JPH03192A - Bathtub water sterilizing and cleaning device - Google Patents

Abstract

PURPOSE:To obtain the bathtub water sterilizing and cleaning device which easily and surely sterilizes and cleans bathtub water by providing an electrolyzer which electrolyzes circulating water at the intermediate point of a circulating path to circulate the bathtub water to the outside. CONSTITUTION:The bathtub water from a bathtub 1 is returned through a filter 5 and the electrolyzer 4 to the bathtub 1 by driving of a circulating pump 3. The water is filtered by the filter 5 and is electrolyzed by the electrolyzer 4 during this time. Hydrogen ions are increased in the water on the anode side in the electrolyzer 4 when the electrolysis of the bathtub water is executed. In addition, NaCl which is the components, such as human sweat, contained in the bathtub water is generated as gaseous chlorine. The water is sterilized by this acidic water and gaseous chlorine. The NaCl and other electrolytes increase as the bathtub water is more contaminated and, therefore, the electrolytic current is naturally increased or decreased according thereto. The sterilization corresponding to the contamination is thus automatically executed. Hydrogen ions are increased on the cathode side to make the water alkaline and to effect sterilization.

Description

[Detailed description of the invention] <Industrial application field> The present invention relates to an apparatus for sterilizing and purifying bathtub water.

<Prior art and its problems> Conventionally, bathtub water has been sterilized by adding a sterilizing agent or by using ozone, but there have been problems with maintenance and complication of the system.

SUMMARY OF THE INVENTION An object of the present invention is to provide a bathtub water sterilization and purification device that can easily and reliably sterilize and purify bathtub water by using different means from conventional methods.

Means for Solving the Problems> In order to achieve the above object, the bathtub water sterilization and purification device of the present invention includes an electrolyzer that electrolyzes the circulating water in the middle of the circulation path that circulates the bathtub water to the outside. The first feature is that

Further, in the bathtub water sterilization and purification device of the present invention, in the first feature, a diaphragm is provided between the anode side and the cathode side in the electrolyzer, and the water entering the anode side and the water entering the cathode side are separated. The second feature is that they do not mix easily.

Moreover, the bathtub water sterilization and purification device of the present invention is characterized by the above-mentioned first or second
The third feature is that electrolysis is performed multiple times along the flow.

Further, in the bathtub water sterilization and purification device of the present invention, in the second feature, a fourth feature is that the flow rate flowing into the cathode side of the electrolyzer is made smaller than the flow rate flowing into the anode side.

Further, in the bathtub water sterilization and purification device of the present invention, in the second feature, a fifth feature is that a part of the water flowing out from the cathode side of the electrolyzer is circulated again to the inlet to the cathode side. It is a feature.

Moreover, the bathtub water sterilization and purification device of the present invention is provided with the second or fourth
Alternatively, in the fifth feature, the sixth feature is that a reaction tank is provided to receive water from the anode side and water from the cathode side of the electrolyzer in a separated state.

Further, the bathtub water sterilization and purification device of the present invention has the above-mentioned first to sixth
In any of the above features, the seventh feature is that a filter is provided in the circulation path together with the electrolyzer.

In addition, in the above, bathtub water includes water from a so-called bathtub as well as a pool or other aquarium.

<Operation> According to the first feature of the present invention, the bathtub water flowing through the circulation path is electrolyzed by the electrolyzer.

On the anode side of the electrolyzer, the hydrogen ion concentration increases and becomes acidic water, and NaCl from human sweat is separated to generate chlorine gas, which has a sterilizing effect. Similarly, on the cathode side, the water becomes alkaline and has some sterilizing effect. That is, bath water is sterilized by electrolysis.

According to the second feature of the present invention, the water on the anode side and the water on the cathode side of the electrolyzer are prevented from easily mixing with each other by the diaphragm, so that the acidic water generated at both electrodes, The bactericidal effect of alkaline water is improved.

According to the third feature of the present invention, the sterilization effect can be improved by performing electrolysis multiple times along the flow.

Further, according to the fourth feature of the present invention, the amount of acidic water relative to the total amount of circulating water is increased by increasing the amount of alkaline water with weak sterilizing power flowing into the anode side than the amount flowing into the cathode side. can improve the bactericidal effect. Note that the alkalinity of the water itself on the cathode side increases.

Furthermore, according to the fifth feature of the present invention, part of the water flowing out from the cathode side of the electrolyzer is recirculated to the cathode side, so as in the case of the fourth feature, Although the alkalinity on the cathode side increases, the ratio of acidic water to the total circulating water increases, improving sterilization efficiency.

According to the sixth feature of the present invention, the acidic water from the anode side and the alkaline water from the cathode side of the electrolyzer enter the reaction tank while being separated and are appropriately retained therein. The time until re-contact with the alkali is correspondingly longer, and sufficient sterilization can be performed during that time.

Moreover, according to the seventh feature of the present invention, since the filter is provided in the circulation path together with the electrolyzer, dust in the bathtub water can be removed at the same time.

<Example> Figure 1 is an overall configuration diagram of an apparatus for implementing the present invention, and Figures 2 to 9 are
The figures up to the figures are sectional views showing examples of electrolyzers.

A circulation path 2 and a circulation pump 3 are provided for a bathtub (including a water tank such as a boule) 1, and an electrolyzer 4 is provided in the middle of the circulation path 2. Further, a filter 5 can be provided in the circulation path 2. In addition, the circulation path 2 can be provided with additional heating means, air bubble introduction means, and the like. The bath water from the bathtub 1 is driven by the circulation pump 3 and passed through the filter 5 and the electrolyzer 4.
Go through and return to bathtub 1. During that time, it is filtered by a filter 5 and electrolyzed by an electrolyzer 4.

The electrolyzer 4 is provided with an anode and a cathode in a bathtub,
The bathtub water is made to pass between them. By applying a DC voltage between the anode and cathode, electrolysis of the bath water occurs, and hydrogen ions increase in the water on the anode side, making it acidic, and components such as human sweat contained in the bath water are removed. Nac 1 is generated as chlorine gas on the anode side. Sterilization is performed using this acidic water and chlorine gas. The NaCl and other electrolytes increase as the bath water becomes dirtier, so the electrolytic current naturally increases or decreases accordingly, and sterilization can be performed automatically depending on the dirt. Furthermore, hydrogen ions increase on the cathode side, making it alkaline and sterilizing it.

The electrolyzer 4 may be vertical as shown in FIG.
A horizontal type electrolyzer 10 shown in the figure may be used. Also the second
As shown in the figure, efficiency can be increased by alternately disposing a large number of anodes 11 and cathodes 12.

13 is a water shield plate that rectifies incoming bath water.

By arranging the electrolyzer in the circulation path 2 as described above, bath water can be sterilized with simple equipment, and no special maintenance is required.

What's more, the sterilizing power is automatically adjusted depending on how dirty the bathtub is. Of course, it is not necessary to add a disinfectant.

The electrolyzer, as shown in the electrolyzer 20 in FIG.
A diaphragm 2 is used to divide the interior into an anode 21 side and a cathode 22 side.
4 is provided, and this diaphragm can prevent water on the anode 21 side and water on the cathode 22 side from easily mixing. By doing so, it is possible to increase the effects of sterilization using the acidic water on the anode 21 side and sterilization using the alkaline water on the cathode 22 side. Further, as in an electrolyzer 30 shown in FIG. 4, the inlet 35 may be introduced into the anode 31 side and the cathode 32 side separated by a diaphragm 34 through branches 35a and 35b.

The electrolyzer also has a -degree anode 41. as shown in the electrolyzer 40 in FIG. Electrolysis may be performed a plurality of times along the flow, such that what is electrolyzed at a and the cathode 42a is further electrolyzed at the anode 41b and the cathode 42b. In this case, in addition to an electrolyzer that performs electrolysis multiple times within one electrolyzer (such as the one shown in FIG. 5), a plurality of electrolyzers may be arranged along the flow. Furthermore, although the diaphragms 44a and 44b are provided in the example shown in FIG. 5, the diaphragms may not be provided.

By performing electrolysis multiple times along the flow, acidic water and alkaline water can be effectively obtained with low current, and the sterilization effect can be improved.

Further, as shown in the electrolyzer 50 in FIG. 6, the electrolyzer is provided with a branch inlet 55a leading to the anode 51 side and a branch inlet 55b leading to the cathode 52 side.
The branch inlet 55b to the second side may be provided with a constriction part 56 or the like to reduce the amount of inflow to the cathode 52 side (and increase the amount of inflow to the anode 51 side. 54 is a diaphragm. By doing this, the alkalinity on the cathode 52 side increases, but the amount of alkaline water decreases;
The amount of water passing through the first side is greater than the amount of water passing through the cathode 52 side, and the amount of acidic water increases.

Since acidic water has a better sterilizing effect, the amount of acidic water relative to the total amount of circulating water increases, and the sterilizing effect of acidic water and chlorine gas improves.

Further, as shown in the electrolyzer 60 in FIG. 7, the electrolyzer is provided with an ejector 67 at the branch inlet 65b toward the cathode 62, and a return pipe is connected to the negative pressure forming part of the ejector 67. In this way, a portion of the water flowing out from the cathode 62 side may be circulated through the return pipe 68 from the branch inlet 65b to the cathode 62 side. 61 is an anode, 6
4 is a diaphragm, 65 is an inlet, and 65a is a branch inlet to the anode 61 side. With this configuration, the degree of alkalinity on the cathode 62 side increases, as in the case of the electrolyzer 50 shown in FIG. The bactericidal effect is improved.

Note that, as in the electrolyzer 70 shown in FIG. 8, a return pump 79 may be provided in the return pipe 78 instead of the ejector 67 shown in FIG. Even with this configuration, it is possible to improve the sterilizing effect similar to that of the electrolyzer 70 shown in FIG. 7. Furthermore, 71
is an anode, 72 is a cathode, 74 is a diaphragm, 75 is an inlet, 75
A is a branch inlet to the anode 71 side, and 75b is a branch inlet to the cathode side.

Further, the electrolyzer, like the electrolyzer 80 in FIG.
Following the electrolyzer, water from the anode 81 side and the cathode 8
A configuration may also be provided in which a reaction tank 90 is provided to receive water from the second side in an isolated state.

84 is a diaphragm. By providing the reaction tank 90 in this way, the time until acidic water and alkaline water come into contact with each other again by the electrolyzer is extended, and therefore the sterilization effect within the reaction tank 90 is improved even if the concentration of acid or alkali is low. do. Note that the reaction tank 90 can be attached to various electrolyzers shown in FIGS. 3 to 8.

The sterilizing effect of treating bath water with an electrolyzer is
For example, this is clear from the experimental results of bathtub water for 5 people (2001) under the same conditions, with and without an electrolyzer attached. That is, at the beginning of the experiment, the number of bacteria was 5 x 10'/m 1, but after 24 hours, the number was 1 x 10'/m 1 for the untreated bacteria, whereas the number for the electrolyzed bacteria was 1 x 10'/m 1. 9X10'
The number of cells/ml was suppressed.

In other words, there was a difference between about 100 million and 1 million sterilizing effects.

Effects> According to the bathtub water sterilization and purification device according to the present invention having the above-described configuration, by providing an electrolyzer, bathtub water can be reliably sterilized with simple equipment. . What's more, the sterilizing power is automatically adjusted depending on how dirty the bath water is. Of course, there is no need to introduce special disinfectants, and no inconveniences arise due to this.

Further, according to the bathtub water sterilization and purification device according to the second aspect, by providing the diaphragm, it is possible to improve the sterilization effect of the bathtub water by acidic water and alkaline water.

Further, according to the bathtub water sterilization and purification device according to the third aspect, the sterilization effect of bathtub water can be increased by performing electrolysis multiple times along the flow.

Further, according to the bathtub water sterilization and purification device according to the fourth aspect, the proportion of the flow rate passing through the anode side with respect to the total circulation amount is increased, and the sterilization effect of the acidic water and the generated chlorine gas is improved.

Furthermore, according to the bathtub water sterilization and purification device according to the fifth aspect, the amount of water passing through the anode side relative to the total circulating amount is similarly increased, and the sterilization effect of the acidic water and the generated chlorine gas is improved.

Further, according to the bathtub water sterilization and purification device according to the sixth aspect, the time until acidic water and alkaline water separated by electrolysis come into contact again is extended, and the membrane surface effect is improved.

Further, according to the bathtub water sterilization and purification device according to the seventh aspect, in addition to sterilization, dust removal using a filter can be performed simultaneously.

[Brief explanation of drawings]

FIG. 1 is an overall configuration diagram of the device implementing the present invention, and FIGS.
The figures up to the figures are sectional views showing examples of electrolyzers. 1: Bathtub 2: Circulation path 3: Circulation pump 4.10.20.30.40.50.60. '70.8
0: Electrolyzer 5: Filter 11.21.31.41.51. 12.22.32.42.52. 24.34.44.54.64. 56: Squeezing part 67: Ejector 68.78: Return pipe 79: Return pump 90: Reaction tank 61.71.81: Anode 62.72.82: Cathode 74.84: Diaphragm

Claims (7)

[Claims] (1) A bathtub water sterilization and purification device characterized in that an electrolyzer for electrolyzing circulating water is provided in the middle of a circulation path for circulating bathwater to the outside. (2) The bathtub according to claim 1, wherein the electrolyzer is provided with a diaphragm between the anode side and the cathode side, so that the water entering the anode side and the water entering the cathode side do not easily mix. Water sterilization purification equipment. (3) The bathtub water sterilization and purification device according to claim 1 or 2, wherein the electrolysis is performed multiple times along the flow. (4) The bathtub water sterilization and purification device according to claim 2, wherein the flow rate flowing into the cathode side of the electrolyzer is lower than the flow rate flowing into the anode side. (5) The bathtub water sterilization and purification device according to claim 2, wherein a part of the water flowing out from the cathode side of the electrolyzer is circulated again to the inlet to the cathode side. (6) The bathtub water sterilization and purification device according to claim 2, 4, or 5, further comprising a reaction tank that receives water from the anode side and water from the cathode side of the electrolyzer in a separated state. (7) The bathtub water sterilization and purification device according to any one of claims 1 to 6, wherein a filter is provided together with an electrolyzer in the circulation path.