KR20030062814A - The electrolysis trillion - Google Patents

Abstract

PURPOSE: An electrolyzer is provided which does not require extra coating or filling of an insulating material, a housing of which is made of MC-nylon that is a synthetic resin, which prevents unnecessary current leakage during electrolysis, and which is a semi-permanent electrolyzer having high corrosion resistance against chemicals. CONSTITUTION: In a manufacturing apparatus for producing mixed gas of oxygen and hydrogen by electrolysis using water, the electrolyzer(100) includes a plural outer pole plates(110) at one side of which a terminal(111) for supplying a power source is installed, and along the circumference of which first connection holes are formed with being spaced apart from each other in a certain distance so that the first connection holes are fixed and connected by connection member; an insulator(120) along the circumference of which a plurality of second connection holes are equally formed on the same position as the first connection holes, which is formed of an NC-nylon material so that it is installed between the plural outer pole plates to insulate the outer pole plates, and at one side of which protrusions are formed; a plural inner pole plates(130) at a certain position of the upper part of which a plurality of fixed holes are formed with being spaced apart from a plural gas connection holes(131) in an equal distance, at a certain position of the lower part of which a water hole(132) is formed, and which are installed at both sides of the protrusions of the insulator; a plurality of supporting insulation packing(140) at one side of which a fixed protrusion(141) is formed, and which are installed with being spaced apart from each other in an equal distance so that the inner pole plates are fixed; and a plurality of connection members which are connected by penetrating the plural outer pole plates, air-tightness maintenance insulation packing(150) and insulator.

Description

The electrolysis trillion

The present invention relates to an electrolysis tank for generating a mixed gas by using electrolysis, wherein the electrolysis tank is configured using a non-metallic synthetic resin material so that unnecessary leakage current does not occur, and an electrolytic bath with strong corrosion resistance from chemicals is provided. will be.

In general, based on the electrolysis technology of water, a method of using oxygen and a mixed gas was developed by Yul Brown of Bulgaria, who separates oxygen and hydrogen from water electrolysis.

The electrolysis of water flows electricity to the two electrode plates of the cathode and the anode in a sealed container containing the electrolyte solution, so that hydrogen ions are dissociated at the cathode and oxygen ions are dissociated at the cathode. This gas has a problem that can not be produced and stored separately because it contains oxygen because it is a highly flammable gas with its own combustion ratio.

Therefore, problems such as convenience, safety, and generator size should be solved when it is necessary to generate and use it immediately.

In general, a water decomposition electrolysis tank 1) connects two tubes of different sizes to each other by connecting the + and-electrodes, and 2) overlaps the small electrode plates and seals them with an insulating material to deliver them. There is a way to use space.

The method of 1) is difficult to cool the electrolysis tank and cannot produce a large amount of gas, and there is a disadvantage that water is accumulated in the gas discharge line due to saturated steam generated by the temperature rise of the electrolysis tank.

The method of 2) is air-cooled, and the space having a narrow electrolytic area overlaps with dozens or hundreds of spaces, and the gas is collected. There was a problem that cannot use the whole electrolysis tank.

Therefore, the present invention is to solve the above problems, the present invention does not require coating, filling, etc. of a separate insulating material, the housing of the electrolysis tank using the MC-Nylon (MC-Nylon), which is a non-metallic synthetic resin housing The purpose of the present invention is to provide a semi-permanent electrolysis tank which prevents the occurrence of unnecessary leakage current generated during electrolysis, and also has strong corrosion resistance to chemicals.

1 is a perspective view showing an electrolysis tank according to the present invention.

2 is a cross-sectional view of a configuration of an electrolysis tank according to the present invention.

Figure 3 is an exploded perspective view showing the configuration of the electrolysis tank according to the present invention.

Figure 4 is a perspective view showing another embodiment of the support insulation packing of the electrolysis tank according to the present invention.

5 is a perspective view showing a state in which the electrolysis tank according to the present invention is connected.

6 is a plan view showing another embodiment of the electrolytic bath according to the present invention.

Figure 7 is a perspective view showing a connection member of the electrolysis tank according to the present invention.

* Description of the symbols for the main parts of the drawings *

100: electrolysis tank 110: outer electrode plate

111: terminal 112: first coupling hole

113: fixing member 120: insulator

120a: protrusion 121: gas discharge unit

122: water inlet 123: second coupling hole

130: inner electrode plate 131: gas communication hole

132: water moving hole 133: fourth coupling hole

140: support insulation packing 141: fixing protrusion

150: confidentiality packing 151: third coupling hole

160: heat radiation fins 170: detection unit

180: heat dissipation unit 181: motor

182: fan 190: drain valve

200: connection member 210, 220: coupling protrusion

211, 221: connection hole 230: electrolyte solution piping

The present invention for achieving the above object is provided with a terminal for supplying power to one side, a plurality of outer electrode plate having a first coupling hole to be fixedly coupled by a coupling member at a predetermined interval along the circumference; A plurality of second coupling holes are formed in the same position as the coupling hole along the circumference thereof, and are made of NC-Nylon material to be installed and insulated between the plurality of outer electrode plates, Insulators having protrusions; A plurality of fixing holes are formed at a predetermined position at an upper portion of the gas communication holes at equal intervals, and a water moving hole is formed at a predetermined position at a lower portion of the plurality of inner electrode plates provided on both sides of the protrusion of the insulator; A plurality of supporting insulation packings having fixed protrusions at one side thereof and installed at equal intervals so that the inner electrode plates can be fixed; And a plurality of coupling members coupled through the plurality of outer electrode plates, the hermetic insulating packing, and the insulator.

In addition, it is provided between the plurality of outer electrode plates and the insulator according to the present invention, characterized in that the airtight packing is further provided to maintain the airtight of the outer electrode plate and the insulator.

In addition, any one of the plurality of outer electrode plate according to the present invention is characterized in that the water level detector for detecting the water level of the water introduced into the inside.

In addition, any one side of the plurality of outer electrode plate according to the invention is characterized in that it further comprises a heat radiation fin is installed to dissipate heat generated therein.

In addition, one side of the insulator according to the present invention is characterized in that the water inlet is further formed.

In addition, any one side of the insulator according to the invention is characterized in that the gas outlet for discharging the mixed gas (oxygen, hydrogen) generated by the electrolysis of water is further formed.

In addition, the support insulation packing according to the invention is characterized in that it is formed in a rectangular shape so that it can be installed along the protrusion formed protruding from one side of the insulator.

In addition, any one side of the outer electrode plate according to the invention is characterized in that the drain valve is further installed to discharge the water contained therein.

In addition, at least two or more electrolysis tank according to the invention is characterized in that the parallel connection by the installation member is installed.

In addition, the electrolytic bath according to the invention is characterized in that it is formed in a circular shape.

In addition, it characterized in that it further comprises a heat dissipation unit which is spaced apart from the battery decomposition tank and a predetermined distance so that the heat generated by the heat dissipation fin can be smoothly generated.

One side of the insulator is characterized in that the electrolyte pipe is further installed so that the electrolyte contained in the electrolysis tank can be moved and at the same time the amount of electrolyte contained in each electrolysis tank is maintained the same.

In addition, the connection member according to the present invention is characterized in that one side has a connection hole open to be connected to the coupling member of the electrolysis tank and both sides protrude.

In addition, the thermal member according to the present invention has a plurality of connection holes to connect the electrolysis tank, characterized in that both sides are bent in the opposite direction.

Hereinafter, the mixed gas production apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view showing an electrolysis tank according to the present invention, Figure 2 is a cross-sectional view of the configuration of the electrolysis tank according to the present invention, Figure 3 is an exploded perspective view showing the configuration of the electrolysis tank according to the present invention.

As shown in FIGS. 1 to 3, the electrolysis tank 100 of the present invention includes a plurality of external electrode plates 110 provided with terminals 111 on one side thereof, and the plurality of external electrode plates ( A plurality of first coupling holes 112 are formed along the circumference of the 110.

An insulator 120 formed in a square or circle shape is installed between the plurality of outer electrode plates 110, and protrusions 120a protrude along the inner side of the insulator 120.

The inner electrode plate 130 is installed at both sides of the protrusion 120a protruding from the inside of the insulator 120, and the gas communication hole 131 is formed at an upper predetermined position of the inner electrode plate 130. The gas communication holes 131 are formed in a plurality of long holes, and a plurality of fourth coupling holes 133 are formed at equal intervals along the circumference of the inner electrode plate 130, and water is disposed below the inner electrode plate 130. The water movement hole 132 is formed so that it can be moved, the water movement hole 132 is also formed as a long hole.

In order to support the inner electrode plates 130 respectively installed on both sides of the insulator 120, support insulation packing 140 is installed at the other side corresponding to one side thereof at equal intervals, and one side of the support insulation packing 140. The fixing protrusion 141 is formed in the same size as the fourth coupling hole 133 formed at equal intervals along the circumference of the inner electrode plate 130.

In addition, the support insulating packing 140 may be formed at equal intervals as described above, but in another embodiment, may also have a rectangular shape as shown in FIG. 4.

Between the insulator 120 and the outer electrode plate 110, a rectangular hermetic insulating packing 150 having a rectangular shape is installed in the same length as the length of the insulator 120 and the supporting insulating packing 140 therein. This is to prevent water from being leaked into the material to be accommodated and to generate mixed gas (oxygen and hydrogen) by electricity.

A third coupling hole 151 is formed in the hermetic insulating packing 150 to allow the fixing member to be coupled thereto.

The plurality of outer electrode plates 110, the plurality of airtight insulating insulating packing 150, the insulator 120 and the bolt (113a) and the nut (the conventional fixing member 113 to be completely sealed at the same time) Fix it using 113b).

A heat dissipation fin 160 is installed at one side of the outer electrode plate 110 to dissipate heat generated when water is electrolyzed, and a motor to dissipate heat radiated by the heat dissipation fin 160 more smoothly. A heat dissipation unit 180 for dissipating heat by the 181 and the fan 182 is provided. When the water is electrolyzed, the sensing unit 170 is installed at one side of the outer electrode plate 110 so that the amount of water is kept constant, and the sensing unit 170 measures the highest height and the lowest height of the water. Always maintain optimal conditions when electrolyzing water.

In addition, a drain valve 190 is installed at one side of the outer electrode plate 110 to remove deposits or other foreign substances introduced by the water during electrolysis of the water, and the drain valve 190 includes foreign substances. This is to allow the water to be discharged when cleaning the existing water or its interior.

A plurality of electrolysis tanks 100 of the present invention configured as shown in FIGS. 1 to 4 may be connected and used, as shown in FIG. 5.

In addition, a connection member is further provided to connect the electrolysis tank 100 to each other, and the connection member 200 is coupled to the fixing member 113 which fixes the outer electrode plate 100. Coupling protrusions 210 having 211 are provided on both sides thereof.

The connecting member 200 allows the electrolysis tank 100 to be in close contact with each other at a minimum distance from each other, and the length may be arbitrarily adjusted by the user as needed.

Figure 6 is a plan view showing another embodiment of the electrolytic bath according to the present invention, and Figure 7 is a perspective view showing a connecting member of the electrolytic bath according to the present invention.

As shown in FIG. 6 or FIG. 7, the present invention shows another embodiment of the electrolysis tank described above, and the electrolysis tanks described above may be arranged in series, and as an example, as shown in FIG. 6. .

In the above-described electrolysis tank, only the additional configuration will be described when describing the contents of FIG. 6 or FIG. 7, and the descriptions overlapping the above description will not be described.

The upper part of the insulator is formed with a water (electrolyte) inlet to supply the electrolyte, and the electrolytic solution is connected to the electrolysis tank and the electrolytic bath so that the electrolyte can move with each other, the electrolytic bath and the electrolytic bath Connection members to be connected to the two ends are installed.

The connecting member forms a coupling protrusion bent in opposite directions to both sides, and the coupling protrusion is formed with a plurality of connecting holes to connect the electrolytic baths by inserting a conventional bolt when the electrolytic bath is connected.

Looking at the effect of the electrolysis tank according to the present invention configured as described above are as follows.

First, looking at the electrolysis of the electrolysis tank 100 of the present invention to produce a mixed gas (hydrogen, oxygen) by the water, the water is supplied through the water inlet 122 installed on one side of the insulator is a certain amount of water When collected in the electrolysis tank 100, power is supplied through the terminals 111 installed on the plurality of external electrode plates 110, and the power supplied through the terminals 111 is different because the polarities thereof are different. Electricity is shorted by using the media collected inside.

Hydrogen and oxygen are generated by electrically decomposing water in the process of shorting the electricity, and the generated oxygen and hydrogen are mixed with oxygen, which is a mixed gas, through the gas discharge unit 121 installed at one side of the insulator 120. Hydrogen is released.

In this case, the mixed gas generated between the inner electrode plate 130 and the outer electrode plate 110 is formed through the gas communication hole 131 formed in the upper portion of the inner electrode plate 130 and the inner electrode plate 130. Collected between and discharged to the gas discharge unit 121, it is possible to use the discharged mixed gas where the user needs.

In addition, when the amount of water collected in the electrolysis tank 100 of the present invention is small, the level of the water is measured by the sensing unit 170 installed on one side of the outer electrode plate 110 to notify the user and At the same time, water can be introduced through the water inlet 122 installed at one side of the insulator 120.

When the amount of water contained in the electrolysis tank 100 of the present invention is excessively introduced and the amount thereof is more than an appropriate amount, it is sensed by the sensing unit 170 installed at one side of the outer electrode plate 110 and the user At the same time, the supply of electricity is cut off to stop the generation of mixed gas.

When the amount of water introduced into the electrolysis tank 100 of the present invention is large, the generation of the mixed gas as described above is stopped and the user is provided with a drain valve 190 installed at one lower side of the outer electrode plate 110. Drain the water through. Water discharged by the drain valve 190 is discharged by moving to the drain valve 170 through the water movement hole 132 formed in the lower portion of the inner electrode plate 130, the electrolysis tank 100 Make sure that the amount of water contained within is maintained.

When water flows in through the water inlet 122 installed at one side of the insulator 120, if the amount of water approaches an appropriate amount, the sensing unit 170 detects the amount of the water to the water inlet 122. Make sure that no more water is supplied.

Heat generated while electrolyzing water in the electrolysis tank 100 of the present invention primarily heats the heat through the heat generating fins 160 installed on one side of the outer electrode plate 110, and the heat radiating fins 160. Heat dissipated through the second dissipates heat through the heat generating unit 180 which is installed at a predetermined distance apart from one side of the electrolysis tank 100.

5 and 6 to connect a plurality of electrolysis tanks 100 of the present invention to collect the mixed gas produced through the electrolysis through one pipe (P) and write it where necessary by the user It can be.

In this way, by using the water and electricity that is cheaper than petroleum fuel to generate a mixed gas by using this, there is an advantage that can be used as a fuel for heating, welding at a low price.

Looking at the effect of the electrolytic bath according to the present invention, the electrolytic bath of the present invention can be used at a low cost by supplying the heating or other necessary energy sources using cheap water and electricity instead of expensive fossil fuel, non-metallic Since NC-Nylon, a synthetic resin, is used, unnecessary leakage current does not occur, resulting in a high corrosion resistance effect from chemicals.

Claims (14)

In the manufacturing apparatus for producing mixed gas (oxygen, hydrogen) by electrolysis using water, A plurality of external electrode plates provided with a terminal for supplying power to one side and having a first coupling hole to be fixedly coupled by the coupling member at predetermined intervals along a circumference thereof; A plurality of second coupling holes are formed in the same position as the coupling hole along the circumference thereof, and are made of NC-Nylon material to be installed and insulated between the plurality of outer electrode plates, Insulators having protrusions; A plurality of fixing holes are formed at a predetermined position at an upper portion of the gas communication holes at equal intervals, and a water moving hole is formed at a predetermined position at a lower portion of the plurality of inner electrode plates provided on both sides of the protrusion of the insulator; A plurality of supporting insulation packings having fixed protrusions at one side thereof and installed at equal intervals so that the inner electrode plates can be fixed; And And a plurality of coupling members coupled through the plurality of outer electrode plates, the hermetic insulating packing, and the insulator. The method of claim 1, And an airtight seal packing disposed between the plurality of outer electrode plates and the insulator, wherein an airtight packing is further provided to maintain the airtightness between the outer electrode plate and the insulator. The method of claim 1, Electrolytic tank, characterized in that the water level detector is further installed on any one side of the plurality of outer electrode plate to determine the state of the water level introduced into the inside. The method of claim 1, Any one side of the plurality of outer electrode plate further comprises a heat dissipation fin is installed so as to dissipate heat generated therein. The method of claim 1, Electrolysis tank, characterized in that the water inlet is further formed on one side of the insulator. The method of claim 1 On one side of the insulator, the electrolysis tank further comprises a gas discharge unit for discharging the mixed gas (oxygen, hydrogen) generated by electrolysis of water. The method of claim 1, The support insulation packing is electrolytic bath, characterized in that formed in a quadrangular shape so that it can be installed along the projection formed protruding from one side of the insulator. The method of claim 1, Either side of the outer electrode plate is characterized in that the drain valve is further installed to discharge the water contained therein. The method of claim 1, Electrolysis tank characterized in that the connection member is further installed so that at least two or more electrolysis tanks can be connected in parallel. The method of claim 1, The electrolytic bath is characterized in that the electrolytic bath is formed in a circular shape. The method of claim 1, Electrolysis tank further comprises a heat dissipation unit which is spaced apart from the battery disassembly tank a predetermined distance so that the heat generated by the heat dissipation fin can be smoothly generated. The method of claim 1 Electrolytic tank, characterized in that the electrolyte pipe is further installed on one side of the insulator so that the electrolyte contained in the electrolysis tank can be moved and at the same time the amount of electrolyte contained in each electrolysis tank is maintained the same. The method of claim 9, The connecting member has an opening in which one side is open so as to be connected to the coupling member of the electrolytic bath, the electrolysis tank, characterized in that both sides protrude. The method of claim 9, The thermal member has a plurality of connection holes to connect the electrolysis tank, the electrolysis tank, characterized in that both sides are bent in the opposite direction.