KR101176282B1 - Apparatus for Cooling Electrolyzer carbon - Google Patents

Abstract

The present invention relates to a carbon electrolytic cell in which a cooling device is installed, and oxygen generated in an electrolytic cell on a bottom surface of an electrolytic cell cover having a plurality of carbon electrode plates having low thermal conductivity at regular intervals installed inside the electrolytic cell at regular intervals, and the upper opening of the electrolytic cell being closed. A plurality of gas collecting paths are formed to easily and easily collect hydrogen gas (brown gas), and a plurality of electrolytic water moving paths are formed at the bottom of an electrolytic cell in which a plurality of carbon electrode plates are installed, so that supplemental water can be uniformly supplied into the electrolytic cell. The cooler is installed on one side of the electrolytic cell, and the cooler is configured to allow cooling water to circulate inside the electrolytic cell by passing through a plurality of carbon electrode plates inside the electrolytic cell by connecting a cooling pipe. Oxygen. It prevents the generation of high heat when hydrogen gas is generated by circulating the cooling water in the cooling pipe, and by installing a large number of carbon electrode plates instead of copper metal electrode plates, it prevents the electrode plate from thinning by electrolysis. There is no need to replace the electrode plate, and relates to a carbon electrolytic cell having a cooling device in which the surface of the electrode plate is not dissolved so that no suspended matter is generated.

Description

Apparatus for Cooling Electrolyzer carbon

The present invention relates to a carbon electrolytic cell in which a cooling device is installed. More specifically, the surface of the electrode plate in the electrolysis process is provided when electricity is applied, such as a copper electrode plate during electrolysis, by installing the electrode plate installed in the electrolytic cell as a carbon electrode plate. Electrolyte in the electrolytic cell by circulating cooling water or refrigerant by installing a cooling pipe that penetrates the carbon electrode plate in the electrolytic cell to minimize the melting and the increase of the temperature and to increase the temperature when water generates a large amount of gas by electrolysis. Cools (water) to prevent the temperature from rising, increasing the efficiency of electrolysis, extending the life and providing good quality oxygen. The present invention relates to a carbon electrolytic cell having a cooling device capable of producing hydrogen mixed gas and supplying green energy for household and industrial use.

Conventional electrolyzers use a metal electrode plate made of copper, so that the surface is dissolved during electrolysis and the electrode plate becomes thinner with time, so that the electrode plate needs to be replaced at regular intervals. In the process of dissolving the electrode plate, the electrolytic water becomes turbid and the dissolved material adheres to the surface of the electrode plate, thereby lowering the electrolytic efficiency, and heat is generated during the electrolysis process, thereby promoting oxidation of the copper electrode plate.

In addition, referring to FIG. 1, which is a prior art in this field, Patent Publication No. 2009-0030555 (Prior Art) is an electrolytic cell for generating Brown's Gas using a forced circulation water-cooling cooling system Brown's Gas generator electrolyte;

An electrolyte circulation pump circulating the electrolyte of the electrolytic cell to the outside;

A water separator (Brown 水 分離 器) separating the Brown's Gas contained in the electrolyte circulated to the outside; And a heat exchanger for cooling the water separated electrolyte in a water-cooled manner. A forced circulation water-cooling cooling system Brown's Gas generator is disclosed. Since the prior art has to circulate the electrolyte to the outside to cool the electrolytic cell, a large amount of electrolyte is circulated to the outside in the process of electrolysis by the electrode plate, so a problem arises in the collection of a separate technology separator to solve this problem. However, the gas of the electrolyzer is the gas generated in the process of electrolysis in the electrode plate and the generated gas is raised to the upper portion is collected in the upper space in the electrolytic cell is most preferably stored in a pressure tank through a separate tube Do. However, since gas is generated and heat is generated in the electrolytic process, the prior art has a problem in that the electrolytic solution is circulated to the outside to cool, thereby reducing the efficiency of electrolysis and installing a separate pipe to the outside of the electrolytic cell.

The present invention is to solve the above problems, by forming the electrode plate in the electrolytic cell with a low thermal conductivity carbon electrode plate, to minimize the generation of heat during electrolysis to prevent the surface of the electrode plate is dissolved, the cooling pipe in the electrolytic cell By circulating the cooling water by installing the circulating coolant, it cools the inside of the electrolytic cell without moving the electrolyte, minimizing heat generation, thereby improving gas generation efficiency and extending the life of the electrode plate, and there is no need to replace the electrode plate. It aims to provide environmentally friendly green energy that is easy and does not cause environmental pollution.

The present invention is to install a plurality of carbon electrode plate inside the electrolytic cell and to install a circulating cooling pipe through it to prevent the melting and heat generation of the electrode plate generated in the electrolytic process,

Oxygen generated in the electrolytic cell on the bottom of the electrolytic cell cover which is installed in the electrolytic cell at a plurality of carbon electrode plates at regular intervals and closed to the upper part of the electrolytic cell. A plurality of gas collecting paths are formed to easily and easily collect hydrogen gas (brown gas), and a plurality of electrolytic water moving paths are formed at the bottom of an electrolytic cell in which a plurality of carbon electrode plates are installed, so that supplemental water can be uniformly supplied into the electrolytic cell. A cooler is installed at one side of the electrolysis tank, and the cooler is connected to the cooling pipe and penetrates the plurality of carbon electrode plates in the electrolytic cell so that the coolant or the coolant in the cooling pipe can circulate inside the electrolytic cell.

The present invention configured as described above is caused by the electrolysis of oxygen. It prevents the generation of high heat when hydrogen gas is generated by circulating the cooling water in the cooling pipe, and by installing a plurality of carbon electrode plates instead of copper metal electrode plates, it prevents the electrode plate from thinning during electrolysis. There is no need to replace the electrode plate, and it is possible to provide a carbon electrolytic cell having a cooling device in which the surface of the electrode plate does not dissolve and no float is generated.

The present invention first, by using the electrode plate installed in the electrolytic cell as a carbon electrode plate electrolysis occurs in the electrolytic cell oxygen. When hydrogen gas is generated, there is an effect of preventing the generation of high heat,

Second, since dissolution does not occur on the surface of the carbon electrode plate during electrolysis, the electrode plate is prevented from thinning, so it is not necessary to replace the electrode plate regularly, and thus the management is easy.

Third, since the surface of the electrode plate is not dissolved, floating matter is generated during electrolysis, and thus it is attached to the surface of the electrode plate, thereby preventing the electrolytic efficiency from dropping.

Fourth, the present invention has the effect of producing high-quality power-producing fuels such as boilers, oxygen welding torch, heating fuel, internal combustion engine fuel, cooking fuel, vehicles, trains, ships used in homes and industrial sites at low cost. Has,

Fifth, oxygen generated while minimizing energy consumption by using water other than electrical energy to operate the electrolyzer. By using hydrogen gas as green energy, it has the effect of providing environmentally friendly business without environmental pollution.

1 is an illustration of an electrolytic cell that is cooled by circulating the electrolyte to the outside as a conventional electrolytic cell.
Figure 2 is a cross-sectional view of the cooling pipe is installed in a plurality of carbon electrode plate as an embodiment of the present invention to cool the electrolytic cell.
Figure 3 is a perspective view showing the external configuration of the electrolytic cell of the present invention.
Figure 4 is a left side view showing a state in which a cooling pipe exposed to one side of the electrolytic cell of the present invention is connected to the cooler.
Figure 5 is a right side view showing the connection to expose the cooling pipe to the other side of the electrolytic cell of the present invention.
Figure 6 is an excerpt of the present invention showing a state in which the carbon electrode plate installed in the electrolytic cell of the present invention and the outer surface is insulated coated cooling pipe is connected.
Figure 7a is an exemplary view showing a state in which the cooling pipe of the present invention is inserted through the insulating packing and connected to the carbon electrode plate.
Figure 7b is a cross-sectional view showing the insulation packing fitted to the outer surface of the cooling pipe of the present invention.
8 is a cross-sectional view showing a state in which a cooling pipe fitted to a hollow bolt welded to the left wall of the electrolytic cell as an embodiment of the present invention is coupled to the coupling member.

Hereinafter, an embodiment of the present invention will be described in detail.

Electrode plates and a plurality of electrode plates installed at regular intervals in the electrolytic cell are equipped with electrode terminals on the top to allow electrolysis by electricity, and the terminals thereof can be connected to + and-electricity, and oxygen hydrogen generated inside the electrolytic cell. In the electrolytic cell in which the gas discharge tube is installed to discharge the gas,

An electrolytic cell 10 having a plurality of fixing members 11 having fitting grooves on both inner walls thereof, and having an electrolytic water movement path 12 formed at the bottom thereof so that the water level is uniform in the bottom;

A plurality of carbon electrode plates 13 fitted to the plurality of fixing members 11 installed on the inner wall of the electrolytic cell 10;

A cooling pipe 14 connected to a cooler installed at one side of the electrolytic cell through a carbon electrode plate to circulate and cool the inside of the electrolytic cell;

An insulating coating 15 coated on an outer surface of the cooling pipe 14 passing through the plurality of carbon electrode plates 13 and insulated from electricity;

An insulation packing (16) inserted between the carbon electrode plate (13) through which the cooling pipe (14) passes and the cooling pipe (14) to maintain watertightness and to insulate the water;

An electrolytic cell cover 19 installed to cover the upper end of the electrolytic cell 10 and having a plurality of gas collecting paths 18 zigzag at a bottom thereof;

A supplementary water supply pipe 20 disposed to be connected to a supplementary water tank provided at a lower end thereof so as to be close to the bottom of the electrolyzer 10 and having an upper portion penetrating the electrolyzer cover 19;

A gas outlet pipe 21 having a lower end disposed in the gas collecting passage 18 and connected to a gas compression tank separately provided at one side through the electrolytic cell cover;

In order to prevent the overflow of the electrolytic water, the electrolytic water overflow prevention valve 22 is installed on one side of the upper side of the electrolytic cell, characterized by the configuration of the electrolytic cell.

Insulated packing, which is inserted into the outer surface of the cooling pipe 14 to maintain watertightness and insulation between the carbon electrode plate 13 and the cooling pipe 14, is formed with an annular ring 17 having a thicker edge portion at both sides than the body of the packing. It features.

The insulating coating 15 coated on the outer surface of the cooling pipe 14 is characterized in that the outer surface is coated by any one of an insulating tape, insulating paint, PP, PE, PVC, rubber tube.

The electrolytic cell is to bond the cooling pipe 14 to the coupling member 24 by welding the hollow bolt 23 to the through part of the wall of the electrolytic cell to fix the cooling pipe 14 to the U-turn so that the coolant can be circulated therein. It is characterized by.

In addition, the electrolytic cell of the present invention is provided with a conventional thermometer, pressure gauge, water level sensor, gas safety valve and the like to display the temperature and gas pressure inside the electrolytic cell on the cover.

In addition, one side of the upper end of the carbon electrode plate so that the power connection terminal protrudes to the top of the electrolytic cell cover to connect the power from the outside, the connection of the power is connected in the form of a normal electrical connector.

The present invention configured as described above will be described in detail with reference to the accompanying drawings.

2 is a cross-sectional view illustrating a configuration of an electrolysis tank in which cooling pipes are installed on a plurality of carbon electrode plates to cool the electrolytic cell as an embodiment of the present invention, and a fixing member having fitting grooves on both side walls of the electrolytic cell body. We install a lot of (11).

The fixing member 11 is made of a material made of an insulating material, and the fitting groove is formed to have a size to which the carbon electrode plate 13 is fitted.

When the fixing member 11 is installed as described above, the carbon electrode plate 13 is installed through the fitting grooves of the fixing member 11 and the fixing member 11 on both sides.

The carbon electrode plate 13 installed on the fixing member 11 is installed so that the cover 19 of the electrolytic cell can be opened and drawn out through the top.

The thickness of the plurality of carbon electrode plates 13 inserted into the fixing member 11 and installed inside the electrolytic cell is determined according to the size of the electrolytic cell, the spacing, and the electrolytic capacity.

 Insertion groove size of the carbon electrode plate 13 of the fixing member 11 is formed during manufacturing to correspond to the thickness of the carbon electrode plate 13, the gap between the carbon electrode plate 13 and the carbon electrode plate 13 is The distance at which decomposition occurs is provided at regular intervals, and the distance for electrolysis may be installed in the same manner as that of a conventional electrolytic cell, but the interval may be adjusted according to the size of the electrolytic cell and the thickness of the carbon electrode plate.

In addition, the carbon electrode plate installed inside the electrolytic cell may be installed in two or more dozens depending on the size and capacity of the electrolytic cell.

Since the heat is generated in the process of electrolysis during operation in the electrolytic cell is installed a plurality of cooling pipes 14 for cooling it.

In the present invention, the cooling pipe 14 is installed to circulate in the electrolytic cell in order to increase the cooling efficiency of the cooling device installed inside the electrolytic cell.

The cooling pipe forms an insulating coating 15 with an insulating coating on the outer surface to prevent electricity from being transferred through the cooling pipe 14 during electrolysis by the carbon electrode plate 13.

The insulating coating 15 installed on the outer surface of the cooling pipe 14 may be coated with a coating using an insulating paint, or the insulating tape may be taped to the outer surface of the cooling pipe to form an insulating coating.

In addition, the insulating coating may form an insulating coating 15 by sandwiching a rubber tube or a soft synthetic resin tube on the outer surface of the cooling pipe 14.

The cooling pipe 14 installed to be circulated is installed to circulate through the carbon electrode plate, and the insulating packing 16 is installed in the through hole of the carbon electrode plate 13 through which the cooling pipe 14 passes to maintain watertightness. At the same time, it is installed to insulate.

In addition, both ends of the cooling pipe 14 installed in the electrolytic cell are exposed to one side and connected to the cooler 30 installed at one side of the electrolytic cell, and the cooler 30 is configured to circulate the coolant or the refrigerant through the cooling pipe 14. do. The cooler 30 is a conventional cooler and is configured to cool the circulated cooling water by installing an evaporator and a compressor therein.

The upper part of the electrolyzer in which the plurality of carbon electrode plates and the cooling pipes 14 are installed is covered with an electrolyzer cover 19 and fastened to the edge by bolts, and a packing is installed between the electrolyzer cover and the top of the body of the electrolyzer body. Do not leak gas from the outside.

The packing installed between the upper end of the electrolyzer and the electrolyzer cover 19 uses a conventional packing.

In addition, a plurality of gas collecting passages 18 are formed in the bottom surface of the electrolytic cell cover 19 in a zigzag manner, so that oxygen and hydrogen gas generated in the carbon electrode plate of the electrolytic cell are raised to the upper portion, and the gas discharge pipes are formed through the gas collecting passages 18. Discharged to (21).

A plurality of gas collecting passages 18 formed on the bottom surface of the electrolytic cell cover 19 are formed so as to be connected between each carbon electrode plate and the upper end of the carbon electrode plate so that the gas generated in the electrolytic cell passes through the gas collecting passage 18. The discharge pipe 21 is discharged.

Figure 3 is a perspective view showing the external configuration of the electrolytic cell of the present invention, a plurality of citron tube on the left side of the electrolytic cell consisting of a rectangular hexahedron is connected to the cooling pipe installed inside the electrolytic cell to allow the cooling water of the cooling pipe to circulate.

In addition, the terminal of the carbon electrode plate protrudes on the upper part of the electrolytic cell cover so that + and-electricity are connected to each other so that electrolysis occurs.

In the upper part of the electrolytic cell cover of the present invention, the gaseous discharge pipe 21 and the supplementary water supply pipe 20 are installed. In addition, the electrolytic cell may display a temperature and a gas pressure inside the electrolytic cell on the cover. , Water level sensor, gas safety valve, etc. are installed but not shown.

4 is a left side view showing a state in which a cooling pipe exposed to one side of an electrolytic cell is connected to a cooler, and a cooling pipe protruding to the left outer surface of the electrolytic cell is circulated from a lower tube to an upper tube, and both ends of the cooling pipe Make sure to connect with the cooler.

The cooler rotates the cooling water or the cooling catalyst in the cooling pipe to cool down the temperature of the electrolyte in the electrolytic cell.

Figure 5 is a right side view showing a state in which the cooling pipe is connected to the other side of the electrolytic cell of the present invention exposed to the outside, the opposite side of Figure 4 is connected to the cooling pipe circulating the cooling pipe and the cooling pipe by a citron tube to circulate the cooling water. .

6 is an essential part showing the state in which the carbon electrode plate installed inside the electrolytic cell of the present invention and the cooling pipe having an outer surface insulated and coated are connected, and the carbon electrode plate 13 installed inside the electrolytic cell of the present invention has both sides at the center thereof. 6 through holes are formed in each of the three to be installed so that the cooling pipe passes through and the insulating pipe 15 is formed on the outer surface of the cooling pipe to prevent electricity from flowing.

The insulating coating 15 formed on the outer surface of the cooling pipe 14 may form an insulating coating by coating an insulating paint, or may be an insulating coating 15 by taping the insulating tape on the outer surface of the cooling pipe. Alternatively, a rubber tube or a soft synthetic resin tube may be installed to be in close contact with the outer surface of the cooling pipe 14 to form an insulating coating 15.

Figure 6 of the present invention is an exemplary view showing a state in which the cooling pipe is penetrated through the carbon electrode plate, showing that the cooling pipe is penetrated to show that the two cooling pipes are installed on the carbon electrode plate. The carbon electrode plate of the electrolytic cell carried out in is installed so that six cooling pipes pass through each of the three (see FIG. 2).

Figure 7a is an exemplary view showing a state in which the cooling pipe of the present invention is inserted into the insulating packing and penetrated to the carbon electrode plate, Figure 7b is a cross-sectional view showing the insulating packing fitted to the outer surface of the cooling pipe of the present invention, the cooling pipe is penetrated The insulating packing 16 is inserted between the carbon electrode plate and the cooling pipe to maintain the watertight and to be insulated.

The insulating packing is inserted into the outer surface of the cooling pipe to maintain watertightness and insulation between the carbon electrode plate and the cooling pipe, and the edge cross-sections of the packing are formed into an annular ring 17 thicker than the body of the packing.

As described above, both edges of the insulation packing 16 have an annular ring shape that is thicker than the body of the packing. The annular rings on both sides of the annular ring have a cooling pipe and carbon in the state where the carbon electrode plate is sandwiched between the annular rings and the annular rings of the insulation packing. The watertight connection part of the electrode plate can be maintained.

8 is a cross-sectional view showing a state in which a cooling pipe fitted to a hollow bolt welded to the left wall of the electrolytic cell as an embodiment of the present invention is coupled to the coupling member. In installing the cooling pipe to cool the interior of the electrolytic cell of the present invention, the insulating packing 16 is used to seal the carbon electrode plate through which the cooling pipe 14 penetrates and the outer wall connection portion of the electrolytic cell, while simultaneously fixing the cooling pipe. Although it may be used as a means, a separate coupling member may be used to firmly couple the cooling pipe passing through the outer wall of the electrolytic cell and the through part of the outer wall.

First, in order to fasten the cooling pipe using a separate coupling member, a fastening member is installed to fasten the coupling member to the electrolytic cell wall through which the cooling pipe passes.

Preferably, the fastening member uses a hollow bolt, and the hollow bolt is manufactured so that a flange is formed at one side thereof so that the flange side of the hollow bolt is positioned inside and the bolt is inserted to protrude outward from the inner wall of the electrolytic cell through which the cooling pipe passes. Install to expose to the outside.

After inserting the cooling pipe with the hollow bolt installed as described above, if the coupling member is fastened to the hollow bolt, the cooling pipe is fixed. At this time, the hollow bolt 23 and the coupling member 24 is fitted with a packing such as O-ring to maintain the watertight.

In another embodiment of the present invention, as shown in FIG. 8, the hollow bolt may be welded to the outer wall at the position where the cooling pipe of the electrolytic cell penetrates to be integrated with the body, and then the cooling pipe may be fastened to the coupling member 24.

In the description of FIG. 8, the embodiment of the present invention is an example in which the hollow bolt is installed to protrude from the inside of the wall to the outside, and the hollow bolt 23 is externally welded and fixed to the denture through which the cooling pipe of the wall passes. For example, the illustration of FIG. 8 illustrates only one embodiment for convenience.

The electrolyzer of the present invention installed as described above, when water is insufficient during use, the supplemental water supply pipe 20 is opened by the signal of the water level sensor 25 installed at one side so that the water is supplied and the supplied water is the electrolyzer 10. It is introduced into the space between the carbon electrode plate and the carbon electrode plate through the electrolytic water movement path 12 formed on the bottom to maintain the overall level of the electrolytic cell uniformly.

Therefore, the electrolyzed water may be reduced during electrolysis. In this case, the electrolyzed water is replenished through the supplemental water supply pipe 20 from the supplemental water tank (not shown) provided at one side of the electrolytic cell by the detection of the water level sensor 25.

The replenishment water supply pipe 20 has one end connected to the replenishment water tank on one side, and the other end is installed to be close to the inner bottom of the electrolyzed water through the electrolytic water cover 19 to supply replenishing water, but is required. In some cases, the supplementary water supply pipe may be installed on one wall of the electrolyzer.

In addition, the electrolytic water overflow prevention valve 22 (see FIG. 2) is installed at the upper end side of the body of the electrolytic cell 10 of the present invention, and when the water level detection sensor 25 has a failure, the supplementary water is continuously supplied from the supplemental water supply pipe 20. Even if it is to flow into the discharge or replenishment water tank through the electrolytic water overflow prevention valve (22).

Oxygen and hydrogen gas generated by electrolysis in the electrolytic cell are collected to the upper end of the electrolytic cell, and the collected gas is supplied to a gas compression tank or a boiler and a torch through a gas discharge tube 21 installed at one side of the electrolytic cell cover 19. do.

In addition, the pressure and temperature of the gas generated inside the electrolyzer are managed by the gas pressure gauge and the temperature pressure gauge installed on the cover of the electrolyzer, and each gauge uses a conventional one. (Each gauge installed in the present invention has a conventional configuration. Omitted)

In addition, the components installed in the periphery for driving the electrolytic cell of the present invention, the means for attaching and detaching the components, the means for supplying electricity, and the like are the same as the components installed for operating the normal electrolytic cell. Since it is conventional, the illustration and description of the drawings are omitted. Of course, components such as check valves and on-off valves installed in the gas discharge pipe also have the same configuration as the conventional ones, and thus description thereof will be omitted.

When the upper gas discharge pipe is directly connected to the boiler or welding torch, the lower gas discharge pipe of the present invention is installed with a backfire prevention gas inlet pipe to prevent the flame from flowing back and recover the backflowing gas. .

A flashback prevention gas inlet pipe is installed at one side of the lower body of the electrolyzer to directly connect the gas generated in the electrolyzer to the boiler or oxygen welding torch without sending it to the gas compression tank. It is to prevent the backflow, and the reversed gas can be reduced to the inside of the electrolytic cell.

The flashback prevention gas inlet pipe is used that is commonly used in other fields.

According to the present invention as described above, the electrolytic cell having a carbon electrode plate provided with a cooling pipe passing through the inside of the electrolytic cell is electrolyzed in the electrolytic cell, causing oxygen. By applying carbon electrode plate, high heat generation when hydrogen gas is generated can be minimized as compared with the existing metal electrode plate. Especially, electrolytic efficiency is improved by installing cooling pipe to cool the electrolytic water so that cooling water can be circulated on the carbon electrode plate. At the same time, since the melting does not occur on the surface of the carbon electrode plate during electrolysis, it is not necessary to replace the electrode plate regularly by preventing the electrode plate from thinning, and since the electrode plate surface dissolution does not occur, floating matter is generated during electrolysis. It adheres to the surface and prevents the drop in electrolytic efficiency.

Therefore, the present invention can be used as a power generating fuel for boilers, generators, oxygen welding torch, heating fuel, internal combustion engine fuel, cooking fuel, vehicles, trains, ships and the like used in homes and industrial sites.

In particular, the present invention can be used as a power energy of various industrial fields, its energy is environmentally friendly because it does not generate any air pollution when used, there is an advantage that can be provided as a green energy that can be used as alternative energy in the future.

10: Electrolyzer 11: Fixed member
12: electrolytic water path 13: carbon electrode plate
14: cooling pipe 15: insulation coating
16: Insulation packing 17: Round ring
18: Gaspo home 19: Electrolytic tank cover
20: Replenishment water supply pipe 21: Gasoline discharge pipe
22: overflow valve 23: hollow bolt
24: coupling member 25: water level sensor

Claims (4)

Electrode plates and a plurality of electrode plates installed at regular intervals in the electrolytic cell are equipped with electrode terminals on the top to allow electrolysis by electricity, and the terminals thereof can be connected to + and-electricity, and oxygen hydrogen generated inside the electrolytic cell. In the electrolytic cell in which the gas discharge tube is installed to discharge the gas,
An electrolytic cell 10 having a plurality of fixing members 11 having fitting grooves on both inner walls thereof, and having an electrolytic water movement path 12 formed at the bottom thereof so that the water level is uniform in the bottom;
A plurality of carbon electrode plates 13 fitted to the plurality of fixing members 11 installed on the inner wall of the electrolytic cell 10;
A cooling pipe 14 connected to a cooler installed at one side of the electrolytic cell through a carbon electrode plate to circulate and cool the inside of the electrolytic cell;
An insulating coating 15 coated on an outer surface of the cooling pipe 14 passing through the plurality of carbon electrode plates 13 and insulated from electricity;
An insulation packing (16) inserted between the carbon electrode plate (13) through which the cooling pipe (14) passes and the cooling pipe (14) to maintain watertightness and to insulate the water;
An electrolytic cell cover 19 installed to cover the upper end of the electrolytic cell 10 and having a plurality of gas collecting paths 18 zigzag at a bottom thereof;
A supplementary water supply pipe 20 disposed to be connected to a supplementary water tank provided at a lower end thereof so as to be close to the bottom of the electrolyzer 10 and having an upper portion penetrating the electrolyzer cover 19;
A gas outlet pipe 21 having a lower end disposed in the gas collecting passage 18 and connected to a gas compression tank separately provided at one side through the electrolytic cell cover;
Carbon electrolytic cell having a cooling device characterized in that the electrolytic cell overflow prevention valve 22 is installed on one side wall of the electrolytic cell 10 to prevent the overflow of the electrolytic water The method of claim 1, wherein
Insulated packing, which is inserted into the outer surface of the cooling pipe 14 to maintain watertightness and insulation between the carbon electrode plate 13 and the cooling pipe 14, is formed with an annular ring 17 having a thicker edge portion at both sides than the body of the packing. Carbon electrolytic cell having a cooling device characterized in that. The method of claim 1, wherein
Insulating coating (15) coated on the outer surface of the cooling pipe (14) is a carbon electrolytic cell having a cooling device, characterized in that the outer surface is covered by an insulating tape or rubber tube. The method of claim 1, wherein
The electrolytic cell is characterized in that to connect the cooling pipe 14 to the coupling member 23 by welding a hollow bolt to the through part of the wall of the electrolytic cell so as to fix the cooling pipe 14 to the U-turn so that the coolant can be circulated therein. Carbon electrolytic cell having a cooling device.

Images