KR200490889Y1 - Anode catalytic pressure type electrolytic cell - Google Patents

Abstract

The present invention relates to an anode catalyst blood pressure electrolyzer. This includes cup base fixing screws, electrolytic cell support, negative electrode, separator, proton membrane, positive electrode, electrolytic cell cap, positive electrode fixing bolt, titanium fiber pad, etc. The negative electrode does not use a catalyst and contacts the injected drinking water. do. There is a catalyst layer coated on the outside of the anode, and a cathode power connection terminal and a cathode power connection end are formed on the cathode and the anode, respectively. Connect the cathode, isolation plate, proton membrane, titanium fiber pad and anode from bottom to top with the electrolytic cell pedestal and cup holder fixing screws. The electrolytic cell cap is connected to the electrolytic cell pedestal, and the anode fixing bolt is inserted into the electrolytic cell cap to fix the titanium fiber pad between the proton membrane and the anode. In the present invention, the cathode has no catalyst layer, and only the anode has a catalyst layer. The negative electrode prevented the precipitation of heavy metals or impurities by realizing an electrolysis catalyst on one side of the positive electrode using a titanium-based material or pure titanium material. In addition, by adding titanium fiber material on the surface to be pressurized, the area to be pressurized is effectively expanded and distributed so that the electrolyzer can operate normally at a constant pressure.

Description

Anode catalytic pressure type electrolytic cell

TECHNICAL FIELD The present invention relates to household goods, and more particularly, to a cathode catalyst pressure electrolyzer.

In the case of the commonly seen hydrogen water cup electrolyzer, when two electrodes are formed of a titanium plate, air passes through holes of a constant density generated by collision of the two electrodes. For this reason, the catalyst layer (coated with platinum, ruthenium, iridium, or a mixture thereof) was coated on the cathode and anode surfaces, followed by pure water electrolysis using a solid electrolyte (for example, a proton membrane) mounted in the middle as a catalyst. .

The drawback of such an electrolytic cell is that impurities such as heavy metals and ozone are precipitated during the electrolysis process from the catalyst layer coated on the surface of the cathode in contact with the drinking water. In addition, since the diameter and density of the electrode plate are limited, when pressure occurs during electrolysis, there is a problem in that the proton membrane ruptures and thus cannot withstand the pressure.

The present invention is to solve the above problems by providing a cathode catalyst pressure electrolyzer. It is simple in structure and does not generate harmful substances during the electrolysis process.

One embodiment of the anode catalyst pressure-type electrolyzer according to the present invention includes a cup support fixing screw, an electrolyzer stand, a cathode, a separator, a proton membrane, an anode, an electrolyzer lid, an anode fixing bolt, and a titanium fiber pad. The negative electrode does not use a catalyst and contacts the injected drinking water. The anode surface has a coated catalyst layer, and the cathode and anode are formed with a cathode power connection terminal and an anode power connection end, respectively. Connect the poles, the separator plate, the proton membrane, the titanium fiber pads, and the anodes from the bottom up to the electrolytic cell pedestal and tighten the electrolytic cell pedestal and cup base fixing screws. The electrolyzer lid is connected to the bottom of the electrolyzer pedestal, and the anode fixing bolt is inserted into the bottom of the electrolyzer lid to fix the titanium fiber pad between the proton membrane and the anode.

According to an embodiment of the present invention, a negative electrode waterproof pad is mounted between the negative electrode and the electrolyzer pedestal. Place one side of the lid of the electrolytic cell close to the bottom of the anode, and attach the waterproof pad on the back of the anode.

The cup base fixing screw and the electrolytic cell base can be assembled with screws.

The negative electrode is made of a titanium-based material or pure titanium, and a titanium fiber pad is mounted on the pressure surface.

The effect of the invention is as follows. First, when the proton membrane is placed between the cathode and the anode, the cathode becomes a non-catalytic electrode and the anode becomes a catalyst electrode, which serves to sort and isolate the proton membrane. If the negative electrode is in contact with drinking water and the positive electrode is connected to the positive electrode and the negative electrode without contacting the drinking water, the noncatalytic negative electrode only serves as an electrode and no electrolysis occurs. Only a small amount of water passing through the proton membrane undergoes electrolysis through the anodic catalyst. Hydrogen ions generated by electrolysis pass through the proton membrane to reach the cathode, and after the electrons are obtained, the generated hydrogen flows into the drinking water. Oxygen generated by electrolysis is removed by evaporation at the anode.

As such, according to the present invention, since electrolysis does not occur in the negative electrode plate in which drinking water reaches, no harmful substances are generated. Therefore, hydrogen water can be ingested without concern for harmfulness, which is beneficial to health.

Secondly, since titanium fiber material is applied to the surface to be pressurized to effectively expand and distribute the area to be pressurized, the electrolyzer has an advantage that it can operate normally at a constant pressure.

In order to better describe the technical solutions among the embodiments of the present invention or the existing technology, it will be briefly described as follows with drawings that require the use of the embodiments or the existing technology. The drawings are only one embodiment of the present invention, and those skilled in the art may obtain other drawings according to the drawings with ordinary efforts only. 1 is an exploded view of a cathode catalyst pressure electrolyzer according to an embodiment of the present invention.

The order of all the features or all the methods or processes disclosed herein is only one embodiment, it is also possible to obtain a cathode catalyst pressure-type electrolytic cell according to the present invention in a different order or combination.

All features disclosed in this specification (including claims, summaries, and drawings) may be replaced by features that may be substituted for other equivalent effects or similar purposes, unless specifically noted otherwise. In other words, unless stated otherwise, all features are merely examples of a series of equivalent effects or similar features.

1 includes a cup underlay fixing screw 1, an electrolytic cell pedestal 2, a cathode 4, a separator 5, a proton membrane 6, an anode 8, an electrolytic cell lid 10, an anode fixing bolt 11, and a titanium fiber pad 7. A catalyst is not used for the negative electrode 4, and the negative electrode 4 contacts the injected drinking water. The anode 8 has a coated catalyst layer on its surface, and a connection terminal is formed on the cathode 4 and the anode 8, respectively. Connect negative electrode 4, separator 5, proton membrane 6, titanium fiber pad 7, and positive electrode 8 sequentially to electrolyzer base 2 and tighten the electrolytic cell base 2 and the cup base fixing screw 1. The electrolytic cell lid 10 is connected to the bottom of the electrolytic cell pedestal 2, and the positive electrode fastening bolt 11 is inserted into the bottom of the electrolytic cell lid 10 to fix the titanium fiber pad 7 between the proton membrane 6 and the positive electrode 8.

Here, the negative electrode waterproof pad 3 is inserted between the negative electrode 4 and the electrolytic cell pedestal 2, and the electrolytic cell lid 10 is placed close to the lower part of the positive electrode 8 to mount the waterproof pad 9 at the positive electrode rear side. Screw between the cup base fixing screw 1 and the electrolytic cell stand 2 with screws. The negative electrode 4 may be made of titanium-based material or pure titanium. A titanium fiber pad is placed between the anode and the proton membrane to evenly distribute the pressure applied to the anode. That is, by applying titanium fiber material on the surface to be pressurized, the area to be pressurized can be effectively expanded and dispersed so that electrolysis can be normally performed even at high pressure.

When the proton membrane is positioned between the cathode and the anode, the cathode becomes a non-catalytic electrode and the anode becomes a catalyst electrode, which serves to sort and isolate the proton membrane. If the negative electrode is in contact with drinking water and the positive electrode is connected to the positive electrode and the negative electrode without contacting the drinking water, the noncatalytic negative electrode only serves as an electrode and no electrolysis occurs. Only a small amount of water passing through the proton membrane undergoes electrolysis through the anodic catalyst. The hydrogen ions generated by electrolysis penetrate the proton membrane to reach the cathode, and after the electrons are obtained, the generated hydrogen enters the drinking water. Oxygen generated by electrolysis is removed by evaporation at the anode. Therefore, since electrolysis does not occur in the negative electrode plate in which the electrolytic cell and drinking water of the present invention, no harmful substances are generated, which helps to the health of the body.

In addition, since the titanium fiber material is applied to the surface to be pressurized, the area to be pressurized is effectively expanded and dispersed, so that the electrolyzer can operate normally at a constant pressure.

Although the foregoing is a specific implementation method of the present invention, the scope of protection of the present invention is not limited thereto. Conventional changes or replacements are also within the scope of protection of the present invention. Therefore, the protection scope of the present invention (utility model) should be based on the protection scope defined in the claims.

DESCRIPTION OF SYMBOLS 1: Cup base fixing screw 2: Electrolyzer base 3: Cathode waterproof pad 4: Cathode 5: Separator 6: Proton membrane 7: Titanium fiber pad 8: Anode 9: Anode rear waterproof pad 10: Electrolyzer lid 11: Anode fixing bolt

Claims (5)

A cup underlay fixing screw, an electrolytic cell pedestal, a negative electrode, a separator, a proton membrane, a positive electrode, an electrolytic cell cap, a positive electrode fixing bolt, and a titanium fiber pad, the catalyst layer is not formed on the surface of the negative electrode, and the negative electrode is injected In contact with the drinking water, a catalyst layer is formed on the surface of the anode, and a cathode power connection terminal and a cathode power connection end are formed on the cathode and the anode, respectively, the cathode, the separator, the proton The membrane, the titanium fiber pad, and the anode are sequentially stacked on the bottom of the electrolyzer pedestal, and fixed by the cup underlay fixing screw located on the top of the electrolyzer pedestal, wherein the electrolyzer lid is coupled to the bottom of the electrolyzer pedestal. The positive electrode fixing bolt is coupled to the lower portion of the electrolytic cell cap and between the proton membrane and the positive electrode An anode catalyst, characterized in that for fixing the titanium fiber pad blood pressure type electrolytic cell. According to claim 1, Cathode catalytic pressure-type electrolytic cell further comprises a negative electrode waterproof pad mounted between the negative electrode and the electrolytic cell pedestal. According to claim 1, Cathode catalytic pressure-type electrolytic cell further comprises a positive electrode back waterproof pad mounted between the anode and the electrolytic cell lid. The positive electrode catalyst pressure-type electrolyzer of claim 1, wherein the cup underlay fixing screw and the electrolytic cell pedestal are coupled with a screw. The cathode catalyst pressure electrolyzer according to claim 1, wherein the cathode is made of pure titanium, and the titanium fiber pad is mounted on a press surface of the anode.

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