KR20160121949A - Bubble separator for hydrogen generation apparatus - Google Patents

Abstract

The present invention relates to a hydrogen-oxygen mixed gas generator for generating hydrogen and oxygen gas by electrolyzing water (electrolytic solution). More specifically, the present invention relates to an electrolytic cell bubble separator for a hydrogen-oxygen mixed gas generator, capable of increasing the generation of hydrogen-oxygen mixed gas by shaking off bubbles of hydrogen and oxygen gas by forming a brush on the bubble forming site. In the case of a hydrogen-oxygen mixed gas generator of the related art, air bubbles are not separated from the surface of an electrode plate (including a charging plate supplied with electric current flowing from the electrode plate through the electrolytic solution), so the generation of the hydrogen-oxygen mixed gas is reduced due to the reduction of an amount of floated bubbles. According to the present invention, provided is an apparatus for separating bubbles from an electrode plate of a hydrogen-oxygen mixed gas generator, in which bubbles formed on the electrode plate (charging plate) are separated by directly applying impact to the generated bubbles and floated to increase an amount of the generated gas mixture. In addition, the brush is formed on one side of the electrode plate (charging plate) where bubbles are generated to rotate by the electrolytic solution circulated from a cooling unit, and the bubbles formed on the electrode plate (charging plate) are brought into contact with the brush, so the bubbles are separated from the electrode plate.

Description

TECHNICAL FIELD [0001] The present invention relates to an electrolytic cell bubble separator for a hydrogen-

The present invention relates to a hydrogen-oxygen mixed gas generating apparatus for generating hydrogen and oxygen gas by electrolyzing water (electrolytic solution), and more particularly, to a hydrogen-oxygen mixed gas generating apparatus for generating water by bubbling hydrogen, And an electrolytic bath bubble separator of a hydrogen-oxygen mixed gas generator capable of raising the amount of hydrogen / oxygen mixed gas generated.

Due to rapid industrial development and indiscriminate environmental development, air pollution The destruction and pollution of the natural environment has reached a serious level, which is threatening not only the ecosystem but also the health of mankind.

In recent years, especially as a result of serious air pollution, damage due to global greenhouse is extremely severe. In order to cope with serious pollution problem such as this warming, introduction of green card to activate green purchasing, We have tried various ways to reduce energy use while proposing policies to reduce energy consumption, but it is not enough.

Therefore, there is an urgent need for new alternative energy sources, so research on environmentally friendly energy sources is being actively carried out. Among them, a device for generating hydrogen-oxygen mixed gas is attracting attention.

Generally, a hydrogen-oxygen mixed gas generator is a device for generating hydrogen and oxygen by electrolyzing water (electrolytic solution).

A mixed gas apparatus for electrolyzing water and generating a mixed gas of hydrogen and oxygen supplies water (electrolytic solution) to which an electrolytic substance is added in a small amount in an electrolytic cell provided with an electrode plate having positive and negative potentials, And circulating the electrolytic bath through the means to generate a hydrogen and oxygen mixed gas which is pollution-free energy.

A mixture of hydrogen and oxygen is produced at a molar ratio of hydrogen: oxygen = 2: 1, which is usually an optimum ratio.

When a current is applied to the electrode plate, the electrode plate electrolyzes the electrolytic solution. In this process, air bubbles are generated on the surface of the electrode plate. Then, when the bubbles generated on the surface of the electrode plate float above the surface of the electrolytic solution, when the hydrogen bubbles burst, the hydrogen coral mixed gas in the bubbles is discharged to the outside and charged into the storage tank.

However, since the air bubbles attached to the surface of the electrode plate are not well separated from the electrode plate (including the charging plate supplied with the electric current from the electrode plate through the electrolytic solution) Causing the generation amount to be lowered.

Therefore, in the electrode plate vibration structure of the oxygen / hydrogen mixed gas generating apparatus of Korea Registered Utility Model No. 0394845, the electrode plate is vibrated so that the bubbles attached to the surface of the electrode plate are separated from the electrode plate, Plate vibration structure.

However, theoretically, the result is that the bubbles generated in the electrode plate are caused by the ultrasonic vibration, but when applied to an actual device, the bubbles are generated in the electrode plate in the electrolyte, The bubbles are not easily separated from the electrode plate.

In view of the above, in the present invention, bubbles formed on the electrode plate (charge plate) are directly blown by impacting the generated bubbles to raise the amount of mixed gas generated. In the electrolyte solution circulated from the cooling means A brush is formed on one side of an electrode plate (charging plate) where bubbles are generated so as to rotate by a hydrogen-oxygen mixture (bipolar plate) so that air bubbles formed on the electrode plate (charging plate) And an electrode plate bubble separator of the gas generating apparatus.

The electrolytic cell bubble separating apparatus of the hydrogen-oxygen mixed gas generating apparatus of the present invention comprises:

The present invention is characterized in that an electrolyte circulation hole for providing a circulation path of an electrolyte solution from a cooling device is formed on one side and an electrode plate structure in which a voltage is supplied to both sides of the electrode plate structure, Of the electrolytic bath.

A plurality of electrification front module modules, each of which is provided with a brush so as to rotate so as to be able to touch bubbles formed on the electrification plate so as to be able to touch the electrification plate, are formed in a plurality of spaces between the both electrode plates, A rotating unit connected to the brush of the charging plate module and rotated by an electrolytic solution flowing into the charging unit side of the electrolytic solution is constituted by a charging plate module connected to the brush of the charging plate module, The brushes of the charging plate modules interlocked with the rotating means and the rotating means are rotated by the circulating electrolyte to separate the bubbles generated in the charging plate formed in the charging plate module from the charging plate by the brush, And is raised to the water surface.

According to the present invention, since the bubbles are separated from the charging plate as soon as the bubbles are generated, the generation space (area) of the bubbles is secured within a short time, and more hydrogen / oxygen mixed air can be obtained within the same time.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic overall configuration of a hydrogen-oxygen mixed gas generator of the present invention. FIG.
BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a hydrogen-
3 is a front view and a side sectional view of a front cover according to the present invention.
4 is a front view and a side sectional view of an electrode plate in the present invention.
5 is a front view and a side sectional view of a module assembly according to the present invention.
6 is a front view and a side sectional view of a rear cover according to the present invention.
Fig. 7 is a front view and a side sectional view of a spindle according to the present invention; Fig.
8 is a front view and a side sectional view of a brush according to the present invention.
9 is a front view of an electrode plate in the present invention.
10 is an exploded perspective view of a charging plate module for showing a coupling structure of a module assembly according to the present invention.
11 is a cross-sectional view taken along the line A-A 'in Fig. 2 for showing the state of coupling of module assemblies in the present invention.
12 is a cross-sectional view taken along the line B-B 'in Fig. 2 for showing the engagement state of the spindle in the present invention.
13 is a view for showing a brushing action in the present invention.

The configuration and operation of the electrolytic cell bubble separator of the hydrogen-oxygen mixed gas generator of the present invention will be described with reference to the embodiments shown in FIGS. 1 to 13. FIG.

The electrolytic cell bubble separating apparatus of the hydrogen-oxygen mixed gas generating apparatus of the present invention comprises:

An electrolytic cell (100) having an electrolytic solution circulation port for providing a circulation path of an electrolytic solution from a cooling device (200) and having an air discharge port for discharging hydrogen / oxygen generated by electrolysis, The front cover 110 and the rear cover 140 are formed on the front and rear surfaces of the front cover 110 and the rear cover 140. The front cover 110 and the rear cover 140 are provided with electrode plates 120 And a charging plate module 130 provided with a brush 123 for rotating the charging plate 121 so as to be able to touch the bubbles formed on the charging plate 121 is disposed between the both electrode plates 120 ), Respectively,

The charging plate module 130 is coupled to the brush 133 of the charging plate module 130 in such a manner that the brush 133 of the charging plate module 130 is connected to the brush 133 of the adjacent charging plate module 130, And a rotating plate 150 which is rotated by an electrolytic solution flowing into the rotating plate module 130. The rotating plate 150 is connected to the brush 133 of the charging plate module 130 adjacent to the rotating plate 150, The brush 133 of each charging plate module 130 interlocked with the discharge plate 150 and the spindle 150 rotates so that the bubbles generated in the charging plate 131 formed in the charging plate module 130 are contacted by the brush 133 And is separated from the charging plate 131 so as to rise to the electrolytic solution water surface.

The present invention as described above includes an electrode plate 120 for electrolyzing electrolytic solution and a brush 133 for blowing air bubbles to the charging plate 131 charged by the electrolytic solution from the electrode plate 120 and electrolyzing the electrolytic solution So that the generation of air bubbles can be increased.

The present invention is a structure in which bolt holes B are formed along the edge surfaces of the front cover 110, the electrode plate 120, the charging plate module 130, and the rear cover 140, .

As shown in FIG. 3, the front cover 110 is provided with an electrolyte circulation hole 110a for circulating the electrolytic solution to the cooling device in the center lower portion, and separating hydrogen / oxygen into a collecting tank (Not shown in the figure) for detecting the water level in the electrolytic bath 100 is formed at one side of the electrolytic solution circulation hole 110a, A water replenishment port 110d is formed at one side of the air discharge port 110b to be connected to a water injection pump.

The electrode plate 120 and the charging plate module 130 are means for generating a mixed gas of oxygen and hydrogen by electrolyzing the electrolytic solution supplied with the DC voltage supplied from the DC square wave control device.

The electrode plate 120 is installed at both ends of the inside of the front cover 110 and the rear cover 120 of the electrolytic bath 100 and the charging plate module 130 is arranged in a plurality of electrode plates 120, And is charged through the electrolyte solution from the electrolyte 120.

10, the charging plate module 130 includes a module assembly 132 to which the charging plate 131 is coupled, and a brush (not shown) is mounted on the charging plate 131 coupled to the module assembly 132 133 are combined with each other.

Fig. 5 is a plan view and side sectional view showing the structure of the module assembly 132. Fig.

Fig. 8 shows a top view and a side sectional view of the brush 133. Fig.

9 shows the above-mentioned charging plate 131. Fig.

The module assembly 132 is provided at the center of the module assembly 132 with a charging engagement portion (not shown) through which the charging plate 131 is exposed in the engaged state and a stepped portion is formed along the outer periphery thereof, 132a.

As shown in FIG. 9, the charging plate 131 may have a disk shape and may have a thickness of about 0.5T (0.5 mm) as an example. The charging plate 131 has a brush engagement hole 131a for coupling the brush 133 ).

Therefore, a step formed on the inside of the charging / contracting portion 132a is configured in consideration of the thickness of the charging plate 131.

The brush 133 is attached to the brush engagement hole 131a of the charging plate 131 coupled to the module assembly 132 as a means for removing bubbles attached to the charging plate 131. [

The brush 133 is inserted into the brush engagement hole 131a of the charging plate 131 at the center of the wing 133a and a wing 133a for bubbling the bubbles generated in the charging plate 131 while rotating, A brush connecting protrusion 133b coupled to the adjoining brush 123 and a brush connecting groove 133c for interlocking the brush 133 adjacent to the back side of the brush connecting protrusion 133b.

The brush connecting protrusions 133b of the brush 133 of the charging plate module 130 adjacent to the brush connecting groove 133c are connected and the brushes 133 of the charging plate module 130 are connected to each other to be interlocked .

As shown in FIG. 7, the spindle 150 rotates relative to the force of the electrolytic solution to rotate the brush 133. The spindle 150 is formed in the shape of a disk, and is formed at the center of the electrode plate 120 A brush connecting protrusion 151 is formed at the center of the brush connecting protrusion 151 and is connected to the brush connecting groove 133c of the brush 133. The electrolytic liquid is transferred along the outer circumference of the brush connecting protrusion 151, And a rotor groove (152) for rotating the electrolyte by the flowing electrolyte.

The spindle 150 is coupled to the rear cover 150 and rotated, and the brush 133 is interlocked.

6, the rear cover 140 is formed with a spindle engaging portion 141 having a central portion opened and a stepped portion formed on an inner side thereof, and the rear cover 140 includes a spindle 150 coupled to the spindle engaging portion 141 An electrolyte inlet 142 for introducing the electrolyte into the spiral groove 152 is formed.

The operation and operation of the present invention having such a configuration will be described as follows.

The brushes 133 are rotated by the electrolytic liquid flowing in the structure in which the brushes 133 and the spindle 150 are interlocked with each other so that the spindle 150 is rotated so that the bubbles of the charging plate 131 are whipped do.

As shown in FIG. 1, the electrolytic solution is circulated in the electrolytic bath while being cooled through the cooling device. The cooling device recognizes the temperature in the electrolytic bath 100 through the water temperature sensor and cools the electrolytic solution flowing from the electrolytic bath 100 And is circulated into the electrolytic bath (100).

Water is replenished through the water replenishment port 110d in accordance with the water level in the electrolytic bath 100. [

When a DC voltage is supplied from the DC square wave control device to the voltage terminal 120b of the electrode plate 120, current flows through the electrode plate 120, and the current is supplied to the respective charge plates 131 ) Is also applied to the electrolytic solution to electrolyze the electrolytic solution. In this process, air bubbles are generated on the surface of the charging plate.

Meanwhile, as described above, the electrolyte flows from the cooling unit through the electrolyte inlet 142 and flows through the electrolyte inlet 142.

At this time, the spindle 150 of the spindle 150 coupled to the rear cover 140 is positioned at the end of the electrolyte inlet 142, so that the spindle 150 rotates while the introduced electrolyte pushes the spindle groove 152 do.

The spindle 150 is in a state in which the electrode plate 120 is coupled to the brush 133 through the charging plate 131 of the charging plate module 130 adjacent to the electrode plate 120 via the coupling hole 121a, And the brush connecting protrusion 151 connected to the brush connecting groove 133c of the brush connecting groove 133c.

The brush 133 connected to the brush connection protrusion 151 is rotated and the brush 133 connected to the brush 133 is rotated so that the air bubble formed while the wing portion 133a of the brush 133 rotates on the charging plate 131 I will shake it off.

When the bubbles generated on the surface of the charging plate 131 rise above the water surface of the electrolytic solution and then burst, the hydrogen-coral mixed gas in the bubbles is discharged to the collection tank through the air outlet 110b.

Since the bubbles formed on the charging plate 131 are discharged in such a short period of time, the bubbles can be reproduced again in the corresponding area, and the production amount of hydrogen / oxygen is increased.

Claims (3)

There is provided an electrolytic cell structure in which an electrolyte circulation port for providing a circulation path of an electrolytic solution is formed on one side and a voltage is supplied to both sides of the electrolytic solution circulation path,
The front and rear surfaces of the electrolytic bath 100 are formed with a front cover 110 and a rear cover 140. Both sides of the front cover 110 and the rear cover 140 are covered with an electrode plate And a charging module 130 having a brush 123 for rotating the charging plate 121 so as to be able to touch the bubbles formed on the charging plate 121, And the brush 133 of each of the charging plate modules 130 is connected to the brush 133 of the adjacent charging plate module 130 to be interlocked with each other The charging plate module 130 is coupled with the brush 133 of the charging plate module 130 which is rotated by the electrolytic solution flowing into the electrolytic bath 100 and is adjacent to the float plate 150, And rotating means for rotating by an incoming electrolytic solution. Sum electrolytic cell foam separation device of the gas generator. The charge plate module according to claim 1, wherein the charge plate module (130)
A module assembly 132 fixed to the front cover 110, the electrode plate 120 and the rear cover 140 through bolt holes B formed along the edge surfaces thereof and having a charging plate 131 coupled thereto, A plate 133 and a brush 133 coupled to the charging plate 131 are formed,
The module assembly 132 includes a charging fixation joint portion (not shown) having a center hole formed at its center so as to expose the charging plate 131 in a coupled state and a stepped portion formed along the outer periphery thereof, 132a,
The charging plate 131 is formed in a disc shape and has a brush coupling hole 131a for coupling the brush 133 at the center,
The brush 133 includes a wing 133a for blowing out the bubbles generated in the charging plate 131 while rotating the brush 133 and a brush 133 for coupling the charging plate 131 to the center of the wing 133a. A brush connecting protrusion 133b which is inserted into the hole 131a and is engaged with the adjacent brush 123 and a brush connecting protrusion 133b which is inserted into the back surface of the brush connecting protrusion 133b and is adjacent to the brush 133, 133c). ≪ / RTI > The brush unit according to claim 1 or 2, wherein the rotating unit is mounted on the rear cover (150) in a circular plate shape and is fitted in a coupling hole (120a) formed at the center of the electrode plate (120) A brush groove connecting protrusion 151 interlocking with the connection groove 133c is formed at the center and an electrolyte groove is formed along the outer circumference so as to be positioned at the electrolyte inflow end so as to rotate by the introduced electrolyte, (150). The apparatus for separating electrolytic cells of an electrolytic cell according to claim 1,

Images