KR200461451Y1 - Hydrogen-oxygen mixed gas product apparatus - Google Patents

Abstract

Disclosed is a hydrogen-oxygen mixed gas generator.
Hydrogen-oxygen mixed gas generator disclosed is the outer case; An electrolytic cell disposed in the outer case and configured to electrolyze an aqueous solution contained therein to generate a hydrogen-oxygen mixed gas; A water separation flashback arrestor, in which the hydrogen-oxygen mixed gas generated in the electrolytic cell flows in to separate water and prevent backfire; And an additive addition main member disposed at a relatively lower position in the outer case than the water separation flashback arrestor, and having an additive to be added to the hydrogen-oxygen mixed gas contained therein.
According to the disclosed hydrogen-oxygen mixed gas generator, the additive addition main member and the additive addition auxiliary member capable of adding an additive to the hydrogen-oxygen mixed gas via the water separation flashback arrestor are integrally disposed in the outer case, thereby adding additives. Since it is not necessary to separately provide a member for, the inconvenience of having to add a member for adding additives in the field in a separate pipe, and handle separately can be eliminated, the hydrogen-oxygen mixed gas generator can be made compact, There is an advantage that can be easily handled.

Description

Hydrogen-oxygen mixed gas product apparatus

The present invention relates to a hydrogen-oxygen mixed gas generator.

Hydrogen-oxygen mixed gas generator is an apparatus which electrolyzes an electrolyte solution and produces | generates hydrogen gas and oxygen gas.

The hydrogen-oxygen mixed gas generator includes an electrolyzer in which electrolysis occurs, a separator for separating the hydrogen-oxygen mixed gas formed by electrolysis in such an electrolyzer from water, an aqueous tank for replenishing the electrolyte with an electrolytic cell, and flame retardation. And a flashback arrestor.

In the electrolytic cell, a plurality of charging plates are arranged in an electrolyte solution, and an electrode plate for applying a current to the charging plate is provided. The interior of such an electrolytic cell is sealed to the outside.

The hydrogen mixed gas through the hydrogen mixed gas generator is supplied to the demand through the additive adder. The additive adder increases the calorific value of the hydrogen mixed gas generated in the hydrogen mixed gas generator, and the hydrogen mixed gas is In order to perform the cleaning of the gas oiled portions, an additive such as hexane is added to the hydrogen-oxygen mixed gas.

However, according to the conventional hydrogen mixed gas generator, since the additive adder is configured separately from the hydrogen mixed gas generator, the additive adder and the hydrogen mixed gas generator should be connected separately in the field and handled separately. There was an inconvenience, such as.

In addition, according to the conventional hydrogen-oxygen mixed gas generator, when the additive contained in the additive adder is exhausted, there is a disadvantage that it is impossible to add the additive unless the additive is supplemented.

An object of the present invention is to provide a hydrogen-oxygen mixed gas generator having a structure capable of adding an additive to the hydrogen-oxygen mixed gas generated inside the apparatus.

Another object of the present invention is to provide a hydrogen-oxygen mixed gas generator having a structure capable of working without supplementary additive even when the additive is exhausted in the main member for additive addition.

Hydrogen-oxygen mixed gas generator according to an aspect of the present invention the outer case; An electrolytic cell disposed in the outer case and configured to electrolyze an aqueous solution contained therein to generate a hydrogen-oxygen mixed gas; Radical separation backfire prevention device in which the hydrogen-oxygen mixed gas generated in the electrolytic cell is introduced to separate moisture and prevent backfire; And an additive addition main member disposed at a relatively lower position in the outer case than the water separation flashback arrestor, and containing an additive to be added to the hydrogen-oxygen mixed gas therein.

According to the hydrogen-oxygen mixed gas generator according to an aspect of the present invention, the additive addition main member and additive addition auxiliary member that can add the additive to the hydrogen-oxygen mixed gas via the water separation flashback arrestor is integrally disposed in the outer case By doing so, since it is not necessary to separately provide a member for adding the additive, inconveniences such as connecting the member for adding the additive to a separate pipe in the field and handling separately can be eliminated, and the hydrogen-oxygen mixed gas generator is compact. It can be made, there is an effect that can be easily handled.

According to the hydrogen-oxygen mixed gas generating apparatus according to another aspect of the present invention, the hydrogen-oxygen mixed gas can be separated from the water while the additive is mixed with the additive addition main member and the additive addition auxiliary member, The additive addition auxiliary member has an effect that can also perform the function of the water separator.

According to the hydrogen-oxygen mixed gas generator according to another aspect of the present invention, by adding the additive addition auxiliary member in addition to the additive addition main member, even if the additive contained in the additive addition main member is exhausted, Since it is added, there is no need to stop the work for the additive supplement, there is an effect that the working efficiency can be improved.

Figure 1 is a cross-sectional view of the configuration of the hydrogen-oxygen mixed gas generating apparatus according to an embodiment of the present invention.
Figure 2 is a cross-sectional view of the configuration of the hydrogen-oxygen mixed gas generator according to an embodiment of the present invention.
Figure 3 is a schematic cross-sectional view showing the internal appearance of the separation separation flasher, the additive addition main member and the additive addition auxiliary member applied to the hydrogen-oxygen mixed gas generator according to an embodiment of the present invention.
Figure 4 is a cross-sectional view showing a state in which the hydrogen-oxygen mixed gas flows out of the separation separation flasher shown in FIG.

Hereinafter, with reference to the drawings will be described for the hydrogen-oxygen mixed gas generator according to an embodiment of the present invention.

1 is a cross-sectional view of a configuration of a hydrogen mixed gas generator according to an embodiment of the present invention, Figure 2 is a cross-sectional view of the configuration of a hydrogen mixed gas generator according to an embodiment of the present invention from the front 3 is a cross-sectional view schematically showing the internal appearance of the separation separation flasher, the additive addition main member and the additive addition auxiliary member applied to the hydrogen-oxygen mixed gas generator according to an embodiment of the present invention, Figure 4 3 is a cross-sectional view showing the outflow of hydrogen mixed gas in the separation separation flasher shown in 3.

1 to 4 together, the hydrogen-oxygen mixed gas generator 100 according to the present embodiment is the outer case 110, the electrolytic cell 120, the power supply unit 130, the aqueous solution tank 140 And the separation separation flashback arrestor 150, the additive addition main member 170, and the additive addition auxiliary member 180.

The outer case 110 has the electrolyzer 120, the power supply unit 130, the aqueous solution tank 140, the water separation flashback arrester 150, the additive addition main member 170, and the additive addition auxiliary member therein. 180 is acceptable.

The electrolyzer 120 is connected to the power supply unit 130 to electrolyze the aqueous solution contained therein to generate a hydrogen-oxygen mixed gas. The electrolyzer 120 includes a pair of cover plates 121 and 123, an intermediate plate 122, and a plurality of charging plates 124.

The pair of cover plates 121 and 123 constitute both side portions of the electrolytic cell 120, and the intermediate plate 122 is between the pair of cover plates 121 and 123, for example, The cover plates 121 and 123 are disposed at approximately middle portions. Each power cable 131, 132, and 133 extending from the power supply unit 130 is connected to the pair of cover plates 121 and 123 and the intermediate plate 122, respectively.

The plurality of charging plates 124 form a space for accommodating the aqueous solution supplied from the aqueous solution tank 140 through the aqueous solution supply pipe 161 therein, and an insulator is inserted therebetween. The pair of cover plates 121 and 123 are installed at both ends of the plurality of charging plates 124, and the intermediate plate 122 is installed between the plurality of charging plates 124. The plurality of charging plates 124 may be nickel-plated on a material such as carbon steel or stainless steel.

Hydrogen-oxygen mixed gas generated in the electrolytic cell 120 is supplied to the aqueous solution tank 140 through the hydrogen-oxygen mixed gas supply pipe 162 in a bubble form with water.

In the present embodiment, the pair of cover plates 121 and 123 have the same current polarity, and the intermediate plate 122 has the current polarity opposite to the pair of cover plates 121 and 123. For example, when the positive electrode is caught by the pair of cover plates 121 and 123, the negative electrode is caught by the intermediate plate 122.

As described above, the pair of cover plates 121 and 123 have the same current polarity in the electrolytic cell 120, and the intermediate plate 122 has a current opposite to the pair of cover plates 121 and 123. When the polarity is applied, the electrolytic capacity is increased in the electrolytic cell 120 of the same size as compared to the case where the positive electrode is applied to either one of the pair of cover plates 121 and 123, and the negative electrode is applied to the other one, and the circulation rate of the aqueous solution is increased. Is increased, and thus the cooling performance of the electrolytic cell 120 can be improved.

Meanwhile, an insulating support 125 is installed between the electrolytic cell 120 and the outer case 110. At least a portion of the insulating support 125 may be made of an insulating material such as plastic. Then, the insulating support 125 is insulated between the electrolytic cell 120 and the outer case 110, so that the electrolytic cell 120 is coupled to the outer case 110. Therefore, the structure of the insulator for the electrolytic cell 120 and the assembly for coupling the electrolytic cell 120 to the outer case 110 may be simplified.

The power supply unit 130 supplies electricity to the electrolytic cell 120, and may include a rectifier or the like.

The aqueous solution tank 140 supplies the aqueous solution for generating the hydrogen mixed gas to the electrolytic cell 120 through the aqueous solution supply pipe 161, and the electrolytic cell 120 through the hydrogen mixed gas supply pipe 162. As the hydrogen-oxygen mixed gas generated at is passed through, the water in the hydrogen-oxygen mixed gas is separated.

In detail, an aqueous solution is accommodated at a predetermined height inside the case 141 of the aqueous solution tank 140, and the mixed hydrogen hydrogen gas supplied through the hydrogen mixed gas supply pipe 162 is a case of the aqueous solution tank 140. While passing through the water surface of the aqueous solution contained in 141, the moisture contained in the hydrogen-oxygen mixed gas is dropped by gravity, so that water may be firstly removed from the hydrogen-oxygen mixed gas.

As described above, the aqueous solution tank 140 supplies the aqueous solution for generating the hydrogen mixed gas to the electrolytic cell 120 through the aqueous solution supply pipe 161, and through the hydrogen mixed gas supply pipe 162 By allowing the hydrogen mixed gas generated in the electrolytic cell 120 to pass through, the water in the hydrogen mixed gas is separated, so that the aqueous solution tank 140 may serve as a primary water separator as well as an aqueous solution supply means. have. Therefore, the structure can be simplified as compared with the case of separately configuring the aqueous solution supply means and the primary water separator.

On the other hand, the hydrogen gas mixed gas via the aqueous solution tank 140 is introduced into the water separation flashback arrestor 150 through a gas inlet pipe 163.

The separation separation flashback arrestor 150 includes a separation separation flashback prevention case 151, a partition wall 152, and a through hole 153.

The flashback prevention liquid is accommodated in the nose separation flashback prevention case 151. The flashback prevention liquid may be made of water or the like.

The partition wall 152 partitions the inside of the radix separation backfire prevention case 151 in a vertical direction to form a first chamber 154 and a second chamber 155. The gas inlet pipe 163 protrudes to a predetermined height in the first chamber 154, and a gas outlet pipe 164 connected to the additive addition main member 170 at a lower portion of the second chamber 155. ) Is connected. Hydrogen-oxygen mixed gas may flow out to the additive addition main member 170 through the gas outlet pipe 164. The size of the second chamber 155 may be formed relatively smaller than the size of the first chamber 154.

The through hole 153 is formed in the partition wall 152 to communicate the first chamber 154 and the second chamber 155.

In the present embodiment, the level of the flashback preventing liquid inside the cardinal separation flash prevention case 151, in particular, the level of the flashback preventing liquid inside the second chamber 155 is relatively higher than the position at which the through hole 153 is formed. Stays high. Then, even if backfire of an external flame occurs through the gas outlet pipe 164, since such backfire does not diffuse to the first chamber 154, the cardinal separation flashback arrestor 150 performs the function of preventing backfire. can do.

In addition, when the hydrogen-oxygen mixed gas flows into the first chamber 154 through the gas inlet pipe 163, the internal pressure of the hydrogen-oxygen mixed gas flows into the first chamber 154. At least a portion of the flashback preventing liquid is moved to the second chamber 155 through the through hole 153. Then, as shown in FIG. 4, the level of the flashback preventing liquid in the first chamber 154 is lower than the position at which the through hole 153 is formed, so that the through hole 153 becomes the first hole. The flashback liquid in the chamber 154 is exposed on the water surface. 4 denotes the volume of the flashback reduction liquid reduced in the first chamber 154, and reference numeral V2 denotes the volume of the flashback prevention liquid increased in the second chamber 155. As shown in FIG. , The two volumes (V1, V2) are the same.

As described above, the hydrogen mixed gas in the first chamber 154 may move to the second chamber 155 through the through hole 153 exposed on the surface of the water. Hydrogen-oxygen mixed gas moved to the second chamber 155 flows out through the gas outlet pipe 164.

Moisture in the hydrogen mixed gas is dropped by gravity while the hydrogen mixed gas introduced through the gas inlet pipe 163 passes through the inside of the water separation flashback prevention case 151 and is removed by gravity. Thus, the water separation flashback arrestor 150 may function as a secondary water separator.

As described above, the cardiac separation flashback arrestor 150 includes the cardiac separation flashback prevention case 151, the partition wall 152, and the through hole 153. Since the level of the flashback prevention liquid is maintained higher than the formation position of the through hole 153, diffusion of flashback through the gas outlet pipe 164 can be prevented, and the hydrogen hydrogen is prevented through the gas inflow pipe 163. When the mixed gas is introduced, at least a portion of the flashback preventing liquid inside the first chamber 154 is transferred to the second chamber 155 through the through hole 153 by the pressure of the mixed hydrogen hydrogen gas. As it moves, the level of the flashback preventing liquid in the first chamber 154 is lower than that of the through hole 153, and thus the hydrogen oxygen mixture in the first chamber 154 through the through hole 153. Gas is moved to the second chamber 155 so that the gas outlet pipe 1 By moving to 64), while being separated from the secondary oxygen to the mixed gas of hydrogen, it is possible to smoothly flow out of the mixed hydrogen hydrogen gas, the separation separation flasher 150 is a flashback arrestor and secondary as described above By performing the function of the conventional separator, the structure can be simpler than the case of separately installing the flashback arrestor and the secondary separator.

Here, the level of the flashback preventing liquid inside the first chamber 154 may be lower than the distal height of the gas inlet pipe 163. Then, since the backfire prevention liquid in the first chamber 154 does not flow out through the gas inlet pipe 163, the brackish water separation without the need for additionally supplying a backfire prevention liquid to the water separation flashback arrestor 150. Since the amount of the flashback prevention liquid in the flashback arrestor 150 can be kept constant, the function of the water separation flashback arrestor 150 can be smoothly performed, and the management thereof can be facilitated.

Meanwhile, a cooling fan 170 is installed at a portion of the outer case 110 that faces the electrolytic cell 120. An outside air introduction hole 111 is formed in a portion of the outer case 110 around the cooling fan 170, and an inside air outlet hole 112 is formed in an upper portion of the outer case 110. The cooling fan 170 may be connected to the power supply 130 to receive electricity. The aqueous solution tank 140 and the water separation flashback arrestor 150 are disposed above the electrolytic cell 120.

When configured as described above, when the cooling fan 170 is operated, outside air is introduced through the outside air introduction hole 111, and an air flow is generated inside the outer case 110, and by such air flow. The electrolytic cell 120, the aqueous solution tank 140, and the water separation flashback arrestor 150 may be sequentially cooled. Therefore, without the separate configuration for cooling the aqueous solution tank 140 and the water separation flashback arrester 150, cooling to the aqueous solution tank 140 and the water separation flashback arrester 150 is possible, The structure of the hydrogen mixed gas generator 100 may be simplified, and stable continuous operation of the hydrogen mixed gas generator 100 may be enabled.

Here, the cooling fan is also installed in a portion of the outer case 110 that faces the power supply unit 130, and the external air introduced into the outer case 110 by the cooling fan is supplied to the power supply unit 130. ), The aqueous solution tank 140 and the water separation flashback arrestor 150 may be sequentially cooled.

The additive addition main member 170 is disposed at a position relatively lower than the water separation flashback arrestor 150 in the outer case 110, and an additive 20 such as hexane to be added to the hydrogen-oxygen mixed gas therein. ) Is accepted.

The additive addition main member 170 is disposed at a position relatively lower than the separation separation flashback arrestor 150, so that the additive addition main member is not included in the separation separation flashback arrester 150 without having to provide a separate pump or the like. Flow of the mixture of the hydrogen-oxygen mixed gas and water to 170 may be made naturally.

The gas outlet pipe 164 connected to the lower portion of the water separation flashback arrestor 150 is connected to a lower portion of the case 171 of the additive addition main member 170, and the hydrogen passes through the water separation flashback arrestor 150. An oxygen mixed gas flows into the additive addition main member 170.

Hydrogen-oxygen mixed gas flowing into the additive adding main member 170 through the gas outlet pipe 164 flows into the additive adding main member 170 in a state of containing moisture (Fig. 10). The additive 20 is disposed above the mixture of the hydrogen mixed gas and water 10 introduced into the additive adding main member 170, and the gas outlet pipe 164 is the hydrogen hydrogen as the mixture 10. The mixed gas is connected to the inflow.

Hydrogen-oxygen mixed gas introduced into the mixture 10 is mixed with the additive 20 while passing through the additive 20, and then the additive is added through the additive-added connecting pipe 173 formed on the case 171. The additional auxiliary member 180 flows in.

Reference numeral 172 is formed in the lower portion of the case 171, and is a water drain pipe that can discharge the water separated from the hydrogen-oxygen mixed gas introduced into the additive addition main member 170 to the outside. Of course, an open / close valve (not shown) may be applied to the water drain pipe 172.

The additive addition auxiliary member 180 is supplied with the hydrogen-oxygen mixed gas introduced through the additive addition connecting member 173 via the additive addition main member 170, and the additive addition main member 170 is introduced therein. The additive to be added auxiliary to the hydrogen-oxygen mixed gas via) is accommodated.

The additive adding connector 173 penetrates the lower portion of the case 181 of the additive adding auxiliary member 180 to protrude up to the predetermined height inside the case 181. The additive 30 is received at a level relatively lower than the protruding height of the additive adding connector 173, so that the additive 30 in the additive adding auxiliary member 180 is transferred through the additive adding connector 173. The additive addition may not be backflowed into the main member 170.

Hydrogen-oxygen mixed gas introduced into the additive addition auxiliary member 180 may be mixed with the vaporized additive 30 via the case 181 inside the additive addition auxiliary member 180, and after such mixing, the case 181 may be discharged to the external demand through the external connection pipe 182 formed on the top.

The hydrogen-oxygen mixed gas mixed with the additive 20 in the additive adding main member 170 is raised in the additive adding main member 170 in a gaseous state, and passes through the additive adding connecting pipe 173. Since the additive addition auxiliary member 180 flows in a gaseous state, water in the hydrogen-oxygen mixed gas may be separated in the gaseous flow process.

As described above, the additive addition main member 170 and the additive addition auxiliary member 180 capable of adding an additive to the hydrogen-oxygen mixed gas via the water separation flashback arrestor 150 are the outer case 110. By being integrally disposed within, it is not necessary to separately provide a member for adding an additive, so that inconveniences such as connecting the member for adding an additive to a separate pipe in the field and handling it separately can be eliminated. The gas generator 100 can be made compact, and its handling can be facilitated.

In addition, the hydrogen-oxygen mixed gas may pass through the additive addition main member 170 and the additive addition auxiliary member 180, and moisture may be separated while the additive is mixed. The additive addition auxiliary member 180 also performs the function of the water separator.

In addition, since the additive addition auxiliary member 180 is provided in addition to the additive addition main member 170, the additive addition auxiliary member 180 may be assisted even when the additive contained in the additive addition main member 170 is exhausted. With the addition of additives, there is no need to interrupt the operation for additive replenishment, thereby improving the working efficiency.

While the present invention has been shown and described with respect to specific embodiments, those skilled in the art can variously modify the present invention without departing from the spirit and scope of the present invention as set forth in the claims below. And that it can be changed. Nevertheless, it is intended to be clear that all such modifications and variations are included within the scope of the present invention.

According to an apparatus for generating hydrogen mixed gas according to an aspect of the present invention, an additive may be added to the hydrogen mixed gas generated inside the apparatus, even when the additive is exhausted in the main member for adding the additive. Work can be done without replenishment, suggesting the possibility of industrial use.

Claims (3)

Outer case;
An electrolytic cell disposed in the outer case and configured to electrolyze an aqueous solution contained therein to generate a hydrogen-oxygen mixed gas;
Radical separation backfire prevention device in which the hydrogen-oxygen mixed gas generated in the electrolytic cell is introduced to separate moisture and prevent backfire; And
And an additive addition main member disposed in the outer case at a lower position than the water separation flashback arrestor, and having an additive to be added to the hydrogen-oxygen mixed gas contained therein. The method of claim 1,
An additive addition disposed in the outer case, the hydrogen-oxygen mixed gas flowing through the additive adding main member is introduced, and an additive to be added to the hydrogen-oxygen mixed gas auxiliary via the additive adding main member is accommodated therein; Hydrogen-oxygen mixed gas generator comprising an auxiliary member. The method of claim 1,
And a water drain pipe through which the water separated from the hydrogen mixed gas introduced into the additive added main member is discharged.

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