阅读说明：本技术 一种循环电解水制造用叠片式电解槽及其叠片工艺 (Laminated electrolytic tank for manufacturing circulating electrolyzed water and laminating process thereof ) 是由 周康 李辞海 于 2021-08-17 设计创作，主要内容包括：本发明公开了一种循环电解水制造用叠片式电解槽及其叠片工艺,包括电极板组件和隔板组件,电极板组件分为第一电极板、第二电极板、第三电极板、第四电极板和第五电极板,电极板组件采用导电材质制成,用以实现正负极电离；隔板组件分为第一隔板、第二隔板、第三隔板和第四隔板,隔板组件通常采用塑料绝缘材质制成。本发明通过优化设计,优化电极板组件和隔板组件结构,使得其通用性更强；优选第二层组和第四层组采用相同结构设置,使得整体工艺更为简化,实现两步重复叠装,简化整体叠装工艺；依据整体电极槽规格需求,可以实现多个电解层组重复叠装,降低了制造成本,提高了产品的通用性。(The invention discloses a laminated electrolytic tank for manufacturing circulating electrolyzed water and a laminating process thereof, and the laminated electrolytic tank comprises an electrode plate assembly and a partition plate assembly, wherein the electrode plate assembly is divided into a first electrode plate, a second electrode plate, a third electrode plate, a fourth electrode plate and a fifth electrode plate; the partition plate assembly is divided into a first partition plate, a second partition plate, a third partition plate and a fourth partition plate, and the partition plate assembly is usually made of a plastic insulating material. According to the invention, the electrode plate assembly and the separator assembly are optimized through optimized design, so that the universality is stronger; preferably, the second layer group and the fourth layer group are arranged in the same structure, so that the overall process is simplified, two-step repeated stacking is realized, and the overall stacking process is simplified; according to the specification requirement of the integral electrode tank, repeated stacking of a plurality of electrolytic layer groups can be realized, the manufacturing cost is reduced, and the universality of the product is improved.)

1. A lamination process of a laminated electrolytic tank for manufacturing circulating electrolyzed water comprises an electrode plate assembly and a separator plate assembly, and is characterized in that: the electrode plate assembly is divided into a first electrode plate, a second electrode plate, a third electrode plate, a fourth electrode plate and a fifth electrode plate, and the separator plate assembly is divided into a first separator plate, a second separator plate, a third separator plate and a fourth separator plate;

step one, a fourth clapboard is used as a base layer and is placed in a platform to form a first layer group;

step two, according to product requirements, repeatedly stacking at least more than 3 groups of electrolyte layer groups on the upper part of the first layer group, wherein the single-layer electrolyte layer group is formed by stacking a second layer group, a third layer group and a fourth layer group in sequence, and the stacking method of the single electrolyte layer comprises the following steps:

s1, a second layer group, namely selecting a first partition plate to be horizontally placed, installing two fifth electrode plates in the first partition plate at intervals, stacking a second partition plate on the upper portion of the first partition plate provided with the fifth electrode plates, stacking a third partition plate on the upper portion of the second partition plate, and installing and matching the third electrode plate, the fourth electrode plate and the fifth electrode plate with the stacked third partition plate respectively to form the second layer group;

s2, a third layer group, namely selecting a first partition plate to be horizontally placed, installing two fifth electrode plates in the first partition plate at intervals, stacking a second partition plate on the upper portion of the first partition plate provided with the fifth electrode plates, stacking a third partition plate on the upper portion of the second partition plate, and installing and matching the first electrode plate, the second electrode plate and the fifth electrode plate with the stacked third partition plate respectively to form the third layer group;

s3, a fourth group of layers, namely selecting a first partition plate to be horizontally placed, installing two fifth electrode plates in the first partition plate at intervals, stacking a second partition plate on the upper portion of the first partition plate provided with the fifth electrode plates, stacking a third partition plate on the upper portion of the second partition plate, and installing and matching the third electrode plates, the fourth electrode plates and the fifth electrode plates with the stacked third partition plate respectively to form the fourth group of layers;

and step three, stacking the fourth partition plate as a top layer on the upper part of the electrolytic layer group to complete the integral stacking.

2. The lamination process of the laminated cell for manufacturing the circulating electrolyzed water as set forth in claim 1, wherein: and in the second layer group, when the third electrode plate, the fourth electrode plate and the fifth electrode plate are arranged on the same surface, the fifth electrode plate is positioned between the third electrode plate and the fourth electrode plate.

3. The lamination process of the laminated cell for manufacturing the circulating electrolyzed water as set forth in claim 2, wherein: and in the third layer group, when the first electrode plate, the second electrode plate and the fifth electrode plate are arranged on the same surface, the fifth electrode plate is positioned between the first electrode plate and the second electrode plate.

4. The lamination process of the laminated cell for manufacturing the circulating electrolyzed water as set forth in claim 1, wherein: the second layer group and the fourth layer group adopt the same stacking structure.

5. The lamination process of the laminated cell for manufacturing the circulating electrolyzed water as set forth in claim 3, wherein: in the single electrolytic layer group, the third electrode plate is positioned at the lower part of the first electrode plate, and the fourth electrode plate is positioned at the lower part of the second electrode plate.

6. A laminated electrolytic tank for manufacturing circulating electrolyzed water is characterized in that: the laminated electrolytic cell for manufacturing circulating electrolyzed water according to any one of claims 1 to 5.

7. The laminated electrolytic cell for producing circulating electrolyzed water according to claim 6, characterized in that: the fifth electrode plate is composed of a fifth positive electrode plate and a fifth negative electrode plate, the fifth positive electrode plate and the fifth negative electrode plate are integrally arranged, and the fifth positive electrode plate and the fifth negative electrode plate are symmetrically arranged.

8. The laminated electrolytic cell for producing circulating electrolyzed water according to claim 6, characterized in that: a plurality of first through holes are distributed in the first partition plate, a plurality of second through holes are distributed in the second partition plate, a plurality of third through holes are distributed in the third partition plate, a plurality of fourth through holes are distributed in the fourth partition plate, the first through holes, the second through holes, the third through holes and the fourth through holes are all in the same distribution structure and are in one-to-one correspondence with the first through holes, the second through holes, the third through holes and the fourth through holes.

9. The laminated electrolytic cell for producing circulating electrolyzed water according to claim 8, characterized in that: the first partition plate adopts an annular integrated structure, two electrode plate mounting grooves are respectively arranged in the inner cavity of the first partition plate, and two first notch openings which are arranged at intervals are arranged on the outer edge of one side of the first partition plate; the second baffle adopts cyclic annular integrative structure, be equipped with two second notch openings that are the interval setting on the second baffle one side outside border, first notch opening with the second notch opening is just right setting from top to bottom.

10. The laminated electrolytic tank for circulating electrolyzed water production according to claim 8 or 9, characterized in that: the third baffle is assisted the baffle including third main baffle and the third that the components of a whole that can function independently set up, third main baffle one side is equipped with the fluting limit, the baffle is located is assisted to the third fluting edge, the baffle both ends are assisted to the third with be formed with the convex notch between the baffle is mainly assisted to the third, the convex notch is used for corresponding with first notch opening and second notch opening, the third main baffle with be equipped with the third electrode slot in the inner chamber that the baffle combination back formed is assisted to the third.

Technical Field

The invention relates to the technical field of electrolytic cells, in particular to a laminated electrolytic cell for manufacturing circulating electrolyzed water and a laminating process thereof.

Background

The mechanism for preparing the electrolyzed water is called as an electrolyzed water generator; when the solution added with a certain proportion of raw materials passes through the electrolytic cell, under the action of direct current, the anode and the solution interface generate oxidation reaction, and the cathode and the solution interface generate reduction reaction to prepare the required product. Existing cells typically consist of a cell body, an anode and a cathode. The electrolytic bath is divided into three types, namely an aqueous solution electrolytic bath, a molten salt electrolytic bath and a non-aqueous solution electrolytic bath according to the difference of the electrolyte. When direct current passes through the electrolytic cell, an oxidation reaction occurs at the interface of the anode and the solution, and a reduction reaction occurs at the interface of the cathode and the solution, so as to prepare the required product.

The publication number CN212051673U discloses a water-lamination type electrolytic tank for generating acid and alkali electrolysis, which comprises a water inlet plate, a water outlet plate and an electrolysis lamination group clamped between the water inlet plate and the water outlet plate, wherein the electrolysis lamination group comprises electrolysis separation acid-alkali section laminations, and the electrolysis separation acid-alkali section laminations comprise first cathode positioning plates, first anode positioning plates which are arranged at intervals and cathode clapboards, water dividing plates and anode clapboards which are clamped between the adjacent first cathode positioning plates and the first anode positioning plates. The inner structure of the lamination stacking machine adopts more special-shaped structural designs, so that in the lamination processing process, more special-shaped parts are adopted, stacking errors are easy to occur, the stacking process is complex, meanwhile, the universality of products with different specifications is inconvenient, the integral manufacturing cost is relatively high, and the use is limited.

Disclosure of Invention

The invention aims to provide a laminated electrolytic tank for manufacturing circulating electrolyzed water and a laminating process thereof, which are used for solving the technical problems, adopt two-step stacking forming, simplify the integral stacking process, realize multilayer and multi-specification stacking according to the requirements, reduce the manufacturing cost and improve the universality of products.

The technical problem solved by the invention can be realized by adopting the following technical scheme:

a lamination process of a laminated electrolytic tank for manufacturing circulating electrolyzed water comprises an electrode plate assembly and a separator plate assembly, wherein the electrode plate assembly is divided into a first electrode plate, a second electrode plate, a third electrode plate, a fourth electrode plate and a fifth electrode plate, and the separator plate assembly is divided into a first separator plate, a second separator plate, a third separator plate and a fourth separator plate; step one, a fourth clapboard is used as a base layer and is placed in a platform to form a first layer group; step two, according to product requirements, repeatedly stacking at least more than 3 groups of electrolyte layer groups on the upper part of the first layer group, wherein the single-layer electrolyte layer group is formed by stacking a second layer group, a third layer group and a fourth layer group in sequence, and the stacking method of the single electrolyte layer comprises the following steps: s1, a second layer group, namely selecting a first partition plate to be horizontally placed, installing two fifth electrode plates in the first partition plate at intervals, stacking a second partition plate on the upper portion of the first partition plate provided with the fifth electrode plates, stacking a third partition plate on the upper portion of the second partition plate, and installing and matching the third electrode plate, the fourth electrode plate and the fifth electrode plate with the stacked third partition plate respectively to form the second layer group; s2, a third layer group, namely selecting a first partition plate to be horizontally placed, installing two fifth electrode plates in the first partition plate at intervals, stacking a second partition plate on the upper portion of the first partition plate provided with the fifth electrode plates, stacking a third partition plate on the upper portion of the second partition plate, and installing and matching the first electrode plate, the second electrode plate and the fifth electrode plate with the stacked third partition plate respectively to form the third layer group; s3, a fourth group of layers, namely selecting a first partition plate to be horizontally placed, installing two fifth electrode plates in the first partition plate at intervals, stacking a second partition plate on the upper portion of the first partition plate provided with the fifth electrode plates, stacking a third partition plate on the upper portion of the second partition plate, and installing and matching the third electrode plates, the fourth electrode plates and the fifth electrode plates with the stacked third partition plate respectively to form the fourth group of layers; and step three, stacking the fourth partition plate as a top layer on the upper part of the electrolytic layer group to complete the integral stacking.

And in the second layer group, when the third electrode plate, the fourth electrode plate and the fifth electrode plate are arranged on the same surface, the fifth electrode plate is positioned between the third electrode plate and the fourth electrode plate.

And in the third layer group, when the first electrode plate, the second electrode plate and the fifth electrode plate are arranged on the same surface, the fifth electrode plate is positioned between the first electrode plate and the second electrode plate.

The second layer group and the fourth layer group adopt the same stacking structure.

In the single electrolytic layer group, the third electrode plate is positioned at the lower part of the first electrode plate, and the fourth electrode plate is positioned at the lower part of the second electrode plate.

The laminated electrolytic tank for manufacturing the circulating electrolyzed water is manufactured by adopting the laminating process of the laminated electrolytic tank for manufacturing the circulating electrolyzed water.

The fifth electrode plate is composed of a fifth positive electrode plate and a fifth negative electrode plate, the fifth positive electrode plate and the fifth negative electrode plate are integrally arranged, and the fifth positive electrode plate and the fifth negative electrode plate are symmetrically arranged.

A plurality of first through holes are distributed in the first partition plate, a plurality of second through holes are distributed in the second partition plate, a plurality of third through holes are distributed in the third partition plate, a plurality of fourth through holes are distributed in the fourth partition plate, the first through holes, the second through holes, the third through holes and the fourth through holes are all in the same distribution structure and are in one-to-one correspondence with the first through holes, the second through holes, the third through holes and the fourth through holes.

The first partition plate adopts an annular integrated structure, two electrode plate mounting grooves are respectively arranged in the inner cavity of the first partition plate, and two first notch openings which are arranged at intervals are arranged on the outer edge of one side of the first partition plate; the second baffle adopts cyclic annular integrative structure, be equipped with two second notch openings that are the interval setting on the second baffle one side outside border, first notch opening with the second notch opening is just right setting from top to bottom.

The third baffle is assisted the baffle including third main baffle and the third that the components of a whole that can function independently set up, third main baffle one side is equipped with the fluting limit, the baffle is located is assisted to the third fluting edge, the baffle both ends are assisted to the third with be formed with the convex notch between the baffle is mainly assisted to the third, the convex notch is used for corresponding with first notch opening and second notch opening, the third main baffle with be equipped with the third electrode slot in the inner chamber that the baffle combination back formed is assisted to the third.

Compared with the prior art, the invention has the following outstanding advantages and effects: according to the invention, the electrode plate assembly and the separator assembly are optimized through optimized design, so that the universality is stronger; preferably, the second layer group and the fourth layer group are arranged in the same structure, so that the overall process is simplified, two-step repeated stacking is realized, and the overall stacking process is simplified; according to the specification requirement of the integral electrode tank, repeated stacking of a plurality of electrolytic layer groups can be realized, the manufacturing cost is reduced, and the universality of the product is improved.

The features of the present invention will be apparent from the accompanying drawings and from the detailed description of the preferred embodiments which follows.

Drawings

FIG. 1 is a schematic diagram of a first electrode plate structure according to the present invention;

FIG. 2 is a schematic diagram of a second electrode plate structure according to the present invention;

FIG. 3 is a schematic diagram of a third electrode plate structure according to the present invention;

FIG. 4 is a schematic diagram of a fourth electrode plate structure according to the present invention;

FIG. 5 is a schematic diagram of a fifth electrode plate structure according to the present invention;

FIG. 6 is a schematic view of a first separator plate according to the present invention;

FIG. 7 is a schematic view of a second separator plate according to the present invention;

FIG. 8 is a schematic view of a third separator plate according to the present invention;

FIG. 9 is a first schematic view of a fourth partition structure according to the present invention;

FIG. 10 is a first schematic view of a second layer assembly structure according to the present invention;

fig. 11 is a second layer set assembly structure of the present invention;

fig. 12 is a third schematic view of a second layer assembly structure according to the present invention;

fig. 13 is a fourth schematic view of a second layer set assembly structure of the present invention;

FIG. 14 is a first assembly view of a third layer assembly according to the present invention;

FIG. 15 is a second assembly view of the third layer assembly of the present invention;

FIG. 16 is a third assembly view of the third layer assembly of the present invention;

FIG. 17 is a fourth assembly diagram of the third layer assembly of the present invention;

FIG. 18 is a first schematic view of a fourth layer assembly structure according to the present invention;

FIG. 19 is a second schematic view of a fourth layer assembly structure according to the present invention;

FIG. 20 is a third schematic view of a fourth layer assembly structure according to the present invention;

FIG. 21 is a fourth layer set assembly configuration of the present invention;

wherein, 1, a first electrode plate; 11. a first conductive plate; 2. a second electrode plate; 21. a second conductive plate; 3. a third electrode plate; 31. a third conductive plate; 4. a fourth electrode plate; 41. a fourth conductive plate; 5. a fifth electrode plate; 51. a fifth positive electrode plate; 52. a fifth negative plate; 6. a first separator; 61. a first through hole; 62. an electrode plate mounting groove; 63. a first notch opening; 7. a second separator; 71. a second through hole; 72. a second notch opening; 8. a third partition plate; 81. a third through hole; 82. a third main partition; 83. a third auxiliary partition plate; 84. a convex slot opening; 85. a middle electrode tank; 86. a side electrode groove; 9. a fourth separator; 91. a fourth via hole; 92. a first flow channel hole; 93. a second flow passage hole.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further explained below by combining the specific drawings.

Example 1

As shown in fig. 1 to 21, the laminated electrolytic cell for manufacturing circulating electrolyzed water provided by the present invention comprises an electrode plate assembly and a separator plate assembly, wherein the electrode plate assembly is divided into a first electrode plate 1, a second electrode plate 2, a third electrode plate 3, a fourth electrode plate 4 and a fifth electrode plate 5, and the electrode plate assembly is made of a conductive material for realizing positive and negative electrode ionization; the partition plate assembly is divided into a first partition plate 6, a second partition plate 7, a third partition plate 8 and a fourth partition plate 9, and is usually made of a plastic insulating material.

The fourth partition plate 9 is of a flat plate structure, and the fourth partition plate 9 is provided with a fourth through hole 91, so that the fourth partition plate is conveniently arranged corresponding to the first through hole 61, the second through hole 71 and the third through hole 81 on the first partition plate 6, the second partition plate 7 and the third partition plate 8, and the integral stacking combination is conveniently realized; the fourth partition plate 9 is also provided with a first flow passage hole 92 and a second flow passage hole 93, which is convenient for realizing the circulation of the internal electrolyte; a plurality of first through holes 61 are distributed on the first partition plate 6, a plurality of second through holes 71 are distributed on the second partition plate 7, a plurality of third through holes 81 are distributed on the third partition plate 8, a plurality of fourth through holes 91 are distributed on the fourth partition plate 9, the first through holes 61, the second through holes 71, the third through holes 81 and the fourth through holes 91 all adopt the same distribution structure, and are a plurality of the first through holes 61, the second through holes 71, the third through holes 81 and the fourth through holes 91 are in one-to-one correspondence from top to bottom.

Wherein, when the fourth separator 9 is used as the first layer group, the first flow channel holes 92 and the second flow channel holes 93 are used for discharging water, typically acidic electrolyzed water and alkaline electrolyzed water, respectively.

Wherein, when the fourth partition 9 is used as the fifth layer group, the first flow passage holes 92 and the second flow passage holes 93 are respectively used for realizing water inlet.

Wherein, the first layer combination fifth layer group can be adjusted and replaced according to the product requirements.

The fourth spacer 9 serves as a first group and a fourth group, respectively, and forms a package of the bottom plate and the top plate.

The electrode plate assembly, the first separator 6, the second separator 7 and the third separator 8 are combined to form an electrolyte layer group respectively, and a single electrolyte layer group is formed by stacking a second layer group, a third layer group and a fourth layer group.

The number of the electrolytic layer groups in a single electrolytic cell is preferably 3-12, and the optimal group number is 6.

The second layer group comprises a first clapboard 6, a second clapboard 7 and a third clapboard 8 which are sequentially stacked from bottom to top, wherein the first clapboard 6 is provided with two fifth electrode plates 5 in a matching way, and the fifth electrode plates 5 are stacked and pressed through the second clapboard 7; when the third electrode plate 3, the fourth electrode plate 4 and the fifth electrode plate 5 in the second group are arranged on the same surface, the fifth electrode plate 5 is located between the third electrode plate 3 and the fourth electrode plate 4, the fifth electrode plate 5 is composed of a fifth positive electrode plate 51 and a fifth negative electrode plate 52, the fifth positive electrode plate 51 and the fifth negative electrode plate 52 are integrally arranged, the fifth positive electrode plate 51 and the fifth negative electrode plate 52 are symmetrically arranged, wherein after the third separator 3 is stacked, the third electrode plate 3 is placed on the upper portion of the fifth positive electrode plate 51 on one fifth electrode plate 5 at one end of the first separator 6, the fourth electrode plate 4 is placed on the upper portion of the fifth negative electrode plate 52 on the other fifth electrode plate 5 at the other end of the first separator 6, and the fifth positive electrode plate 51 in the fifth electrode plate 5 mounted on the third separator 8 is correspondingly placed on the upper portion of the fifth negative electrode plate 52 on one fifth electrode plate 5 at one end of the first separator 6, the fifth negative electrode plate 52 of the fifth electrode plate 5 positioned on the third separator 8 is placed on the fifth positive electrode plate 51 of the other fifth electrode plate 5 positioned on the other end of the first separator 6.

The third layer group comprises a first partition plate 6, a second partition plate 7 and a third partition plate 8 which are stacked from bottom to top, and the same partition plate stacking structure is adopted, so that the number of parts is reduced, and the whole stacking process is simpler and more clear; when the first electrode plate 1, the second electrode plate 2 and the fifth electrode plate 5 in the third layer group are arranged on the same surface, the fifth electrode plate 5 is positioned between the first electrode plate 1 and the second electrode plate 2, wherein two fifth electrode plates 5 are installed on the first partition plate 6 in a matching way, and the fifth electrode plates 5 are laminated through the second partition plate 7; the fifth electrode plate 5 is composed of a fifth positive electrode plate 51 and a fifth negative electrode plate 52, the fifth positive electrode plate 51 and the fifth negative electrode plate 52 are integrally provided, the fifth positive electrode plate 51 and the fifth negative electrode plate 52 are symmetrically arranged, wherein after the stacking of the third separator 8 is completed, the first electrode plate 1 is placed on the upper portion of the fifth positive electrode plate 51 on one fifth electrode plate 5 positioned at one end of the first separator 6, the second electrode plate 2 is placed on the upper portion of the fifth negative electrode plate 52 on the other fifth electrode plate 5 positioned at the other end of the first separator 6, and the fifth positive electrode plate 51 of the fifth electrode plate 5 mounted on the third separator 8 is placed on the fifth negative electrode plate 52 of one fifth electrode plate 5 positioned at one end of the first separator 6, and the fifth negative electrode plate 52 of the fifth electrode plate 5 positioned on the third separator 8 is placed on the fifth positive electrode plate 51 of the other fifth electrode plate 5 positioned at the other end of the first separator 6.

The fourth group of layers comprises a first partition plate 6, a second partition plate 7 and a third partition plate 8 which are sequentially stacked from bottom to top, and the same partition plate stacking structure is adopted, so that the number of parts is reduced, and the overall stacking process is simpler and more clear; two fifth electrode plates 5 are installed on the first partition plate 6 in a matching mode, and the fifth electrode plates 5 are laminated through the second partition plate 7; the fifth electrode plate 5 is composed of a fifth positive electrode plate 51 and a fifth negative electrode plate 52, the fifth positive electrode plate 51 and the fifth negative electrode plate 52 are integrally provided, the fifth positive electrode plate 51 and the fifth negative electrode plate 52 are symmetrically arranged, wherein after the stacking of the third separator 8 is completed, the third electrode plate 3 is placed on the upper portion of the fifth positive electrode plate 51 on one fifth electrode plate 5 positioned at one end of the first separator 6, the fourth electrode plate 4 is placed on the upper portion of the fifth negative electrode plate 52 on the other fifth electrode plate 5 positioned at the other end of the first separator 6, and the fifth positive electrode plate 51 of the fifth electrode plate 5 mounted on the third separator 8 is placed on the fifth negative electrode plate 52 of one fifth electrode plate 5 positioned at one end of the first separator 6, and the fifth negative electrode plate 52 of the fifth electrode plate 5 positioned on the third separator 8 is placed on the fifth positive electrode plate 51 of the other fifth electrode plate 5 positioned at the other end of the first separator 6.

The second layer group and the fourth layer group adopt the same stacking structure, the stacking process is integrally slowed down, repeated stacking is convenient to realize, and the manufacturing cost is reduced.

The first partition plate 6 is of an annular integrated structure, specifically a rectangular annular structure, two electrode plate mounting grooves 62 are respectively arranged in the inner cavity of the first partition plate 6, and the two electrode plate mounting grooves 62 are of a rectangular groove structure and used for correspondingly and matchingly mounting the fifth electrode plate 5; the second partition plate 7 is of an annular integrated structure, specifically a rectangular annular structure, and can realize laminating fixation of the fifth electrode plate 5.

Among the first electrode plate 1, the second electrode plate 2, the third electrode plate 3 and the fourth electrode plate 4, the first electrode plate 1 and the third electrode plate 3 are made of negative electrode plates, and the second electrode plate 2 and the fourth electrode plate 3 are made of positive electrode plates, so that positive and negative electrification is conveniently realized; in another embodiment, the polarity of the anode and the cathode can be adjusted and changed correspondingly.

The first electrode plate 1 and the second electrode plate 2 are arranged in the same structure, and the third electrode plate 3 and the fourth electrode plate 4 are arranged in the same structure.

The main parts of the first electrode plate 1, the second electrode plate 2, the third electrode plate 3, the fourth electrode plate 4 and the fifth electrode plate 5 are all made of square electrode slices, wherein the shape and the size of the fifth positive electrode plate 51 and the fifth negative electrode plate 52 in the fifth electrode plate 5 are both single square electrode slices; the first electrode plate 1 and the second electrode plate 2 adopt single square electrode plates, and a first conductive plate 11 and a second conductive plate 12 are arranged on one side edge in an extending manner; a single square electrode plate is adopted in the third electrode plate 3 and the fourth electrode plate 4, and a third conductive plate 31 and a fourth conductive plate 41 are arranged on one side edge in an extending manner; the first conductive plate 11 corresponds to the third conductive plate 31, the second conductive plate 21 corresponds to the fourth conductive plate 41, the first conductive plate 11 and the second conductive plate 21 are respectively matched with the corresponding first groove 63 and the second groove 72 in the first partition plate 6 and the second partition plate 7, and the third conductive plate 31 and the fourth conductive plate 41 correspond to the convex notch 84 in the third partition plate 8, so that the structure is optimized, the alignment installation is convenient to realize, the stacking is convenient, and the subsequent conductive connection of the positive electrode and the negative electrode is convenient.

The structure is that two first notch openings 63 which are arranged at intervals are arranged on the outer edge of one side of the first clapboard 6; two second notch openings 72 which are arranged at intervals are arranged on the outer edge of one side of the second partition board 7, and the first notch opening 63 and the second notch opening 72 are arranged oppositely up and down; the third separator 8 includes a third main separator 82 and a third auxiliary separator 83 which are separately arranged, a slotted edge is arranged on one side of the third main separator 82, the third auxiliary separator 83 is located on the slotted edge, a convex notch 84 is formed between two ends of the third auxiliary separator 83 and the third main separator 82, the convex notch 84 is used for corresponding to the first notch 63 and the second notch 72, a third electrode slot is arranged in an inner cavity formed after the third main separator 82 and the third auxiliary separator 83 are combined, the third electrode slot is divided into a middle electrode slot 85 located in the middle and side electrode slots 86 located on two sides, the middle electrode slot 85 is used for installing the fifth electrode plate 5 in a matching manner, and the side electrode slots 86 are used for installing the first electrode plate 1 and the second electrode plate 2 in a matching manner respectively.

In the single electrolytic layer group, the third electrode plate 3 is located at the lower part of the first electrode plate 1, and the fourth electrode plate 4 is located at the lower part of the second electrode plate 2.

According to the invention, the electrode plate assembly and the separator assembly are optimized through optimized design, so that the universality is stronger; preferably, the second layer group and the fourth layer group are arranged in the same structure, so that the overall process is simplified, two-step repeated stacking is realized, and the overall stacking process is simplified; according to the specification requirement of the integral electrode tank, repeated stacking of a plurality of electrolytic layer groups can be realized, the manufacturing cost is reduced, and the universality of the product is improved.

Example 2

As shown in fig. 1 to 21, the lamination process of the laminated electrolytic cell for manufacturing the circulating electrolyzed water according to the present invention adopts the specific structure of the embodiment 1, and the lamination process specifically comprises:

step one, a fourth clapboard is used as a base layer and is placed in a platform to form a first layer group;

step two, according to product requirements, repeatedly stacking at least more than 3 groups of electrolyte layer groups on the upper part of the first layer group, wherein the single-layer electrolyte layer group is formed by stacking a second layer group, a third layer group and a fourth layer group in sequence, and the stacking method of the single electrolyte layer comprises the following steps:

s1, a second group of layers, as shown in fig. 10 to 13, selecting a first separator to be placed horizontally, installing two fifth electrode plates in the first separator at intervals, stacking the second separator on the upper portion of the first separator on which the fifth electrode plates are installed, stacking a third separator on the upper portion of the second separator, and installing and matching the third electrode plate, the fourth electrode plate and the fifth electrode plate with the stacked third separator respectively to form a second group of layers;

s2, selecting a first separator to be horizontally placed, installing two fifth electrode plates in the first separator at intervals, stacking a second separator on the upper portion of the first separator with the fifth electrode plates installed, stacking a third separator on the upper portion of the second separator, and installing and matching the first electrode plate, the second electrode plate and the fifth electrode plate with the stacked third separator to form a third layer group, as shown in fig. 14 to 17;

s3, a fourth group of layers, as shown in fig. 18 to 21, selecting a first separator to be placed horizontally, installing two fifth electrode plates in the first separator at intervals, stacking a second separator on the upper portion of the first separator on which the fifth electrode plates are installed, stacking a third separator on the upper portion of the second separator, and installing and matching the third electrode plate, the fourth electrode plate and the fifth electrode plate with the stacked third separator respectively to form a fourth group of layers;

and step three, stacking the fourth partition plate as a top layer on the upper part of the electrolytic layer group to complete the integral stacking.

In the second step, a plurality of electrolyte layer groups need to be overlapped according to product requirements, so the stacking manner is usually the first layer group + (the second layer group + the third layer group + the fourth layer group +. the second layer group + the third layer group + the fourth layer group) + the fifth layer group.

The arrangement of the arrangement in the specific stacking process is arranged according to the corresponding arrangement in example 1.

Example 3

An electrolyzed water generator based on a laminated electrolytic tank for manufacturing circulated electrolyzed water adopts the laminated electrolytic tank for manufacturing circulated electrolyzed water in the embodiment 1 or the embodiment 2, and further comprises a machine body, wherein the laminated electrolytic tank is arranged in the machine body.

In the present invention, the term "plurality" means two or more unless explicitly defined otherwise. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items. The terms "mounted," "connected," "fixed," and the like are used broadly and encompass, for example, a fixed connection, a removable connection, or an integral connection, and a connection may be a direct connection or an indirect connection via intermediate media. The specific meaning of the above terms in the present invention can be understood by those of ordinary skill in the art according to specific situations.

It will be understood that when an element is referred to as being "mounted to," "secured to" or "disposed on" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "upper," "lower," "left," "right," and the like as used herein are for illustrative purposes only and do not denote a unique embodiment.

In the description of the present specification, the description of the terms "one embodiment," "some embodiments," "specific embodiments," etc., means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the claims and their equivalents.