KR200219181Y1 - Electrolysis pail for oxygen,bydrogen compositeness gas occurrence - Google Patents

Abstract

The present invention relates to an electrolytic cell for oxygen and hydrogen composite gas generation, and to attach a heat sink 202 to the entire outer circumference of the electrolyzer body 2 and a bolt 701 on the upper fixing plate 7 of the pole tube 6 in the electrolyzer body 2. 6) by protruding and fixing the end thereof to the metal plate 902 on the upper portion of the metal support plate 9 formed with the wire 15 and the contact portion 901 formed at each corner while being formed on the upper surface of the electrolytic cell body 2. The electrolytic cell body 2 is suspended and installed, and a plurality of packing plates 903 and a synthetic resin plate 10 are placed between the metal support plate 9 and the metal plate 902 so as to be alternately stacked, and then the metal plate 902. ) And the support plate (9) to be crimped and fixed with an insulator (12) so that the inside of the electrolytic cell body (2) is sealed, while the synthetic resin sheathing tube (112) is fastened to the outer periphery of the bolt (701) The upper end contacts the bottom of the synthetic resin plate 10 superimposed on the support plate (9) One side of the electrolyzer body (2) forms an injection port (3) in which a safety valve (301) is installed, and a sludge dropping tube (4) is provided in the lower part of the electrolyzer body (2) to connect the electrolyzer body (5). 2) It is connected so as to communicate with the inside and the connection pipe (5) is to cut the central portion so that the valve 501 is interposed therebetween to facilitate the disassembly and to facilitate the sludge discharge smoothly.

Description

Electrolyte for oxygen, hydrogen composite gas generation {Electrolysis pail for oxygen, bydrogen compositeness gas occurrence}

The present invention relates to an electrolytic cell that generates oxygen and hydrogen by being installed in an oxygen / hydrogen composite gas generator, and in particular, makes sludge discharge smooth and electrically safe while simplifying disassembly and assembly.

In the conventional electrolytic cell 50, as shown in FIG. 5, the synthetic resin fixing plates 53 and 54 are disposed on upper and lower ends of the polar tube 52 in the electrolytic cell body 51 having the injection hole 511 formed on the upper surface thereof. After fixing the bolt 55 of the lower fixing plate 54 to the outside of the insulating pad 56 of the bottom of the electrolytic cell body 51 to the wire 57 is coupled.

However, since the sludge discharge hole is not formed, the electrolytic cell 50 having such a structure is difficult to be decomposed. When sludge is deposited and accumulated in the lower part of the electrolytic cell body 51, the accumulated sludge is difficult to remove and thus the productivity is lowered. For this reason, if the accumulating sludge is left unattended, an electrical short (SHORT) phenomenon occurs due to the accumulation of sludge in the interior of the cathode tube 52, thereby damaging the cathode tube 52, and thus, the life of the electrolyzer 50 is considerably shortened. Of course, there was a drawback that the insulating pad 56 at the bottom of the electrolytic cell body 51 melted easily due to a short phenomenon and the electrolyte was leaked.

In addition, since the electrolyte leaked by the insulating pad 56 is penetrated into the electric wire 57 under the electrolytic cell body 51, it destroys the insulation state between the electrolytic cell main body 51 and the electric wire 57, and thus, a short and overcurrent phenomenon There was a problem to stop the operation of the generator by causing the,

In addition, since the injection hole 511 is formed on the upper surface of the electrolytic cell body 51, when water is injected into the electrolytic cell body 51 based on the injection hole 511, water is incorrectly injected or due to over-injection of the electrolytic cell body 51. When overflowing, the overflowing water flows along the outer surface of the electrolyzer body 51, affecting the surrounding electrical apparatus, thereby causing an electrical problem around the electrolyzer body 51 and the electrolyzer body 51. Since a plurality of heat sinks 512 are attached to the electrolytic cell body 51 only up to three quarters of the total length of the electrolytic cell body 51, the heat dissipation ability of the high temperature generated in the electrolytic cell body 51 is reduced, and thus the electrolytic cell 50 can not be continuously operated. Thereby lowering the productivity.

The present invention has been developed to solve the above-mentioned conventional discontinuity and to prevent the electrical short phenomenon and leakage of the electrolyte and excellent heat dissipation effect, which will be described in more detail with the accompanying drawings as follows.

1 is an exemplary view of a composite gas generating device in which the present invention is installed

2 is a perspective view of the present invention

3 is a longitudinal cross-sectional view of the subject innovation

4 is a partial perspective view of the present invention

5 is a diagram illustrating a conventional electrolytic cell.

* Explanation of symbols for important parts of the drawings

B: gas generating part C: gas processing part

D: Detection and Control 1: Electrolyzer

2: electrolytic cell body 202: heat sink

3: inlet 301: safety valve

4: sludge dropping tube 5: connector

501: valve 6: pole tube

7,8: fixing plate 701: bolt

9: support plate 901: contact groove

902: metal plate 903: packing plate

10: synthetic resin plate 112: coating tube

12: insulation hole 13: coupling bolt

14 Nut 15 Wire

In installing the pole tube 6 in the electrolytic cell body 2 to which the plurality of heat sinks 202 are attached to the outer periphery, and fixing it with the upper and lower synthetic resin fixing plates 7 and 8, the entire outer periphery of the electrolytic cell body 2 The heat sink 202 is attached thereto, and the bolt 701 is protruded to the upper fixing plate 7 of the pole tube 6 in the electrolytic cell body 2 so that an end thereof is formed on the upper surface of the electrolytic cell body 2. 15) The pole tube 6 is suspended in the electrolytic cell body 2 by being fixed to the metal plate 902 on the metal support plate 9 on which the contact grooves 901 are formed, and the metal support plate 9 and the metal plate 902 above. A plurality of packing plates 903 and a synthetic resin plate 10 are placed to be superimposed alternately, and then a plurality of vertically separated insulating holes 12 are equally spaced from the metal plate 902 to the support plate 9 so as to be spaced apart. The inside of the electrolytic cell body 2 by pressing and fixing with the bolt 13 and the nut 14 It is to be sealed, but the upper end of the coating tube 112 is in contact with the bottom of the synthetic resin plate 10 superimposed on the support plate (9) while the synthetic resin coating tube 112 is fastened to the outer periphery of the bolt 701 and the upper part of the electrolytic cell body (2) One side of the safety valve 301 is formed in the inlet (3) is installed, the lower part of the electrolytic cell body (2) is provided with a sludge dropping tube (4) so as to communicate with the interior of the electrolytic cell body (2) by the connecting pipe (5). The connection pipe 5 is to cut the center portion so that the valve 501 is interposed therebetween.

The present invention as described above, when sludge is generated when electrolyzing water in the electrolyzer body 2 to generate oxygen and hydrogen complex gas, the sludge generated is precipitated to the lower side of the electrolyzer body 2 and the connection pipe 5. The sludge dropping tube 4 connected to the dropping and dropping is collected and the sludge can be removed by separating the sludge dropping tube 4 from the valve 501 of the connecting pipe 5 and the valve 501 ) To prevent the discharge of electrolyte in the electrolytic cell body (2).

Therefore, the present invention can collect the sludge produced as described above into the sludge dropping tube 4 and remove the collected sludge by separating the sludge dropping container 4, thereby preventing the electric short phenomenon caused by the accumulated sedimentation of the sludge. 6) It is possible to prevent damage and at the same time, it does not need to be cleaned for a long period of time, and as a result, it is possible to obtain an electrolytic cell (1) with a long life, thereby improving productivity.

In addition, since the bolt 701 of the upper fixing plate 7 for fixing the pole tube 6 in the electrolytic cell body 2 is fixed to the metal plate 902 fixed to the upper part of the supporting plate 9, it is suspended in the electrolytic cell body 2. The entire electrolytic apparatus (cathode, upper and lower plate, coated tube) can be disassembled by separating the metal plate 902 from the support plate 9, so that the inside of the electrolytic cell body 2 can be easily cleaned and the after-sales service of the electrolytic cell 1 is also convenient. There is also an advantage that it can also be a lot of space is formed between the pole tube (6) and the bottom of the electrolytic cell body (2) which is suspended in the electrolytic cell body (2) is easy sludge precipitation and the bolt 701 is fixed to the metal plate 902 The outer surface of the synthetic resin cladding tube 112 is coated to contact the bottom surface of the synthetic resin sheet 10 between the metal plate 902 and the support plate 9 to prevent electrical short-circuit in the electrolytic cell body 2. At the same time to prevent corrosion of the bolt This will be in.

In addition, a packing plate 903 is disposed between the metal plate 902, the support plate 9, and the synthetic resin plate 10, and they are crimped with a plurality of insulators 12 which are bound by the coupling bolt 13 and the nut 14. Since it is fixed, it is possible to maintain perfect airtightness in the electrolytic cell body 2, and also have the effect of reliably realizing insulation between the electrolytic cell body 2 and the metal plate 902,

In addition, since the wires 15 and the contact grooves 901 are formed at each corner of the support plate 9, even if the electrolyte leaks, the penetration of the electrolyte leaked into the wire 15 is prevented, thereby solving the electrical problem. Since the injection port 3 is protruded to one side of the main body 2, the water is prevented from flowing out of the electrolyzer body 2 even if the water flows due to over-injection of the water into the electrolytic cell body 2 or flooded or misinjected. Since the electrical short phenomenon is completely eliminated, and the heat sink 202 is attached to the entire outer circumference of the electrolytic cell body 2, the heat dissipation ability is improved, so that the continuous use of the electrolytic cell 1 is possible.

Claims (1)

In installing the pole tube 6 in the electrolytic cell body 2 to which the plurality of heat sinks 202 are attached to the outer periphery, and fixing it with the upper and lower synthetic resin fixing plates 7 and 8, the entire outer periphery of the electrolytic cell body 2 The heat sink 202 is attached thereto, and the bolt 701 is protruded to the upper fixing plate 7 of the pole tube 6 in the electrolytic cell body 2 so that an end thereof is formed on the upper surface of the electrolytic cell body 2. 15) The pole tube 6 is suspended in the electrolytic cell body 2 by being fixed to the metal plate 902 on the metal support plate 9 on which the contact grooves 901 are formed, and the metal support plate 9 and the metal plate 902 above. A plurality of packing plates 903 and a synthetic resin plate 10 are placed to be alternately superimposed, and then the metal plate 902 and the support plate 9 are pressed and fixed with several insulators 12. 2) The inside is sealed, but the synthetic resin coating pipe 112 sieves around the bolt 701 The top of the cladding tube 112 is in contact with the bottom surface of the synthetic resin plate 10 superimposed on the support plate 9, and on one side of the electrolytic cell main body 2, an injection port 3 in which a safety valve 301 is installed is formed. (2) the lower portion is provided with a sludge dropping tube (4) connected to the electrolytic cell body (2) by the connection pipe (5), the connection pipe (5) is cut in the center portion between the valve 501 intervening Electrolyzer for oxygen and hydrogen complex gas generation.