TWI877794B - Electrolyzer structure - Google Patents

Abstract

The present invention relates to an electrolytic cell structure, which includes: a first body group having a first opening, a second opening and a chamber; a second body group being assembled with the opening of the first body group, the second body group sealing the first body group; the second body group being equipped with a second body, a plurality of fixed parts and a plurality of first gaskets; the second body sealing the first body group, the second body being equipped with at least one chamber to align with the chamber, each of the chambers being equipped with a plurality of chambers on the outer periphery, each of the plurality of chambers being equipped with a chamber hole; each of the plurality of fixed parts being accommodated in each of the plurality of chambers; the plurality of first gaskets being assembled outside the plurality of chambers; at least one electrode group being assembled from the chamber into the chamber, the electrode group being able to seal the chamber.

Description

Electrolyzer structure

The present invention is related to an electrolytic cell structure, and in particular to an electrolytic cell structure in which the first body group, the second body group and the electrode group are arranged in a manner that can save the volume of the electrolytic cell structure.

As we know before, the commonly used electrolytic cell structure is as shown in patent case No. 105127003, certificate number: I582272, patent name: a tubular electrolytic water treatment machine, the patent structure is:

A tubular electrolytic water treatment machine includes at least: a first electrolytic tube, and the lower side end of the first electrolytic tube is connected to the lower side end of one or more second electrolytic tubes, and a second electrolytic electrode element is arranged in the second electrolytic tube.

However, the shortcomings of this conventional electrolytic cell structure are:

1. After the first electrolysis tube and the second electrolysis tube of the tubular electrolysis water treatment machine are assembled, the overall volume and extension length are quite large and occupy a lot of space. The combined structure with a large volume has very limited space for use. This is a structural defect of the conventional tubular electrolysis water treatment machine structure.

2. Please refer to Figure 1. The upper ends of the first and second electrolytic tubes are permeable. Some substances will produce odors during the electrolysis process. The odors during the electrolysis process are easy to be emitted from the upper ends of the first and second electrolytic tubes. Some of them may even be toxic and harmful to the working environment.

In view of the above-mentioned shortcomings of the conventional structure, the inventor, with many years of experience in manufacturing, production and design in related industries, finally came up with a product with an electrolytic cell structure that can solve the conventional shortcomings.

Problem to be solved by the invention: In conventional electrolytic cell structures, after the first electrolytic tube and the second electrolytic tube are assembled, their overall volume and extension length are quite large and occupy space. In an electrolytic cell structure of the present invention, the first body group, the second body group and the electrode group are assembled, and the first body group, the second body group and the electrode group can save the volume of the electrolytic cell structure.

Technical means to solve the problem: An electrolytic cell structure, which includes: a first body group is provided with a first opening, a second opening and a chamber; a second body group is assembled with the opening of the first body group, and the second body group closes the first body group; the second body group is provided with a second body, a plurality of fixed parts and a plurality of first gaskets; the second body closes the first body group, and the second body is provided with at least one groove to align with the chamber, and each of the grooves is provided with a plurality of grooves on the outer periphery, and each of the plurality of grooves is provided with a hole; each of the plurality of fixed parts is accommodated in each of the plurality of grooves; the plurality of first gaskets are arranged outside the plurality of grooves; at least one electrode group is assembled from the groove to the chamber, and the electrode group can close the groove.

Compared with the effect of the prior art: the first body group, the second body group and the electrode group are arranged in combination, and the first body group, the second body group and the electrode group can greatly save the volume of the electrolytic cell structure. The flow path of the waste liquid of the electrolytic cell structure is composed of the plurality of first body groups and the second body groups. The electrolytic cell structure has the advantage of simple components and saves costs.

In order to enable the members of the Jun Bureau and those familiar with this technology to fully understand the effects of the present invention, the structure and composition of the present invention are explained below with diagrams and figure numbers. However, the following is only used to explain the implementation examples of the present invention and is not intended to limit the present invention in any form. Therefore, any modifications and changes made within the spirit of the present invention should still fall within the scope of protection of the present invention.

10: The first body group

101: First plate

102: Second plate

103: The third plate

104: Support block

105: Closed piece

11: First opening

12: Second opening

13: Storage room

14: First connection section

15: Second connection section

16: Channel

20: Second body group

21: Second body

211: Container

212: Storage tank

213:Rong Kong

22:Fixed parts

23: First gasket

30: Electrode set

31: First electrode plate

311: First conductive part

312: First piercing

32: Second electrode plate

321: Second conductive part

322: Second piercing

33: First screw-on component

331: Second screw-on component

34: Pad

35: First conductive element

351: Second conductive member

36: First gasket

361: Second gasket

37:Joining parts

371: Organization Department

372: The third piercing

373: Second gasket

38: Third screw fitting

39: Fourth screw fitting

Figure 1 is a three-dimensional exploded view of the electrolytic cell structure of the present invention.

Figure 2 is a three-dimensional exploded view of the first body group of the electrolytic cell structure of the present invention.

Figure 3 is a three-dimensional exploded view of the first body component of the electrolytic cell structure of the present invention.

Figure 4 is a three-dimensional exploded view of the second body group of the electrolytic cell structure of the present invention.

Figure 5 is an enlarged view of point A in Figure 4 of the electrolytic cell structure of the present invention.

Figure 6 is a three-dimensional exploded view of the electrode assembly of the electrolytic cell structure of the present invention.

Figure 7 is a three-dimensional assembly diagram of the electrode assembly of the electrolytic cell structure of the present invention.

Figure 8 is a side view of the electrode assembly of the electrolytic cell structure of the present invention.

Figure 9 is a three-dimensional assembly diagram of part of the electrolytic cell structure of the present invention.

Figure 10 is a side view of the electrolytic cell structure Figure 9 of the present invention.

Figure 11 is a three-dimensional assembly diagram of the electrolytic cell structure of the present invention.

Figure 12 is a three-dimensional exploded view of the second embodiment of the electrolytic cell structure of the present invention.

Figure 13 is a three-dimensional exploded view of the third embodiment of the electrolytic cell structure of the present invention.

Figure 14 is a three-dimensional schematic diagram of the third embodiment of the electrolytic cell structure of the present invention.

Figure 15 is a schematic diagram of the third embodiment of the electrolytic cell structure of the present invention.

Figure 16 is a three-dimensional assembly diagram of the third embodiment of the electrolytic cell structure of the present invention.

First, please refer to FIG. 1, which is a three-dimensional exploded view of the electrolytic cell structure of the present invention, FIG. 2 is a three-dimensional exploded view of the first body group 10 of the electrolytic cell structure of the present invention, FIG. 3 is a three-dimensional exploded view of the partial structure of the first body group 10 of the electrolytic cell structure of the present invention, FIG. 4 is a three-dimensional exploded view of the second body group 20 of the electrolytic cell structure of the present invention, FIG. 5 is an enlarged view of A in FIG. 4 of the present invention, and FIG. 6 is an electrolytic cell structure of the present invention. The three-dimensional exploded view of the electrode group 30, FIG. 7 is a three-dimensional assembly view of the electrode group of the electrolytic cell structure of the present invention, FIG. 8 is a side view of the electrode group of the electrolytic cell structure of the present invention, FIG. 9 is a three-dimensional assembly view of a part of the structure of the electrolytic cell of the present invention, FIG. 10 is a side view of the electrolytic cell structure of FIG. 9 of the present invention, and FIG. 11 is a three-dimensional assembly view of the electrolytic cell structure of the present invention. The present invention is related to an electrolytic cell structure, which includes:

A first body assembly 10, the first body assembly 10 is provided with a first opening 11, a second opening 12 and a chamber 13, the first opening 11 is for fluid to enter the chamber 13, the second opening 12 is for the purified fluid to be discharged, the fluid enters the chamber 13 and is discharged from the chamber 13;

The fluid is generally waste liquid, waste gas or various substances that need to be purified;

The chamber 13 is spaced and provided with a plurality of first connecting parts 14, a plurality of second connecting parts 15 and a plurality of channels 16. The plurality of channels 16 are interconnected and are in a tortuous shape to form a longer path for the fluid to pass through. The first opening 11 is located at the starting point of the path, and the second opening 12 is located at the end point of the path. The plurality of channels 16 are slightly U-shaped horizontal and U-shaped vertical paths;

The first body assembly 10 is provided with a plurality of first plates 101, a second plate 102, a plurality of third plates 103 and a plurality of supporting blocks 104;

The number of the plurality of first plates 101 is five, and the plurality of first plates 101 are assembled to form a rectangular box with an opening, and the opening of the rectangular box formed by the plurality of first plates 101 is facing forward, and the second plate 102 and the plurality of third plates 103 are assembled vertically and accommodated in the rectangular box formed by the plurality of first plates 101, and the second plate 102 is arranged upright, and the number of the plurality of third plates 103 is two, and the plurality of The third plate 103 is horizontally arranged and vertically arranged with the second plate 102. There is an appropriate distance between the third plates 103. The third plates 103 are inserted into the second plate 102. The support blocks 104 are respectively fixed on the first plate 101 at the bottom and each of the third plates 103, with the second plate 102 as the middle partition. The support blocks 104 are respectively located on the two sides of the second plate 102;

The first opening 11 is disposed on one side of the first plate 101 at the bottom of the first body assembly 10, and the second opening 12 is disposed on one side of the first plate 101 at the top of the first body assembly 10. The first opening 11 and the second opening 12 are staggered. The chamber 13 is disposed between the plurality of first plates 101, the second plates 102, and the plurality of third plates 103. The plurality of first connecting portions 14 and the plurality of third plates 103 are centered on the second plate 102. The second connecting portion 15 is a notch formed at the turning point between the second plate 102 and the third plate 103. The plurality of first connecting portions 14 are formed because the second plate 10 is shorter than the first plate 101. The plurality of second connecting portions 15 are formed because the lengths of the two sides of the third plate 103 are different. The plurality of channels 16 are formed by the plurality of first connecting portions 14 and the plurality of second connecting portions 15 in the chamber 13 to form a curved circuitous path;

A second body assembly 20, the second body assembly 20 is assembled with the opening of the first body assembly 10, and the second body assembly 20 closes the first body assembly 10;

A sealing gasket, welding or sealing structure is provided between the second body assembly 20 and the first body assembly 10, so that the fluid will not flow out from between the second body assembly 20 and the first body assembly 10;

The second body assembly 20 is provided with a second body 21, a plurality of fixing parts 22 and a plurality of first gaskets 23;

The shape of the second body 21 is assembled with the opening of the first body set 10. The second body 21 closes the first body set 10. The second body 21 is provided with at least one receiving groove 211. The receiving groove 211 is aligned with the receiving chamber 13. There are multiple receiving grooves 11. The number of the receiving grooves 11 is the same as the number of the multiple channels 16. Each of the receiving grooves 11 is aligned with each of the multiple channels 16. The number of the receiving grooves 211 is six. The outer periphery of each of the receiving grooves 211 is provided with multiple receiving grooves 212. The receiving grooves 212 are non-circular grooves. The multiple receiving grooves 212 are hexagonal grooves. Each of the multiple receiving grooves 212 is provided with a receiving hole 213. The receiving hole 213 is a penetrating circular hole.

Each of the plurality of fixed components 22 is accommodated in each of the plurality of receiving grooves 212, and the plurality of fixed components 22 is in the form of a nut component structure;

The plurality of first gaskets 23 are assembled outside the plurality of receiving grooves 212. The plurality of first gaskets 23 can seal the plurality of receiving grooves 212 so that the plurality of receiving grooves 212 have a leak-proof effect. The plurality of first gaskets 23 are assembled on the second body 21 or the plurality of fixed parts 22 by adhesive or various structures;

At least one electrode set 30 is assembled in the chamber 13 from the groove 211. The electrode set 30 can close the groove 211. The electrode set 30 is assembled on the second body set 20 with a screw structure and can be removed from the groove 211. The other end of the electrode set 30 is against the support block 104. There are multiple electrode sets 30, and the number of the electrode sets 30 is the same as the number of the multiple channels 16. Each electrode set 30 has a plurality of electrodes. The electrode assembly 30 is assembled in each of the plurality of channels 16, and includes a plurality of first electrode plates 31, a plurality of second electrode plates 32, a plurality of first screw members 33, a plurality of second screw members 331, a plurality of gaskets 34, a first conductive member 35, a second conductive member 351, a first gasket 36, a second gasket 361, a coupling member 37, a second gasket 373, a plurality of third screw members 38 and two fourth screw members 39;

The plurality of first electrode plates 31 are in the shape of thin long plates. A first conductive portion 311 is provided at one end of each first electrode plate 31. The first electrode plate 311 is provided with a plurality of first through holes 312. The plurality of first through holes 312 are arranged in a matrix and are in the shape of circular holes.

The plurality of second electrode plates 32 are in the shape of a long plate. A second conductive portion 321 is provided at one end of each second electrode plate 32. The second conductive portion 321 and the first conductive portion 311 are provided at the same end. The positions of the second conductive portion 321 and the first conductive portion 311 are staggered. The second electrode plate 32 is provided with a plurality of second through holes 322. The plurality of second through holes 322 are arranged in a matrix. Each second through hole 322 is aligned with each first through hole 312. The plurality of second through holes 322 are in the shape of a circular hole.

The plurality of first electrode plates 31 and the plurality of second electrode plates 32 are interlaced and stacked, and there is a gap between the plurality of first electrode plates 31 and the plurality of second electrode plates 32. The plurality of second electrode plates 32 are disposed between two of the plurality of first electrode plates 31. The number of the plurality of first electrode plates 31 is one more than the number of the plurality of second electrode plates 32. The total number of the plurality of first electrode plates 31 and the plurality of second electrode plates 32 is an odd number. The number of first electrode plates 31 is three, the number of the plurality of second electrode plates 32 is two, the outermost side is two of the plurality of first electrode plates 31, the positive and negative electrodes are respectively connected to the plurality of first electrode plates 31 and the plurality of second electrode plates 32, the first conductive part 311 is connected to a power source, the first conductive part 311 is electrically connected to the positive electrode, the second conductive part 321 is connected to a power source, and the second conductive part 321 is electrically connected to the negative electrode;

One end of the plurality of first screw-in parts 33 is provided with an external thread. The plurality of first screw-in parts 33 are inserted into the plurality of first through-holes 312 and the plurality of second through-holes 322 and are screwed together with the plurality of second screw-in parts 331, so that the plurality of first electrode plates 31 and the plurality of second electrode plates 32 are assembled and cannot be separated from each other;

The plurality of gaskets 34 are disposed between the plurality of first electrode plates 31 and the plurality of second electrode plates 32, so that there is a gap between the plurality of first electrode plates 31 and the plurality of second electrode plates 32. The plurality of gaskets 34 are aligned with the plurality of first through holes 312 and can be passed through by the plurality of first screw members 33.

The first conductive member 35 and the second conductive member 351 are in the shape of long screws. The first conductive member 35 is assembled at the first conductive portion 311, and the second conductive member 351 is assembled at the second conductive portion 321;

The first gasket 36 and the second gasket 361 are sleeved on the first conductive member 35 and the second conductive member 351, and the first gasket 36 and the second gasket 361 have sealing and leak-proof functions;

The coupling member 37 can seal the receiving groove 211. The coupling member 37 is in the shape of a square sheet in accordance with the shape of the receiving groove 211. The coupling member 37 is slightly larger than the receiving groove 211. Two assembly parts 371 are provided in the middle of the coupling member 37. The assembly parts 371 are provided for the first conductive member 35 and the second conductive member 351 to penetrate each other. The coupling member 37 is against the first gasket 36 and the second gasket 361. The assembly part 371 is in the shape of a circular hole. The periphery of the coupling member 37 is provided with a plurality of third through holes 372. The plurality of third through holes 372 are aligned with the plurality of receiving grooves 212. The plurality of third through holes 372 are in the shape of circular holes.

The second gasket 373 is assembled with the coupling member 37, the second gasket 373 is disposed between the coupling member 37 and the receiving groove 211, the second gasket 373 is assembled between the coupling member 37 and the first conductive member 35 and the second conductive member 351, and the second gasket 373 has a sealing effect;

The plurality of third screw-on components 38 are inserted through the plurality of third through-holes 372 and the plurality of receiving holes 213. The plurality of third screw-on components 38 are respectively screwed on the plurality of fixed components 22. The ends of the plurality of third screw-on components 38 do not abut against the surface of the plurality of first gaskets 23 to avoid damaging the sealing and leak-proofing effect.

The first conductive member 35 and the second conductive member 351 are respectively inserted into the assembly portion 371, and the fourth screw member 39 is screwed together with the first conductive member 35 and the second conductive member 351.

Please continue to refer to FIG. 12, which is a three-dimensional exploded view of the second embodiment of the electrolytic cell structure of the present invention. In the embodiment, the first opening 11 and the second opening 12 are in the shape of protruding circular tubes, and the first body assembly 10, the second body assembly 20 and the electrode assembly 30 are in a single assembly structure. The single assembly structure is smaller in size to facilitate single use, and the single assembly structure is in a separate electrolysis state.

Please continue to refer to Figures 13 and 14. Figure 13 is a three-dimensional exploded view of the third embodiment of the electrolytic cell structure of the present invention, and Figure 14 is a three-dimensional schematic view of the third embodiment. In this embodiment, the first body group 10, the second body group 20 and the electrode group 30 are in a single group structure, the first opening 11 and the second opening 12 are in multiple numbers and are located at the two ends of the first body group 20, and multiple closing members 105 are added. The multiple closing members 105 are assembled in conjunction with the first opening 11 and the second opening 12. The multiple closing members 105 close the first opening 11 and the second opening 12 and have the function of preventing leakage;

The number of the first openings 11 is four, and the first openings 11 are arranged around the four sides of the first body set 10, and the second openings 12 are arranged around the four sides of the first body 10.

Please continue to refer to FIG. 15, which is a schematic diagram of the third embodiment of the present invention. FIG. 16 is a three-dimensional diagram of the third embodiment of the present invention. The first body set 10 is a plurality of first body sets 10, and the plurality of first body sets 10 are arranged in pairs. The plurality of closing members 105 can be assembled in part of the first opening 11 and part of the second opening 12, so that the plurality of first body sets 10 form a closed interior. The multiple channels 16 can be selected to remove some of the multiple closing parts 105 according to the different ways of assembling the multiple first body sets 10. Some of the multiple closing parts 105 close part of the first opening 11 and the second opening 12. The multiple first body sets 10 are mutually assembled to have the multiple channels 16 bypassing the multiple channels. If the number of the first body sets 10 is six, the assembly has the same effect as Figure 1.

After some of the multiple closing parts 105 are removed, the first opening 11 and the second opening 12 between the first body set 10 and another first body set 10 can be provided with sealing gaskets to prevent leakage.

As shown in Figure 1, the opening of the first body assembly 10 faces forward, and the electrode assembly 30 also faces forward. When the first body assembly 10 is placed against a wall, it is more convenient to remove and replace the electrode assembly 30, but when removing and replacing the electrode assembly 30, the waste liquid in the chamber 13 needs to be discharged first. In another structural method, the opening of the first body assembly 10 can face upward, which makes it less difficult to remove and replace the electrode assembly 30, but when the opening of the first body assembly 10 faces upward, the waste liquid does not need to be completely discharged.

In another embodiment of the present invention, the first opening 11 can be the outlet of the fluid, and the second opening 12 is the inlet of the fluid, so that the fluid inlet and outlet flow directions are opposite to those in FIG1 .

In another embodiment of the present invention, the first body assembly 10 shown in FIG. 1 is composed of the plurality of first plates 101, the second plates 102 and the plurality of third plates 103. The plurality of first plates 101, the second plates 102 and the plurality of third plates 103 can be in a one-piece shape, that is, the first body assembly 10 directly separates the plurality of channels 16. The plurality of first plates 101, the second plates 102 and the plurality of third plates 103 can be connected by adhesive, welding or various sealing structures to have a leak-proof effect.

Another embodiment of the present invention provides a liquid supply barrel, which contains the fluid;

The waste liquid in the liquid supply barrel enters the bottommost chamber 13 through the first opening 11, and the waste liquid in the chamber 13 is then transported to the first connecting portion 14 at the bend, and the waste liquid in the first connecting portion 14 enters the chamber 13 on the other side of the third plate 103, and the waste liquid in the chamber 13 enters the chamber 1 on the upper layer through the second connecting portion 15 that communicates with each other. 3, the electrode group 30 generates an electrolytic reaction with the waste liquid, and the electrode group 30 absorbs the impurities in the waste liquid. After electrolysis, the waste liquid becomes a relatively clean liquid. The liquid after electrolysis is discharged through the second opening 12, or the waste liquid that is still not clean flows into the liquid supply barrel again, thus forming an electrolysis cycle. After multiple cycles of electrolysis, the waste liquid can be discharged as a relatively clean fluid.

The advantages of the electrolytic cell structure of the present invention are:

1. The first body group 10, the second body group 20 and the electrode group 30 are assembled together. The first body group 10, the second body group 20 and the electrode group 30 can greatly save the volume of the electrolytic cell structure.

2. The flow path of the waste liquid of the electrolytic cell structure is composed of the plurality of first body groups 10 and the second body group 20. The electrolytic cell structure has the advantage of simple components and saves component costs.

3. The electrode assembly 30 can seal the container 211, and the plurality of first body assemblies 10 and the second body assembly 20 are in a closed structure. If the electrode assembly 30 generates substances harmful to the human body during the electrolysis reaction, the damage to human health can be avoided. The electrode assembly 30 can have the effect of a safe structure during the electrolysis process.

4. The electrode assembly 30 is mounted on the second body assembly 20 by means of a screw-in structure, and the electrode assembly 30 can be removed from the second body assembly 20. The electrode assembly 30 can be conveniently replaced after electrolysis for a period of time.

5. The first connecting part 14 and the second connecting part 15 are formed in the chamber 13, so that the first connecting part 14 and the second connecting part 15 form a plurality of channels 16 of a sequentially connected structure, and the waste liquid can pass through each of the electrode groups 30 in sequence. The waste liquid can pass through the electrode groups 30 and have the best electrolysis effect. .

6. Please refer to Figures 12 and 15 to change the combination of the first body group 10, the second body group 20 and the electrode group 30 to form a single cycle structure, a six-cycle structure or a plurality of cycle structures. The electrolytic cell structure of the present invention has the variability of the combination structure and is expandable.

7. The plurality of first plates 101, the second plates 102 and the plurality of third plates 103 are combined in parallel or vertically to form a box with a grid-like space. Each third plate 103 is connected to the next third plate 103 by forming the first connecting portion 14 and the second connecting portion 15 to form a plurality of channels 16 in a cycle. The regular combination method is quite simple and is not prone to assembly errors.

Therefore, the electrolytic cell structure of this invention has industrial applicability, novelty and advancement, and can truly meet the application requirements for invention patents, so an application is filed in accordance with the law.

10: The first body group

11: First opening

12: Second opening

13: Storage room

20: Second body group

30: Electrode set

Claims (13)

An electrolytic cell structure includes: a first body assembly, the first body assembly is provided with a first opening, a second opening and a chamber; a second body assembly is assembled with the opening of the first body assembly, and the second body assembly seals the first body assembly; the second body assembly is provided with a second body, a plurality of fixing parts and a plurality of first gaskets; the second body seals the first body assembly, and the second body is provided with at least one chamber, and the chamber is opposite to the chamber. Each of the plurality of receiving grooves is provided with a plurality of receiving grooves on the outer periphery, and each of the plurality of receiving grooves is provided with a receiving hole; each of the plurality of fixed parts is accommodated in each of the plurality of receiving grooves; the plurality of first gaskets are assembled outside the plurality of receiving grooves, and the plurality of first gaskets can close the plurality of receiving grooves; at least one electrode group, the electrode group is assembled from the receiving groove into the receiving chamber, the electrode group can close the receiving groove, and the electrode group is assembled on the second body group with a screw structure and can be removed from the receiving groove. The electrolytic cell structure as described in claim 1, wherein the first opening is for fluid to enter the chamber, and the second opening is for the purified fluid to be discharged, the fluid enters the chamber and is discharged from the chamber, or the first opening can be the fluid discharge point, and the second opening is the fluid entry point, the fluid is various waste liquids, various waste gases or various substances that need to be purified, and a sealing gasket, welding or various sealing structures are provided between the second body group and the first body group, so that the fluid will not flow out from between the second body group and the first body group. The electrolytic cell structure as described in claim 1, wherein the chamber is spaced and provided with a plurality of first connecting parts, a plurality of second connecting parts and a plurality of channels, the plurality of channels are interconnected and curved to form a longer path for the fluid to pass through, the first opening is located at the starting point of the path, the second opening is located at the end point of the path, and the plurality of channels are slightly U-shaped horizontal and U-shaped vertical paths. An electrolytic cell structure as described in claim 3, wherein the first body assembly is provided with a plurality of first plates, a second plate, a plurality of third plates and a plurality of support blocks; the number of the plurality of first plates is five, the plurality of first plates are assembled to form a rectangular box with an opening, the opening of the rectangular box formed by the plurality of first plates is facing forward, the second plate and the plurality of third plates are assembled vertically and accommodated in In the rectangular box in which the plurality of first plates are assembled, the second plate is arranged upright, the number of the plurality of third plates is two, the plurality of third plates are arranged horizontally and arranged perpendicularly to the second plate, there is a distance between the plurality of third plates, the plurality of third plates are for the second plate to be inserted, the plurality of support blocks are respectively fixed on the first plate at the bottom and each of the third plates, with the second plate as The plurality of support blocks are respectively located at two sides of the second plate; the first opening is located at one side of the first plate at the bottom of the first body set, and the second opening is located at one side of the first plate at the top of the first body set. The positions of the first opening and the second opening are staggered. The chamber is located between the plurality of first plates, the second plates and the plurality of third plates, with the second plate as the center. The plurality of first connecting parts and the plurality of second connecting parts are gaps at the turning point formed between the second plate and the third plate. The plurality of first connecting parts are formed because the second plate is shorter than the first plate, and the plurality of second connecting parts are formed because the lengths of the two sides of the third plate are different. The plurality of channels are formed by the plurality of first connecting parts and the plurality of second connecting parts in the chamber to form a curved circuitous path. The electrolytic cell structure as described in claim 3, wherein the shape of the second body is assembled to match the opening of the first body group, the plurality of containing slots is the same as the number of the plurality of channels, each of the containing slots is aligned with each of the plurality of channels, the number of the containing slots is six, the containing slot is in the shape of a non-circular slot, or the plurality of containing slots are in the shape of a hexagonal slot, the containing hole is in the shape of a through-hole; the plurality of fixing parts are in the shape of a nut part; the plurality of containing slots have a leak-proof effect, and the plurality of first gaskets are assembled on the second body or the plurality of fixing parts with adhesive or various structures. The electrolytic cell structure as described in claim 4, wherein the other end of the electrode group is against the support block, the electrode group is plural, the number of the electrode groups is the same as the number of the plural channels, and each of the electrode groups is arranged in each of the plural channels. The electrolytic cell structure as described in claim 1, wherein the electrode assembly includes a plurality of first electrode plates, a plurality of second electrode plates, a plurality of first screwed parts, a plurality of second screwed parts, a plurality of gaskets, a first conductive part, a second conductive part, a first washer, a second washer, a coupling part, a second gasket, a plurality of third screwed parts and two fourth screwed parts; the plurality of first electrode plates are in the shape of thin long plates, each of which has a first conductive part at one end, The electrode plate is provided with a plurality of first through-holes, which are arranged in a matrix and are in the shape of round holes; the plurality of second electrode plates are in the shape of long plates, and one end of each second electrode plate is provided with a second conductive part, and the second conductive part and the first conductive part are arranged at the same end, and the positions of the second conductive part and the first conductive part are staggered, and the second electrode plate is provided with a plurality of second through-holes, which are arranged in a matrix, and each second through-hole is connected to each first conductive part. The first plurality of through-holes are aligned with each other, and the second plurality of through-holes are in the shape of round holes; the first plurality of electrode plates and the second plurality of electrode plates are interlaced and overlapped, and there is a gap between the first plurality of electrode plates and the second plurality of electrode plates; the second plurality of electrode plates are arranged between two of the first plurality of electrode plates; the number of the first plurality of electrode plates is one more than the number of the second plurality of electrode plates; the total number of the first plurality of electrode plates and the second plurality of electrode plates is an odd number; the first plurality of electrode plates are arranged between the first plurality of electrode plates and the second plurality of electrode plates; The number of electrode plates is three, the number of the plurality of second electrode plates is two, the outermost sides are two of the plurality of first electrode plates, the positive and negative electrodes are connected to the plurality of first electrode plates and the plurality of second electrode plates respectively, the first conductive part is connected to a power source, the first conductive part is electrically connected to the positive electrode, the second conductive part is electrically connected to the negative electrode: one end of the plurality of first screw parts is provided with an external thread, and the plurality of first screw parts are penetrated The plurality of first through holes and the plurality of second through holes are screwed together with the plurality of second screwing members, so that the plurality of first electrode plates and the plurality of second electrode plates are assembled and not separated; the plurality of pads are arranged between the plurality of first electrode plates and the plurality of second electrode plates, so that there is a gap between the plurality of first electrode plates and the plurality of second electrode plates, the plurality of pads are aligned with the plurality of first through holes, and the plurality of first screwing members can be passed through; the first conductive member and the second conductive member are The first conductive member is arranged at the first conductive part, and the second conductive member is arranged at the second conductive part; the first gasket and the second gasket are sleeved on the first conductive member and the second conductive member, and the first gasket and the second gasket have sealing and leak-proof effects; the coupling member can seal the container, and the coupling member is in the shape of a square sheet in accordance with the shape of the container, and the coupling member is slightly larger than the container, and two assembly parts are arranged at the middle position of the coupling member, and the assembly parts are provided at the middle position of the coupling member. The first conductive part and the second conductive part are provided to penetrate each other, the coupling part is against the first gasket and the second gasket, the assembly part is in the shape of a circular hole, the periphery of the coupling part is provided with a plurality of third through-holes, the plurality of third through-holes are aligned with the plurality of receiving grooves, and the plurality of third through-holes are in the shape of circular holes; the second gasket is assembled with the coupling part, the second gasket is arranged between the coupling part and the first conductive part and the receiving groove, and the second gasket is assembled between the coupling part and the first conductive part and the receiving groove. The second gasket has a sealing effect between the first and second conductive parts; the plurality of third screw parts are inserted through the plurality of third through holes and the plurality of receiving holes, and the plurality of third screw parts are respectively screwed on the plurality of fixed parts, and the ends of the plurality of third screw parts do not touch the surface of the plurality of first gaskets to avoid damaging the sealing and leak-proof effect; the first conductive part and the second conductive part are respectively inserted through the assembly part, and the fourth screw part is screwed with the first conductive part and the second conductive part. The electrolytic cell structure as described in claim 1, wherein the first opening and the second opening are in the shape of a protruding circular tube, the first body assembly, the second body assembly and the electrode assembly are in a single assembly structure, the single assembly structure is smaller in size for easy single use, and the single assembly structure is in a separate electrolysis state. The electrolytic cell structure as described in claim 3, wherein the first body group, the second body group and the electrode group are a single group structure, the first opening and the second opening are plural and are disposed at two ends of the first body group, and a plurality of closing members are additionally provided, the plurality of closing members are assembled in conjunction with the first opening and the second opening, the plurality of closing members close the first opening and the second opening and have a leakage prevention effect; the number of the first openings is four, the first openings are arranged in a ring on the four sides of the first body group, and the second openings are arranged in a ring Arranged on the four sides of the first body, the number of the first body groups is plural, the plural first body groups are mutually assembled, the plural closing parts can be assembled in part of the first opening and part of the second opening, so that the plural first body groups form the plural closed channels inside, and some of the plural closing parts can be selected to be removed according to the different assembly methods between the plural first body groups, and some of the plural closing parts are used to close part of the first opening and the second opening, and the plural first body groups are mutually assembled to form the plural closed channels. The electrolytic cell structure as described in claim 9, wherein after some of the plurality of closing parts are removed, the first opening and the second opening between the first body assembly and another first body assembly may be provided with sealing gaskets to prevent leakage. As for the electrolytic cell structure described in claim 1, the opening of the first body assembly faces forward, and the electrode assembly also faces forward. When the first body assembly is placed against a wall, it is more convenient to remove and replace the electrode assembly, but when removing and replacing the electrode assembly, the waste liquid in the chamber needs to be discharged first. In another structural method, the opening of the first body assembly can face upward, which makes it less difficult to remove and replace the electrode assembly, but when the opening of the first body assembly faces upward, the waste liquid does not need to be completely discharged. The electrolytic cell structure as described in claim 4, wherein the first body set is composed of the plurality of first plates, the second plates and the plurality of third plates, the plurality of first plates, the second plates and the plurality of third plates can be in one body, that is, the first body set directly separates the plurality of channels, and the plurality of first plates, the second plates and the plurality of third plates can be connected by adhesive, welding or various sealing structures to have a leak-proof effect. The electrolytic cell structure as described in claim 4, wherein a liquid supply barrel is provided, wherein the liquid supply barrel contains the fluid, i.e., the waste liquid; the waste liquid in the liquid supply barrel enters the bottommost chamber through the first opening, the waste liquid in the chamber is then transported into the first connecting portion at the bend, the waste liquid in the first connecting portion enters the chamber on the other side of the third plate, and the waste liquid in the chamber is then transported into the second connecting portion which is connected from top to bottom. The waste liquid enters the chamber of the upper layer through the connecting part, and the electrode group reacts with the waste liquid to absorb the impurities in the waste liquid. The waste liquid becomes a cleaner liquid after electrolysis. The electrolyzed liquid is discharged through the second opening, or the still unclean waste liquid flows into the liquid supply barrel again, thus forming an electrolysis cycle. After multiple cycles of electrolysis, the waste liquid can be discharged as a relatively clean fluid.