrating a toilet apparatus according to an embodiment of the present invention.
In addition, in FIG. 9, the schematic diagram showing a sanitary washing apparatus is a typical top view for convenience of explanation, and the schematic diagram showing a western-style seat toilet is a schematic sectional view.

  The toilet device 10 shown in FIG. 9 includes a sanitary washing device 100 provided on a Western-style seated toilet (hereinafter simply referred to as “toilet”) 800. The toilet bowl 800 has a bowl 801. The sanitary washing device 100 includes a casing 400, a toilet seat 200, and a toilet lid 300. The toilet seat 200 and the toilet lid 300 are pivotally supported with respect to the casing 400 so as to be freely opened and closed. Note that the toilet lid 300 is not necessarily provided.

  For example, a spray nozzle (spraying means) 481 for spraying water or sterilizing water on the surface of the bowl 801 of the toilet bowl 800 is provided at the lower part of the casing 400. The spray nozzle 481 may be provided inside the casing 400 or may be attached outside the casing 400. Inside the casing 400, the acidic water generator 405 described above with reference to FIGS. Note that the acidic water generator provided in the casing 400 may be either the acidic water generator 406 described above with reference to FIG. 4 or the acidic water generator 407 described above with reference to FIG. 5.

  In the present specification, “water” includes not only cold water but also heated hot water. In the present specification, “sterilizing water” refers to a liquid containing more sterilizing components such as hypochlorous acid than tap water (also simply referred to as “water”).

  Here, when the residual water remaining in the bowl 801 evaporates after the toilet cleaning operation is completed and the surface of the bowl 801 is dried, scale may adhere to the bowl 801. Usually, when the concentration of silicic acid increases in the process of evaporating water in the residual water, the polymerization of silicic acid is promoted. This causes a coffee stain phenomenon (a phenomenon in which the solute flows to the outer periphery of the droplet due to the evaporation of the solvent in the droplet and accumulates in a ring shape), thereby forming a strong scale. When the water scale adheres to the bowl 801, the bowl 801 becomes dirty. Further, since the scale adheres firmly to the bowl 801, it is difficult to remove the scale.

  In contrast, the toilet apparatus 10 according to the present embodiment adds an aqueous solution having a high pH or an aqueous solution having a high pH containing metal ions to the residual water remaining in the bowl 801. In other words, the toilet apparatus 10 according to the present embodiment replaces the remaining water remaining in the bowl 801 with an aqueous solution having a high pH containing metal ions. According to this, the polymerization of silicic acid can be suppressed and the generation of scale can be suppressed. Further, the generated scale can be easily removed.

The reason why these effects can be obtained is as follows. However, this is an assumption or a hypothesis based on the knowledge obtained by the present inventor, and is not limited to this in the present embodiment.
When the pH of the residual water is increased, the progress of the polymerization of silicic acid in the residual water can be suppressed. Then, even if the solute concentration increased in the process of evaporating the water, the coffee stain phenomenon did not occur, and the phenomenon of the solvent flowing in the central direction was observed. And it was confirmed that the adhesion between the generated scale and the substrate is small, and the scale is easily peeled off. Further, the effect that the generation of scale is suppressed and the generated scale can be easily removed is obtained not only for the scale of the silicate component but also for the scale of the calcium ion component or the magnesium ion component.

The pH of the acidic water is, for example, about pH 4 or less. If it is acidic water which has pH of this range, the production | generation of acidic water is possible by the electrolytic cell 420 which electrolyzes water. Therefore, for example, maintenance such as replenishment of medicine becomes unnecessary.
Moreover, when adding a metal ion to acidic water, the metal ion contained in acidic water is an aluminum ion (Al3 ⁺ ), a copper ion (Cu2 ⁺ ), etc., for example. When such metal ions are added to acidic water, they intervene between silicic acid (SiO ₂ ) molecules in the generated scale. When water is supplied by washing or the like, metal ions are eluted. Then, it is considered that the silicic acid aggregate becomes more brittle and the scale can be easily removed. The concentration of metal ions is about 3 ppm or more.

Next, the toilet apparatus 10 according to the present embodiment will be further described with reference to the drawings.
FIG. 10 is a block diagram illustrating a main configuration of the toilet apparatus according to the present embodiment.
Moreover, FIG. 11 is a block diagram showing the principal part structure of the modification of the toilet apparatus concerning this embodiment.
Moreover, FIG. 12 is a block diagram showing the principal part structure of the other modification of the toilet apparatus concerning this embodiment.
FIG. 13 is a schematic cross-sectional view illustrating the metal ion water addition system of this embodiment.
In addition, FIGS. 10-12 represents the principal part structure of the waterway system and the electrical system collectively.

  As shown in FIG. 10, the sanitary washing device 100 included in the toilet device 10 according to the present embodiment includes the main flow path 23 that guides the water supplied from the water supply means 401 to the buttocks washing nozzle 439 and the spray nozzle 481. A valve 413 and a heat exchanger unit 415 are provided on the upstream side of the main flow path 23. The valve 413 is an electromagnetic valve that can be opened and closed, and controls the supply of water based on a command from the control unit 411 provided in the casing 400. The heat exchanger unit 415 has a hot water heater (not shown), and heats the supplied water to make predetermined hot water.

  A first flow path switching valve 417 is provided downstream of the valve 413 and the heat exchanger unit 415. The first flow path switching valve 417 opens, closes and switches water supply to the buttocks washing nozzle 439 and the spray nozzle 481. The main flow path 23 includes a first flow path 25 that guides cleaning water and the like to the buttocks cleaning nozzle 439 by a first flow path switching valve 417, and a second flow path that guides cleaning water and acidic water to the spray nozzle 481. And 27.

  The acidic water generator 405 described above with reference to FIGS. 1 to 3 is provided on the upstream side of the second flow path 27. However, the acidic water generation device of the present embodiment is not limited to the acidic water generation device 405 described above with reference to FIGS. 1 to 3, and is the acidic water generation device 406 described above with reference to FIG. 4 as illustrated in FIG. 11. Alternatively, as shown in FIG. 12, the acidic water generator 407 described above with reference to FIG. 5 may be used.

In the present embodiment, the second flow path switching valve 431 directly discharges the alkaline water supplied from the electrolytic bath 420 to the drain pipe 807 of the toilet bowl 800. According to this, alkaline water does not contact the surface of the bowl 801 of the toilet bowl 800. Therefore, it can suppress that alkaline water reduces the bactericidal action of acidic water.
Or the 2nd flow-path switching valve 431 may flow the alkaline water supplied from the electrolytic cell 420 to the toilet bowl 800 within the range which does not inhibit the scale control effect of this embodiment.
The acidic water released from the cation exchange resin system 460 is guided to the metal ion water addition system 440 provided on the downstream side of the cation exchange resin system 460.
Here, the metal ion water addition system 440 will be described with reference to the drawings.
In the present embodiment, the case where the metal ions dissolved in the metal ion water addition system 440 are aluminum ions (Al ³⁺ ) will be described as an example.

  As shown in FIG. 13, the metal ion water addition system 440 of the present embodiment includes a tank 441 and aluminum 443 installed in the tank 441. Acidic water supplied from the electrolytic cell 420 via the second flow path switching valve 431 and the cation exchange resin system 460 is stored in the tank 441. The aluminum 443 installed in the tank 441 is in a state of being immersed in the acid water stored in the tank 441.

Then, the aluminum 443 immersed in acidic water dissolves (slow dissolution), for example, over about 30 seconds to 30 minutes. Thereby, the acidic water in the tank 441 becomes acidic water containing aluminum ions. That is, in the metal ion water addition system 440, an aqueous solution having a high pH containing metal ions (Al ^{3+ in} this embodiment) is generated.

  Returning to FIG. 10, the acidic water containing aluminum ions generated in the metal ion water addition system 440 is guided to the flow rate adjustment valve 437 by being pushed by the acidic water flowing from the downstream side. The flow rate adjustment valve 437 adjusts the water flow (flow rate), sets the supply destination of acidic water to the spray nozzle 481, and guides the acidic water to the spray nozzle 481. The spray nozzle 481 sprays acidic water supplied from the flow rate adjustment valve 437 to the bowl 801.

  On the other hand, the wash water guided to the first flow path 25 by the first flow path switching valve 417 is guided to the wet cleaning nozzle 439 via the electromagnetic pump 435 and the flow rate adjustment valve 437. Then, the washing water is jetted from a water outlet (not shown) provided in the butt washing nozzle 439 toward the “butt” of the user seated on the toilet seat 200.

  As shown in FIG. 10, the sanitary washing device 100 of the present embodiment includes an entrance detection sensor (human body detection sensor A) 451, a human body detection sensor (human body detection sensor B) 453, a seating detection sensor 455, Have

  The entrance detection sensor 451 can detect a user immediately after opening a toilet room door or entering a toilet room and a user existing in front of the door. That is, the entrance detection sensor 451 can detect not only the user who entered the toilet room, but also the user before entering the toilet room, that is, the user existing in front of the door outside the toilet room. As such an entrance detection sensor 451, a pyroelectric sensor, a microwave sensor such as a Doppler sensor, or the like can be used. When using a sensor that uses the microwave Doppler effect or a sensor that detects the object to be detected based on the amplitude (intensity) of the microwave transmitted and reflected, the user's The presence can be detected. That is, the user before entering the toilet room can be detected.

  The human body detection sensor 453 can detect a user who is in front of the toilet bowl 800, that is, a user who is present at a position spaced forward from the toilet seat 200. That is, the human body detection sensor 453 can detect a user who enters the toilet room and approaches the toilet seat 200. As such a human body detection sensor 453, for example, an infrared light projecting / receiving distance measuring sensor or the like can be used.

  The seating detection sensor 455 can detect a human body existing above the toilet seat 200 immediately before the user sits on the toilet seat 200 and a user seated on the toilet seat 200. That is, the seating detection sensor 455 can detect not only a user seated on the toilet seat 200 but also a user existing above the toilet seat 200. As such a seating detection sensor 455, for example, an infrared light projecting / receiving type distance measuring sensor or the like can be used.

  According to this embodiment, acidic water having a relatively low pH can be generated by the acidic water generator 405. Therefore, the metal can be gradually dissolved. Thereby, even when it has the water quality which cannot produce | generate acidic water of desired low pH by the electrolysis in the electrolytic cell 420, acidic water with a comparatively high metal ion density | concentration can be produced | generated. Therefore, with a simple system, polymerization of silicic acid can be suppressed and generation of scale can be suppressed. Further, the generated scale can be easily removed.

Next, a specific example of the operation of the toilet apparatus 10 according to the present embodiment will be described with reference to the drawings.
FIG. 14 is a timing chart illustrating a specific example of the operation of the toilet apparatus according to this embodiment.

  First, when the entrance detection sensor (human body detection sensor A) 451 detects a user who has entered the toilet room, the toilet lid 300 is opened, the valve 413 is opened, and the first flow path switching valve 417 is moved to the second flow path 27. The second flow path switching valve 431 is switched to the metal ion water addition system 440 side (timing t1). Thereby, clean water is sprayed on the surface of the bowl 801. In this way, the filth attached to the surface of the bowl 801 can be reduced by wetting the surface of the bowl 801 before the user uses the toilet bowl 800.

  As indicated by the broken line in the “electrolysis tank” column shown in FIG. 14, when the room detection sensor 451 detects a user who has entered the toilet room, energization of the electrolysis tank 420 is started, and the acidic water is discharged. It may be generated (timing t1). In this case, acidic water (or acidic water containing metal ions) is sprayed on the surface of the bowl 801. According to this, dirt and scale adhering to the surface of the bowl 801 can be further reduced.

  Subsequently, when the human body detection sensor (human body detection sensor B) 453 detects a user in front of the toilet bowl 800, the valve 413 is closed and the first flow path switching valve 417 is switched to the first flow path 25 side. The second flow path switching valve 431 is switched to the drain side (timing t2). Subsequently, the seating detection sensor 455 detects the seating of the user on the toilet seat 200 (timing t3), and detects the separation from the toilet seat 200 (timing t4).

  Subsequently, when a predetermined time elapses after the human body detection sensor 453 no longer detects a user in front of the toilet bowl 800 (timing t5), the valve 413 is opened and the first flow path switching valve 417 is moved to the second flow rate. Switching to the path 27 side (timing t6). Further, energization to the electrolytic cell 420 is started (timing t6). Thereby, the alkaline water produced | generated in the electrolytic vessel 420 is discharged | emitted on the surface of the bowl 801 before the toilet bowl washing | cleaning (timing t8-t9).

Subsequently, when a predetermined time has elapsed after the discharge of the alkaline water generated in the electrolytic cell 420 is finished (timing t7), toilet flushing is started (timing t8).
Subsequently, when a predetermined time T elapses after toilet cleaning is finished (timing t9), the valve 413 is opened, the first flow path switching valve 417 is switched to the second flow path 27 side, and the second flow path 27 is switched to the second flow path 27 side. The flow path switching valve 431 is switched to the metal ion water addition system 440 side (timing t10). Further, energization to the electrolytic cell 420 is started (timing t10). Thereby, acidic water containing metal ions is sprayed on the surface of the bowl 801.

  The predetermined time T from the end of toilet cleaning (timing t9) to the time when acidic water containing metal ions is sprayed on the surface of the bowl 801 (timing t10) is the time during which the surface of the bowl 801 is not dried, specifically For example, about 30 seconds to 30 minutes. According to the knowledge obtained by the present inventor, an example of the time of about 30 minutes after the toilet cleaning is completed is the time when the surface of the bowl of the toilet bowl on which the glaze layer is formed begins to dry. According to this, the polymerization of silicic acid can be suppressed and the generation of scale can be suppressed. Further, the generated scale can be easily removed.

  Thus, in this specific example, the spray nozzle 481 sprays acidic water containing metal ions on at least the surface of the bowl 801 of the toilet bowl 800 after cleaning the toilet bowl. Moreover, the alkaline water produced | generated in the electrolytic vessel 420 is discharged | emitted on the surface of the bowl 801 before the toilet bowl washing | cleaning. In addition, the alkaline water produced | generated in the electrolytic vessel 420 may be discharged | emitted on the surface of the bowl 801 at the time of toilet bowl washing | cleaning.

  According to this, since the alkaline water is discharged to the surface of the bowl 801 of the toilet bowl 800, the alkaline water is discharged by a simpler structure rather than a complicated structure such as discharging to the drain pipe 807 of the toilet bowl 800, for example. Can do. The alkaline water discharged to the surface of the bowl 801 is discharged to the drain pipe 807 of the toilet bowl 800 by toilet flushing with neutral tap water. Therefore, when acidic water is sprayed on the surface of the bowl 801 of the toilet bowl 800, it can suppress that the bactericidal action of acidic water reduces.

The embodiment of the present invention has been described above. However, the present invention is not limited to these descriptions. As long as the features of the present invention are provided, those skilled in the art appropriately modified the design of the above-described embodiments are also included in the scope of the present invention. For example, the shape, size, material, arrangement, etc. of each element included in the acidic water generation apparatuses 405, 406, 407 and the toilet apparatus 10 and the installation form of the electrolytic cell 420 and the cation exchange resin system 460 are illustrated. It is not necessarily limited and can be changed as appropriate.
Moreover, in this embodiment, the toilet apparatus was mentioned as an example and demonstrated as a watering apparatus provided with the acidic water production | generation apparatuses 405,406,407. However, the watering device provided with the acidic water generating devices 405, 406, and 407 is not limited to this, and may be, for example, a kitchen, a bathroom, or a bathroom vanity.
Moreover, each element with which each embodiment mentioned above is provided can be combined as long as technically possible, and the combination of these is also included in the scope of the present invention as long as it includes the features of the present invention.

  DESCRIPTION OF SYMBOLS 10 Toilet apparatus, 21 Flow path, 21a 1st flow path, 21b 2nd flow path, 21c Bypass flow path, 23 Main flow path, 25 1st flow path, 27 2nd flow path, 30 Water supply source, 100 Sanitary washing device, 200 toilet seat, 300 toilet lid, 400 casing, 401 water supply means, 405, 406, 407 acidic water generator, 411 control unit, 413 valve, 415 heat exchanger unit, 417 first flow path switching valve, 420 Electrolyzer, 424 Anode Plate, 425 Cathode Plate, 431, 432 Channel Switch Valve, 433 First Channel Switch Valve, 434 Second Channel Switch Valve, 435 Electromagnetic Pump, 437 Flow Control Valve, 439 Cleaning Nozzle , 440 Metal ion water addition system, 441 tank, 443 aluminum, 451 entrance detection sensor, 453 human body detection Sensor, 455 seating detection sensor, 460 cation exchange resin system, 461 housing, 463 cation exchange resin, 481 spray nozzle, 800 toilet, 801 bowl, 807 drainage pipe

Claims (5)

An acidic water generator for generating acidic water,
An electrolysis system that produces acidic water by electrolysis;
A cation exchange resin system that is arranged in series with the electrolysis system downstream from the electrolysis system and generates acidic water by a cation exchange resin;
An acidic water generating device comprising: An acidic water generator for generating acidic water,
An electrolysis system that produces acidic water by electrolysis;
A cation exchange resin system that is arranged in parallel with the electrolysis system and generates acidic water by the cation exchange resin;
With
The acidic water generated by the electrolysis system and the acidic water generated by the cation exchange resin system merge on the downstream side of the electrolysis system and the cation exchange resin system. Acid water generator. The acidic water generator according to any one of claims 1 and 2,
Spraying means for spraying at least the surface of the bowl of the toilet bowl with the acidic water generated by the acidic water generator;
With
The alkaline water generated by the electrolysis system is directly discharged into a drain pipe of the toilet bowl. The acidic water generator according to any one of claims 1 and 2,
Spraying means for spraying at least the surface of the bowl of the toilet bowl with the acidic water generated by the acidic water generator;
With
The spraying means sprays the acidic water after washing the toilet bowl,
The alkaline water generated by the electrolysis system is discharged to the surface of the bowl when the toilet bowl is washed or before the toilet bowl is washed. A metal ion water addition system that gradually dissolves the metal using the acidic water generated by the acidic water generator;
The toilet device according to claim 3 or 4, wherein the spraying means sprays acidic water containing the metal ions.

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