KR101159306B1 - Electrode structure - Google Patents

Abstract

The present invention is a flat electrode plate; The electrode plate is disposed in plural numbers, spaced apart from each other by insulating washers disposed between the electrode plate and the electrode plate, and fastened by an insulating fastening member inserted into a coupling hole formed in the electrode plate. A plurality of holes are formed in the electrode plate, and the anode of the electrode plate relates to an electrode structure in which platinum (Pt) is plated on a titanium (Ti) substrate. And since the oxygen bubbles can be easily separated from the electrode plate, there is no portion such as a conventional protrusion on the surface of the electrode plate, to minimize the volume when forming the electrode plate assembly by disposing the electrode plate and the other electrode plate spaced apart It is possible to maintain the concentration of the electrolyte even when used for a long time, it is possible to reduce the short phenomenon between the electrodes due to impurities.

Description

Electrode structure

The present invention relates to an electrode structure used in a system for electrolyzing water to generate hydrogen bubbles and oxygen bubbles.

Korean Patent Publication No. 2007-73655 (hereinafter, referred to as a conventional technology) generates an oxygen / hydrogen mixed gas to increase the amount of oxygen / hydrogen mixed gas generated by increasing the contact area with the electrolyte and the amount of electricity passing therethrough. Electrode plates to be installed in the apparatus are known.

As illustrated in FIG. 3, the electrode plate 32 of the prior art has a plurality of protrusion pieces 38 punched on three surfaces except for one surface thereof, and the protrusion pieces 38. Is bent inclined toward one side, the through hole 40 is formed in the electrode plate 32 as much as the size of the protruding piece 38 is formed.

However, the protruding piece 38 protrudes from the electrode plate 32 of the prior art, and the hydrogen / oxygen gas generated from the electrode plate 32 when the water is electrolyzed touches the protruding piece 38. It was not easily detached from (23).

Therefore, hydrogen / oxygen gas is trapped in the electrode plate 32, so that the resistance of the electrode plate 32 becomes large, so that excessive current is required when current flows through the electrode plate 32, and excessive heat is generated. It was.

As a result, corrosion of the electrode plate 32 is actively progressed, which shortens its lifespan, and consumes a large amount of current, thereby wasting energy.

In addition, when the electrode plate 32 and the other electrode plate 32 are disposed to form an electrode plate assembly, the gap between the electrode plate 32 and the other electrode plate 32 is reduced by the protruding pieces 38. Since it was not possible, there was a problem that the volume of the electrode plate assembly was increased.

Further, when the distance between the electrode plate 32 and the other electrode plate 32 in the electrode plate assembly is far, a higher voltage is required, there is a problem that the amount of electricity consumed accordingly increases.

An object of the present invention is to allow the hydrogen bubbles and oxygen bubbles generated in the electrode plate to be easily separated from the electrode plate.

In addition, there is another object to minimize the volume of the electrode plate assembly in which the electrode plate and the other electrode plate is spaced apart.

In addition, there is another purpose to maintain the concentration of the electrolyte even in long time use and to reduce the short phenomenon between the electrodes due to impurities.

The electrode structure of the present invention for achieving the above object is a flat electrode plate; The electrode plate is disposed in plural numbers, spaced apart from each other by insulating washers disposed between the electrode plate and the electrode plate, and fastened by an insulating fastening member inserted into a coupling hole formed in the electrode plate. A plurality of holes are formed in the anode, and the anode of the electrode plate is an electrode in which platinum (Pt) is plated on a titanium (Ti) substrate.

With such a configuration, it is possible to easily escape the hydrogen bubbles and oxygen bubbles generated in the electrode plate from the electrode plate by the through holes during the electrolysis of water.

In addition, since there is no portion like the conventional protrusion on the surface of the electrode plate, it is possible to minimize the volume when forming the electrode plate assembly by separating the electrode plate and the other electrode plate.

In addition, in the electrode structure of the present invention, a chamfer is formed on one side of the electrode plate.

By such a configuration, the (+) terminal can be connected to a plurality of (+) electrode plate of the electrode plate assembly at the same time by the bolt and nut of the conductor material, and the (-) terminal can also be connected in the same way.

Further, in the electrode structure of the present invention, the cathode of the electrode plate is an electrode which is stainless steel.

As described above, the electrode structure of the present invention has the following advantages.

1) By electroporation formed in the electrode plate during the electrolysis of water, hydrogen bubbles and oxygen bubbles generated in the electrode plate can be easily separated from the electrode plate.

Therefore, since the resistance of the electrode plate can be reduced, excessive current does not flow to the electrode plate, so that loss of electrical energy can be reduced, and heat generation can be significantly lowered than that of the conventional electrode plate, resulting in excessive heat generation. Corrosion of the electrode plate due to can be prevented.

2) The electrode structure of this invention does not have a part like the conventional protrusion on the surface of the electrode plate 100.

Therefore, when configuring the electrode plate assembly by separating the electrode plate and the other electrode plate, since the distance between the electrode plate and the electrode plate can be adjusted at an appropriate interval, the volume can be minimized, so that the installation area of the electrode plate assembly and Therefore, the electric energy consumed can be reduced.

3) The (+) terminal can be connected to multiple (+) electrode plates of the electrode plate assembly at the same time with the bolt and nut of the conductor material, and the (-) terminal can also be connected in the same way.

4) The electrode plate of the present invention is composed of a (+) electrode plate of platinum (Pt) plated on a titanium (Ti) substrate and a (-) electrode plate of stainless steel, it is possible to maintain the concentration of the electrolyte even in a long time use, Short phenomenon between electrodes due to impurities can be reduced.

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

For reference, among the configurations of the present invention to be described below, the same configuration as the prior art will be referred to the above-described prior art, and a detailed description thereof will be omitted.

As shown in FIG. 1, in the electrode structure of the present invention, a plurality of flat rectangular plate-shaped electrode plates are disposed, and the electrode plate is an insulating washer disposed between the electrode plate 100a and the electrode plate 100b. Spaced apart from each other by 110, and fastened by an insulating fastening member 130 inserted into the coupling holes 120, 120 'formed in the electrode plates (100a, 100b), the electrode plate (100a) A plurality of through holes 140 are formed in the 100b.

At this time, the electrode plate 100a is a (+) electrode plate electrically connected to the (+) terminal 242, the electrode plate 100b is a (-) electrode plate electrically connected to the (-) terminal 252 to be.

The material of the electrode plate 100a is a (+) electrode plate in which platinum (Pt) is plated on a titanium (Ti) substrate, and the electrode plate 100b is made of a (-) electrode plate of stainless steel. Titanium (Ti) of the (+) electrode plate has a relatively low ionization tendency compared to conventional stainless steel composed of iron (Fe), chromium (Cr), and nickel (Ni), and thus less impurities are generated in the electrolyte. Therefore, it is possible to maintain the concentration of the electrolyte even when used for a long time, it is possible to reduce the short phenomenon between the electrodes due to impurities.

The insulating washer 110 and the insulating fastening member 130 may be made of rubber or plastic.

On the other hand, on one side of the electrode plate (100a) and the electrode plate (100b), chamfers (150, 150 ') chamfered both edges of the one side is formed, the outer edges of both ends of the other side Coupling holes 160 and 160 ′ to which the positive (+) (−) terminals 242 and 252 are connected are formed.

The electrode plate 100a and the electrode plate 100b are stacked in such a manner as to be divided in turn, and the insulating washer 110 is sandwiched between the electrode plate 100a and the electrode plate 100b to form a coupling hole 120 ( 120 ') and inserts the bolt 130a of the insulating fastening member 130, and then tightens the nut 130b to the ends of the electrode plate 100a and the electrode plate 100b into which the bolt 130a is inserted. The plate assembly 100 is configured.

In this case, the interval between the electrode plate 100a and the electrode plate 100b may be adjusted according to the size of the insulating washer 110.

That is, when the size of the insulating washer 100 is large, the distance between the electrode plate 100a and the electrode plate 100b is increased, so that the volume of the electrode plate assembly 100 is increased, and when the size of the insulating washer 100 is small, the electrode plate ( The spacing between the electrode plate assembly 100 and the electrode plate 100b is reduced, so that the volume of the electrode plate assembly 100 is relatively small.

Meanwhile, the direction in which the chamfer 150 is formed in the electrode plate 100a and the direction in which the coupling hole 160 ′ is formed in the electrode plate 100b are arranged in the same direction among the electrode plate assembly 100. It is preferable to make it.

Then, the coupling hole 160 of the (+) electrode plate 100a positioned at the top of the electrode plate assembly 100 and the coupling hole 241 formed in the (+) terminal 242 communicate with each other, and then the bolt The positive terminal 242 is electrically connected to the plurality of positive electrode plates 100a by inserting the 161a into the coupling holes 160 and 241 to fasten the nut 161b. You can.

Similarly, after the coupling hole 160 'of the negative electrode plate 100b positioned at the bottom of the electrode plate assembly 100 and the coupling hole 251 formed at the (-) terminal 252 are in communication with each other, The (-) terminal 252 is electrically connected to the plurality of (-) electrode plates 100b by inserting a bolt 161a 'into the coupling holes 160' and 251 to fasten the nut 161b '. Can be connected to connect.

At this time, the bolts (161a) (161a ') and the nuts (161b) (161b') are made of a conductor material.

Due to this configuration, in the electrode plate assembly 100 in which a plurality of (+) electrode plates 100a and (-) electrode plates 100b are stacked, the (+) terminal 242 is connected to the (-) electrode plate ( It may be connected to a plurality of (+) electrode plate 100a in a state of not contacting 100b), and the (-) terminal 252 is a plurality of (-) electrode plate in a state of not touching the (+) electrode plate 100a. Since it can be connected to the (100b), it is possible to prevent the (+) electrode plate 100a and the (-) electrode plate (100b) is in contact with each other to become a short.

As described above, in the electrolysis of water, the electrode structure of the present invention includes hydrogen bubbles and oxygen bubbles generated in the electrode plates 100a and 100b by the through holes 140 formed in the electrode plates 100a and 100b. It can be easily separated from the electrode plate (100a) (100b), it can smoothly cause convection of water.

Therefore, since the resistance of the electrode plates 100a and 100b can be reduced, excessive current does not flow into the electrode plates 100a and 100b, thereby reducing the loss of electrical energy consumed in an electrochemical reaction. Since heat generation can be significantly lowered than the conventional electrode plate, corrosion of the electrode plates 100a and 100b due to excessive heat generation can be prevented, and wear of the electrode plates 100a and 100b can be minimized. Can be.

In addition, the electrode structure of this invention does not have a part like the conventional protrusion on the surface of electrode plate 100a, 100b.

Therefore, when the electrode plate assembly 100 is formed by spaced apart from the electrode plate 100a and the other electrode plate 100b, the interval between the electrode plate 100a and the electrode plate 100b can be adjusted at an appropriate interval. Since the volume can be minimized, the installation area of the electrode plate assembly 100 and the electric energy consumed accordingly can be reduced.

On the other hand, in the electrode structure of the present invention, the diameter of the through-hole 140 formed in the electrode plate (100a) (100b) is 10mm, the height of the insulating washer 110 is 2mm, but the generation of hydrogen bubbles and oxygen bubbles, hydrogen The size and number of the electrode plates 100a, 100b, the through hole 140, and the insulating washer 110 may be changed in order to optimally raise the bubbles and oxygen bubbles.

Hereinafter, the electrolysis process of water using the electrode structure of the present invention having the above configuration will be described.

As shown in FIG. 2, an electrolytic cell is provided inside the electrolysis device 200, in which water is accommodated in the electrolytic cell and an electrode plate assembly 100 is installed.

Thereafter, the (+) terminal 242 is connected to the (+) terminal connecting portion 240 formed on one side of the electrolytic apparatus 200 to externally the (+) electrode plate 100a of the electrode plate assembly 100. A power source (not shown) is conducted and an external power source is connected to the (-) electrode plate 100b of the electrode plate assembly 100 by connecting the (-) terminal 252 to the (-) terminal connection part 250. do.

Then, when power is applied from the outside, current flows through the positive electrode assembly 242 and 252 to the electrode plate assembly 100, and hydrogen and oxygen bubbles are generated in the water contained in the electrolytic cell. The generated hydrogen bubbles and oxygen bubbles are discharged through an outlet 280 installed to communicate the internal space and the external space of the electrolytic cell.

As mentioned above, the temperature of the electrolyzed water rises.

The water is delivered to the cooling fan 220 by the pump 210 provided outside the electrolysis device 200 and cooled, and the cooled water is filtered through the filter 230 and again the electrolysis device 200. It is supplied to the electrolyzer inside.

On the other hand, the electrolysis device 200 has a liquid supply unit 260 for supplying a liquid such as water, a liquid discharge unit 270 for discharging the liquid, and the user to operate under the set pressure by adjusting the pressure An adjustable relief valve 290 may be additionally provided.

As described above, although described with reference to a preferred embodiment of the present invention, those skilled in the art various modifications or variations of the present invention without departing from the spirit and scope of the invention described in the claims below Can be carried out.

The present invention can be widely applied to industrial and medical fields using oxygen and hydrogen, environmentally friendly energy, and automobiles.

1 is an exploded perspective view of the electrode structure of the present invention.

2 is a view showing a state in which the electrode structure of the present invention is applied to an electrolysis device.

3 is a view showing an electrode plate of the prior art.

<Explanation of symbols for the main parts of the drawings>

100: electrode plate assembly 110: insulating washer 120: bonding hole

130: fastening member 140: through hole 150: chamfer

160: coupling hole 200: electrolysis device

Claims (3)

Flat electrode plate The electrode plate is disposed in plurality, The (+) electrode plate electrically connected to the (+) terminal and the (-) electrode plate electrically connected to the (-) terminal are arranged in order so as to be distinguished in order. Spaced apart from each other by insulating washers disposed between the (+) electrode plate and the (-) electrode plate, The (+) electrode plate is plated with platinum on a titanium (Ti) substrate, Fastened by an insulating fastening member inserted into a first coupling hole formed in each of the electrode plates, Each electrode plate is formed with a plurality of through holes, A chamfer is formed at one side of each electrode plate, and a second coupling hole is formed at both edges of the other side of each electrode plate to connect (+) (-) terminals for conducting external power. And the direction in which the chamfer is formed in the (+) electrode plate and the direction in which the second coupling hole is formed in the (-) electrode plate are arranged in the same direction. delete The method of claim 1, The electrode structure of the electrode plate is stainless steel.

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