KR100878052B1 - Gas generator using electrolysis - Google Patents

Abstract

A gas generating system is provided to generate hydrogen and oxygen by simplifying structure of the gas generating system and increasing electrolysis efficiency, thereby electrolyzing water in a super-efficient manner, and to separately store the generated hydrogen and oxygen. A gas generating system comprises: a water feeder(10) feeding water; an electrolyzer(20) to which water is fed by the water feeder to electrolyze water; positive electrode plates(30) and negative electrode plates(40) which are installed within the electrolyzer, and to which an electric current is applied to generate oxygen and hydrogen by oxidation and reduction reactions; a positive electrode grounding terminal(50) and a negative electrode grounding terminal(60) installed on an outer part of the electrolyzer; a plurality of diaphragms(70) which are installed within the electrolyzer, surround the circumference of each of the positive electrode plates, and isolate generated oxygen and hydrogen gases from each other to prevent the oxygen gas and hydrogen gas from mixing with each other; a hydrogen gas outlet(81) and an oxygen gas outlet(82) exhausting the generated oxygen and hydrogen gases; and a hydrogen gas storage container(91) and an oxygen gas storage container(92) storing the exhausted hydrogen and oxygen gases respectively.

Description

Gas Generator using Electrolysis

The present invention relates to a gas generator, and more particularly, to provide a gas generator to separate and store oxygen and hydrogen generated by electrolysis of water, respectively.

Electrolysis causes a chemical reaction by applying an electric current to an ion conductor such as an aqueous electrolyte solution or a molten salt, and when an electric current is applied to the electrode, the cations move to the cathode and the anion to the anode, causing various chemical changes on the surface of the electrode.

Such electrolysis has been practically applied to a wide range of fields, and is also used as one of the industrial manufacturing methods for obtaining hydrogen using water.

A gas generator using electrolysis is a device for producing oxygen and hydrogen, which are products obtained by electrolysis of water. Oxygen / hydrogen mixed gas which is a pollution-free energy source by supplying water and applying a DC voltage in an electrolytic cell equipped with a positive electrode and a negative electrode Will be generated. The importance of such a gas generator is emerging due to the growing interest in environmental problems.

Accordingly, researches on gas generators have been made, and gas generators for more efficiently producing a larger amount of oxygen and hydrogen have been proposed.

In general gas generators, the positive electrode plate and the negative electrode plate are alternately stacked, and when current is supplied, water is electrolyzed into oxygen and hydrogen. Such a gas generator has a problem in that the contact area with the electrolyte is small and the electrolysis efficiency is not large and the yield of the gas is not large. Accordingly, research to increase the electrolysis efficiency of the electrode plate is urgently needed.

The present invention has been made to solve the above problems, an object of the present invention is to provide a gas generator for generating hydrogen and oxygen gas by electrolyzing water in a super-efficient way, the structure is simple and the electrolysis efficiency is increased. To provide.

In addition, another object of the present invention is to provide a gas generator for separating and storing the generated hydrogen and oxygen, respectively.

Gas generator of the present invention for achieving the above object is a water supply for supplying a water (10); An electrolytic cell 20 which is made of lead (Pb) plate, is supplied with water by the water supply device 10 to be electrolyzed, and a negative voltage is applied thereto; Installation spaced plurality dog alternating within the electrolytic cell 20 and the oxidizing and reducing reaction by the current application and generate hydrogen and oxygen to hydrogen peroxide lead (PbO ₂₎ as the positive electrode plate 30, and lead (Pb) Negative electrode plate 40; A positive electrode ground terminal 50 and a negative electrode ground terminal 60 connected to the positive electrode plate 30 and the negative electrode plate 40 in parallel and respectively installed outside the electrolytic cell 20; It is installed inside the electrolytic cell 20 and wraps around each of the positive electrode plates 30, and electrolyte and ions pass therethrough, and the oxygen gas and negative electrode plates 40 and the inner wall of the electrolytic cell 20 generated from the positive electrode plate 30 pass through. A plurality of diaphragms 70 that are isolated from each other to prevent mixing of the generated hydrogen gas; A hydrogen gas outlet 81 installed in the electrolytic cell 20 to discharge hydrogen gas generated from an inner wall of the negative electrode plate 40 and the electrolytic cell 20; An oxygen gas outlet 82 which communicates with each of the diaphragms 70 to merge oxygen gas generated from the positive electrode plate 30 in each of the diaphragms 70 and discharge the combined oxygen gas; A hydrogen gas storage container 91 and an oxygen gas storage container 92 for storing hydrogen gas and oxygen gas discharged to the hydrogen gas outlet 81 and the oxygen gas outlet 82, respectively; Characterized in that comprises a.

In addition, the positive electrode plate 30 and the negative electrode plate 40 are kneaded with lead peroxide (PbO ₂ ) particles and lead (Pb) fine particle powders each with sulfuric acid, respectively, and sintered by filling a lead plate having a lattice-shaped frame. It features.

In addition, each of the diaphragm 70 contacts the positive electrode plate 30 and supports the diaphragm 70 so as to be spaced apart from the positive electrode plate 30, and the oxygen gas generated from the positive electrode plate 30 is upper. An inner support portion 71 of a pillar or protrusion shape is disposed at a predetermined interval so that the oxygen gas movement passage 73 is moved to the outside, and each of the diaphragm 70 is adjacent to the adjacent negative electrode plate 40. Pillars arranged to be in contact with each other to support the diaphragm 70 so as to be spaced apart from the negative electrode plate 40 and to have a hydrogen gas movement passage 74 in which the hydrogen gas generated from the negative electrode plate 40 is moved upward. Or it is preferable that the outer support portion 72 of the projection shape is provided.

In addition, the inner support portion 71 and the outer support portion 72 is characterized in that the separation distance between the diaphragm 70, the positive electrode plate 30 and the negative electrode plate 40 has a height of 3 ~ 10mm.

In addition, the portion exposed to the outside of the diaphragm 70 of the connection portion 32 between the positive electrode plate 30 and the positive electrode ground terminal 50 is characterized in that the insulating coating.

In addition, the positive electrode plate 30 and the negative electrode plate 40 is characterized in that a plurality of gas movement grooves 31 are formed from the bottom to the top to facilitate the movement of the generated hydrogen and oxygen gas.

In addition, a low-frequency vibrator for discharging bubbles generated when hydrogen and oxygen are generated in the negative electrode plate 40 and the positive electrode plate 30 from the negative electrode plate 40 and the positive electrode plate 30 inside or outside the electrolytic cell 20. (22) is further provided.

In addition, the vibration frequency of the low frequency vibrator 22 is characterized in that the same 120Hz as the conventional AC frequency.

In addition, the electrolytic cell 20 is provided with a water level sensor for checking the level of the water supplied to the electrolytic cell 20 to operate in conjunction with the water supply 10, the electrolytic cell 20 outside the electrolytic cell ( It is characterized in that the water level confirmation tube 110 is connected to the 20 to check the water level.

In addition, the water supply 10 is characterized in that the check valve is provided to prevent the back flow of the supplied water.

In addition, the front of the water supply 10 is characterized in that the filter 11 is further provided for filtering the water.

In addition, the gas filter 100 is installed at the rear ends of the gas outlets 81 and 82 to further remove particulates and water vapor of the electrolyte from the discharged gas.

The present invention is simple in structure and can generate gas by electrolyzing water in a super-efficient method, by increasing the contact area with the electrolyte solution to increase the electrolysis efficiency to increase the yield of gas, By smoothing heat dissipation and shutting off the power when the temperature rises, it is possible to safely generate gas, and by separating and storing the generated hydrogen and oxygen, there is an effect that can be used according to the application.

Hereinafter, a gas generator of the present invention will be described with reference to the accompanying drawings.

1 is a perspective view showing a gas generator according to the present invention, Figure 2 is a cross-sectional view showing the internal structure of the gas generator according to the present invention, Figure 3 is a cross-sectional view showing the internal structure of the gas generator according to the present invention. 4 is a perspective view showing the arrangement of the positive electrode plate of the present invention, Figure 5 is a cross-sectional view showing the electrode plate of the present invention.

As shown, the gas generator according to the present invention includes a water supply (10) for supplying water; An electrolytic cell 20 in which water is supplied and electrolyzed by the water supply 10; A positive electrode plate 30 and a negative electrode plate 40 installed inside the electrolytic cell 20 to generate oxygen and hydrogen in an oxidation and reduction reaction by applying an electric current; A positive electrode ground terminal 50 and a negative electrode ground terminal 60 installed outside the electrolytic cell 20; It is installed inside the electrolytic cell 20 and wraps around each of the positive electrode plates 30, and electrolyte and ions pass therethrough, and the oxygen gas and negative electrode plates 40 and the inner wall of the electrolytic cell 20 generated from the positive electrode plate 30 pass through. A plurality of diaphragms 70 that are isolated from each other to prevent mixing of the generated hydrogen gas; A hydrogen gas outlet 81 and an oxygen gas outlet 82 for discharging hydrogen and oxygen gas generated in the electrolytic cell 20; A hydrogen gas storage container 91 and an oxygen gas storage container 92 for storing the discharged hydrogen gas and oxygen gas, respectively; It is made, including.

The water supplier 10 serves to supply water into the electrolytic cell 20. The water supplier 10 supplies and blocks water by sensing a level sensor (not shown) that checks the level of water supplied to the electrolytic cell 20.

In addition, the water supply 10 is preferably provided with a check valve (not shown) to prevent the back flow of the supplied water. In addition, the front of the water supply 10 is preferably provided with a filter 11 for filtering the water further.

The electrolytic cell 20 is made of lead (Pb) plate, the water is supplied by the water supply 10 to be electrolyzed and a negative voltage is applied. By applying a negative voltage to the electrolytic cell 20 can be used as a negative electrode plate during electrolysis as well as can be mounted on the vehicle itself.

The electrolytic cell 20 has a negative electrode plate 40 and a positive electrode plate 30 alternately provided therein, and a positive electrode ground terminal 50 for connecting the positive electrode plate 30 and the negative electrode plate 40 in parallel to each other. A negative electrode ground terminal 60 is provided. In addition, the electrolytic cell 20 is preferably provided with a water level sensor to check the level of the water supplied to the electrolytic cell 20 to operate in conjunction with the water supply (10).

Outside of the electrolytic cell 20 is provided with a heat dissipation piece 21 for dissipating heat generated inside the electrolytic cell 20 during electrolysis.

In addition, inside or outside of the electrolytic cell 20, bubbles generated when hydrogen and oxygen are generated in the negative electrode plate 40 and the positive electrode plate 30 are detached from the electrode plate so that the electrolyte rises rapidly, thereby allowing the electrolyte solution around the electrode plate to rise. It is preferable to further include a low frequency vibrator 22 to promote contact with and to increase the generation efficiency of oxygen and hydrogen. As described above, bubbles generated by the vibration generated by the low frequency vibrator 22 are released from the electrode plate so as to quickly rise, thereby increasing electrolysis efficiency and gas generating efficiency. At this time, the vibration frequency of the low frequency vibrator 22 is about 120 Hz, which is the same as a typical AC voltage frequency.

In addition, the outside of the electrolytic cell 20 is connected to the electrolytic cell 20 is preferably provided with a level check tube 110 for checking the water level.

A plurality of the negative electrode plate 40 and the positive electrode plate 30 are alternately installed in the electrolytic cell 20 and spaced apart, and reduction and oxidation reactions occur by application of current to generate hydrogen and oxygen gas, respectively.

In addition, the positive electrode plate 30 and the negative electrode plate 40 are kneaded with lead peroxide (PbO ₂ ) particles and lead (Pb) fine particles with sulfuric acid (90% or more), respectively, and filled in a lead plate having a lattice-shaped frame. Sintered is preferable. As such, the positive electrode plate 30 and the negative electrode plate 40 maximize the surface area at the time of electrolysis by agglomerating fine particles, so that the electrolytic efficiency is improved and the calorific value is reduced by the smooth electrolytic action in the unit area. . Accordingly, the electrolysis efficiency can be increased, and the generation efficiency of the gas can be increased. At this time, Pb becomes PbSO ₄ , but when electrolyzed, SO ₄ becomes H ₂ SO ₄ to become an electrolyte and Pb is reduced.

Conventional electrolytic electrode plates generally use stainless steel plates, nickel-chromium-plated plates, etc., and have to have a large amount of current flowing in order to increase gas generation during electrolysis. As such, when a large amount of current flows, a phenomenon corresponding to a short circuit occurs, resulting in a large amount of heat generated and a large amount of power consumed. In order to solve this problem, the electrode plate of the present invention is manufactured by kneading the fine powder with sulfuric acid and sintering it to maximize the surface area to improve the electrolytic efficiency to increase the gas generation efficiency.

At this time, the negative electrode plate 40 and the positive electrode plate 30 is preferably formed to facilitate the movement of oxygen and hydrogen gas generated by forming a plurality of gas moving grooves 31 from the bottom to the top. The gas moving grooves of the negative electrode plate 40 are not shown.

The positive electrode ground terminal 50 and the negative electrode ground terminal 60 connect the positive electrode plate 30 and the negative electrode plate 40 in parallel, respectively, and are installed outside the electrolytic cell 20.

When the current is excessively supplied through the positive electrode ground terminal 50 and the negative electrode ground terminal 60, the temperature rise in the electrolytic cell 20 is brought about, so that the positive electrode ground terminal 50 and the negative electrode ground terminal ( The wire connected to 60 is preferably provided with a bimetal switch (not shown) that cuts off the power supply when the electrolyte reaches 50 ° C.

The diaphragm 70 is installed inside the electrolytic cell 20 and surrounds each of the positive electrode plates 30, passes through electrolyte and ions, and generates oxygen gas and negative electrode plates 40 generated from the positive electrode plates 30, and The electrolytic cell 20 serves to isolate each other to prevent the mixing of the hydrogen gas generated in the inner wall is a plurality.

Therefore, oxygen gas is generated in the positive electrode plate 30 installed inside the diaphragm 70, and hydrogen gas is generated in the negative electrode plate 40 installed outside the diaphragm 70, respectively, and generated inside and outside the diaphragm 70. Oxygen and hydrogen gas can be stored separately.

Oxygen gas generated from the positive electrode plate 30 installed in each of the diaphragm 70 is combined through each hose to be discharged to the oxygen discharge port 82 and the negative electrode plate 40 installed outside the diaphragm 70. ) And the hydrogen gas generated in the inner wall of the electrolytic cell 20 are discharged through the hydrogen gas outlet 81 installed in the electrolytic cell 20.

In addition, each of the diaphragm 70 contacts the positive electrode plate 30 and supports the diaphragm 70 so as to be spaced apart from the positive electrode plate 30, and the oxygen gas generated from the positive electrode plate 30 is upper part. It is preferable that the inner support portion 71 of the pillar or the projection form is disposed at a predetermined interval so that the oxygen gas movement passage 73 is moved to be provided.

In addition, the outside of each of the diaphragm 70 is in contact with the adjacent negative electrode plate 40 and supports the diaphragm 70 to be spaced apart from the negative electrode plate 40 and the hydrogen gas generated in the negative electrode plate 40 It is preferable that an outer support portion 72 having a pillar or a protrusion shape disposed at a predetermined interval so that the hydrogen gas movement passage 74 is moved upward is provided.

In addition, it is preferable that the inner support part 71 and the outer support part 72 have a height such that the separation distance between the diaphragm 70, the positive electrode plate 30, and the negative electrode plate 40 is 3 to 10 mm. If the height of the inner support part 71 and the outer support part 72 is too small, oxygen gas and hydrogen gas are not easily moved, and if the height is too large, the distance between the positive electrode plate 30 and the negative electrode plate 40 becomes too large. Since the decomposition efficiency is lowered and the gas generating efficiency is lowered, it is preferable to have an appropriate distance.

The inner support part 71 and the outer support part 72 are made of an insulating synthetic resin material, and are formed in the form of a thin column or protrusion to form an oxygen gas movement passage 73 and a hydrogen gas movement passage 74 between the pillars or the projections. By providing the inner and outer sides of the diaphragm 70, respectively, the oxygen gas and the hydrogen gas are rapidly increased, and the positive electrode plate 30 and the negative electrode plate 40 are preferably in contact with the electrolyte solution.

When oxygen gas is generated outside of the diaphragm 70, oxygen gas may not be generated because it is mixed with hydrogen gas and there is a risk of explosion. Therefore, the portion exposed to the outside of the diaphragm 70 of the connection portion 32 between the positive electrode plate 30 and the positive electrode ground terminal 50 is preferably insulated. When a portion of the connection portion 32 between the positive electrode plate 30 and the positive electrode ground terminal 50 exposed to the outside of the diaphragm is subjected to insulation coating, oxygen gas is not generated outside the diaphragm 70, so that the negative electrode plate ( There is no risk of explosion due to mixing with hydrogen gas generated in 40).

In addition, the diaphragm 70 may be installed to wrap around the negative electrode plate 40 as opposed to installing to surround the positive electrode plate 30 as described above, but to surround the positive electrode plate 30. The reason why it is installed is that the amount of generated hydrogen gas is twice the amount of generated oxygen gas, thereby reducing the internal volume occupied by the diaphragm, thereby reducing the material cost.

In the positive electrode plate 30, it is preferable that the connection portion 32 of the positive electrode ground terminal 50 exposed to the outside of the diaphragm 70 in the electrolytic cell 20 is insulation coated.

The oxygen gas outlet 82 communicates with the interior of each of the diaphragms 70, joins oxygen gas generated from the positive electrode plate 30 installed in each of the diaphragms 70, and discharges the combined oxygen gas. Do it.

The hydrogen gas outlet 81 is installed in the electrolytic cell 20 to be connected to the outside of the diaphragm 70 to discharge hydrogen gas generated from the inner wall of the negative electrode plate 40 and the electrolytic cell 20.

It is preferable that the gas filter 100 is further provided at the rear ends of the hydrogen gas outlet 81 and the oxygen gas outlet 82 to remove particulates and water vapor of the electrolyte from the discharged oxygen gas and hydrogen gas.

The oxygen gas storage container 92 and the hydrogen gas storage container 91 store the discharged oxygen gas and hydrogen gas, respectively.

1 is a perspective view showing a gas generator according to the present invention.

2 is a cross-sectional view showing the internal structure of the gas generator according to the present invention.

Figure 3 is a cross-sectional view showing the internal structure of the gas generator according to the present invention.

Figure 4 is a perspective view showing the arrangement of the positive electrode plate of the present invention.

5 is a cross-sectional view showing an electrode plate of the present invention.

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

10: water supply 11: filter

20: electrolyzer 21: heat dissipation piece

22: low frequency vibrator 30: positive electrode plate

40: negative electrode plate 31: gas moving groove

50: positive electrode ground terminal 60: negative electrode ground terminal

70: diaphragm 81: hydrogen gas outlet

82: oxygen gas outlet 91: hydrogen gas storage container

92: oxygen gas storage container 100: gas filter

110: level check tube

Claims (13)

A water supply 10 for supplying water; An electrolytic cell 20 which is made of lead (Pb) plate, is supplied with water by the water supply device 10 to be electrolyzed, and a negative voltage is applied thereto; The plurality of electrolytic cells 20 are alternately installed and spaced apart, and hydrogen and oxygen are generated by oxidation and reduction by application of current, and are made of a positive electrode plate 30 made of lead peroxide (PbO ₂ ) and lead (Pb). Negative electrode plate 40; A positive electrode ground terminal 50 and a negative electrode ground terminal 60 connected to the positive electrode plate 30 and the negative electrode plate 40 in parallel and respectively installed outside the electrolytic cell 20; It is installed inside the electrolytic cell 20 and wraps around each of the positive electrode plates 30, and electrolyte and ions pass therethrough, and the oxygen gas and negative electrode plates 40 and the inner wall of the electrolytic cell 20 generated from the positive electrode plate 30 pass through. A plurality of diaphragms 70 that are isolated from each other to prevent mixing of the generated hydrogen gas; A hydrogen gas outlet 81 installed in the electrolytic cell 20 to discharge hydrogen gas generated from an inner wall of the negative electrode plate 40 and the electrolytic cell 20; An oxygen gas outlet 82 which communicates with each of the diaphragms 70 to merge oxygen gas generated from the positive electrode plate 30 in each of the diaphragms 70 and discharge the combined oxygen gas; A hydrogen gas storage container 91 and an oxygen gas storage container 92 for storing hydrogen gas and oxygen gas discharged to the hydrogen gas outlet 81 and the oxygen gas outlet 82, respectively; Gas generating device comprising a. The method of claim 1, The positive electrode plate 30 and the negative electrode plate 40 are kneaded with lead peroxide (PbO ₂ ) fine powder and lead (Pb) fine powder respectively with sulfuric acid, and then sintered by filling them in a lead plate having a lattice-shaped frame. Gas generator. The method according to claim 1 or 2, Each of the diaphragm 70 contacts the positive electrode plate 30 and supports the diaphragm 70 so as to be spaced apart from the positive electrode plate 30, and the oxygen gas generated in the positive electrode plate 30 moves upward. The inner support portion 71 of the pillar or the projection form is provided at a predetermined interval so that the oxygen gas movement passage 73 is provided, Outside of each of the diaphragm 70 is in contact with the adjacent negative electrode plate 40 and supports the diaphragm 70 to be spaced apart from the negative electrode plate 40 and the hydrogen gas generated in the negative electrode plate 40 is upward Gas generating apparatus, characterized in that the outer support portion 72 is provided with a column or a projection is arranged at a predetermined interval so that the hydrogen gas movement passage 74 is moved. The method of claim 3, wherein The inner support part 71 and the outer support part 72 have a height such that the separation distance between the diaphragm 70, the positive electrode plate 30, and the negative electrode plate 40 is 3 to 10 mm. . The method according to claim 1 or 2, Part of the connection portion 32 between the positive electrode plate 30 and the positive electrode ground terminal 50 is exposed to the outside of the diaphragm 70, the gas generator, characterized in that the insulation coating. The method according to claim 1 or 2, Gas generator, characterized in that the outside of the electrolytic cell 20 is further provided with a heat dissipation piece (21) for dissipating heat generated inside the electrolytic cell (20). The method according to claim 1 or 2, The positive electrode plate 30 and the negative electrode plate 40 are gas generators, characterized in that a plurality of gas movement grooves 31 are formed from the bottom to the top to facilitate the movement of the generated hydrogen and oxygen gas to the top . The method according to claim 1 or 2, The low frequency vibrator 22 which discharges bubbles generated when hydrogen and oxygen are generated in the negative electrode plate 40 and the positive electrode plate 30 from the negative electrode plate 40 and the positive electrode plate 30 inside or outside the electrolytic cell 20. Gas generator characterized in that it is further provided. The method of claim 8, The vibration frequency of the low frequency vibrator (22) is a gas generator, characterized in that 120 Hz equal to the normal AC frequency. The method according to claim 1 or 2, The electrolyzer 20 is provided with a water level sensor for checking the water level supplied to the electrolyzer 20 to operate in conjunction with the water supply 10, the electrolyzer 20 outside the electrolyzer 20 Gas generating device, characterized in that provided with a water level check tube 110 for checking the water level. The method according to claim 1 or 2, The water supply unit 10 is a gas generator, characterized in that provided with a check valve to prevent the back flow of the supplied water. The method according to claim 1 or 2, Gas generator, characterized in that the filter is further provided for filtering the water is installed in front of the water supply (10). The method according to claim 1 or 2, And a gas filter (100) installed at a rear end of the gas outlet (81,82) to remove particulates and water vapor of the electrolyte from the discharged gas.

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