KR100824827B1 - Water gas generator having a electrolyte tank with a electrolyzer incorporated in a body - Google Patents

Abstract

A water gas generator having an electrolyte tank is provided to improve production efficiency of water gas by preventing an electrolyte from interfering with water gas. A water gas generator comprises an electrolyte tank(110) integrally formed with an electrolytic cell(120) and a cooling device(140) for cooling an electrolyte contained in the electrolyte tank. The electrolyte tank includes a lower body(111) for containing the electrolyte therein, and an upper cover(112) assembled with the lower body. The electrolytic cell is installed on a bottom of the lower body. The electrolytic cell includes a plurality of cylindrical electrolytic plates having diameters different from each other.

Description

Water gas generator having an electrolytic tank integrated electrolyte tank {Water gas generator having a electrolyte tank with a Electrolyzer incorporated in a body}

1 is a block diagram of a water gas generator having an electrolytic cell integrated electrolyte tank of the present invention,

2 is an enlarged cross-sectional view of an electrolyte tank of a water gas generator having an electrolytic cell integrated electrolyte tank according to the present invention;

3 is a plan sectional view of an electrolytic cell of the water gas generator having the electrolytic cell integrated electrolyte tank of the present invention.

※ Explanation of code for main part of drawing

110: electrolyte tank, 111: lower body, 112: upper cover, 113: insulating coating layer, 114: terminal,

120: electrolytic bath, 121: electrolytic plate, 122: fixing table, 122a: fixing plate, 123: electrode plate,

123a: contact piece, 130: electrolyte assist tank, 131: insulation coating layer, 132: water level sensor,

133: water supply pump, 134: water supply pipe, 140: cooling means, 141: radiator, 142: blowing fan,

143: circulating pump, 150: air supply means, 151: air nozzle, 151a: exhaust hole,

152: air pump, 153: filter unit, 160: air mixing control unit, 161: temperature sensor,

162: control valve, 163: controller, 171: water tank, 172: pressure storage tank, 173: nucleic acid tank,

174: combustion nozzle, 175: check valve

According to the present invention, the electrolytic cell is positioned inside the electrolytic bath, thereby increasing the water gas generation efficiency by minimizing the supply of the electrolytic solution to the electrolytic cell and the movement of the water gas generated from the electrolytic cell, and miniaturizing the electrolytic cell integrated electrolyte. A water gas generator having a tank.

In general, water gas refers to a mixed gas of oxygen and hydrogen generated by the electrolysis of water. Commonly referred to as oxyhydrogen mixed gas, aqua gas, water gas, etc., it is a mixed gas mixed with a chemical equivalent ratio of 2: 1 without separating hydrogen and oxygen obtained by electrolysis of water.

This water gas is regarded as a pure energy source without environmental pollution since it uses water as an infinite resource and only generates steam after complete combustion.It generates super high temperature by inducing an impregnation phenomenon that collects sparks during combustion. Energy efficiency is also good.

However, in the related art, an electrolytic bath containing an electrolyte solution and an electrolytic bath that is connected to the electrolytic bath and are supplied with an electrolytic solution from the electrolytic bath to electrolyze to generate water gas are separately formed.

That is, the water gas generated in the electrolytic cell is moved toward the electrolytic bath through the pipe connecting the electrolytic bath and the electrolytic bath. The electrolytic solution of the electrolytic bath is supplied toward the electrolytic bath through the same pipe, and the electrolyte and the water gas flow in opposite directions. Since there is a problem that the water gas and the electrolyte does not move smoothly.

The present invention has been made in order to solve the above problems, the electrolytic cell integrated electrolyte tank to improve the production efficiency of water gas by preventing the movement of the electrolytic solution moving to the electrolytic cell and the water gas moving from the electrolytic cell to the upper side of the electrolytic bath is not interfere with each other. It is an object to provide a water gas generator having a.

In addition, as water gas is generated between the cylindrical electrolyte plates of different diameters, which are prepared, the water gas bubbles stay between the electrolyte plates and minimize the time for water gas bubbles to stay between the electrolyte plates, thereby increasing the contact area between the electrolyte and the electrolyte plates. It is an object of the present invention to provide a water gas generator having an electrolytic cell integrated electrolyte tank having improved efficiency.

In addition, an object of the present invention is to provide a water gas generator having an electrolyzer integrated electrolyte tank in which external air is supplied in the electrolyte tank so that the water gas and the external air are stored in the form of compressed gas.

In addition, an object of the present invention is to provide a water gas generator having an electrolyzer integrated electrolyte tank for cooling the electrolyzer and the electrolyte by allowing the outside air to rise in a bubble form through a ring-shaped air nozzle on the outside of the bottom of the electrolyzer.

The water gas generator having an electrolytic cell integrated electrolyte tank according to the present invention has an electrolytic cell integrated electrolyte tank configured to maintain a constant mixing ratio by adjusting the mixing amount of external air according to the generation amount of water gas whose electrolysis yield varies depending on the temperature of the electrolytic solution. The object is to provide a water gas generator.

The water gas generator having the electrolytic cell integrated electrolyte tank according to the present invention has an electrolytic cell integrated type which allows the electrolyte in the electrolyte tank to be cooled while being heat-exchanged with air by a blower fan in the radiator of the cooling means to maintain an optimal temperature for electrolysis of the electrolyte. It is an object of the present invention to provide a water gas generator having an electrolyte tank.

It is also an object of the present invention to provide a water gas generator having an electrolytic cell-integrated electrolytic solution tank, which is capable of continuously generating water gas by providing an electrolyte auxiliary tank to continuously supply the electrolyte to the electrolyte tank.

On the other hand, there is provided a water gas generator having an electrolytic cell integrated electrolyte tank in which the mixed gas of the water gas and external air is completely burned by filtering impurities such as nitrogen and carbon dioxide of the air column on the suction side of the air pump of the air supply means. There is a purpose.

The water gas generator having an electrolytic cell integrated electrolyte tank according to the present invention for achieving the above object is, in the water gas generator, the lower body is accommodated with the electrolyte, the upper cover is assembled with the lower body to seal the inside; An electrolyte tank in which an electrolytic cell is installed on the bottom of the lower body to electrolyze the electrolyte by supplying power to generate water gas; And a cooling means for cooling the electrolyte of the electrolyte tank. It is achieved by providing a water gas generator having an electrolytic cell integrated electrolyte tank.

The electrolytic cell includes a plurality of cylindrical electrolytic plates having different diameters and disposed to coincide with each other, a holder for fixing the cylindrical electrolytic plates, and an electrode plate for alternately applying an anode and a cathode to the electrolytic plates. It is desirable to.

The lower body and the upper cover is preferably formed with an insulating coating layer on the inner surface, the insulating coating layer is preferably made of fluororubber material.

The cooling means preferably includes a circulation pump for circulating the electrolyte to the outside, a radiator through which the circulated electrolyte passes, and a cooling fan for cooling the electrolyte by blowing cooling air toward the radiator.

A water level sensor for accommodating the electrolyte therein and sensing the level of the electrolyte, and a water supply pump for supplying the electrolyte according to the detection signal of the level sensor is formed to include an electrolyte auxiliary tank for continuously supplying the electrolyte to the electrolyte tank. desirable.

The pipe through which the electrolyte solution of the cooling means is circulated is preferably a polyvinyl chloride material or a fluorine rubber-coated pipe.

It is preferable to further include an air supply means for injecting external air into the electrolyte tank.

The air supply means preferably comprises a ring-shaped air nozzle which is formed in the discharge hole is spaced apart a predetermined interval and installed in the lower side of the electrolytic cell, and an air pump for supplying external air to the air nozzle.

Preferably, the air supply means further includes a filter part disposed at the inlet side of the air pump to filter out impurities in the intake air.

A temperature sensor formed in the electrolyte tank to measure the temperature of the electrolyte solution, a control valve formed on the air supply means to regulate the supply amount of air supplied to the air nozzle, and a control valve according to the measurement signal of the temperature sensor Preferably, the air mixing controller further comprises a controller.

A water tank having a predetermined amount of water therein and installed so that the tip of the pipe connected to the electrolyte tank is positioned at the lower end of the water, and a pressure storage tank storing water gas passing through the water by being connected to the water tank; A nucleic acid tank accommodating a predetermined amount therein and having a tip of a pipe connected to the pressure storage tank positioned under the normal nucleic acid solution, a combustion nozzle for burning water gas passing through the nucleic acid solution tank; It is preferred to include a flashback prevention valve formed between the nucleic acid tank and the combustion nozzle to prevent backfire.

Preferably, a check valve is formed on the pipe connecting the electrolyte tank and the water tank and the pipe connecting the water tank and the pressure storage tank to pass the water gas only in the supply direction.

Preferably, a pressure reducing valve is formed on the discharge side of the pressure storage tank to reduce the discharge pressure of the water gas.

Hereinafter, a preferred embodiment of the water gas generator having the electrolytic cell integrated electrolyte tank of the present invention will be described in detail with reference to the accompanying drawings.

1 is a configuration diagram of a water gas generator having the electrolytic cell integrated electrolyte tank of the present invention, Figure 2 is an enlarged cross-sectional view of the electrolyte tank of the water gas generator having an electrolytic cell integrated electrolyte tank of the present invention, Figure 3 This is a plan sectional view of an electrolytic cell of a water gas generator having an electrolytic cell integrated electrolyte tank.

The water gas generator having the electrolytic cell integrated electrolyte tank as shown in the drawings, the electrolyte tank 110, the electrolyte tank 110, the electrolyte auxiliary tank 130, the cooling means 140 and , Air supply means 150, air mixing controller 160, water tank 171, pressure storage tank 172, nucleic acid tank 173, nucleic acid tank 173, combustion nozzle 174 ), And a backfire prevention valve 175 is configured.

The electrolyte tank 110 has a lower body 111 for receiving a predetermined amount of the electrolyte therein, the upper cover 112 is assembled on the upper side of the lower body 111 to maintain the interior of the sealed state, and An insulating coating layer 113 made of fluororubber material formed on inner surfaces of the upper cover 112 and the lower body 111, a pressure gauge G installed on the upper cover 112 to measure internal pressure, and It is installed on the upper cover 112 is installed on the bottom of the lower body 111 so as to be immersed in the pressure pin (P), the power supply terminal 114 and the electrolyte when the internal pressure is higher than the set pressure and the It is configured to include an electrolytic cell 120 connected to the power supply terminal 114 and the wire (W) to receive power to electrolyze the electrolyte to generate water gas.

Here, the electrolytic cell 120 is formed of a different diameter and the plurality of cylindrical electrolytic plates 121 of stainless steel material disposed in the same center and the top of the electrolytic plate 121 to maintain the interval between the electrolytic plates 121 And an electrode plate 122 disposed on the lower end and an electrode plate installed on the fixing base 122 to alternately apply power of the positive electrode (+) and the negative electrode (−) to the plurality of electrolytic plates 121 ( 123).

Here, the holder 122 is made of a resin material for insulation and corrosion prevention, is formed of a "double" shape, the fixing pieces 122a for supporting the cylindrical electrolyte plate 121 are spaced a predetermined interval on the inner surface Many protrusions are formed.

In addition, the electrode plate 123 has a pair of electrode plates 123 for applying a positive electrode (+) and a negative electrode (−) to supply adjacent power to the adjacent electrolyte plate 121 to form an electrolyte tank ( It is connected to the terminal 114 of the 110 and the electric wire (W), a plurality of contact pieces (123a) in contact with the electrolytic plate 121 is formed on the inner surface so as to be spaced a predetermined interval.

The electrolyte auxiliary tank 130 accommodates an electrolyte solution therein, and an insulating coating layer 131 made of a fluorine rubber material formed on an inner surface thereof, a water level sensor 132 for detecting the surface of the electrolyte at a predetermined position on one side, and a water level. The feed water pump 133 for supplying the electrolyte according to the detection signal of the sensor 132, and the water supply pipe 134 for connecting the feed water pump 133 and the electrolyte auxiliary tank 130.

The cooling means 140 is a heat exchanger radiator 141, a blowing fan 142 for blowing cooling air toward the radiator 141, the electrolyte tank 110, the radiator 141 and the electrolyte auxiliary tank Circulation pipe (P1) connecting the 130 and the electrolyte tank 110, the circulation pump 143 formed on the circulation pipe (P1) for forced circulation of the electrolyte, and the pressure difference from the electrolyte tank 110 It includes a check valve (CV) to prevent the back flow of the electrolyte to the electrolyte auxiliary tank 130 by, the circulation pipe (P1) is made of polyvinyl chloride (PVC) or fluoro rubber (Fluoro Rubber) material Is made of.

The air supply means 150 forms a plurality of discharge holes 151a spaced at predetermined intervals on an upper surface thereof, and has a ring-shaped air nozzle 151 disposed outside the lower end of the electrolytic cell 120 and the air nozzle 151. An air pump 152 for supplying external air to the furnace and a filter unit 153 provided on the inlet side of the air pump 152 to filter out impurities such as nitrogen and carbon dioxide in the intake air.

The air mixing controller 160 is formed in the electrolyte tank 110 to measure the temperature of the electrolyte and the temperature sensor 161, the air supply means 150 of the air supplied to the air nozzle 151 The control valve 162 for adjusting the supply amount, and the controller 163 for adjusting the control valve 162 according to the measurement signal of the temperature sensor 161. That is, the mixing ratio of the water gas and the external air is kept constant by adjusting the supply amount of the external air according to the amount of water gas generated by the temperature of the electrolyte.

The water tank 171 is formed in a closed container shape receiving a predetermined amount of water therein, the front end of the supply pipe (P2) connected to the electrolyte tank 110 is located at the bottom of the water, the supply pipe (P2 ) Is formed a check valve (CV) for passing the water gas only in the supply direction.

The pressure storage tank 172 is to receive and store the water gas through the supply pipe (P2) connected to the water tank 171, the pressure gauge (G) indicating the internal pressure on the top, when the set pressure is abnormal An open pressure pin P is formed, and a pressure reducing valve 172a for reducing the discharge pressure of the water gas is formed on the discharge side through which the water gas is discharged.

The nucleic acid tank 173 is a sealed container accommodating a predetermined amount of normal nucleic acid solution therein, and a tip of a supply pipe P2 connected to the pressure storage tank 172 is located at a lower end of the normal nucleic acid solution. In the piping P2, the check valve CV which passes a water gas only in a supply direction is formed.

The nucleic acid tank 173 is to burn the water gas is increased heat passing through the nucleic acid tank 173, the nucleic acid tank on the supply pipe (P2) connecting the nucleic acid tank 173 and the nucleic acid tank 173. A backfire prevention valve 175 is formed to prevent the back flow of flame from 173.

Hereinafter, the operation of the water gas generator having the electrolytic cell integrated electrolyte tank having the above configuration will be described.

First, looking at the assembly state of the electrolyte tank 110, the inside of the electrolyte tank 110 is sealed while the upper cover 112 is assembled to the upper side of the lower body 111 is filled with a predetermined amount of electrolyte, the lower body ( The bottom of the 111 is an electrolytic cell 120 is installed so as to be immersed in the electrolyte is composed of an integral.

Here, the electrolyzer 120 has a plurality of cylindrical diameter plates 121 having upper diameters and lower ends respectively fixed to the fixing pieces 122a of the cross-shaped holders 122 disposed up and down of the electrolytic plates 121, each having a different diameter. The centers of the cylindrical electrolyte plates 121 are arranged to coincide with each other to form a space in which the electrolyte is filled between the electrolyte plates 121.

In addition, the plurality of cylindrical electrolytic plates 121 have contact plates 123a of the electrode plates 123 disposed in a pair so as to supply power of the positive electrode (+) and the negative electrode (−) to each other. Are respectively contacted to apply different electrodes.

Looking at the action of the electrolytic cell 120 assembled as described above, the power supply of the positive electrode (+) and the negative electrode (-) is connected to the terminal 114 and the wire (W) of the electrolyte tank 110 is supplied with power The received electrode plate 123 is in contact with the electrolytic plate 121 through the contact piece 123a to transfer power to the electrolytic plate 121. In particular, since the pair of contact pieces 123a of the electrode plates 123, which are arranged to cross each other, are alternately arranged to apply different polarities of power to the adjacently disposed electrolytic plates 121, they have different polarities. Water gas is generated as the electrolyte is electrolyzed between the cylindrical electrolyte plates 121.

In addition, an air nozzle 151 having a plurality of discharge holes 151a spaced apart from each other by a predetermined interval is disposed on a lower outer side of the electrolytic cell 120, and the air nozzle 151 is external to the electrolyte tank 110. Is connected to the air pump 152 provided in the pipe to receive the external air, the filter unit 153 formed on the outside air inlet side of the air pump 152 does not burn the nitrogen or carbon dioxide in the air The ingredients are filtered out.

Therefore, the air supplied to the inside of the electrolyte tank 110 from the outside through the air supply means 150 rises in a bubble form from the lower side of the electrolyte upward through the discharge hole (151a) of the air nozzle 151 water gas And compressed and stored in a state where water gas and external air are mixed in the electrolyte tank 110, and the external air cools the electrolyte 120 as well as the electrolyte in the process in which the external air rises in the form of bubbles from the lower portion of the electrolyte. do.

When the water gas and the outside air are mixed and stored in the interior of the electrolyte tank 110 sealed through the lower body 111 and the upper cover 112 as described above, the pressure gauge G provided on the upper cover 112 is compressed. The pressure is displayed on the upper cover 112 together with the pressure gauge G when a pressure higher than the set pressure of the pressure pin P is applied to the inside of the electrolyte tank 110. As the pin P is opened, the internal gas is discharged to the outside to prevent an overpressure from being applied to the electrolyte tank 110.

On the other hand, since the electrolyte in the electrolyte tank 110 is consumed while being electrolyzed, the electrolyte is continuously charged through the electrolyte auxiliary tank 130 which is connected to the electrolyte tank 110 and supplies the electrolyte, thereby continuously supplying water gas. To produce.

The electrolyte auxiliary tank 130 detects the level of the electrolyte through the water level sensor 132 formed at a predetermined height on one side, and when the level of the electrolyte is not detected, the electrolyte auxiliary tank through the feed pump 133 of the water supply pipe 134. When the electrolyte level is supplied to the 130 and the level of the electrolyte is detected by the water level sensor 132, the operation of the water supply pump 133 is blocked or the water supply pipe 134 is locked to block the supply of the electrolyte.

The electrolyte in the electrolytic solution tank 110 to be electrolyzed as described above is gradually heated by the heat generated during the electrolysis process of the electrolytic cell 120, and the temperature is raised to a high temperature. When the temperature of the electrolyte rises as described above, water vapor from the electrolyte Is generated and mixed with the water gas, so that the temperature of the electrolyte is cooled through the cooling means 140 to maintain 30 to 40 ° C. suitable for electrolysis of the electrolyte.

The cooling means 140 allows the electrolyte of the electrolyte tank 110 to move to the electrolyte auxiliary tank 130 through the inside of the radiator 141 through the circulation pump 143, and is supplied to the electrolyte auxiliary tank 130. The electrolyte is circulated while moving back into the electrolyte tank 110 to form one cycle of the electrolyte, and the blower fan 142 supplies cooling air toward the radiator 141 to pass the heated electrolyte into the radiator. Heat exchanged with the outside air at 141 to be cooled.

In addition, the electrolyte that is circulated by the cooling means 140 is a current flows and there is a risk of short circuit or short circuit, the lower body 111 and the inner surface of the upper cover 112 of the electrolyte tank 110. The insulating coating layer 113 is formed, and not only the insulating coating layer 131 of fluororubber material is formed on the inner surface of the electrolyte auxiliary tank 130, but also the circulation pipe P1 through which the electrolyte is circulated is polyvinyl chloride or Since it is made of fluorine rubber, the electrolyte flowing through the current is prevented from being shorted or short-circuited in the process of circulating the components of the electrolyte tank 110, the electrolyte auxiliary tank 130, and the cooling means 140.

Meanwhile, the electrolyte tank 110 in which the electrolytic cell 120 is integrally formed therein while storing the electrolyte is compressed and stored in a state where water gas and external air are mixed inside by receiving external air through the air supply means 150. The water gas electrolyzed in the electrolytic cell 120 may vary in amount depending on the temperature of the electrolyte, thereby controlling the supply amount of external air according to the amount of water gas generated through the air mixing controller 160.

That is, the measurement signal value of the temperature sensor 161 which is provided in the electrolyte tank 110 to measure the temperature of the electrolyte is received from the controller 163 and is supplied to the air nozzle 151 based on the signal value. By adjusting the control valve 162 formed in the control to supply the amount of external air to maintain a constant mixing ratio of water gas and external air.

In addition, the ratio of the external air mixed in the water gas according to the use of the mixed gas may be controlled through the air mixing control unit 160.

As described above, the mixed gas of the water gas and the external air stored in the electrolyte tank 110 is supplied to the water tank 171 through the supply pipe (P2), because the tip of the supply pipe (P2) is located in the water bubble form As it passes through the water to rise to the upper side of the water tank (171). In this process, water vapor or impurities contained in the mixed gas are filtered out. In addition, since the gas passes through the water and stays in the water tank 171, the backfire of the flame is prevented and the backflow of the gas due to the pressure difference is prevented.

Subsequently, the mixed gas passing through the water tank 171 is moved to the pressure storage tank 172 through the supply pipe P2 and stored in the pressure storage tank 172, and the pressure located at the top of the pressure storage tank 172. You can check the storage pressure through the gauge (G), the explosion is prevented by the pressure pin (P) that is opened during overpressure.

On the other hand, the supply pipe (P2) in a state in which the mixed gas stored at a high pressure in the pressure storage tank 172 is lowered to a pressure suitable for combustion by the pressure reducing valve 172a formed on the discharge side of the pressure storage tank 172 It is moved to the nucleic acid tank 173 through.

Here, similarly to the water tank 171, the tip of the supply pipe P2 is positioned below the normal nucleic acid solution filled in the nucleic acid tank 173 in a predetermined amount so that the mixed gas is discharged from the tip of the supply pipe P2 to normal nucleic acid. As the solution passes through the bubble form, the normal nucleic acid component is included in the mixed gas to increase the heat of combustion of the mixed gas.

As described above, the mixed gas passing through the normal nucleic acid solution stays on the upper side of the nucleic acid tank 173 and moves to the nucleic acid tank 173 through the supply pipe P2 and burns in the nucleic acid tank 173.

At this time, when the flame combusted by the combustion nozzle 174 is backfired along the supply pipe P2 due to the pressure difference between the supply side and the combustion side, the supply pipe P2 between the nucleic acid tank 173 and the combustion nozzle 174. It is blocked by the backfire prevention valve 175 disposed in the flame is prevented from flashing along the supply pipe (P2).

On the other hand, the check valve (CV) to pass the mixed gas only to the supply side to the supply pipe (P2) connecting between the electrolyte tank 110 and the water tank 171 and the water tank 171 and the pressure storage tank 172. ) Is formed to prevent backflow of the gas.

The water gas generator having the electrolytic cell integrated electrolyte tank of the present invention as described above has an effect of increasing the generation efficiency of water gas while miniaturizing the device by constituting the electrolytic solution tank and the electrolytic cell in one body.

In addition, when water gas is generated between a plurality of cylindrical cylinders of different diameters, the water gas is immediately floated to the upper side of the electrolyte, thereby minimizing the residence time of the bubbles between the electrolyte plates and increasing the contact time between the electrolyte and the electrolyte plates. It also has the effect of generating efficiency.

In addition, there is an effect to supply the external air in the electrolyte tank to store the water gas and the external air in the form of compressed gas.

In addition, the outside air rises in the form of bubbles through the ring-shaped air nozzle on the outside of the lower end of the electrolytic cell, thereby cooling the temperature of the electrolytic cell and the electrolyte.

The water gas generator having the electrolytic cell integrated electrolyte tank according to the present invention has an effect of maintaining a predetermined amount of mixing ratio by adjusting the mixing amount of external air according to the generation amount of water gas whose electrolysis yield varies depending on the temperature of the electrolyte.

The water gas generator having the electrolytic cell integrated electrolyte tank according to the present invention has the effect of maintaining the optimum temperature for the electrolysis of the electrolyte by allowing the electrolyte in the electrolyte tank to be cooled by heat exchange with air by a blower fan in the radiator of the cooling means. .

In addition, by providing an electrolyte auxiliary tank to continuously supply the electrolyte to the electrolyte tank there is an effect that can generate the water gas continuously.

On the other hand, by filtering impurities such as nitrogen and carbon dioxide of the air column on the suction side of the air pump of the air supply means, there is also an effect to completely burn the mixed gas of the water gas and the external air.

Claims (14)

In the water gas generator, A lower body into which an electrolyte is accommodated, an upper cover assembled with the lower body to seal the inside, and an electrolytic cell installed at the bottom of the lower body to generate water gas by electrolyzing the electrolyte by supplying power. Electrolyte tank; And, Water gas generator having an electrolytic cell integrated electrolyte tank comprising a; cooling means for cooling the electrolyte of the electrolyte tank. The method of claim 1, The electrolyzer includes a plurality of cylindrical electrolytic plates having different diameters and arranged to coincide with each other, a holder for fixing the cylindrical electrolytic plates, and an electrode plate for alternately applying an anode and a cathode to the electrolytic plates. Water gas generator having an electrolytic cell integrated electrolyte tank, characterized in that. The method of claim 1, The lower body and the upper cover is a water gas generator having an electrolytic cell integrated electrolyte tank, characterized in that the insulating coating layer is formed on the inner surface. The method of claim 3, wherein The insulating coating layer is a water gas generator having an electrolytic cell integrated electrolyte tank, characterized in that the fluorine rubber material. The method of claim 1, The cooling means includes a circulating pump for circulating the electrolyte to the outside, a radiator through which the circulating electrolyte passes, and a cooling fan for cooling the electrolyte by blowing cooling air toward the radiator. Water gas generator having a. The method of claim 5, A water level sensor for accommodating the electrolyte solution and sensing the level of the electrolyte solution, and a water supply pump for supplying the electrolyte solution according to the detection signal of the water level sensor, and including an electrolyte auxiliary tank for continuously supplying the electrolyte solution to the electrolyte tank. A water gas generator having an electrolytic cell integrated electrolyte tank. The method of claim 6, The pipe through which the electrolyte of the cooling means is circulated is a polyvinyl chloride pipe or a fluorine rubber-coated pipe. The method of claim 1, Water gas generator having an electrolytic cell integrated electrolyte tank further comprises an air supply means for injecting external air into the electrolyte tank. The method of claim 8, The air supply means is a water discharged water tank having an electrolytic cell integrated electrolyte tank, characterized in that the discharge hole is formed to be spaced apart a predetermined interval, the ring-shaped air nozzle is installed on the outer side of the electrolytic cell, and the air pump for supplying external air to the air nozzle Gas generator. The method of claim 9, The air supply means is a water gas generator having an electrolytic cell integrated electrolyte tank characterized in that it further comprises a filter unit disposed on the inlet side of the air pump to filter out impurities in the intake air. The method of claim 9, A temperature sensor formed in the electrolyte tank to measure the temperature of the electrolyte solution, a control valve formed on the air supply means to regulate the supply amount of air supplied to the air nozzle, and a control valve according to the measurement signal of the temperature sensor Water gas generating apparatus having an electrolytic cell integrated electrolyte tank further comprises an air mixing controller configured as a controller. The method according to any one of claims 1 to 11, A water tank installed to accommodate a predetermined amount of water therein so that a tip of a pipe connected to the electrolyte tank is positioned at a lower end of the water; A pressure storage tank for connecting the water tank with pipes and storing the water gas passing through the water; A nucleic acid tank configured to receive a predetermined amount of normal nucleic acid solution therein and to have a tip of a pipe connected to the pressure storage tank located under the normal nucleic acid solution; A combustion nozzle for burning the water gas which has passed through the nucleic acid solution tank; A water gas generator having an electrolyzer integrated electrolyte tank, characterized in that it is formed between the nucleic acid tank and the combustion nozzle to prevent backfire. The method of claim 12, On the pipe connecting the electrolyte tank and the water tank and on the pipe connecting the water tank and the pressure storage tank, a check valve for passing the water gas only in the supply direction is formed water gas generation having an electrolytic cell integrated electrolyte tank Device. The method of claim 12, A water gas generator having an electrolytic cell integrated electrolyte tank, characterized in that a pressure reducing valve for reducing the discharge pressure of the water gas on the discharge side of the pressure storage tank.

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