KR102616454B1 - Hydrogen generating device - Google Patents

Abstract

The present invention relates to a water electrolysis-type hydrogen generator. More specifically, the invention is designed to improve gas generation efficiency by more easily discharging hydrogen and oxygen gas generated by electrolyzing water through an insulating plate. .
The configuration of the present invention is an anode plate in which an anode receiving portion 11 is formed on one or both sides, water supplied through the anode inlet 13 moves along the anode receiving portion 11, and the positive electrodes are electrically connected. (10) and;
A cathode accommodating portion 21 is formed on one or both sides facing the anode plate 10, a cathode inlet 23 is formed in the cathode accommodating portion 21, and the cathode plate 20 is electrically connected to the cathode electrode. )and;
The anode plate 10 and the cathode plate 20 are disposed opposite to each other or between the anode plate 10 and the cathode plate 20 overlapping, so that each of the anode plate 10 and the cathode plate 20 an insulating plate 30 that insulates;
The insulating plate 30 has a discharge cutout 34 through which gas is discharged on the upper side, and a gas passage hole 36 communicating with the discharge cutout 34 is connected to the anode plate 10 and the cathode plate 20. It is configured to be molded through the insulating head portion 35, which is seated on the upper surface, to discharge gas from the anode accommodating portion 11 and the cathode accommodating portion 21.

Description

Water electrolysis type hydrogen generator {HYDROGEN GENERATING DEVICE}

The present invention relates to a water electrolysis-type hydrogen generator, and more specifically, to improve gas generation efficiency by more easily discharging hydrogen and oxygen gas generated by electrolyzing water through an insulating plate. .

In general, a hydrogen generation device using electrolysis is a device that applies electrical energy to water containing electrolyte, etc., and as water molecules are decomposed, oxygen gas is generated at the anode side and hydrogen gas is generated at the cathode side.

Various types of hydrogen generating devices have been developed and used. Generally, a pair of cases is provided with an inlet and an outlet through which water flows in and out, a positive electrode plate and a negative electrode plate are placed within the case, and a gap between the positive electrode plate and the negative electrode plate is provided. It has a structure in which an ion membrane is placed.

Additionally, as water passes through the space formed on both sides of the case based on the ion membrane, positive plate, and negative plate, water molecules may be decomposed by electrical energy to generate hydrogen and oxygen.

The conventional hydrogen generator as described above uses a case made of an insulator such as synthetic resin, and an ion film, an anode plate, and a cathode plate are placed in close contact within the case made of an insulator.

In addition, various studies are being conducted to extend the contact time of water with the ion film, anode plate, and cathode plate in the hydrogen generator. In general, a water channel is formed inside the case to allow water to proceed along a specific path, and the case A method of slowing down the flow of water by complicating the path of water flowing into the interior was used.

However, in the conventional hydrogen generator as described above, even if the water flow rate is delayed by forming a water flow path in the case, it only controls the time the water is in contact with the anode plate and the cathode plate, so it decomposes water to generate hydrogen. There was a problem with efficiency limitations.

In addition, the hydrogen generator discharged hydrogen generated in the cathode plate through an outlet connected to a storage tank, etc., but the work efficiency and hydrogen discharge were complicated due to the inconvenience of forming an outlet in the cathode plate or molding work to connect the internal cathode path to the outlet. There was a problem that reduced efficiency.

Republic of Korea Patent Publication No. 10-1773022 Hydrogen water/oxygen water generator (registration date August 24, 2017)

In order to solve the problems of the prior art as described above, the purpose of the present invention is to provide a hydrogen generator that can maximize the efficiency of generating and discharging hydrogen.

In addition, the present invention arranges a pair of cathode plates facing each other and arranges an anode plate outside them to form a set of plate blocks, so that oxygen and hydrogen gases generated as water moves from one side through the inlet on the other side. The purpose is to provide a hydrogen generator that can be configured to discharge through a gas discharge cap assembled on the insulating head.

In addition, the present invention provides a hydrogen generator that is configured to discharge hydrogen and oxygen to the upper side through an insulating plate, thereby simplifying the mold of the plate and reducing manufacturing costs to improve product competitiveness. There is a purpose.

According to the present invention to solve this technical problem, an anode receiving portion 11 is formed on one or both sides, water supplied through the anode inlet 13 moves along the anode receiving portion 11, and the positive electrode This electrically connected anode plate (10);

A cathode accommodating portion 21 is formed on one or both sides facing the anode plate 10, a cathode inlet 23 is formed in the cathode accommodating portion 21, and the cathode plate 20 is electrically connected to the cathode electrode. )and;

The anode plate 10 and the cathode plate 20 are disposed opposite to each other or between the anode plate 10 and the cathode plate 20 overlapping, so that each of the anode plate 10 and the cathode plate 20 an insulating plate 30 that insulates;

The insulating plate 30 has a discharge cutout 34 through which gas is discharged on the upper side, and a gas passage hole 36 communicating with the discharge cutout 34 is connected to the anode plate 10 and the cathode plate 20. It is configured to be molded through the insulating head portion 35 mounted on the upper surface of the anode accommodating portion 11 and the cathode accommodating portion 21 to discharge gas.

In addition, the insulating plate 30 is formed with at least two discharge cutouts 34 and gas passage holes 36 connected to the insulating head 35, and the insulating head 35 is connected to the head. The gas discharge cap 50, which is inserted into the fitting hole 51 to collect the gas discharged through the gas passage hole 36 and discharges it to the gas discharge port 55, can be configured to be further assembled.

In addition, the gas discharge cap 50 has a head locking protrusion 52 formed stepwise on the inside of the head fitting hole 51 formed in the longitudinal direction of the insulating head portion 35, so that the insulating head portion 35 As the head locking jaw 52 is assembled, a gas collection space 53 is formed on one side, and a gas outlet 55 is formed on one side of the gas collection space 53.

And, on the inner wall of the anode receiving portion 11, fluid interference holes 12 having a honeycomb shape are continuously protruded at regular intervals, so that water flows from the anode inlet 13 to the cathode inlet 23. It can be configured to move while hitting the fluid interference sphere 12.

In addition, a pair of cathode plates 20 is arranged to face each other with an insulating plate 30 in between, and the anode plate 10 is placed between the other side of the cathode plate 20 and the insulating plate 30. Arranged and assembled to have an anode plate 10, an insulating plate 30, a cathode plate 20, an insulating plate 30, a cathode plate 20, an insulating plate 30, and an anode plate 10, The bottom of the insulating head part 35 protruding from the three insulating plates 30 is supported on the upper surface of the cathode plate 20 and the anode plate 10 and is composed of a set of plate blocks 40, and the insulating head part A gas discharge cap 50 having a head fitting hole 51 formed corresponding to (35) and a gas discharge port 55 communicating with the head fitting hole 51 is configured to be assembled to the insulating head portion 35. can do.

In addition, as the plate blocks 40 are arranged continuously, oxygen and hydrogen gas are discharged through the insulating head portion 35 where the anode and cathode plates face, and the insulating head portion 35 where the cathode and cathode plates face each other. This is achieved by configuring hydrogen gas to be discharged through and oxygen gas to be discharged through the insulating head portion 35 where the anode and anode plate face each other.

According to the present invention, an insulating head portion for discharging hydrogen and oxygen gas is formed on an insulating plate, enabling continuous arrangement between the anode plate and the cathode plate, thereby increasing the discharge efficiency of hydrogen and oxygen gas generated by electrolysis. There is an effect that can be improved.

In addition, a pair of cathode plates are placed facing each other, and an anode plate is placed outside them to form a set of plate blocks, so that oxygen and hydrogen gases generated as water moves from one side through the inlet on the other side are discharged through the insulating head. Convenience in collecting gas can be improved by configuring it to be discharged with a gas discharge cap assembled in the unit.

In addition, it is configured to discharge hydrogen and oxygen to the upper side through the insulating plate, which has the effect of simplifying the configuration, reducing production costs and improving product competitiveness.

Figure 1 is a combined perspective view showing the water electrolysis type hydrogen generator of the present invention.
Figure 2 is an exploded perspective view showing the water electrolysis type hydrogen generator of the present invention.
Figure 3 is a front view of the anode plate of the present invention.
Figure 4 is a front view of the cathode plate of the present invention.
Figure 5 is a bottom perspective view showing the assembled state of the hydrogen gas discharge cap, which is a component of the present invention.
Figure 6 is a plan view of the hydrogen gas discharge cap of the present invention.
Figure 7 is an enlarged cross-sectional view showing the assembled state of the water electrolysis type hydrogen generator of the present invention.
Figure 8 is a cross-sectional view of the insulating plate configured according to the present invention.
Figure 9 is a plan view showing the discharge location of oxygen and hydrogen gas of the present invention.

The present inventor's water electrolysis type hydrogen generator was invented to improve gas generation efficiency by more easily discharging hydrogen and oxygen gases generated by electrolyzing water through an insulating plate.

Hereinafter, the features of the water electrolysis-type hydrogen generating device according to the present invention will be described in detail with reference to the attached drawings.

Since the present invention can be subject to various changes and can have various forms, embodiments will be described in detail in the text. However, this is not intended to limit the present invention to a specific disclosed form, and should be understood to include all changes, equivalents, and substitutes included in the spirit and technical scope of the present invention.

First, the water electrolysis type hydrogen generator to which the present invention is applied is largely provided with an anode plate 10, a cathode plate 20, and an insulating plate 30 located between them, as shown in FIGS. 1 to 8. , and includes a gas discharge cap 50 assembled to the insulating head portion 35 of the insulating plate 30.

The anode plate 10 has a rectangular or square shape and has an anode inlet 13 on one side through which water can flow in and out, and an anode receiving portion 11 on one or both sides. A positive electrode connection portion 18 for connecting electrodes on one side may be formed to protrude.

In addition, the anode plate 10 may be made of metal. In this embodiment, it may be manufactured using titanium. By plating titanium with platinum, the anode plate 10 may be manufactured using titanium. It can increase corrosion resistance and chemical resistance, and can prevent contamination of water, which is an electrolyte, even if the water is ionized.

The metal and plated material applied to the anode plate 10 can be configured in various ways according to the needs of those skilled in the art, so it is not limited to a specific configuration.

In addition, a plurality of coupling holes are formed along the edge of the anode plate 10, and in this embodiment, they are formed to surround the anode receiving portion 11.

In addition, the anode inlet 13 of the anode plate 10 is provided to supply water to the anode accommodating part 11 or discharge water from the anode accommodating part. The anode inlet 13 is located on the anode plate facing the cathode plate. The position and shape at which it is formed can be applied in various ways according to the needs of those skilled in the art, so it is not limited to a specific configuration.

Additionally, the anode inlet 13 may be arranged diagonally from the edge of the anode plate 10, and the discharged water may contain oxygen generated by electrolysis.

In addition, in the anode receiving portion 11 facing the cathode plate 20 on the inner wall of the anode plate 10, fluid interference holes 12 arranged continuously in a honeycomb shape are protruded, as shown in FIG. 3. It is molded into a shape so that the water flowing in through the anode inlet 13 moves in the direction of the cathode plate and moves while hitting the fluid interference hole 12. The shape of the anode receiving portion 11 is limited to a honeycomb shape. However, it can be manufactured in other shapes such as triangles, squares, and circles, which can improve hydrogen generation efficiency by interfering with the movement of water and delaying the flow rate.

The cathode plate 20 has a shape corresponding to the anode plate 10, has a protruding negative electrode connection portion 28 for connecting the electrode upward, and has a penetrating cathode receiving portion 21 formed on one or both sides. .

Here, the cathode plate 20 may be made of a metal like the anode plate 10. In this embodiment, it may be manufactured using titanium, and is manufactured by plating platinum on titanium, thereby forming the cathode plate ( 20) Corrosion resistance and chemical resistance can be improved, and contamination of water, which is an electrolyte, can be prevented even if the water is ionized.

The metal and plated material applied to the cathode plate 20 can be configured in various ways according to the needs of those skilled in the art, so it is not limited to a specific configuration.

In addition, a plurality of coupling holes are formed along the edge of the cathode plate 20. In this embodiment, they are disposed at positions corresponding to the coupling holes formed on the anode plate 10 and are formed to surround the cathode receiving portion 21. do.

The cathode receiving portion 21 is formed on one or both sides of a cathode path portion 22 through which hydrogen gas moves to have a groove shape, and a cathode inlet 23 penetrates both ends of the cathode path portion 22. It is formed so that water supplied through the anode inlet 13 flows into the cathode path part 22 or is supplied to the other side through the cathode inlet 23.

In the present invention, the cathode path portion 22 is formed in a zigzag shape from one side of the inner wall of the cathode plate 20 to the other side, but the shape can be applied in various ways according to the needs of those skilled in the art, so it is not limited to a specific shape. No.

In addition, the negative electrode connecting portion 28 provided on one upper side of the negative electrode plate 20 includes a negative electrode connecting portion 28 that can be formed to connect an external power source to the negative electrode plate 20.

The insulating plate 30 has a shape corresponding to the shape of the anode plate 10 and the cathode plate 20 and is disposed between the anode plate 10 and the cathode plate 20 to prevent water leakage while insulating them from each other. Assemble so that

The insulating plate 30 can be manufactured using Teflon, a material with excellent chemical resistance, heat resistance, and hydrophobicity. A material that can insulate between the anode plate and the cathode plate, such as silicone or synthetic resin material, is used. It is also possible to do so.

In addition, the insulating plate 30 is preferably formed to be relatively thinner than the anode plate 10 and the cathode plate 20, and the thickness may vary depending on the power applied to the anode plate 10 and the cathode plate 20. However, it is not limited to this.

The insulating plate 30 has a coupling hole formed at a position corresponding to the coupling hole formed on the anode plate 10 and the cathode plate 20, between the anode plate and the cathode plate, between the cathode plate and the cathode plate, and between the anode plate and the anode plate. They are respectively disposed between the anode plates, and in a state where the plates are coupled to each other by bolts, etc., water flowing into the anode receiving portion 11 of the anode plate 10 or hydrogen gas generated in the cathode receiving portion 21 is transmitted to the outside. prevent leakage.

In addition, the anode plate 10, the insulating plate 30, and the cathode plate 20 are connected using bolts, etc., and to prevent the anode plate and the cathode plate from being short-circuited by the bolt, the anode plate 10, the insulating plate 30, and the cathode plate 20 are connected to each other using bolts. It can be configured to be electrically insulated by assembling an insulating pipe made of silicone, rubber, or synthetic resin into the coupling port.

In addition, the insulating plate 30 has an insulating head portion 35 protruding from the upper portion, which is seated on the upper surfaces of the anode plate and the cathode plate, and is formed on the bottom of the insulating head portion 35 and the upper side of the diaphragm insertion hole 31. It is integrally molded to have at least two discharge incisions (34).

Therefore, even if a plurality of discharge cutouts 34 are formed on the upper side of the insulating plate 30, they are all connected to the insulating head portion 35, and the insulating head portion 35 has a gas cylinder in communication with the discharge cut portion 34. Since the and holes 36 are formed through each other, the anode can be easily assembled between the anode accommodating part 11 and the cathode accommodating part 21, and the anode can be supplied through the discharge cut part 34 and the gas passing hole 36. Oxygen and hydrogen gases generated in the receiving portion 11 and the cathode receiving portion 21 may be discharged.

In addition, the insulating plate 30 is formed with at least two discharge cutouts 34 and gas passage holes 36 connected to the insulating head portion 35, and the insulating head portion 35 is connected to the head portion 35. The gas discharge cap 50, which is inserted into the fitting hole 51 to collect oxygen and hydrogen gas discharged through the gas passage hole 36 and discharges it to the gas discharge port 55, can be configured to be further assembled.

The gas discharge cap 50 has a head locking protrusion 52 formed stepwise on the inside of the head fitting hole 51 formed in the longitudinal direction of the insulating head portion 35, so that the insulating head portion 35 As it is assembled by being hung on the locking protrusion 52, a gas collection space 53 is formed at the top thereof, and a gas discharge port 55 is formed on one side of the gas collection space 53.

That is, the gas discharge cap 50 has an insulating head portion 35 having a plurality of gas passage holes 36 hermetically inserted into the head fitting hole 51, and collects gas through the gas passage holes 36. The oxygen and hydrogen gases collected in the space 53 are discharged at high pressure through a gas outlet 55 with a small diameter formed on one side of the gas collection space 53.

In addition, at least two of the anode plate 10 and the cathode plate 20 are arranged alternately in succession with the insulating plate 30 interposed to form at least two protruding insulating head portions 35, and the insulating A gas discharge cap 50 having a head fitting hole 51 corresponding to the head portion 35 and a gas discharge port 55 communicating with the head fitting hole 51 is configured to be assembled to the insulating head portion 35. This can be done, but it is natural that the head fitting is molded in accordance with the number of insulating head parts.

In an embodiment of the present invention, a pair of cathode plates 20 is arranged to face each other with an insulating plate 30 in between, and an anode plate 10 is placed on the other side of the cathode plate 20. ) is disposed with an anode plate (10), an insulating plate (30), a cathode plate (20), an insulating plate (30), a cathode plate (20), an insulating plate (30), and an anode plate (10). When assembled, the bottom surfaces of the three protruding insulating head parts 35 are supported on the upper surfaces of the cathode plate 20 and the anode plate 10 to form a set of plate blocks 40.

Here, a gas discharge cap 50 having three head fitting holes 51 corresponding to the insulating head part 35 of the plate block 40 is assembled to the insulating head part 35, so that each gas cylinder The gas moved to the gas discharge cap 50 through the overhole 36 is configured to be discharged through the gas discharge port 55.

When explaining the operating process of the hydrogen generator 100 configured as above, the (+) pole of the direct current power supply is connected to the positive electrode connection portion 18 of the anode plate 10, and the negative electrode connection portion 28 of the cathode plate 20 ) is connected to the (-) pole of the DC power supply.

Then, water is supplied through the anode inlet 13 of the anode plate 10 located on one side of the plate block 40, and the anode receiving portion 11 is filled with water, and the water and the anode plate 10 come into contact with water. This is electrolyzed.

In addition, the water supplied through the anode inlet 13 is supplied along the cathode inlet 23 and the cathode receiving portion 21 and is discharged through the anode inlet 13 provided on both plates 10 on the other side. Hydrogen gas electrolyzed in the cathode plate 20 is collected on the negative electrode receiving part 21, and oxygen gas is collected on the positive positive electrode receiving part 11.

Therefore, when the plate blocks 40 are arranged in series, the anode plate and the anode plate on one side overlap with the insulating plate as shown in FIG. 9, so that during electrolysis, the insulating head portion where the anode plate and the cathode plate face each other Oxygen and hydrogen gas are discharged through (35), hydrogen gas is discharged through the insulating head portion (35) where the cathode plate and the anode plate face, and the insulating head portion (35) where the anode plate and the anode plate face each other. It can be configured to emit oxygen gas through.

Therefore, the insulating head portion 35 of the insulating plate 30 is located at the top of the plate block 40, allowing the gas discharge cap 50 to be easily assembled, and the oxygen collected in the gas collection space 53 And hydrogen gas is configured to be supplied to the oxygen and hydrogen gas purification unit (not shown) through one gas outlet (55).

As described above, the above-described embodiments describe the most preferred examples of the present invention, but are not limited to the above embodiments, and it is clear to those skilled in the art that various modifications are possible without departing from the technical spirit of the present invention. .

10. Anode plate 11. Anode receiving part
12. Fluid interference sphere 18. Positive electrode connection part
20. Cathode plate 21. Cathode receptor
22. Cathode path section 28. Cathode connection section
30. Insulating plate 31. Diaphragm insertion hole
34. Discharge incision 35. Insulating head
36. Hydrogen gas passage hole 40. Plate block
50. Gas discharge cap 51. Head fitting hole
52. Head locking jaw 53. Gas collection space
55. Gas outlet 100. Hydrogen generator

Claims (6)

An anode plate 10 on which an anode receiving portion 11 is formed on one or both sides, water supplied through the anode inlet 13 moves along the anode receiving portion 11, and the positive electrodes are electrically connected;
A cathode accommodating portion 21 is formed on one or both sides facing the anode plate 10, a cathode inlet 23 is formed in the cathode accommodating portion 21, and the cathode plate 20 is electrically connected to the cathode electrode. )and;
The anode plate 10 and the cathode plate 20 are disposed opposite to each other or between the anode plate 10 and the cathode plate 20 overlapping each other, so that the anode plate 10 and the cathode plate 20 are formed respectively. an insulating plate 30 for insulating;
The insulating plate 30 has a discharge cutout 34 through which gas is discharged on the upper side, and a gas passage hole 36 communicating with the discharge cutout 34 is connected to the anode plate 10 and the cathode plate 20. A water electrolysis type hydrogen generator, characterized in that it is molded through the insulating head portion (35) mounted on the upper surface of and is configured to discharge gas from the anode accommodating portion (11) and the cathode accommodating portion (21).
According to clause 1,
In the insulating plate 30,
It is formed with at least two discharge cutouts (34) and gas passage holes (36) connected to the insulating head portion (35), and the insulating head portion (35) is inserted into the head fitting hole (51) to allow gas to pass through. A water electrolysis type hydrogen generator characterized in that a gas discharge cap (50) is further assembled to collect the gas discharged through the hole (36) and discharge it through the gas discharge port (55).
According to clause 2,
The gas discharge cap 50 is,
A head locking protrusion 52 is formed stepwise on the inside of the head fitting hole 51 formed in the longitudinal direction of the insulating head portion 35, so that the insulating head portion 35 is caught on the head locking protrusion 52 and assembled. A water electrolysis type hydrogen generator, characterized in that a gas collection space (53) is formed on one side of the gas collection space (53), and a gas outlet (55) is formed on one side of the gas collection space (53).
According to clause 1,
On the inner wall of the anode receiving portion 11,
It has a honeycomb shape and the fluid interference holes 12 are formed to protrude continuously at regular intervals, so that water moves from the anode inlet 13 to the cathode inlet 23 and moves while hitting the fluid interference holes 12. A water electrolysis type hydrogen generator characterized in that.
According to clause 1,
A pair of cathode plates 20 is arranged to face each other with an insulating plate 30 in between,
The anode plate 10 is disposed between the other side of the cathode plate 20 and the insulating plate 30,
Assembled to have an anode plate 10, an insulating plate 30, a cathode plate 20, an insulating plate 30, a cathode plate 20, an insulating plate 30, and an anode plate 10, three insulating plates are formed. The bottom of the insulating head part 35 protruding from (30) is supported on the upper surface of the cathode plate 20 and the anode plate 10, and is composed of a set of plate blocks 40,
A gas discharge cap 50 having a head fitting hole 51 formed corresponding to the insulating head portion 35 and a gas discharge port 55 communicating with the head fitting hole 51 is provided with the insulating head portion 35. A water electrolysis type hydrogen generator, characterized in that it is assembled to.
According to clause 5,
As the plate blocks 40 are arranged continuously,
Oxygen and hydrogen gas are discharged through the insulating head part 35 where the anode and the cathode plate face each other, and hydrogen gas is discharged through the insulating head part 35 where the anode and the anode plate face each other. A water electrolysis type hydrogen generator, characterized in that oxygen gas is discharged through the insulating head portion (35).

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