KR101444440B1 - Scale-Proof Electrolytic Bath - Google Patents

Abstract

The electrolytic cell includes an electrolytic member, a waterproofing member, a gas discharging member, a water shut-off diaphragm, and the like. The electrolytic member is constituted by a frame which opens to both sides. And an anode member and a cathode member separated into an insulating diaphragm inside the frame. One side of the frame is provided with an inlet for supplying water to the inside, and the other side is provided with an outlet for discharging the inside water to the outside. The frame has a first voltage line for supplying a voltage to the anode member and a second voltage line for supplying a voltage to the cathode member on the other side. The electrolytic member electrolyzes the water flowing through the inlet port and then discharges it through the outlet port. The scuff preventing member has a first communicating portion communicating with the electrolytic member, and a scavenging agent is provided in the first communicating portion. The gas discharge member has a second communication portion communicating with the first communication portion of the scrubbing prevention member. Further, the gas discharging member has a gas outlet communicating with the second communicating portion. The gas discharging member discharges the gas generated in the electrolytic member to the outside. The water shut-off diaphragm is coupled between the first communicating portion of the scrubbing prevention member and the second communicating portion of the gas exhausting member, and blocks water movement from the first communicating portion to the second communicating portion and permits gas movement.

Description

[0001] Scale-Proof Electrolytic Bath [

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electrolytic cell for preventing water scarcely,

Generally, a water purifier is a type in which cold water or hot water is provided by cooling or heating a water container containing purified water, or tap water is filtered with a filter to provide purified water.

In recent years, a water purifier for electrolyzing purified water to provide ionized water has been a favorite not only for drinking tap water but for drinking water. An example is an ionized water supply. One of the major causes of modern geriatric diseases such as hypertension, diabetes, and heart disease is excessive intake of acidic foods such as meat, fish and so on, and the constitution is acidified. In order to improve such acidic constitution into weak alkaline constitution, It is the ionized water supply device that provides such alkaline ionized water.

The ionized water supply apparatus electrolyzes water or raw water purified with tap water into an electrolytic cell to produce ionized water. However, when water is electrolyzed for a long time in order to obtain ionized water, a scale of calcium, magnesium, or the like is adhered to the negative electrode plate. Such water drops reduce the electrolytic current and reduce the efficiency of electrolysis. As a result, the ionized water supply capability of the ionized water supply device is lowered.

However, the formation of the water mist adhered to the negative electrode plate is inevitable, and the scale must be removed periodically to prevent the deterioration of the ionization due to the water mist. For this purpose, a method of replacing the polarity of the electrode has been used. However, the way to change these polarities requires a new program and changes the water taste. In addition, the ionized water itself may have a characteristic odor due to the generated gas, but it can not be removed.

Further, in the conventional ionized water supply device, a packing made of rubber or the like is mounted on the frame to prevent water from leaking. However, when the inside water touches the rubber packing, the odor of the rubber packing may leak into the water. In this case, the rubber smells from the water, which lowers the quality of the drinking water.

The present invention has been made to solve such a problem,

First, the electrode plate of the electrolytic cell, that is, the copper, magnesium, calcium and the like adhered to the platinum titanium electrode,

Second, it is possible to minimize the odor due to the gas generated by the electrolysis of the electrolytic cell,

Third, the rubber packing used in the frame can be structured so that it does not touch the inside water, so that the rubber odor can be prevented from flowing into the water,

Fourth, an object of the present invention is to provide a water-scavenging electrolytic cell capable of generating hydrogen in a large amount of hydrogen in electrolyzed water.

To attain the above object, the antiscattering electrolytic bath of the present invention comprises an electrolytic member, a scrubber, a gas exhaust member, a water shut-off diaphragm, and the like.

The electrolytic member is constituted by a frame which opens to both sides and communicates. And an anode member and a cathode member separated into an insulating diaphragm inside the frame. An inlet for supplying water to the inside of the electrolytic member is provided at one side of the frame, and an outlet for discharging the water inside to the outside is provided at the other side. A first voltage line for supplying a voltage to the anode member is connected to one side of the frame, and a second voltage line for supplying a voltage to the negative electrode member is connected to the other side. The electrolytic member electrolyzes the water flowing through the inlet port and then discharges it through the outlet port.

The waterproofing member has a first communicating portion that communicates with a lateral opening of the electrolytic member, and a scavenging agent is provided in the first communicating portion.

The gas discharge member has a second communication portion communicating with the first communication portion of the scrubbing prevention member. Further, the gas discharging member has a gas outlet communicating with the second communicating portion. The gas discharging member discharges the gas generated in the electrolytic member to the outside.

The water shut-off diaphragm is coupled between the first communicating portion of the scrubbing prevention member and the second communicating portion of the gas exhausting member, and prevents the water from moving from the first communicating portion to the second communicating portion and allows the gas to move.

In the antiscale electrolyzer according to the present invention, the electrolytic member and the antifogging member face each other, and the packing member is inserted into the antifogging member and the side face of the gas discharging member. Further, the electrolytic member and the watertight prevention member, and the watertight prevention member and the gas discharge member are provided with the concave-convex portion which is positioned more toward the communication portion than the packing member. In this case, the outer edge of the water shut-off diaphragm may be extended to the scuff preventing member and the irregular portion of the gas discharging member, or may be extended to the packing member of the scrubbing preventing member and the gas discharging member.

In the antiscattering electrolytic bath of the present invention, the electrolytic member and the antifogging member may be integrally formed. In this case, the waterproofing member and the gas discharging member are provided with a concave / convex portion which is inserted into a surface of the gas discharge member opposite to the edge, and which is positioned more toward the communicating portion than the packing member. Then, the outer edge of the water shut-off diaphragm is inserted at least into the concave-convex portion.

In the antiscattering electrolyzer according to the present invention, the antiscattering member and the gas discharging member may be integrally formed by incorporating a water-blocking diaphragm. In this case, the electrolytic member and the watertight preventing member are provided with a concave-convex portion which is inserted into a surface of the electrolytic member and the watertight-preventing member opposite to the edge, and is positioned more toward the communicating portion than the packing member.

In the anti-fogging electrolyzer according to the present invention, the anti-fogging member may have a plurality of partitions for placing the anti-fogging agent in the first communication part. The partition wall can be formed in the form of a honeycomb or the like.

In the antiscattering electrolytic bath of the present invention, the water shut-off diaphragm can use not only a water shut-off but also a material which selectively blocks the movement of hydrogen gas. In this case, water in the electrolytic bath contains a large amount of hydrogen, And is discharged through an outlet.

According to the electrolytic bath of the present invention having such a constitution, even if there is a component such as copper, magnesium, calcium adhered to the electrode plate of the electrolytic bath, that is, the platinum titanium electrode, In addition, the odor due to the gas generated by the electrolysis can be minimized, and furthermore, the rubber packing does not touch the water in the electrolytic cell, and the odor of the rubber packing can be prevented from escaping into the water. In addition, hydrogen water and the like can be easily generated by appropriately selecting the material of the water barrier diaphragm.

1A, 1B, and 1C are a perspective view, an exploded perspective view, and a shaving view of the antiscattering electrolytic cell according to the present invention.
FIGS. 2A and 2B are a perspective view and a cross-sectional view of a watertight electrolytic cell according to the present invention, in which an electrolytic member and a watertight prevention member are integrally formed.
Figs. 3A and 3B are perspective views and cross-sectional views of another embodiment of the antiscaling electrolytic cell according to the present invention, in which the antiscattering member and the gas discharging member are integrally formed. Fig.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1A is a perspective view of a scum prevention electrolytic cell according to the present invention.

1A, the antiscaling electrolyzer comprises a frame composed of the electrolytic member 100, the antiscattering members 210 and 220 and the gas discharging members 510 and 520, an inlet 111 communicating with the upper portion of the frame, A first voltage line 121 connected to an upper portion of the frame, and a second voltage line 131 connected to a lower portion of the frame.

The electrolytic member 100 is located at the center of the entire frame and includes an inlet 111, an outlet (not shown), first and second voltage lines 121 and 131, and the like.

The waterproofing members 210 and 220 are coupled to both sides of the electrolytic member 100 so that the waterproofing members 210 and 220 and the electrolytic member 100 are sealed with each other and water does not leak to the outside.

The gas discharging members 510 and 520 are respectively coupled to the outside of the scratch protection members 210 and 220. The gas discharging members 510 and 520 and the scratch prevention members 210 and 220 are sealed with each other so that water does not leak to the outside.

The gas discharge port 521 is provided at one side of the gas discharge member 520 and discharges the gas generated by electrolysis in the electrolytic member 100 and collected inside the gas discharge member 520 to the outside.

The inlet 111 guides the water supplied from the outside to the inside of the electrolytic cell and is usually provided on the electrolytic member 100 to increase the efficiency of water electrolysis and on the electrolytic member 100 on the water flow .

The outlet 131 guides the electrolyzed water from the electrolytic member 100 to the outside, and is located below the electrolytic member 100 in the water flow.

 The first voltage line 121 is connected to an anode member provided in the electrolytic member 100 and the second voltage line 131 is connected to a cathode member provided in the electrolytic member 100.

1A, the anti-fogging electrolytic cell is illustrated as a hexahedron, but the shape thereof is not limited to this, and may be variously formed as a circle, a polygon, or the like.

1B is an exploded perspective view of the antiscattering electrolytic cell according to the present invention.

1B, the antiscaling electrolytic cell includes electrolytic member 100, inner packing members 313 and 323, antiscattering members 210 and 220, outer packing members 310 and 320, water shut-off diaphragms 410 and 420, 510 and 520, and the like.

The electrolytic member 100 is constituted by a frame having an inlet 111 and an outlet opening sidewardly opened in addition to the outlet described above. The anode member 123 and the cathode members 133a and 133b are connected to the first voltage line 121 and the second voltage line 131, respectively. Normally, the anode member 123 and the cathode members 133a and 133b are formed in a plate shape, and the material thereof is platinum-titanium or the like. Platinum Titanium is made of titanium (Ti) as a base material and platinum is coated on it. The platinum coating can be plated or spray coated. The anode member and the cathode member may have various shapes such as a plate shape, a mesh shape, and the like.

The anode member 123 and the cathode members 133a and 133b are insulated by the insulating diaphragms 140a and 140b. The insulating diaphragms 140a and 140b may be formed of a mesh-type insulator, for example, plastic.

When a voltage is applied to the anode member and the cathode member, the hydroxide ions are reduced in the anode member to generate oxygen gas. At this time, anions such as chlorine, phosphorus, and sulfur other than the hydroxide ions form an acid, so that the water in the anode member becomes acidic. In the cathode member, hydrogen ions are reduced and hydrogen gas is generated. At this time, cations such as sodium, magnesium, and calcium other than hydrogen ions form a pair of hydrogen ions, so that the water in the cathode member becomes alkaline. On the other hand, over time, positive ions such as magnesium and calcium adhere to the cathode member, resulting in inefficiency of water electrolysis.

The scale preventing members 210 and 220 have a communicating portion that communicates with the lateral opening of the electrolytic member 100, and a plurality of diaphragms 213 and 223 are provided in the communicating portion. And at least one antifogging agent 211 is inserted into each of the spaces defined by the diaphragms 213 and 223.

Inner packing members 313 and 323 for preventing water leakage are inserted between the electrolytic member 100 and the scuff preventing members 210 and 220. The inner packing members 313 and 323 are made of a material such as rubber and can be inserted into the inner packing members 313 and 323 by forming grooves or the like in the frame of the electrolytic member 110 and the waterproofing members 210 and 220. The groove may be provided only on one side of the electrolytic member 110 or the scratch prevention members 210 and 220. The shape of the grooves can be variously formed, such as square and circular.

The gas discharging members 510 and 520 have communicating portions communicating with the lateral openings of the scuff preventing members 210 and 220, and the communicating portion has a single or multiple spaces for accommodating the gas. The gas exhaust member 520 has a gas exhaust port 521 for exhausting gas, and the gas exhaust port 521 communicates with one or more spaces. The gas outlet 521 may have a plurality of gas outlets 521.

Outer packing members 310 and 320 are inserted between the gas discharging members 510 and 520 and the scale preventing members 210 and 220 to prevent water leakage. The outer packing members 310 and 320 are also made of rubber or the like, and the gas discharge members 510 and 520 and the waterproofing members 210 and 220 may have recesses or the like formed therein and inserted therein. The groove may be provided only on one side of the gas discharge members (510, 520) or the scratch prevention members (210, 220). The shape of the grooves can be variously formed, such as square and circular.

The water shut-off diaphragms 410 and 420 are, for example, 'ion dry diaphragms' coupled between the gas venting members 510 and 520 and the antiscattering members 210 and 220, When the gas generated in the electrolytic member 100 moves to the scratch prevention members 210 and 220, the gas is passed in the direction of the gas exhaust members 510 and 520.

The water shut-off diaphragms 410 and 420 can be configured to select a gas to be passed through. If a material blocking the movement of the hydrogen gas is used, the hydrogen gas is left in the electrolytic member 100 and the waterproofing members 210 and 220 , And as a result, water discharged through the outlet 113 becomes hydrogen containing a large amount of hydrogen.

1C is a cross-sectional view of the antiscaling electrolyzer according to the present invention.

As shown in FIG. 1C, on the opposed surfaces of the electrolytic member 100 and the antiscattering members 210 and 220, the protrusions R1 and P1 are positioned more toward the communicating portion than the positions of the inner packing members 313 and 323, , R2 and P2, respectively. When the electrolytic member 100 and the watertight members 210 and 220 are coupled to each other, the opposing faces of the electrolytic member 100 and the watertight members 210 and 220 are formed by the irregularities R1, P1, R2, So as to block the leakage of water therein. By doing so, it is possible to prevent the water in the inside thereof from touching the inner packing members 313, 323.

The protrusions R3, P3, R4, and P4, which are positioned more toward the communicating portion than the positions of the outer packing members 310 and 320, are formed on the opposite surfaces of the scuff preventing members 210 and 220 and the gas discharging members 510 and 520, Respectively. When the gas discharge members 510 and 520 and the waterproofing members 210 and 220 are coupled to each other, the waterproofing members 210 and 220 and the gas discharge members 510 and 520 are opposed to each other by the irregularities R 3, P 3, R 4, and P 4, Is firstly closed to block leakage therein. By doing so, it is possible to prevent the water in the inside thereof from touching the outer packing members 310 and 320. Here, the water blocking diaphragms 410 and 420 may be extended to the outer packing members 310 and 320, and extended to only the protrusions R3, P3, R4, and P4.

Although the concave and convex portions R1 to R4 and P1 to P4 are shown in a rectangular shape in FIG. 1C, the shapes of the concave and convex portions R1 to R4 and P1 to P4 can be variously configured as triangular, circular, and the like.

FIGS. 2A and 2B are a perspective view and a cross-sectional view of a watertight electrolytic cell according to the present invention, in which an electrolytic member and a watertight prevention member are integrally formed.

As shown in FIGS. 2A and 2B, the electrolytic bath of the present invention can integrally form the electrolytic member 100 and the scratch prevention members 210 and 220. In this case, there is no need for an inner packing member for sealing the electrolytic member 100 and the scale preventing members 210 and 220.

The electrolytic baths of FIGS. 2A and 2B are the same as the electrolytic baths of FIGS. 1A, 1B, and 1C in the rest of the configuration, and therefore the detailed description of the same components will be omitted from the explanation of the components described in FIGS. 1A, 1B and 1C.

Figs. 3A and 3B are perspective views and cross-sectional views of another embodiment of the antiscaling electrolytic cell according to the present invention, in which the antiscattering member and the gas discharging member are integrally formed. Fig.

As shown in FIGS. 3A and 3B, the electrolytic bath of the present invention may include the scrubbing preventing members 210 and 220 and the gas discharging members 510 and 520 integrally. In this case, there is no need for an outer packing member for sealing the scuff preventing members 210, 220 and the gas discharging members 510, 520. However, the water shut-off diaphragms 410 and 420 are provided in the form of being integrated into the water shut-off diaphragms 210 and 220 and the gas exhaust members 510 and 520 when they are integrally formed.

The electrolytic baths of FIGS. 3A and 3B are the same as the electrolytic baths of FIGS. 1A, 1B, and 1C in the rest of the configuration, and therefore the detailed description of the same components is omitted from the explanation of each component described in FIGS. 1A, 1B and 1C.

While the invention has been described in terms of several embodiments, it is to be understood that the invention is not limited thereto. Those skilled in the art will appreciate that various modifications and changes may be made based on this embodiment. Accordingly, the scope of the present invention should be determined by the following claims, and variations and modifications made by those skilled in the art can be construed as being included in the scope of the present invention.

100: electrolytic member 210, 220:
310, 320, 313, 323: packing member 410, 420:
510, 520: gas discharging member 511, 521: gas discharging port
R1 to R4, P1 to P4: concave and convex portions

Claims (7)

In the electrolytic bath,
An anode member and an anode member separated into an insulating diaphragm inside the frame; an inlet for supplying water to the inside of one side of the frame; An electrolytic member provided with an outlet through which water flows out to the outside, the electrolytic member electrolyzing water;
A water blocking member having a first communicating portion communicating with an opening of the electrolytic member and containing an antiscaling agent in the first communicating portion;
A gas discharging member having a second communicating portion communicating with the first communicating portion of the water blocking member and having a gas discharging port communicating with the second communicating portion;
And a water shut-off diaphragm coupled between the first communicating portion of the scrubbing prevention member and the second communicating portion of the gas discharging member and blocking water movement from the first communicating portion to the second communicating portion and allowing gas movement Wherein the electrolytic cell is a water-proof electrolytic cell. The method according to claim 1,
And a packing member coupled to a surface of the electrolytic member facing the edge of the watertight prevention member and a surface of the watertight prevention member facing the edge of the gas discharge member,
Wherein the electrolytic member and the watertight prevention member, and the watertight prevention member and the gas discharge member have a concave-convex portion that is positioned more toward the communication portion than the packing member on the edge-
And an outer edge of the water shut-off diaphragm extends to the concavo-convex portion of the watertight prevention member and the gas discharge member. 3. The method of claim 2,
And an outer edge of the water blocking diaphragm extends to the packing member of the gas discharge member and the gas discharge member. The method according to claim 1,
Wherein the electrolytic member and the watertight prevention member are integrally formed,
And a packing member coupled to an edge-facing surface of the stacking prevention member and the gas discharging member,
Wherein the waterproofing member and the gas discharging member are provided with a concavo-convex portion that is positioned more toward the communicating portion than the packing member,
Wherein an outer edge of the water-blocking diaphragm is extended to at least the uneven portion. The method according to claim 1,
Wherein the waterproofing member and the gas discharging member are integrally formed through a water blocking diaphragm,
And a packing member coupled to an edge-opposing surface of the electrolytic member and the water-blocking member,
Wherein the electrolytic member and the watertight prevention member are provided with a concavo-convex portion that is positioned more shifted toward the communicating portion than the packing member. 6. The method according to any one of claims 1 to 5,
Wherein the water blocking member has a plurality of partition walls that surround the anti-fogging agent in the first communication portion. 6. The method according to any one of claims 1 to 5,
Wherein said water shut-off diaphragm blocks the movement of hydrogen gas.

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