KR20050049148A - Expandable electrolyte cell - Google Patents

Abstract

The present invention relates to an electrolyzer that generates oxygen and hydrogen mixed gas.

The present invention provides an electrolytic cell having an electrode plate (10) and decomposing an electrolyte to generate oxygen and hydrogen mixed gas, comprising: a unit cell (2) accommodating the electrode plate 10 of a predetermined quantity at uniform intervals; Fastening member for horizontally binding the predetermined number of unit cells (2): and the insulating cover 12 mounted on the fastening member via an insulating washer 32 to accommodate the outside of the plurality of unit cells (2) It characterized by consisting of.

According to the above configuration and operation, the present invention forms a single electrolytic cell by continuously attaching unit cells composed of a plurality of electrode plates, and the capacity of the unit cells can be easily increased by increasing the number of unit cells according to the amount of gas generated, and electrolyte solution in a laminated structure. It is effective in preventing air leakage and improving airtightness.

Description

Expandable electrolyte cell {Expandable electrolyte cell}

The present invention relates to an electrolytic cell that generates oxygen and hydrogen mixed gas, and more particularly, an electrolytic cell forms a single electrolytic cell by continuously attaching unit cells composed of a plurality of electrode plates. Accordingly, the present invention relates to an electrolytic cell that generates oxygen and hydrogen mixed gas to increase the airtightness by increasing the quantity and to easily increase the capacity, and to prevent leakage of the electrolyte by using fasteners.

Oxygen and hydrogen mixed gas, commonly known as brown gas, aqua gas and water gas, is a mixed gas in which the content ratio is 1: 2 without separating the oxygen and hydrogen obtained by electrolyzing water. Oxygen and hydrogen mixed gas generates super high temperature by inducing the phenomenon of condensation (flaming) during combustion, and it is recognized as a clean energy source without environmental pollution because it not only has excellent energy efficiency but also generates water vapor after combustion.

In general, an electrolysis apparatus is provided with a plurality of diaphragms in an electrolytic cell, and includes two electrode plates in a space provided between the diaphragms, so that oxygen and hydrogen gas are separated from the electrolyte filled in the electrolytic cell by applying power. The separated gas is to be used for cutting and welding the material.

However, the oxygen and hydrogen mixed gas generated during the electrolysis process of the electrolytic solution cannot be compressed and stored in the container. Therefore, a large-capacity mixed gas device is required, but it is difficult to manufacture a large-capacity generating device. In case of electrolyte leakage, the risk of electric shock or explosion was always inherent.

Accordingly, the present invention consequently forms one electrolytic cell by continuously attaching unit cells composed of a plurality of electrode plates in view of the above disadvantages, and the number of unit cells can be easily expanded by increasing the quantity according to the amount of gas generated. In addition, an object of the present invention is to provide an electrolytic cell that generates oxygen and hydrogen mixed gas to increase the airtightness by preventing leakage of the electrolyte by using a fastener.

       In order to achieve the above object, the present invention provides an electrolytic cell having an electrode plate 10 and decomposing an electrolyte to generate oxygen and hydrogen mixed gas:

A unit cell 2 accommodating the predetermined quantity of electrode plates 10 at even intervals;

Fastening member for horizontally binding the predetermined amount of unit cells (2): And

And an insulating cover 12 mounted on the fastening member via an insulating washer 32 to accommodate the outside of the plurality of unit cells 2.

The unit cell 2 of the present invention includes a housing 25 having a protruding jaw 27 on an inner surface and a groove for inserting an O-ring 28 on one side thereof; And a housing cover 22 inserted into the same size as the protruding jaw 27 and spaced apart from the electrode plate 10.

The fastening member of the present invention is an insulating pipe 31 penetrating the unit cell (2), a stud bolt (35) fixed to both ends of the insulating pipe 31, the plate spring at the end of the stud bolt (35) A nut 37 is fastened via 36.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 1 is a perspective view of the overall configuration of the electrolytic cell according to the present invention.

The present invention relates to an electrolytic cell having an electrode plate 10 and decomposing an electrolyte solution to generate oxygen and hydrogen mixed gas. Usually, the electrolytic cell includes a plurality of electrode plates 10 for electrolyzing an electrolytic solution. Usually, when a three-phase 380 volt power source is applied to an electrode, oxygen and hydrogen gas (aka Brown gas) are generated. The electrolyte solution is a mixture of a strong basic solution and distilled water, the distilled water can be used to purify the raw water, such as industrial water or ground water.

 Terminals 18 and 19 are terminals attached to the electrodes to connect the electrodes in the power supply unit, and the terminal 18 and the terminal 19 are configured, and the power supply unit may include a device for rectifying AC power to DC.

The cover 14 is made of metal such as aluminum alloy as a lid surrounding an electrolytic cell such as a unit cell, and glass fiber or glass wool may be added thereto. The insulating cover 12 is installed outside the cover 14 of the electrolytic cell and is used to prevent the conversion of heat by conduction between the inside and the outside of the electrolytic cell. The material of the insulating cover may be an inorganic, magnetic, glass, fibrous, resin, rubber, varnish or the like as a solid insulating material.

In FIG. 1, reference numerals 15 and 15 ′ denote water supply pipes for supplying an electrolyte solution from an electrolyte supply unit to an electrolytic cell, and reference numerals 16 and 16 ′ are gas exhaust pipes for discharging the mixed gas generated in the electrolytic cell to the outside. Although not shown, it is possible to supply the mixed gas by connecting the water removal tank and the gas collection tank to the downstream side of the gas exhaust pipe 16 '.

2 is a cross-sectional view of a unit cell constituting an electrolytic cell according to the present invention.

The unit cell 2 according to the present invention accommodates the predetermined number of electrode plates 10 at uniform intervals. To this end, the unit cell 2 includes an electrode plate 10, a housing 25, a housing cover 22, and the like. The housing 25 and the housing cover 22 are formed of a material having insulation and chemical resistance, and in particular, the housing 25 also requires mechanical strength to protect the electrode plate 10 from external impact.

The unit cell 2 can select the number of electrode plates 10 accommodated in the range of 3 to 6, it is appropriate to configure the four electrode plates 10 and three housing covers 22 as shown. Do. If the quantity of the electrode plate 10 of the unit cell 2 is too small, the number of steps for assembling the electrolytic cell is increased. On the contrary, if the amount of the electrode plate 10 is too high, the capacity of the electrolytic cell cannot be finely changed.

Although not shown, two or three holes are provided in the electrode plate 10 to smoothly move the electrolyte in the unit cell 2. In the case of the two holes, it is preferable to make the holes parallel to the positions of the water supply pipes 15 and 15 'and the gas exhaust pipes 16 and 16' so as to be symmetrical to the lower part and the upper part of the electrode plate. In the case of three holes, it is preferable to dig one hole in the water supply pipe 15 'portion of the lower part of the electrode plate and to dig two holes so as to be symmetrical to the position of the water supply pipe 15 pipe of the electrode plate.

The housing 25 has a protruding jaw 27 on the inner surface of the unit cell 2 and a groove for inserting the O-ring 28 on one side thereof. The housing 25 is made of a material which is completely insulated and free of chemical reactions to the electrolyte and a material having little mechanical deformation. In addition, a material having good moldability for forming the grooves for the protruding jaw 27 and the O-ring 28 is preferable. The protruding jaw 27 is formed in the same cross-sectional size as the housing cover 22 to maintain the electrode plate 10 at uniform intervals. In addition, the electrode plate 10 is prevented from being separated from the housing 25 when the unit cell 2 is moved or stored. The O-ring 28 is inserted in order to prevent the electrolyte from leaking to the outside in a state in which the unit cells 2 are stacked laterally.

The housing cover 22 is inserted in the same size as the protruding jaw 27 to space the electrode plate 10. The housing cover 22 is necessary for securing a space where uniform electrolysis occurs between the electrode plates in the unit cell 2. In the case of digging a groove in the housing cover 22 and the housing 25 and attaching a separator between the electrode plates, it is easy to change the structure to easily separate oxygen and hydrogen gas. The separator may be inserted and installed between the pole plates, and the material of the separator may be asbestos, which is asbestos, which is a fiber of magnesium silicate having high fire resistance and good insulation.

Accordingly, hydrogen gas is generated at the cathode and oxygen gas is generated at the cathode by electrolysis in the spaces between the respective electrode plates 10, and these gases escape the holes processed in the electrode plates 10 to the outside. I will gather.

Figure 3 is a left side view of the electrolytic cell according to the present invention, Figure 4 is an enlarged partial cross-sectional view of the main portion of the electrolytic cell according to the present invention.

The fastening member of the present invention horizontally binds the unit cell 2 of the predetermined amount. The fastening member is composed of an insulating pipe 31, a stud bolt 35, a dish spring 36, a nut 37 and the like.

Through-holes are formed in four sides of the housing 25 in the unit cell 2 at regular intervals, and the insulation pipes 31 of the same size are inserted in this order as shown in the figure. The insulating pipe 31 provides the fastening effect and the insulating effect between the unit cell 2 and the stud bolt 35.

The stud bolts 35 are fixed to the same size at both ends of the insulating pipe 31. According to the overall design capacity of the electrolyzer, a stud bolt 35 of appropriate length is used in combination with the insulation pipe 31. The coupling of the stud bolt 35 and the insulating pipe 31 is preferably to dig a spiral groove in the insulating pipe to be coupled in a spiral manner.

The nut 37 is fastened to the end of the stud bolt 35 via a plate spring 36. Dish spring 36 combines a plurality of pairs of the state facing each other as shown in the figure and keeps the clamping force constant in response to changes in expansion and contraction of the electrolytic cell. It also prevents the nut 37 from loosening like a spring washer.

In addition, the present invention includes an insulating cover 12 mounted on the fastening member via an insulating washer 32 to accommodate the outside of the plurality of unit cells 2. The insulating cover 12 is in contact with the outer surface of the unit cell 2 in the form of a plate so that only the entire cover of the electrolytic cell passes through the heat.

The insulating washer 32 is inserted between the insulating cover 12 and the dish spring 36 on the stud bolt 35, and prevents damage to the insulating cover 12 and obtains an insulating effect during assembly. .

In assembling, the unit cells 2 of the set quantity are arranged horizontally, the insulation cover 12 is disposed outside thereof, and then a plurality of insulation pipes 31 are inserted in turn, and are placed at both ends of the stud bolts 35. The insulating washer 32, the dish spring 36, and the nut 37 are inserted in this order. It is preferable to use a torque wrench for the final assembly of the nut 37.

According to the above configuration and operation, the present invention forms a single electrolytic cell by continuously attaching unit cells composed of a plurality of electrode plates, and the capacity of the unit cells can be easily increased by increasing the number of unit cells according to the amount of gas generated, and electrolyte solution in a laminated structure. It is effective in preventing air leakage and improving airtightness.

It is apparent to those skilled in the art that the present invention is not limited to the described embodiments, and that various modifications and variations can be made without departing from the spirit and scope of the present invention. Therefore, such modifications or variations will have to belong to the claims of the present invention.

1 is a perspective view of the overall configuration of the electrolytic cell according to the present invention.

2 is a cross-sectional view of a unit cell constituting an electrolytic cell according to the present invention.

3 is a left side view of an electrolytic cell according to the present invention.

Figure 4 is an enlarged partial cross-sectional view of the main portion of the electrolytic cell according to the present invention.

Explanation of symbols on the main parts of the drawings

10: electrode plate 12: insulation cover

14: cover 15,15 ': water pipe

16, 16 ': Gas exhaust pipe 18:-terminal, 19: + terminal

22: housing cover 25: housing

26: through hole 27: fastening projection jaw

28: O-ring 31: insulation pipe

32: Insulation washer 35: STUD BOLT

36: Dish spring

Claims (3)

In an electrolytic cell having an electrode plate 10 and decomposing an electrolyte solution to generate oxygen and hydrogen mixed gas: A unit cell 2 accommodating the predetermined quantity of electrode plates 10 at even intervals; Fastening member for horizontally binding the predetermined amount of unit cells (2): And And an insulating cover (12) mounted on the fastening member via an insulating washer (32) to accommodate the outside of the plurality of unit cells (2). The method of claim 1, The unit cell 2 includes a housing 25 having a protruding jaw 27 on an inner surface thereof and a groove for inserting an O-ring 28 on one side thereof; Extended electrolytic cell, characterized in that it comprises a housing cover 22 is inserted into the same size as the protruding jaw (27) to space the electrode plate (10). The method of claim 1, The fastening member includes an insulating pipe 31 penetrating through the unit cell 2, a stud bolt 35 fixed to both ends of the insulating pipe 31, and a plate spring 36 at an end of the stud bolt 35. Expanded electrolytic cell, characterized in that it comprises a nut 37 which is interposed.