KR102122684B1 - Equalizing electrode plate with insulated split-flow conductive structure - Google Patents

Abstract

In the present invention, an insulated divided flow conducting structure in which an insulator is coated is provided on the outside of an electrical conductor, one end of the insulated split flow conducting structure is fastened to the electrical energy input/output terminal of the electrode plate, and the other end of the electrical energy output terminal among the electrode plates The distance between is relatively large and/or the impedance is fastened to a region of a relatively large electrode plate, and the exclusive isolated split flow conduction structure and the electrical energy input/output terminals are connected to each other, thereby providing an isolated split flow that professionally transfers the electric energy between the two. An equalizing electrode plate with a conductive structure is presented.

Description

EQUALIZING ELECTRODE PLATE WITH INSULATED SPLIT-FLOW CONDUCTIVE STRUCTURE

The present invention is a novel improvement of the electrode plate conduction structure used in a fuel cell or a device capable of charging and discharging, which is applied to a capacitor that charges and discharges static electricity or converts electrical energy into chemical energy and/or converts chemical energy into electrical energy. As it is, the electrode plate according to the improved invention is used in the electrical supply and / or charging and discharging device, the characteristic of the improved electrode plate is an insulator coated with an insulator on the outside of the electrical conductor is a specific installation, the insulation structure is isolated, One end of the split flow conduction structure is fastened to the electrical energy input/output terminal of the electrode plate, and the other end of the electrode plate has a relatively large distance from the electrical energy output terminal and/or a relatively large impedance plate area (around and/or around the electrode plate). Intermediate and/or bottom ends) allow an electrode plate section with a relatively large distance between the path of the current and the electrical energy output terminal and/or a relatively large impedance to pass the current. Is to professionally transmit the electrical energy between the two by being connected, and when the electrical energy output and/or electrical energy input, the electrical conductor of each region of the electrode plate and the electrochemically active material in contact therewith enter the electrical energy and It is characterized by operating at a relatively averaged current density at the time of output.

In the conventional electrode plate, one or more electrical energy input/output terminals are generally installed on one side, and electrical energy input/output in a structural position and an electrode plate area on the other side whose structural position is relatively far from the electrical energy input/output terminals. The electric energy is output or charged in the electrode plate region relatively close to the terminal, and since the impedance between the two and the input/output terminals is different, when the electric energy is output and/or the electric energy is input, there is a problem that the currents of the two are unbalanced.

The present invention has been devised to solve the above-mentioned problems, and an object of the present invention is to specifically install an insulated divided flow conducting structure in which an insulator is coated on the outside of an electrical conductor, and one end of the insulated divided flow conducting structure is used to electrically It is fastened to the energy input/output terminal and the other end, when electric energy is output and/or electrical energy is input from the electrode plate, the distance between the electric current path and the electric energy input/output terminal terminal is relatively long and/or fastened to the electrode plate area having a relatively high impedance. As a result, the distance between the electric current output terminal and the electric energy output terminal is relatively long and/or the electrode plate region having a relatively large impedance to pass the electric current is connected between the two by means of the connection between the exclusive isolated split flow conduction structure and the electric energy input/output terminals. The electrical energy is professionally transmitted, and the electrical conductors and the electrochemically active materials in contact with the individual zones on the electrode plate have a current density capable of relatively averaged operation when the electrical energy is output and/or input of electrical energy, The present invention is an electrode plate composed of a plate-shaped or thin-plate-type or wound-type electrode plate and a primary battery that converts electrical energy into chemical energy, a secondary battery that can be charged and discharged, a capacitor, a super capacitor, and a fuel cell that converts chemical energy into electrical energy. It is to provide an equalizing electrode plate having an insulated split flow conduction structure applicable to the present invention.

The first aspect of the present invention is an electrode plate 101 having a uniform insulating split flow conduction structure,

It is provided with an electrical energy input and output terminal 102, an electrochemically active material 103, an insulating divided flow conducting structure 104, the electrode plate 101 is a grid sheet-like electrode plate, a sheet-like electrode plate having a radial grid, A positive electrode or a negative electrode plate composed of at least one of a laminate electrode plate and a wound electrode plate,

The input/output terminal 102 is extended or separately installed from the electrode plate, is connected to at least one side of the electrode plate 101, and is installed at least on one side of the electrode plate 101 By being made, an interface for inputting and outputting electrical energy between the electrode plate and the outside, the electrically conductive material of the input/output terminal is made of the same or different material from the electrode plate,

The electrochemically active material 103 includes any one of the gaseous, liquid, gel, and solid phase electrochemical materials,

The insulating divided flow conducting structure 104 is composed of an electrical conductor 1045 of the same or different material as the electrode plate, and a part of the electrical conductor 1045 is covered and surrounded by an insulator 1046, one The above-described insulating divided flow conducting structure 104 is installed along a side edge of the electrode plate and/or in an intermediate region of the electrode plate, and one end of the insulating divided flow conducting structure 104 has an electrical conductivity function. As, the welding between heat sealing, spot welding, mechanical riveting, locking, clamping and blocking at least one of the input and output terminals 102 of the electrode plate 101 or the two between the input and output terminals 102 Is connected to the electrical conductor of the electrode plate 101,

The other end of the insulated split flow conducting structure 104 is a method having an electrically conductive function, and is connected to the electrode plate by at least one of welding, heat sealing, spot welding, mechanical riveting, locking, clamping and blocking, When outputting and/or inputting electrical energy, a distance between a current path and the input/output terminal 102 is connected to an electrode plate region where a distance is relatively large and/or a resistance of a current is relatively large, and the electrical energy between the two is transmitted,

The electrode plate is a positive electrode and/or a negative electrode plate, a primary cell composed of at least one of a grid sheet type electrode plate, a sheet type electrode plate having a radial grid, a laminate electrode plate and a wound electrode plate, and a secondary battery that can be charged and discharged. , An electrode plate capable of constituting at least one of a capacitor, a super capacitor or an electrode plate of a charge/discharge device or a fuel cell that converts electrical energy into chemical energy and/or converts chemical energy into electrical energy.

Another aspect of the present invention, the electrical conductor 1045 of the insulated split flow conducting structure 104,

(1) It is made of the same material as the electrode plate, or

(2) It is different from the electrode plate material, and the resistance coefficient is composed of a material having a lower conductivity than the electrode plate material, or

(3) The electrode plate is constituted by any one or more of those constructed by coating an electrode plate material with a material having a lower coefficient of resistance than an electrical conductor of the electrode plate material.

Another aspect of the present invention, the insulating split flow conducting structure 104 and the configuration of the electrode plate 101,

The insulating divided flow conducting structure 104 and the electrode plate 101 are integrally assembled,

Surrounding the periphery of the electrical conductor 1045 of the insulated split flow conducting structure 104 with the insulator 1046, or covered with the insulator 1046,

The insulating divided flow conducting structure 104 is the electrode plate forming a part of the electrode plate according to the shape of the flat or curved surface of the electrode plate 101.

Another aspect of the present invention, the insulating split flow conducting structure 104 and the configuration of the electrode plate 101,

The insulated split flow conductive structure 104 constitutes the electrical conductor 1045 as an independent conductive line or conductive sheet, and is parallel to the electrode plate 101 in planar manner, and surrounds the electrical conductor 1045 with the insulator. Surrounded by (1046) or covered with the insulator (1046),

The insulating divided flow conducting structure 104 is the electrode plate forming a part of the electrode plate according to the shape of the flat or curved surface of the electrode plate 101.

Another aspect of the present invention, the insulating split flow conducting structure 104 and the configuration of the electrode plate 101,

Insulating split flow conduction structure 104 is an independent conducting line or a conductive sheet, the insulated split flow conduction structure 104 constitutes the electrical conductor 1045, and the insulated split flow conduction structure 104 includes the electrode plate ( 101) is installed on one side or both sides, or the electrode plate 101 is installed so as to overlap, surrounding the electrical conductor 1045 with the insulator 1046 or surrounding it, or covered with the insulator 1046 and,

The insulating divided flow conducting structure 104 is the electrode plate forming a part of the electrode plate according to the shape of the flat or curved surface of the electrode plate 101.

Another aspect of the present invention, as an electrode plate 101 having a uniform insulating split flow conduction structure,

It is provided with an electrical energy input and output terminal 102, an electrochemically active material 103, an insulating divided flow conducting structure 104,

The electrode plate 101 is a positive electrode or a negative electrode plate composed of at least one of a grid sheet electrode plate, a sheet electrode plate having a radial grid, a laminate electrode plate, and a wound electrode plate,

The input/output terminal 102 is extended or separately installed from the electrode plate, is connected to at least one side of the electrode plate 101, and is installed at least on one side of the electrode plate 101 By being made, an interface for inputting and outputting electrical energy between the electrode plate and the outside, the electrically conductive material of the input/output terminal is made of the same or different material from the electrode plate,

The electrochemically active material 103 includes any one of the gaseous, liquid, gel, and solid phase electrochemical materials,

The insulating divided flow conducting structure 104 is composed of an electrical conductor 1045 of the same material or different material from the electrode plate,

The insulating split flow conducting structure 104 and the configuration method of the electrode plate 101,

The insulating divided flow conducting structure 104, which is a member different from the member on which the input/output terminal 102 is formed, is installed at the edge of the electrode plate,

The insulated split flow conducting structure 104 has an electrical conductor 1045,

Another input/output terminal 1023 is formed at one end of the electrical conductor 1045,

The outside of the electrical conductor 1045 is covered with an insulator 1046,

The other end of the electrical conductor 1045 is a method having an electrical conductivity function, the current path and the input and output terminal 102 in at least one of welding, heat sealing, spot welding, mechanical riveting, locking, clamping and blocking When the distance between them is relatively far and/or is connected to the electrode plate region where the resistance of the current is relatively large, and when outputting and/or inputting electrical energy, the electrical energy is transmitted through the other input/output terminals 1023,

The electrode plate is a positive electrode and/or a negative electrode plate, a primary cell composed of at least one of a grid sheet type electrode plate, a sheet type electrode plate having a radial grid, a laminate electrode plate and a wound electrode plate, and a secondary battery that can be charged and discharged. , An electrode plate constituting at least one of a capacitor, a super capacitor or an electrode plate of a charge/discharge device or a fuel cell that converts electrical energy into chemical energy and/or converts chemical energy into electrical energy.

In another aspect of the present invention, at least one side of the electrode plate 101 is provided with one or more of the input/output terminals 102, and one side or both sides of the electrode plate 101 from the input/output terminal 102. The insulated divided flow conducting structure 104 extending in parallel toward the lower side is installed in parallel, and the insulated divided flow conducting structure 104 further extends to the middle of the side edge of the electrode plate 101, and/or the It is the electrode plate extending to the side edge of the electrode plate 101 and/or extending to the side edge of the electrode plate 101 and also extending to the lower middle of the electrode plate 101.

Another aspect of the present invention, the input and output terminals 102, or within the electrode plate area except the side of the electrode plate 101, the electrical energy input and output terminal 102, or between the two input and output terminals 102 The insulated divided flow conducting structure 104 is installed by extending downward from the electrical conductor of the electrode plate 101,

The insulating split flow conduction structure 104,

It extends to the middle region of the electrode plate, or extends downward through the middle region of the electrode plate 101 to the bottom of the electrode plate 101, or downwards through the middle region of the electrode plate 101 Extending to the bottom of the electrode plate 101 and further along the bottom, and/or

From the input/output terminal 102, one side or both sides of the electrode plate 101 extend downward, and extend to an intermediate portion of the side of the electrode plate 101, and/or the electrode plate 101 It is the electrode plate which extends to the side edge and/or extends to the side edge of the electrode plate 101 and then extends along the lower end of the electrode plate 101.

In another aspect of the present invention, the insulated divided flow conducting structure 104 extends from the other input/output terminal 1023 to the bottom of one side of the electrode plate 101 along one side of the electrode plate 101. Or, extend from the other input/output terminal 1023 to one side of the electrode plate 101 and the lower middle of the electrode plate 101 to the lower middle portion of the electrode plate 101, or the other input/output terminal It is the electrode plate extending from (1023) to one side of the electrode plate 101 and the bottom of the other side of the electrode plate 101 along the lower end of the electrode plate 101.

In another aspect of the present invention, two input/output terminals 102 are installed on the upper end of the electrode plate 101, and the input/output terminal 102 and the electrode plate near the upper left of the electrode plate 101 ( The distance on the left side of 101) is relatively close, and the distance on the right side of the input/output terminal 102 and the electrode plate 101 close to the upper right is relatively close,

The two input/output terminals 102 are installed at the lower end of the electrode plate 101, and the distance between the input/output terminal 102 close to the upper right and the right side of the electrode plate 101 is relatively close and close to the lower left. The distance between the input/output terminal 102 and the left side of the electrode plate 101 is relatively close,

The insulated divided flow conducting structure 104 is directed downward along the right side of the electrode plate 101 from the input/output terminal 102 installed near the upper right, and extends to the middle of the right side of the electrode plate 101. Is installed, and directly transmits input/output current between the input/output terminal 102 near the upper right and the middle of the right side of the electrode plate 101,

The insulated divided flow conducting structure 104 is directed upward along the left side of the electrode plate 101 from the input/output terminal 102 installed near the bottom left, and extends to the vicinity of the middle portion of the left side of the electrode plate 101. It is installed, it is the electrode plate to directly transfer the input and output current between the input and output terminals 102 near the lower left and the middle portion close to the left side of the electrode plate 101.

Another aspect of the present invention is the electrode plate having at least one side of the electrode plate having the input/output terminal having one width equal to or close to the same width.

In another aspect of the present invention, at least one of the input/output terminals 102 is installed on the upper end of the electrode plate 101, and the insulating divided flow conduction structure 104 is provided from the input/output terminals 102 to the electrode plate. (101) is directed downward along the left side, extends to the vicinity of the lower middle portion, and directly transmits input/output current between the lower middle portion of the electrode plate 101 and the input/output terminal 102,

An electrode from the input/output terminal 102 on which the insulating divided flow conducting structure 104 is provided on the rightmost side of the electrode plate, or from the input/output terminal 102 on the right side when the input/output terminal 102 is single. Along the right side of the plate 101, extends downward to the bottom, and is also installed along the bottom, to directly transmit the input/output current between the lower right side of the electrode plate 101 and the input/output terminal 102,

The insulating divided flow conducting structure 104 extending to the lower left of the electrode plate 101 and the insulating divided flow conducting structure 104 extending to the lower right of the electrode plate 101 are the electrode plate 101 ) Is electrically connected at the bottom,

When three or more of the input/output terminals 102 are installed, the insulating split flow conduction structure 104 is installed extending from the input/output terminals 102 in the middle toward the lower end of the electrode plate 101, so that the electrode It is the electrode plate that directly transmits input/output electrical energy between the input/output terminals 102 at the lower and middle portions of the plate 101.

In another aspect of the present invention, at least one of the input/output terminals 102 is installed on the upper end of the electrode plate 101, and the insulated divided flow conducting structure 104 is located on the upper end of the electrode plate 101. It is installed to extend downward from the input/output terminal 102 to a position close to the lower end of the electrode plate 101, and a region close to the bottom side of the electrode plate 101 and the insulating divided flow connected to the region. It is an electrode plate that electrically connects the input/output terminal 102 connecting the other end of the conductive structure 104.

In another aspect of the present invention, the input/output terminal 102 having a width equal to or close to the same width as the electrode plate is provided on the top of the electrode plate 101.

Some of the insulating split flow conduction structures 104,

The electrode plate 101 extends from the middle of the input/output terminal 102 downward to the lower region from the middle of the electrode plate 101 in the extending direction of the insulating divided flow conducting structure 104. ) And electrically connect the input/output terminal 102 connecting the region beyond the middle of the side and the other end of the insulated divided flow conducting structure 104 connected to the region,

Other said insulated divided flow conducting structure 104,

It extends downward from the input/output terminal 102 and extends to an area near the center of the electrode plate 101 in the extending direction of the insulating divided flow conducting structure 104, so that the electrode plate 101 It is the electrode plate which electrically connects the input/output terminal 102 which connects the zone in the middle and the other end of the insulated divided flow conducting structure 104 connected to the zone.

Another aspect of the present invention, the insulator 1046 is an electrode plate comprising an epoxy resin, insulating rubber, insulating paint, varnish or PVF.

Another aspect of the present invention is a charging/discharging device in which a plurality of electrode pairs comprising the electrode plates according to claims 1 to 15 are formed as positive and negative electrode plates in parallel connection and/or series connection.

As described above, in the equalizing electrode plate having various insulated and divided flow conducting structures described above, the application form is used as a device for charging and discharging functions by constructing an electrode pair with a positive electrode plate and several electrodes. Pairs are connected in parallel and/or in series to form various rated voltages, and expansion of a constant current is achieved.

1 is a first embodiment of the present invention.
2 is a second embodiment of the present invention.
3 is a third embodiment of the present invention.
4 is a fourth embodiment of the present invention.
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12 is a twelfth embodiment of the present invention.
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15 is a fifteenth embodiment of the present invention.
16 is a sixteenth embodiment of the present invention.
17 is a seventeenth embodiment of the present invention.
18 is an eighteenth embodiment of the present invention.
19 is a 19th embodiment of the present invention.
20 is a twentieth embodiment of the present invention.
21 is a twenty-first embodiment of the present invention.
22 is a twenty-second embodiment of the present invention.
23 is a twenty-third embodiment of the present invention.
24 is a twenty-fourth embodiment of the present invention.
25 is a 25th embodiment of the present invention.
Fig. 26 is the second embodiment of Fig. 25;
27 is a 27th embodiment of the present invention.
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45 is a 45th embodiment of the present invention.
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48 is the 48th embodiment of the present invention.
49 is the 49th embodiment of the present invention.
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60 is a 60th embodiment of the present invention.
61 is a 61st embodiment of the present invention.
62 is the 62nd embodiment of the present invention.
63 is a 63rd embodiment of the present invention.
64 is a 64th embodiment of the present invention.
65 is a 65th embodiment of the present invention.
66 is a 66th embodiment of the present invention.
67 is a 67th embodiment of the present invention.
68 is a 68th embodiment of the present invention.
69 is the 69th embodiment of the present invention.
70 is a 70th embodiment of the present invention.
71 is a 71st embodiment of the present invention.
72 is a 72nd embodiment of the present invention.
73 is the 73rd embodiment of the present invention.
74 is the 74th embodiment of the present invention.
75 is the 75th embodiment of the present invention.
76 is a 76th embodiment of the present invention.
77 is the 77th embodiment of the present invention.
78 is the 78th embodiment of the present invention.
79 is the 79th embodiment of the present invention.
80 is an 80th embodiment of the present invention.
81 is the 81st embodiment of the present invention.
82 is a 82nd embodiment of the present invention.
83 is the 83rd embodiment of the present invention.
84 is the 84th embodiment of the present invention.
85 is the 85th embodiment of the present invention.
86 is an 86th embodiment of the present invention.
87 is an 87th embodiment of the present invention.
88 is the 88th embodiment of the present invention.
89 is the 89th embodiment of the present invention.
90 is a 90th embodiment of the present invention.
91 is the 91st embodiment of the present invention.
92 is the 92th embodiment of the present invention.
93 is a 93th embodiment of the present invention.
94 is the 94th embodiment of the present invention.
95 is an AA cross-sectional view of an insulating split flow conduction structure 104 in accordance with the present invention.
96 is a BB sectional view of an electrically conductive grid of an electrode plate according to the present invention.
97 is a CC cross-sectional view of an insulated split flow conducting structure 104 in accordance with the present invention.
98 is a DD cross-sectional view of an insulating split flow conduction structure 104 in accordance with the present invention.
99 is an EE cross-sectional view of a parallel insulated split flow conduction structure 104 in accordance with the present invention.
100 is an insulator 1046 installed on at least one side of the electrical conductor 1045 of the insulation split flow conduction structure 104 in one direction in the insulation split flow conduction structures 1041 and 1042 parallel to each other according to the present invention. It is not a cross section of FF.
101 is a GG cross-sectional view in which the parallel insulated divided flow conducting structures 1041 and 1042 according to the present invention are stacked vertically.
102 is a cross-sectional view in which an insulator is not installed on at least one side of the insulated split flow conduction structure 1041 and/or the insulated split flow conduction structure 1042 shown in FIG.
103 is a cross-sectional view of an HH in which an electrode plate is attached to one side of an insulating divided flow conducting structure 104 according to the present invention.
104 is a cross-sectional view in which an insulator is not installed on at least one side of the insulated divided flow conducting structure 104 shown in FIG. 103.

In the present invention, an insulated divided flow conducting structure in which an insulator is coated is installed on the outside of an electrical conductor having one or more paths, and one end of the insulated divided flow conducting structure is fastened to the electrical energy input/output terminal of the electrode plate and the other. One end is fastened to the periphery and/or the middle and/or the bottom of the electrode plate, and when electric energy is output and/or electric energy is input, the distance between the current path and the electric energy input/output terminal terminals is relatively long and/or the impedance is relatively large. By being fastened to the electrode plate (eg, around and/or the middle and/or bottom of the electrode plate) zone, the distance between the electric current output terminal and the electric energy output terminal is relatively long and/or the electrode plate region having a relatively high impedance passing through the electric current. By exclusively connecting the insulated split flow conduction structure and the electrical energy input/output terminals, the electrical energy between the two is professionally transmitted, and the electrical conductors in the individual zones on the electrode plate and the electrochemically active material in contact therewith output electrical energy. And/or an equalizing electrode plate with an insulated split flow conduction structure with a current density capable of relatively averaged operation upon electrical energy input.

1 to 70 illustrate the principle and basics of an equalizing electrode plate having an insulated divided flow conduction structure according to the present invention, and the preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 to 70, the main configuration includes an electrode plate 101, an electrical energy input/output terminal 102, an electrochemically active material 103 and an insulating split flow conduction structure 104. Done,

The electrode plate 101 is an electrode plate having a radial sheet shape, or an electrode plate having a radial grid sheet shape, or a laminate electrode plate, or a positive electrode and/or negative electrode plate composed of a wound electrode plate, The positive electrode and the negative electrode of the electrode plate may be composed of the same or different electrically conductive materials,

The electrical energy input/output terminal 102 is connected to one side or more than one side of the electrode plate 101 or extends from the electrode plate to the outside. The terminal is installed so that the electrode plate outputs electrical energy to the outside and/or is used as an interface through which the electrical energy is input, which includes outputting electrical energy to the outside and/or inputting electrical energy from the outside. The radial material of the input/output terminal and the electrode plate may be configured identically or differently,

The electrochemically active material 103 is made of a gaseous phase or a liquid phase or a gel phase or a solid phase electrochemical material,

The insulating divided flow conducting structure 104 is an electrical conductor 1045 of the same material or different material from the electrode plate, and is composed of an insulator 1046 enclosed or coated around the insulating plate, and the insulating divided flow conducting structure 104 ) May be installed where one or more paths are installed to lead to a radial and/or intermediate region of the electrode plate, and one end of the insulated divided flow conducting structure 104 has an electrical conductivity function. , Welding, heat sealing, spot welding, mechanical riveting, locking, clamping and blocking in a manner including the electrical energy input/output terminal 102 of the electrode plate 101 or an electrical conductor of the electrode plate, the other end It is connected to the electrode plate in a way that has electrical conduction function, i.e. welding, heat sealing, spot welding, mechanical riveting, locking, clamping and blocking, and when the electric energy output and/or electric energy input, the current path and The distance between the electrical energy input/output terminals 102 is relatively long and/or the electrode plate area having a relatively large impedance to pass electric current professionally transmits the electrical energy between the two.

In the equalization electrode plate having an insulated divided flow conduction structure according to the present invention, the electrode plates usable as positive and negative polarities are grid sheet-shaped electrode plates, radial sheet-shaped electrode plates, laminate electrode plates, or A primary battery composed of a wound electrode plate, a secondary battery capable of charging and discharging, a capacitor, a super capacitor or an electrode composed of a charging/discharging device or a fuel cell that converts electrical energy into chemical energy and/or converts chemical energy into electrical energy. It is characterized by including a plate.

In the equalizing electrode plate having an insulated divided flow conducting structure according to the present invention, the construction method of the electrical conductor 1045 of the insulated divided flow conducting structure 104 is: 1) a method composed of the same material as the electrode plate, 2 ) It is a material that is different from the electrode plate, and the electrical radial coefficient is composed of a material having superior electrical and electrical conductivity lower than the electrode plate material. 3) It is coated with the material of the electrode plate and the electrical resistance coefficient is made of an electric conductor that is lower than the material portion of the electrode plate. Method, 4) Two or two or more materials different from the material of the electrode plate are characterized by being configured in one or more ways of being composed of two or more layers of two or more rings.

The insulating split flow conducting structure 104 and the electrode plate 101 may be configured by one or more of the following methods.

1) The insulated divided flow conducting structure 104 and the electrode plate 101 are integrally formed, and an insulator 1046, that is, an circumference of the insulated divided flow conducting structure 104 around the electrical conductor 1045, that is, ex Insulator 1046 having similar functions, such as epoxy resin or insulating adhesive, insulating paint, varnish, or PVF, is enclosed or covered, and the electrical energy input/output is applied to the electrode plate 101 and one end of the insulating split flow conducting structure 104. The terminal 102 and/or the electrode plate zone set to transmit current directly with the electrical conductor of the electrode plate 101 is integrally formed, and the other end is the electric energy input/output terminal 102 or the electrode plate 101 ) Is integrally formed with an electrical conductor, and between these two, a current can be directly transmitted with a relatively low impedance, and the insulated divided flow conductive structure 104 forms a plane or a curved surface with the electrode plate 101, and It is a part of the electrochemical action of the application device, and the structure of the bucket-shaped structure or the body is installed inside the pupil,

2) One end of the insulated divided flow conducting structure 104 and the electrode plate 101, and an electrode plate set to directly transmit the electrical conductor input/output terminal 102 and/or the electric conductor and current of the electrode plate 101 The zones are integrally formed and have similar functions, such as an insulator 1046, ie epoxy resin or insulating adhesive, insulating paint, varnish or PVF, around the electrical conductor 1045 of the insulating split flow conducting structure 104. The insulator 1046 is enclosed or covered, and the electrical energy input/output terminal 102 and/or the electrical conductor of the electrode plate 101 can directly transmit current with a relatively low impedance, and the insulated split flow conduction structure (104) is a method of forming a part of the electrode plate and forming a plane or a curved surface with the electrode plate 101, and is installed as a pupil in a water tank-like structure or each body of the electrochemical action of the application device,

3) The insulated divided flow conducting structure 104 constitutes the electrical conductor 1045 with an independent conductive line or conductive sheet, and an insulator 1046, ie, an epoxy resin or an insulating adhesive, around the electrical conductor 1045 , Insulating paint, varnish or PVF, and similar functional insulator 1046 is enclosed or covered, and both ends of the electrical conductor 1045 of the insulated split flow conductive structure 104 are welded, heat sealed, spot welded, respectively. Mechanical riveting, locking, clamping and blocking methods, one end of which is fastened to the electrical conductors of the electrical energy input/output terminal 102 and/or the electrode plate 101, the other end of the electrode plate The electrical energy input/output terminal 102 and/or the electrical conductor of the electrode plate 101 is fastened to an electrode plate region set to directly transmit current, and parallel to the electrode plate 101 in parallel with the electric energy output and When the electrical energy is input, the electrode plate area and the energy input/output terminal 102 set before the electrical energy input/output terminal 102 and/or the electrical conductor and current of the electrode plate 101 are directly transmitted from the electrode plate. ) And/or a current with a relatively low impedance can be directly transferred between the electrical conductors of the electrode plate 101, and a part of the electrode plate is formed by forming a plane or a curved surface in common with the electrode plate 101. The method of jointly installing inside the body or the shape of a bucket of electrochemical action of the application device,

4) The insulated divided flow conducting structure 104 constitutes the electrical conductor 1045 with an independent conductive line or conductive sheet, and an insulator 1046, ie, an epoxy resin or an insulating adhesive, around the electrical conductor 1045 , Insulator 1046, such as insulating paint, varnish, or PVF, is enclosed or covered, and both ends of the electrical conductor 1045 of the insulated split flow conducting structure 104 are welded, heat sealed, spot welded, mechanical riveted, respectively. , Locking, clamping and blocking methods are fastened to the electrical conductors of the electrical energy input/output terminal 102 and/or the electrode plate 101, and the other end of the electrical energy input/output from the electrode plate 101 The terminal 102 and/or the electrical conductor of the electrode plate 101 is fastened to an electrode plate region set to directly transmit current, and the insulating divided flow conducting structure 104 is one side or both sides of the electrode plate 101. It is possible to install on the electrode plate 101 and is superimposed, and in the current path for outputting electrical energy and/or inputting electrical energy, the electrical energy input/output terminal 102 and the electrode plate 101 / Or between the electrical conductor input and output terminals 102 or the electrical conductors of the electrode plate 101 and the electrode plate area set to directly transmit the electrical conductors and current of the electrode plate 101 with a relatively low impedance. It can be directly transmitted, and the insulated divided flow conducting structure 104 and the electrode plate 101 form a part of the electrode plate in a flat or curved surface and form a bucket-like structure for electrochemical action of the application device. The way that it is installed jointly inside each body,

5) The isolated divided flow conducting structure 104 is installed on the outside of the bucket-like structure or each body of the electrode plate, and the isolated divided flow conducting structure 104 is the electricity of the isolated split flow conducting structure 104. The insulator 1046 enclosed or coated on the outside of the conductor 1045 or the insulator 1046 such as epoxy resin or insulating adhesive, insulating paint, varnish, or PVF is the electrical energy input/output terminal at the electrode plate 101 The electrode plate 101 is set to directly transmit electrical conductors and electric currents of the electrode plate 101 and/or to output electric energy and/or to the electrode plate 101 in the current path in which electric energy is input. The electrical energy input/output terminal 102 and/or the electrical conductor of the electrode plate 101 and the electrode plate area set to directly transmit current and the electrical energy input/output terminal 102 and/or the electrical conductor of the electrode plate 101 The liver is characterized in that it includes a method of directly transmitting electrical energy with a relatively low impedance by connecting to the outside or outputting electrical energy individually in a separated state and/or inputting electrical energy.

The leveling electrode plate having an insulated divided flow conduction structure according to the present invention can be excreted for various structures based on the above-described principle, hereinafter, examples of application according to excretion for various magnetic structures are exemplified. It is not.

The embodiment of the equalizing electrode plate having an insulated divided flow conducting structure according to the present invention is shown in FIGS. 1 to 10, a grid sheet-shaped electrode plate, or a radial grid sheet-shaped electrode plate, or a laminate. As an electrode plate or a wound electrode plate, one or more of the electrical energy input/output terminals 102 are installed on one side of the electrode plate 101, and the electrical energy input/output terminals 102 are the electrodes. The insulated divided flow conducting structure 104 is installed in one or both sides facing the plate 101 in a downward direction, and the installation position is in the middle of the electrode plate 101 and/or the electrode plate 101. It is characterized in that it extends to the side end of the side and/or to the bottom end of the electrode plate 101 and again to the lower end of the electrode plate 101.

1 is a first embodiment according to the present invention, as shown in Figure 1, the upper left corner of the electrode plate 101 is provided with an electrical energy input and output terminal 102 and along the mountain peak of the electrode plate 101 An insulating split flow conduction structure 104 is installed in the electric energy input/output terminal 102, which extends to the right side, which is relatively far away, and then extends along the right side of the electrode plate 101 to the bottom end or closer to the bottom end. The current input/output between the lower right part of the electrode plate 101 and the electrical energy input/output terminal 102 is directly transmitted.

Figure 2 is a second embodiment according to the present invention, as shown in Figure 2, the upper left of the electrode plate 101, the electrical energy input and output terminal 102 is installed and the electrical energy input and output terminal 102 is the An insulating split flow conduction structure 104 is installed in a place along the upper left corner of the electrode plate 101 and the lower left end of the electrode plate 101 to provide a bottom end of the electrode plate 101 and the electrical energy input/output terminals 102. ) Directly transfers the input and output currents.

Figure 3 is a third embodiment according to the present invention, as shown in Figure 3, the upper end of the electrode plate 101, the electrical energy input and output terminal 102 is installed, the upper right and the right side of the electrode plate 101 In a place that extends to a place close to the middle, an insulated divided flow conducting structure 104 is installed to directly transmit the current input and output between both the intermediate portions of the electrode plate 101 and the electrical energy input/output terminals 102, and Insulated split flow conduction structures 104 are installed at the left and right extremities along the upper end of the electrode plate 101 to be input/output between the lower end of the electrode plate 101 and the electrical energy input/output terminals 102. Direct current transfer.

4 is a fourth embodiment according to the present invention. As shown in FIG. 4, an electrical energy input/output terminal 102 is installed at the top of the electrode plate 101, and the electrical energy input/output terminal 102 is an electrode plate ( 101) An insulated split flow conduction structure 104 is installed at the right and left sides and along both sides along the upper end of the 101 to directly transmit and receive current input/output between both ends of the electrode plate 101 and the electrical energy input/output terminals 102. do.

Figure 5 is a fifth embodiment according to the present invention, as shown in Figure 5, the upper end of the electrode plate 101 is provided with an electrical energy input and output terminal 102 and both sides along the top of the electrode plate 101 In the installation of the insulated divided flow conducting structure 104 in a subsequent place, the insulated divided flow conducting structure 104 installed along the left side of the electrode plate 101 relatively close to the electrical energy input/output terminal 102 is the It extends near the middle of the lower end of the electrode plate 101 and directly transmits the input/output current between the middle of the lower end of the electrode plate 101 and the electric energy input/output terminal 102, and the electric energy input/output terminal 102 The insulated divided flow conducting structure 104 installed along the right side of the electrode plate 101 that is relatively far away extends to a position closer to the right middle bottom of the electrode plate 101 to the right middle bottom of the electrode plate 101. A current input/output between a nearby place and the electrical energy input/output terminal 102 is directly transmitted.

6 is a sixth embodiment according to the present invention, as shown in FIG. 6, in which two electrical energy input/output terminals 102 are installed at the top of the electrode plate 101, the electricity close to the top left The distance between the energy input/output terminal 102 and the left side of the electrode plate 101 is relatively close, and the distance between the right side of the electrical energy input/output terminal 102 and the right side of the electrode plate 101 is relatively close, and the electric energy close to the upper right side. Where the input/output terminal 102 extends along the right middle of the electrode plate 101 to a place near the bottom end, the insulating split flow conduction structure 104 is installed to be close to the right middle bottom end of the electrode plate 101. And an electric current input/output between the electrical energy input/output terminal 102 close to the upper right.

7 is a seventh embodiment according to the present invention, as shown in FIG. 7, in which two electrical energy input/output terminals 102 are installed at the top of the electrode plate 101, the electricity close to the top left The distance between the energy input/output terminal 102 and the left side of the electrode plate 101 is relatively close, and the distance between the right side of the electrical energy input/output terminal 102 and the right side of the electrode plate 101 is relatively close, and the electric energy close to the upper right side. Where the input/output terminal 102 extends along the right side of the electrode plate 101 to the middle of the bottom, an insulating split flow conducting structure 104 is installed to close the electric energy near the middle and top right of the bottom of the electrode plate 101. The current input/output between the input/output terminals 102 is directly transferred.

8 is an eighth embodiment according to the present invention, as shown in FIG. 8, in which two electrical energy input/output terminals 102 are installed on the top of the electrode plate 101, the electricity close to the top left The distance between the energy input/output terminal 102 and the left side of the electrode plate 101 is relatively close, and the distance between the right side of the electrical energy input/output terminal 102 and the right side of the electrode plate 101 is relatively close, and the electric energy close to the upper left side. Where the input/output terminal 102 extends along the left side of the electrode plate 101 in a downward direction to the bottom end, an insulated split flow conducting structure 104 is installed to be close to the left bottom end of the electrode plate 101. And the electric energy input/output terminal 102 near the upper left directly transmits an input/output current, and the electric energy input/output terminal 102 near the upper right is hem downward along the right side of the electrode plate 101. Where it extends to a place close to the insulation split flow conduction structure 104 is installed, the electric current input/output between the electrical energy input/output terminal 102 near the right bottom end and the upper right of the electrode plate 101 is installed. Send directly.

9 is a ninth embodiment according to the present invention, as shown in FIG. 9, in which two electrical energy input/output terminals 102 are installed on the top of the electrode plate 101, the electricity close to the top left The distance between the energy input/output terminal 102 and the left side of the electrode plate 101 is relatively close, and the distance between the right side of the electrical energy input/output terminal 102 and the right side of the electrode plate 101 is relatively close, and the electric energy close to the upper right side. Where the input/output terminal 102 is near the middle extending from the left side of the electrode plate 101 to the hem in the downward direction, an insulated split flow conducting structure 104 is installed to be close to the middle of the hem of the electrode plate 101. And the electric energy input/output terminal 102 near the upper left directly transmits an input/output current, and the electric energy input/output terminal 102 near the upper right is hem downward along the right side of the electrode plate 101. The current that is input/output between the electrical energy input/output terminal 102 near the middle of the lower right of the electrode plate 101 and the upper right by installing the insulated split flow conducting structure 104 near the middle leading up to Directly transmitting, and the bottom end of the insulated split flow conducting structure 104 in which the left side of the electrode plate 101 extends downward is connected to or adjacent to each other, and electricity is passed between the bottom end and the electrode plate 101. .

10 is a tenth embodiment according to the present invention, as shown in FIG. 10, the upper end of the electrode plate 101 is provided with an electrical energy input and output terminal 102 and the electrical energy input and output terminal 102 is the electrode Places extending along the left and right sides of the plate 101 in a downward direction closer to the bottom end are provided with an insulated split flow conduction structure 104 configured in both directions to be close to both ends of the electrode plate 101 and the electricity. Directly transmits the current input and output between the energy input and output terminals 102, and in the middle near the bottom of the insulated split flow conducting structure 104 on both sides individually having a split function leading to the electrode plate 101 to the inside. By installing the insulated divided flow conducting structure 104, a location close to the bottom of the electrode plate 101 and an intermediate end of the electrode plate 101 lead toward the interior of the electrode plate 101 and the electricity The current input/output between the energy input/output terminals 102 is directly transmitted.

The implementation method of the equalization electrode plate having an insulated divided flow conduction structure according to the present invention is as shown in FIGS. 11 to 14, a grid sheet-shaped electrode plate, or a radial grid sheet-shaped electrode plate, or a laminate. As an electrode plate or a wound electrode plate, one or more electrical energy input/output terminals 102 are installed on one side of the electrode plate 101, and the electrical energy input/output terminals 102 are provided on the electrode plate 101. ), where two or more than two are installed in parallel, the insulated split flow conduction structures 104 are installed in parallel along one side or both sides, and the insulated split flow conduction structures 104 of individual paths are individually In the downward direction, it extends to the middle of the side end of the electrode plate 101 and/or in the downward direction to the side end of the electrode plate 101 and/or via the side end of the electrode plate 101. 101).

11 is an eleventh embodiment according to the present invention, as shown in FIG. 11, an electric energy input/output terminal 102 is installed near the upper left of the electrode plate 101 and the electrode plate 101 In the bidirectional insulated split flow conduction structures 1041 and 1042 installed parallel to the right along the top or installed up and down as shown in FIG. 99, the insulated split flow conduction structure 1041 is the top of the electrode plate 101. A near the middle that extends to the right side of the electrode plate 101 along, it directly transmits an input/output current between the right middle portion of the electrode plate 101 and the electrical energy input/output terminal 102, and the insulation split flow. The conductive structure 1042 is a place near the bottom end extending to the right side of the electrode plate 101 along the upper end of the electrode plate 101, the right bottom end of the electrode plate 101 and the electrical energy input/output terminal 102 Directly transfers the input/output current between them.

12 is a twelfth embodiment according to the present invention, as shown in FIG. 12, an electric energy input/output terminal 102 is installed near the upper left of the electrode plate 101 and the electrode plate 101 In the bidirectional insulated split flow conduction structures 1041 and 1042 installed parallel to the right along the top or installed up and down as shown in FIG. 99, the insulated split flow conduction structure 1041 is the top of the electrode plate 101. A near the middle that extends to the right side of the electrode plate 101 along, it directly transmits an input/output current between the right middle portion of the electrode plate 101 and the electrical energy input/output terminal 102, and the insulation split flow. The conductive structure 1042 is a place near the bottom end extending to the right side of the electrode plate 101 along the upper end of the electrode plate 101, the right bottom end of the electrode plate 101 and the electrical energy input/output terminal 102 The insulated split flow conduction structure 104 composed of a single direction where the current inputted/outputted therebetween is directly transmitted and extends from the top to the left of the electrode plate 101 and extends downward to the bottom left of the electrode plate 101. Is installed to directly transmit the current input/output between the left bottom end of the electrode plate 101 and the electrical energy input/output terminal 102.

13 is a thirteenth embodiment according to the present invention, as shown in FIG. 13, an electric energy input/output terminal 102 is installed near the upper left of the electrode plate 101 and the electrode plate 101 In the bidirectional insulated split flow conduction structures 1041 and 1042 installed parallel to the right along the top or installed up and down as shown in FIG. 99, the insulated split flow conduction structure 1041 is the top of the electrode plate 101. A near the middle that extends to the right side of the electrode plate 101 along, it directly transmits an input/output current between the right middle portion of the electrode plate 101 and the electrical energy input/output terminal 102, and the insulation split flow. The conductive structure 1042 is a place near the bottom end extending to the right side of the electrode plate 101 along the upper end of the electrode plate 101, the right bottom end of the electrode plate 101 and the electrical energy input/output terminal 102 Directly transfers the current input and output between,

And in the direction to the left along the electrical energy input and output terminal 102 on the top of the electrode plate 101, in the installation of the insulated split flow conduction structures 1041 and 1042 configured in both directions, the insulated split flow conduction structure (1041) is near the middle extending to the left side of the electrode plate 101 along the upper end of the electrode plate 101, between the left middle of the electrode plate 101 and the electrical energy input and output terminal 102 The input/output current is transmitted directly, and the insulated divided flow conduction structure 1042 is a place near the bottom end extending to the left side of the electrode plate 101 along the upper end of the electrode plate 101, and the electrode plate 101 Directly transmits the input and output current between the left hem and the electrical energy input and output terminal 102.

14 is a 14th embodiment according to the present invention, as shown in FIG. 14, an electric energy input/output terminal 102 is installed near the upper left of the electrode plate 101 and the electrode plate 101 In the bidirectional insulated split flow conduction structures 1041 and 1042 installed in parallel along the top to the right or installed up and down as shown in FIG. 99, the insulated split flow conduction structure 1041 is an upper end of the electrode plate 101 A region inwardly curved to the middle that extends to the right side of the electrode plate 101 along the line, which is input and output between the region in which the electrode plate 101 is inwardly curved and the electric energy input/output terminal 102 in the upper right. Transmitting current directly, the insulated split flow conduction structure 1042 follows the upper end of the electrode plate 101 to a place closer to the right bottom end of the electrode plate 101 and the right bottom end of the electrode plate 101 Directly transmits the current input and output between the electrical energy input and output terminals 102 on the upper right,

In addition, in the installation of the insulated split flow conducting structures 1041 and 1042 configured in both directions along the electric energy input/output terminal 102 near the upper left of the upper end of the electrode plate 101, the insulation The divided flow conduction structure 1041 is an area that is bent inward near the middle extending to the left side of the electrode plate 101 along the upper end of the electrode plate 101, and is bent inward from the left middle of the electrode plate 101. Directly transmitting and receiving current between the area and the electrical energy input/output terminal 102 close to the upper left, the insulating divided flow conduction structure 1042 is along the upper end of the electrode plate 101, the electrode plate 101 It is close to the hem that extends to the left side of, and directly transmits the input and output current between the left hem of the electrode plate 101 and the electrical energy input/output terminal 102.

An embodiment of an equalizing electrode plate having an insulated divided flow conducting structure according to the present invention is shown in FIGS. 15 to 21, a grid sheet-shaped electrode plate, or a radial grid sheet-shaped electrode plate, or a laminate. An electrode plate or a wound electrode plate, which is provided with electrical energy input/output terminals 102 on each side of each or more of the electrode plates 101, wherein the electrical energy input/output terminals 102 are provided on the electrode plate 101. ) Is installed in the downward direction toward one or both sides of the insulated split flow conduction structure 104, and the installation position is in the middle extending to the side of the electrode plate 101, the insulated split flow conduction structure 104 And/or the insulated split flow conducting structure 104 is installed at the bottom end leading to the side surface of the electrode plate 101 and/or the electrode plate again at the bottom end leading up to the side surface of the electrode plate 101. 101).

15 is a fifteenth embodiment according to the present invention. As shown in FIG. 15, an electrical energy input/output terminal 102 is installed at the top of the electrode plate 101, and the electrical energy input/output terminal 102 is the electrode. An insulated split flow conduction structure 104 is installed in a place along the upper left side of the plate 101 in the downward direction to the middle of the left, between the left middle portion of the electrode plate 101 and the electric energy input/output terminals 102 at the top. The insulated split flow conduction structure where the electric current input and output is directly transmitted from and the electrical energy input/output terminal 102 extends to the right along the upper end of the electrode plate 101 to the right side of the electrode plate 101. (104) is installed to directly transmit the current input and output between the electrical energy input and output terminals 102 on the right and top of the electrode plate 101,

Further, the electrical energy input/output terminal 102 is installed at the lower end of the electrode plate 101, and the right side of the electrical energy input/output terminal 102 faces upward and extends to the middle of the right side of the electrode plate 101. Insulating split flow conduction structure 104 is installed to directly transfer the current input and output between the electrical energy input/output terminals 102 at the lower right and middle of the electrode plate 101, and the electrical energy input/output terminals 102 A place that extends from the left to the bottom left along the bottom of the electrode plate 101 is installed between the bottom left of the electrode plate 101 and the electrical energy input/output terminal 102 by installing the insulating split flow conduction structure 104. The insulation split flow conduction structure 104 is provided where the input/output current is directly transmitted and the electrical energy input/output terminal 102 extends from the bottom and bottom of the electrode plate 101 to the middle along the right side of the electrode plate 101. Is installed to directly transmit the current input/output between the electrical energy input/output terminals 102 in the middle and lower right of the electrode plate 101.

16 is a sixteenth embodiment according to the present invention, as shown in FIG. 16, an electric energy input/output terminal 102 is installed on the upper left side of the electrode plate 101, and a lower right side of the electrode plate 101 is installed. In the installation of the electrical energy input and output terminal 102, the left side of the electrical energy input and output terminal 102 on the upper end of the electrode plate 101 along the downward direction to the lower electrical energy input and output terminal 102 between the An insulated split flow conduction structure 104 is installed to directly transfer the current input and output between the upper and lower electrical energy input/output terminals 102 and the lower electrical energy input and output terminals 102.

17 is a seventeenth embodiment according to the present invention, as shown in FIG. 17, the electrical energy input and output terminal 102 is installed on the upper left of the electrode plate 101, and the electrical energy input and output terminal 102 on the top In the downward direction along the upper right side of the right to the middle of the right side, an insulated split flow conduction structure 104 is installed to close the middle of the right side of the electrode plate 101 and the upper electrical energy input/output terminal 102. Directly transfers the current input and output between,

Further, the electrical energy input/output terminal 102 is installed on the lower right side of the electrode plate 101, and the electrical energy input/output terminal 102 on the lower side is the electrode in the left and up directions along the lower end of the electrode plate 101. The insulated split flow conduction structure 104 is installed near the middle extending to the left side of the plate 101 to between the near middle left side of the electrode plate 101 and the electrical energy input/output terminals 102 at the bottom. It directly transmits the input/output current.

18 is an eighteenth embodiment according to the present invention, as shown in FIG. 18, an electric energy input/output terminal 102 is installed on the upper left side of the electrode plate 101, and the electric energy input/output terminal 102 on the top An insulation split flow conduction structure 104 is installed in a place near the middle extending to the right in the downward direction along the right side of between the closest middle portion of the electrode plate 101 and the electrical energy input/output terminal 102 at the top. The insulation split flow conduction structure 104 is located near the middle where the electric current input/output is directly transmitted from the upper end and the electrical energy input/output terminal 102 at the top extends to the left in the left and down directions along the upper end of the electrode plate 101. ) Is installed to directly transmit the current input and output between the electrical energy input/output terminal 102 at the top and the middle near the left of the electrode plate 101,

Further, the electrical energy input/output terminal 102 is installed on the lower right side of the electrode plate 101, and the electrical energy input/output terminal 102 on the lower side is the electrode in the left and up directions along the lower end of the electrode plate 101. The insulated split flow conduction structure 104 is installed in the middle close to the left side of the plate 101 to close to the middle of the right side of the electrode plate 101 and between the electrical energy input and output terminals 102. The insulation is placed in the middle where the electric current to be transmitted is directly transmitted and the electrical energy input/output terminal 102 at the bottom extends closer to the right side of the electrode plate 101 in the right and up directions along the bottom of the electrode plate 101. The split flow conduction structure 104 is installed to directly transmit the current input and output between the electric energy input/output terminal 102 and the place near the middle of the right side of the electrode plate 101.

19 is a 19th embodiment according to the present invention, as shown in FIG. 19, in the installation of two electrical energy input and output terminals 102 on the top of the electrode plate 101, the electricity close to the upper left The energy input/output terminal 102 is relatively close to the left side of the upper end of the electrode plate 101, and the electric energy input/output terminal 102 close to the upper right side is relatively close to the right side of the electrode plate 101 and the electrode plate 101 ) In the installation of two electrical energy input/output terminals 102 at the lower end, the electrical energy input/output terminals 102 close to the lower right are relatively close to the lower right of the electrode plate 101 and closer to the lower left. The electrical energy input/output terminal 102 is relatively close to the left side of the electrode plate 101, and the electrical energy input/output terminal 102 close to the upper left side is along the upper end of the electrode plate 101 and the left and the electrode plate 101. ) To the bottom of the electrode plate 101 in the downward direction along the left side of the electrical energy input/output terminal 102 near the left side and continues to the right side along the bottom of the electrode plate 101 to the bottom left side. The insulation split flow conduction structure 104 is installed to directly transmit the current input/output between the electrical energy input/output terminal 102 near the upper left and the electrical energy input/output terminal 102 near the lower left.

20 is a twentieth embodiment according to the present invention, as shown in FIG. 20, in which two electrical energy input/output terminals 102 are installed on the upper side of the electrode plate 101, close to the upper left The distance between the electrical energy input/output terminal 102 and the left side of the electrode plate 101 is relatively close, and the distance between the electrical energy input/output terminal 102 and the right side of the electrode plate 101 close to the upper right is relatively close and the electrode plate ( In the lower side of 101), the two electric energy input/output terminals 102 are installed, and the distance between the electric energy input/output terminal 102 close to the lower right and the right side of the electrode plate 101 is relatively close and lower left. The distance between the electrical energy input/output terminal 102 near and the left side of the electrode plate 101 is relatively close, and the electrical energy input/output terminal 102 near the upper left side is closer to the lower left side in the downward direction along the left side located closer to the side. An insulating split flow conduction structure 104 is installed between the electrical energy input/output terminals 102 close to the left side leading to the lower end, and the electrical energy input/output terminals 102 close to the upper left and the electrical energy input/output terminals close to the lower left. The electric energy input/output between 102 is directly transmitted, and the electric energy input/output terminal 102 close to the upper right and the electric energy close to the right side leading to the lower end closer to the lower right side along the right side located closer to the side. Between the input and output terminals 102, the insulation split flow conducting structure 104 is installed to input and output current between the electrical energy input/output terminals 102 near the upper right and the electrical energy input/output terminals 102 near the lower right. Directly.

21 is a twenty-first embodiment according to the present invention, as shown in FIG. 21, in which two electrical energy input/output terminals 102 are installed at the top of the electrode plate 101, the electricity close to the top left The energy input/output terminal 102 is relatively close to the left side of the top of the electrode plate 101, and the electrical energy input/output terminal 102 close to the top right side is relatively close to the right side of the electrode plate 101, and close to the top left side. A portion that extends to a place near the middle of the left along the left side of the electrical energy input/output terminal 102 is provided with an insulated split flow conducting structure 104 to be near the middle of the left side of the electrode plate 101 and close to the top left side. The insulated split flow conduction structure (directly transmits the current input/output between the electrical energy input/output terminals 102, and extends along the right side of the electrical energy input/output terminals 102 close to the right-to-phase right to the middle of the right-hand side) 104) is installed to directly transmit the current inputted and output between the electrical energy input/output terminal 102 close to the middle of the right and the upper right of the electrode plate 101,

In addition, in the lower end of the electrode plate 101, the two electrical energy input/output terminals 102 are installed, and the electrical energy input/output terminal 102 close to the lower right is relatively lower right of the electrode plate 101. The electrical energy input/output terminal 102 that is close and relatively close to the bottom left and close to the bottom left is relatively close to the left side of the electrode plate 101, and the electrode along the left side of the electrical energy input/output terminal 102 close to the bottom left. The electrical energy input/output terminal 102 near the middle left and the bottom left of the electrode plate 101 is provided by installing the insulated split flow conduction structure 104 to a place near the left middle of the plate 101. The insulated split flow conduction structure 104 is transmitted directly between the input and output currents and extends along the right side of the electrical energy input/output terminal 102 close to the lower right to the middle of the right side of the electrode plate 101. Is installed to directly transmit the input/output current between the electrical energy input/output terminal 102 near the middle of the right and the lower right of the electrode plate 101.

An embodiment of an equalizing electrode plate having an insulated divided flow conducting structure according to the present invention, as shown in FIGS. 22 to 28, a grid sheet-shaped electrode plate, or a radial grid sheet-shaped electrode plate, or a laminate An electrode plate or a wound electrode plate, which is provided in an electrode plate region other than a side surface of the electrode plate 101 to install an electric energy input/output terminal 102 or the electrode plate between two electric energy input/output terminals 102. Where the electrical conductor of 101 extends downward, an insulated divided flow conducting structure 104 is installed, that is, it extends to the middle region of the electrode plate or via the middle region of the electrode plate 101 to the downward direction. The insulated split flow conduction structure 104 that extends to the bottom of the electrode plate 101 or through the middle region of the electrode plate 101 to the bottom of the electrode plate 101 in the downward direction and then again toward the bottom. And/or where the electrical energy input/output terminal 102 extends toward one or both side surfaces of the electrode plate 101, the insulating split flow conducting structure 104 is installed, that is, in the middle of the electrode plate 101 and It is characterized in that it extends to the bottom end of the side of the electrode plate 101 and/or the bottom end of the side of the electrode plate 101 and back to the bottom end of the electrode plate 101.

22 to 28, between the electrical energy input/output terminal 102 and the middle and/or bottom of the electrode plate 101 of the electrode sheet of a grid sheet module having a grid-shaped electrical conductor according to the present invention. An insulated split flow conduction structure 104 is installed in the current density and other regions are relatively close when current is input/output between the middle or bottom of the electrode plate 101 and the electrical energy input/output terminal 102. Accordingly, an embodiment of the related configuration is as follows.

22 is a 22nd embodiment according to the present invention, as shown in FIG. 22, in which two electrical energy input/output terminals 102 are installed on the upper side of the electrode plate 101, near the upper left The distance between the electrical energy input/output terminal 102 and the left side of the electrode plate 101 is relatively close, and the distance between the electrical energy input/output terminal 102 and the right side of the electrode plate 101 close to the upper right is relatively close, and is located on the upper left side. In the middle of the electrical energy input/output terminal 102 close to the bottom of the electrode plate 101 in a downward direction, an insulated split flow conducting structure 104 is installed to form a gap between the middle of the lower left of the electrode plate 101. Directly transmits the current input and output between the electrical energy input and output terminal 102 close to the upper left,

And where the electrical energy input/output terminal 102 close to the upper right extends to the bottom in the downward direction along the right side of the electrode plate 101, the electrode plate 101 is provided by installing the insulating split flow conduction structure 104. Directly transmits the current input and output between the electrical energy input and output terminal 102 near the lower right and near the upper right,

And between the electrical energy input and output terminal 102 close to the upper left of the electrode plate 101 and the electrical energy input and output terminal 102 close to the upper right of the electrode plate 101 toward the middle of the An input and output between the electrical energy input/output terminal 102 near the middle and upper left of the electrode plate 101 and the electrical energy input/output terminal 102 near the upper right by further installing an insulated split flow conduction structure 104. To be transmitted directly.

23 is a 23rd embodiment according to the present invention, as shown in FIG. 23, in which two electrical energy input/output terminals 102 are installed at the top of the electrode plate 101, the electricity close to the upper left The distance between the energy input/output terminal 102 and the left side of the electrode plate 101 is relatively close, and the distance between the electric energy input/output terminal 102 close to the upper right and the right side of the electrode plate 101 is relatively close and the electrode plate ( In the lower end of 101), the two electrical energy input/output terminals 102 are installed, and the distance between the electrical energy input/output terminal 102 close to the lower left and the left side of the electrode plate 101 is relatively close, and on the lower right The distance between the electric energy input/output terminal 102 close to the right side of the electrode plate 101 is relatively close,

In addition, the insulating split flow conduction structure 104 is installed in the middle of the electrical energy input/output terminal 102 close to the upper left to the left of the electrode plate 101 in the downward direction along the left side of the electrode plate 101. The electrode plate 101 directly transmits current input/output between the electric energy input/output terminal 102 near the middle of the left and the upper left, and the electric energy input/output terminal 102 near the upper right of the electrode plate A place near the middle extending from the right side of the (101) downward to the right side of the electrode plate 101 is installed near the middle of the right side of the electrode plate 101 by installing the insulating split flow conduction structure 104 And the electric energy input/output terminal 102 close to the upper right and transmits the input/output current directly,

The insulating split flow conduction structure 104 is located near the middle where the electrical energy input/output terminal 102 near the bottom left extends to the left of the electrode plate 101 in the upward direction along the left side of the electrode plate 101. Installed to directly transfer the current input/output between the electrical energy input/output terminal 102 near the middle of the left and the lower left of the electrode plate 101, and the electrical energy input/output terminal 102 near the lower right of the A place near the middle extending to the right side of the electrode plate 101 in the upward direction along the right side of the electrode plate 101 is provided near the middle of the right side of the electrode plate 101 by installing the insulating split flow conducting structure 104 And the electric energy input/output terminal 102 close to the lower right side directly transmits the input/output current,

Between the electrical energy input/output terminal 102 near the upper right of the electrode plate 101 and the electrical energy input/output terminal 102 near the upper left, the insulation extends toward the middle of the electrode plate 101. The current flows in and out between the electrical energy input/output terminal 102 close to the middle and upper five sides of the electrode plate 101 and the electrical energy input/output terminal 102 near the upper left side by installing the split flow conduction structure 104. Send it directly,

And between the electrical energy input/output terminal 102 close to the lower right of the electrode plate 101 and the electrical energy input/output terminal 102 closer to the lower left of the electrode plate 101 toward the middle of the electrode plate 101, An electric current input/output between the electrical energy input/output terminal 102 close to the middle and lower right of the electrode plate 101 and the electrical energy input/output terminal 102 close to the lower left by installing an insulated split flow conducting structure 104. Directly.

24 is a twenty-fourth embodiment according to the present invention, as shown in FIG. 24, in which two electrical energy input/output terminals 102 are installed at the top of the electrode plate 101, the electricity close to the top left The distance between the energy input/output terminal 102 and the left side of the electrode plate 101 is relatively close, and the distance between the electric energy input/output terminal 102 close to the upper right and the right side of the electrode plate 101 is relatively close,

And where the electrical energy input/output terminal 102 close to the upper left extends along the left side of the electrode plate 101 in the downward direction to the bottom, the insulating split flow conducting structure 104 is installed to install the electrode plate 101. Directly transmitting and receiving current between the electrical energy input/output terminal 102 close to the lower left and upper left of the, and the electrical energy input/output terminal 102 close to the upper right along the right side of the electrode plate 101. In the direction extending to the bottom in the direction, the insulation split flow conducting structure 104 is installed to directly transmit the current input and output between the electrical energy input/output terminals 102 near the lower right and upper right of the electrode plate 101, ,

And between the electrical energy input and output terminal 102 close to the upper left of the electrode plate 101 and the mall electrical energy input and output terminal 102 close to the upper right to the near to the middle of the electrode plate 101 The insulation split flow conducting structure 104 is installed to input and output between the electrical energy input/output terminal 102 near the middle and upper left of the electrode plate 101 and the electrical energy input/output terminal 102 near the upper right. Direct current transfer.

25 is a 25th embodiment according to the present invention, as shown in FIG. 25, in which one or more electrical energy input/output terminals 102 can be installed on the top of the electrode plate 101, the above The electrode plate 101 is provided with an insulated split flow conduction structure 104 where one or more lower ends of the electrical energy input/output terminals 102 extend downward through the middle of the electrode plate 101. It is characterized by.

26 is a 26th embodiment according to the present invention, and FIG. 26 is a second embodiment of an equalizing electrode plate having an insulated divided flow conduction structure, which has the same structure shown in FIG.

27 is a 27th embodiment according to the present invention. As shown in FIG. 27, one or more electrical energy input/output terminals 102 are installed at the top of the electrode plate 101, and the electrode plate ( One or more of the electrical energy input/output terminals 102 are installed at a lower end of 101), and the electrical energy input/output terminals 102 installed at the upper ends of the electrode plates 101 and the lower ends of the electrode plates 101. The electrical energy input/output terminal 102 installed in the cross-section is installed in an alternating form, and the lower end of the electrical energy input/output terminal 102 installed on the upper end of the electrode plate 101 has a middle of the electrode plate 101. An insulated divided flow conduction structure 104 is installed in a place extending downwardly via the input/output between the electrical energy input/output terminal 102 installed at the top of the electrode plate 101 and the intermediate region of the electrode plate 101. Directly transmitting the current to be, and at the upper end of the electrical energy input/output terminal 102 installed at the lower end of the electrode plate 101 via the middle of the electrode plate 101, the insulation split flow conduction in a direction leading upward. The structure 104 is installed to directly transmit current input/output between the electrical energy input/output terminal 102 installed at the lower end of the electrode plate 101 and an intermediate region of the electrode plate 101.

28 is a 28th embodiment according to the present invention, and FIG. 28 is a second embodiment of an equalizing electrode plate having an insulated divided flow conduction structure, which has the same structure shown in FIG.

An embodiment of an equalizing electrode plate having an insulated divided flow conducting structure according to the present invention is shown in FIGS. 29 to 31, a grid sheet-shaped electrode plate, or a radial grid sheet-shaped electrode plate, or a laminate. An electrode plate, or composed of a wound electrode plate, is provided with an independent insulating split flow conduction structure 104 on one or more of the electrode plates 101, the independent isolated split flow conduction structure 104 is independently An electric energy input/output terminal 1023 for outputting electric energy is provided outside, and extends along a side surface of the electrode plate 101 to a bottom end of the side surface of the electrode plate 101 and/or the electrode plate 101. It is characterized in that it extends to the bottom end of the electrode plate 101 and/or to the bottom end of the electrode plate 101 and back to the entire bottom end of the electrode plate 101.

29 is a 29th embodiment according to the present invention, as shown in FIG. 29, in which an electric energy input/output terminal 102 is installed on the top of the electrode plate 101, the bottom end of the electrode plate 101 It is characterized in that the independently installed insulated split flow conduction structure 104 is connected to the electrical energy input/output terminal 1023 which outputs electrical energy to the outside, and extends toward the direction of the electrical energy input/output terminal 102 independently. Is done.

30 is a 30th embodiment according to the present invention, as shown in FIG. 30, in which an electric energy input/output terminal 102 is installed on the top of the electrode plate 101, the bottom end of the electrode plate 101 In the middle, the independently installed insulated divided flow conducting structure 104 extends from the lower middle of the electrode plate 101 toward the direction of the electrical energy input/output terminal 102, and the electrical energy input/output terminal independently outputs electrical energy to the outside. Characterized by following (1023).

31 is a 31st embodiment according to the present invention, as shown in FIG. 31, in which an electric energy input/output terminal 102 is installed on the top of the electrode plate 101, the electrode plate 101 and the At the bottom where the electrical energy input/output terminals 102 are diagonally fastened, an independently installed insulated split flow conduction structure 104 continues toward the direction of the electrical energy input/output terminals 102 and independently outputs electrical energy to the outside. It is characterized by being connected to the energy input/output terminal 1023.

The equalizing electrode plate having an insulated divided flow conduction structure according to the present invention described in FIGS. 1 to 31 is one or more electrical energy on one or all sides of one or more of the electrode plates having a radial grid-shaped electrical conductor. An input/output terminal 102 is additionally installed, and an isolated split flow consisting of one or more paths between the electrical energy input/output terminal 102 and the periphery of the electrode plate 101 and/or the middle and/or bottom ends. The conductive structure 104 is installed.

32 to 40 is a configuration in which an insulating split flow conducting structure 104 is installed between the electrical energy input/output terminal 102 and the electrode plate 101 around an electrode plate having a radial grid-shaped electrical conductor according to the present invention. As an example, the detailed description is as follows.

32 is a 32nd embodiment according to the present invention, as shown in FIG. 32, the configuration of the insulated divided flow conducting structure 104 is the same as the embodiment of FIG.

Figure 33 is a 33rd embodiment according to the present invention, as shown in Figure 33, the configuration of the insulating split flow conducting structure 104 is the same as the embodiment of Figure 3.

34 is a 34th embodiment according to the present invention, as shown in FIG. 34, the configuration of the insulated divided flow conducting structure 104 is the same as that of FIG.

35 is a 35th embodiment according to the present invention, as shown in FIG. 35, the configuration of the insulating split flow conduction structure 104 is the same as the embodiment of FIG.

36 is a 36th embodiment according to the present invention, as shown in FIG. 36, the configuration of the insulated divided flow conducting structure 104 is the same as the embodiment in FIG.

37 is a 37th embodiment according to the present invention, as shown in FIG. 37, the configuration of the insulating split flow conduction structure 104 is the same as the embodiment of FIG.

Figure 38 is a 38th embodiment according to the present invention, as shown in Figure 38, the configuration of the insulating split flow conduction structure 104 is the same as the embodiment of Figure 17.

39 is a 39th embodiment according to the present invention, as shown in FIG. 39, in which two electrical energy input/output terminals 102 are installed at the top of the electrode plate 101, the electricity close to the upper left The distance between the energy input/output terminal 102 and the left side of the electrode plate 101 is relatively close, and the distance between the electric energy input/output terminal 102 close to the upper right and the right side of the electrode plate 101 is relatively close and the electrode plate ( In the lower part of 101), the two electrical energy input/output terminals 102 are installed, and the distance between the electrical energy input/output terminal 102 close to the upper right and the right side of the electrode plate 101 is relatively close, and on the lower left The distance between the electric energy input/output terminal 102 near the left and the electrode plate 101 is relatively close,

In addition, the insulated split flow conduction structure 104 is installed in the vicinity of the electric energy input/output terminal 102 close to the upper right to the right of the electrode plate 101 in a downward direction along the right side to install the electrode. Directly transmits the current input and output between the electrical energy input/output terminal 102 near the middle of the right and the upper right of the plate 101,

And in the middle near the bottom of the electrical energy input and output terminal 102 near the bottom left to the left side of the electrode plate 101 in an upward direction along the left side, the insulating split flow conducting structure 104 is installed to install the electrode. It is characterized in that the input/output current is directly transmitted between the electric energy input/output terminal 102 close to the middle of the left and the lower left of the plate 101.

Figure 40 is a 40th embodiment according to the present invention, as shown in Figure 40, the configuration of the insulating split flow conducting structure 104 is the same as the embodiment of Figure 21.

Figures 41-42 are insulated split flow conduction structures 104 between the electrical energy input/output terminals 102 and the middle and/or bottom end of the electrode plate 101 of the electrode plate having a radial grid-shaped electrical conductor according to the present invention. ) Is an embodiment showing a configuration to be installed, and detailed descriptions thereof are as follows.

Figure 41 is a 41st embodiment according to the present invention, as shown in Figure 41, the configuration of the insulating split flow conducting structure 104 is the same as the embodiment of Figure 23.

Figure 42 is a 42nd embodiment according to the present invention, as shown in Figure 42, the configuration of the insulating split flow conducting structure 104 is the same as the embodiment of Figure 24.

In the equalization electrode plate having an insulated divided flow conducting structure according to the present invention, the electrical energy input/output terminal 102 of the laminate electrode plate and the surrounding and/or intermediate and/or intermediate laminate electrode plates 101 and/or It can be constructed by installing an insulated split flow conduction structure between the bottom ends.

43 to 62 show a configuration in which an insulating split flow conduction structure 104 is installed between the electrical energy input/output terminal 102 of the laminated electrode plate and the periphery or bottom of the electrode plate 101 according to the present invention. In the illustrated embodiment, detailed descriptions thereof are as follows.

43 is a 43rd embodiment according to the present invention, as shown in FIG. 43, the configuration of the insulating split flow conduction structure 104 is the same as the embodiment of FIG.

44 is a 44th embodiment according to the present invention, as shown in FIG. 44, the configuration of the insulated split flow conducting structure 104 is the same as the embodiment in FIG.

Figure 45 is a 45th embodiment according to the present invention, as shown in Figure 45, the configuration of the insulating split flow conducting structure 104 is the same as the embodiment of Figure 3.

Figure 46 is a 46th embodiment according to the present invention, as shown in Figure 46, the configuration of the insulating split flow conduction structure 104 is the same as the embodiment of Figure 4.

Figure 47 is a 47th embodiment according to the present invention, as shown in Figure 47, the configuration of the insulating split flow conduction structure 104 is the same as the embodiment of Figure 5.

Figure 48 is a 48th embodiment according to the present invention, as shown in Figure 48, the configuration of the insulating split flow conducting structure 104 is the same as the embodiment of Figure 6.

49 is a 49th embodiment according to the present invention, and as shown in FIG. 49, the configuration of the insulated split flow conducting structure 104 is the same as the embodiment of FIG.

50 is a 50th embodiment according to the present invention, as shown in FIG. 50, the configuration of the insulated split flow conducting structure 104 is the same as the embodiment of FIG.

Figure 51 is a 51st embodiment according to the present invention, as shown in Figure 51, the configuration of the insulating split flow conducting structure 104 is the same as the embodiment of Figure 10.

52 is a 52nd embodiment according to the present invention. As shown in FIG. 52, the configuration method of the insulated divided flow conducting structure 104 is the same as the embodiment of FIG.

53 is a 53rd embodiment according to the present invention, as shown in FIG. 53, the configuration of the insulating split flow conduction structure 104 is the same as the embodiment of FIG.

Figure 54 is a 54th embodiment according to the present invention, as shown in Figure 54, the configuration of the insulating split flow conducting structure 104 is the same as the embodiment of Figure 12.

55 is a 55th embodiment according to the present invention, as shown in FIG. 55, the configuration of the insulated split flow conducting structure 104 is the same as the embodiment of FIG.

Figure 56 is a 56th embodiment according to the present invention, as shown in Figure 56, the configuration of the insulating split flow conduction structure 104 is the same as the embodiment of Figure 14.

Figure 57 is a 57th embodiment according to the present invention, as shown in Figure 57, the configuration of the insulating split flow conduction structure 104 is the same as the embodiment of Figure 16.

58 is a 58th embodiment according to the present invention, and as shown in FIG. 58, the configuration of the insulated divided flow conducting structure 104 is the same as that of FIG.

59 is a 59th embodiment according to the present invention. As shown in FIG. 59, the configuration of the insulated split flow conducting structure 104 is the same as that of FIG.

60 is a 60th embodiment according to the present invention, as shown in FIG. 60, the configuration of the insulating split flow conduction structure 104 is the same as the embodiment of FIG.

FIG. 61 is a sixty-first embodiment according to the present invention. As shown in FIG. 61, the configuration method of the insulated divided flow conducting structure 104 is the same as the embodiment of FIG.

Figure 62 is a 62nd embodiment according to the present invention, as shown in Figure 62, the configuration of the insulating split flow conducting structure 104 is the same as the embodiment of Figure 21.

63 to 72 are insulated split flow conduction structures 104 between the electrical energy input/output terminals 102 of the laminated electrode plate and the middle and/or bottom of the electrode plate 101 according to the present invention. As an embodiment showing the configuration, detailed descriptions thereof are as follows.

Figure 63 is a 63rd embodiment according to the present invention, as shown in Figure 63, the configuration of the insulating split flow conducting structure 104 is the same as the embodiment of Figure 22.

Figure 64 is a 64th embodiment according to the present invention, as shown in Figure 64, the configuration of the insulating split flow conducting structure 104 is the same as the embodiment of Figure 23.

Figure 65 is a 65th embodiment according to the present invention, as shown in Figure 65, the configuration of the insulating split flow conducting structure 104 is the same as the embodiment of Figure 24.

FIG. 66 is a 66th embodiment according to the present invention. As shown in FIG. 66, the configuration method of the insulated divided flow conducting structure 104 is the same as the embodiment of FIG.

Figure 67 is a 67th embodiment according to the present invention, as shown in Figure 67, the configuration of the insulating split flow conducting structure 104 is the same as the embodiment of Figure 26.

Figure 68 is a 68th embodiment according to the present invention, as shown in Figure 68, the configuration of the insulating split flow conducting structure 104 is the same as the embodiment of Figure 27.

Figure 69 is the 69th embodiment according to the present invention, as shown in Figure 69, the configuration of the insulating split flow conduction structure 104 is the same as the embodiment of Figure 28.

FIG. 70 is a 71st embodiment according to the present invention. As shown in FIG. 71, a configuration method of the insulated divided flow conducting structure 104 is the same as the embodiment of FIG.

71 is a 71st embodiment according to the present invention, as shown in FIG. 71, the configuration of the insulating split flow conduction structure 104 is the same as the embodiment of FIG.

72 is a 72nd embodiment according to the present invention, and as shown in FIG. 72, the configuration of the insulated divided flow conducting structure 104 is the same as the embodiment of FIG.

The equalizing electrode plate having an insulated divided flow conducting structure according to the present invention is applied to an electrode plate made of an electrically conductive material in the form of a grid sheet, or an electrode plate in the form of a radial grid sheet, or an electrode plate in a laminate, or a wound electrode In one or several sides of the electrode plate is provided with one electrical energy input/output terminal 102 having a thickness equal to or close to the thickness of the electrode plate, the method of exposing the isolated split flow conducting structure 104 is described above. In one embodiment, a single electrical energy input/output terminal is installed on one or several sides of the electrode plate 101.

73 is a 73rd embodiment according to the present invention, as shown in FIG. 73, the electrode plate 101 has a grid sheet-like structure, and the configuration of the insulating split flow conducting structure 104 is shown in FIG. It is characterized in that on one side of the electrode plate is an electrical energy input/output terminal having a thickness equal to or close to two of the electrode plates.

74 is a 74th embodiment according to the present invention, as shown in FIG. 74, the electrode plate 101 is a structure of a laminate, and the structure of the insulating divided flow conducting structure 104 is shown in FIG. It is characterized in that the electrical energy input and output terminals having a thickness equal to or close to two of the electrode plates on one side of the electrode plate.

75 is a 75th embodiment according to the present invention, as shown in FIG. 75, the electrode plate 101 is a grid sheet-shaped structure, the configuration of the insulating split flow conducting structure 104 is shown in FIG. It is characterized in that on one side of the electrode plate is an electrical energy input/output terminal having a thickness equal to or close to two of the electrode plates.

Figure 76 is a 76th embodiment according to the present invention, as shown in Figure 76, the electrode plate 101 is a structure of a laminate (Laminate), the structure of the insulating split flow conducting structure 104 is shown in Figure 46 It is characterized in that the electrical energy input and output terminals having a thickness equal to or close to two of the electrode plates on one side of the electrode plate.

77 is a 77th embodiment according to the present invention, as shown in FIG. 77, the electrode plate 101 is a grid sheet-like structure, the upper end of the electrode plate 101 is an electrical energy input and output terminal 102 Is installed, the electrical energy input/output terminal 102 is installed near the middle of the electrode plate 101 to the bottom in the downward direction along the left side to install the insulating split flow conducting structure 104 to install the electrode plate 101 ) Directly transmits an input/output current between the near middle of the bottom and the electrical energy input/output terminal 102, and the electrical energy input/output terminal 102 extends downward along the right side of the electrode plate 101 to the bottom. The insulated split flow conduction structure 104 is installed in the middle, to directly transmit the current input and output between the electrical energy input/output terminal 102 and the place near the lower right middle of the electrode plate 101, and the electrode plate. The bottom end of the insulated split flow conducting structure 104 extending downward from the left to the left of (101) is adjacent or connected to each other and is characterized in that it is connected to each other between the bottom end and the electrode plate (101).

78 is a 78th embodiment according to the present invention, as shown in FIG. 78, the electrode plate 101 is a structure of a laminate, and the structure of the insulating split flow conducting structure 104 is shown in FIG. Same as

79 is a 79th embodiment according to the present invention. As shown in FIG. 79, the electrode plate 101 has a grid sheet-like structure, and an electrical energy input/output terminal 102 is provided at the top of the electrode plate 101. Is installed, the electrical energy input/output terminal 102 is installed near the middle of the electrode plate 101 to the bottom in the downward direction along the left side to install the insulating split flow conducting structure 104 to install the electrode plate 101 ) Directly transmits an input/output current between the near middle of the bottom and the electrical energy input/output terminal 102, and the electrical energy input/output terminal 102 extends downward along the right side of the electrode plate 101 to the bottom. The insulated split flow conduction structure 104 is installed in the middle, to directly transmit the current input and output between the electrical energy input/output terminal 102 and the place near the lower right middle of the electrode plate 101, and the electrode plate. The bottom ends of the insulated divided flow conducting structures 104 extending from the left to the left of the 101 are adjacent or connected to each other, and between the bottom of the insulated divided flow conducting structures 104 and the electrode plate 101 Connected to the bottom of the electrode plate 101 in the middle of the electrical energy input and output terminal 102 to install the insulated split flow conducting structure 104, the lower end of the electrode plate 101 and the electrical energy input and output The current input/output between the terminals 102 is directly transmitted.

80 is an 80th embodiment according to the present invention. As shown in FIG. 80, the electrode plate 101 is a structure of a laminate, and the structure of the insulating split flow conducting structure 104 is shown in FIG. Same as

81 is the 81st embodiment according to the present invention, as shown in FIG. 81, the electrode plate 101 is a grid sheet-shaped structure, the top of the electrode plate 101 is the same as the thickness of the electrode plate or Electrical energy input and output terminals 102 with adjacent thickness are installed,

The insulation split flow conduction structure 104 is installed between an area close to the middle of the electrical energy input/output terminal 102 on the upper end of the electrode plate 101 to the electrode plate 101 in a downward direction. The electrical energy input/output terminal 102 configured to directly transmit current from the electrode plate 101 with a relatively low impedance, and the electrical energy input/output connected to the other end of the insulating divided flow conducting structure 104 connected thereto. The current input/output between the terminals 102 is directly transmitted.

82 is a 82nd embodiment according to the present invention, as shown in FIG. 82, the electrode plate 101 is a structure of a laminate (Laminate), the structure of the insulating split flow conducting structure 104 is shown in Figure 81 Same as

83 is a 83rd embodiment according to the present invention, as shown in FIG. 83, the electrode plate 101 is a grid sheet-shaped structure, the upper end of the electrode plate 101 is the same as the thickness of the electrode plate or Electrical energy input and output terminals 102 with adjacent thickness are installed,

In the middle of the electrical energy input/output terminal 102 on the upper end of the electrode plate 101, two or more paths (indicated in both directions in the drawing) are installed, leading to the electrode plate 101 in a downward direction. Between the regions close to, the insulating divided flow conducting structure 104 is installed to connect the electric energy input/output terminal 102 and the electrode plate region of the electrode plate 101 with a relatively low impedance to be directly connected to the electrode plate region. The current input/output between the electrical energy input/output terminals 102 connected to the other side of the isolated split flow conducting structure 104 is directly transmitted.

84 is a 84th embodiment according to the present invention, as shown in FIG. 84, the electrode plate 101 is a structure of a laminate, and the structure of the insulating divided flow conducting structure 104 is shown in FIG. Same as

85 is the 85th embodiment according to the present invention. As shown in FIG. 85, the electrode plate 101 has a grid sheet-like structure, and the thickness of the electrode plate in both upper and lower sides of the electrode plate 101 is shown. Electrical energy input and output terminal 102 having a thickness equal to or close to is installed,

Two or more paths (shown in both directions in the drawing) are installed on both sides of the electric energy input/output terminal 102 on the upper end of the electrode plate 101, and the electrode plate 101 is directed downward. The insulated split flow conduction structure 104 is installed between the regions close to the middle leading up to and extends downward from the surface of the electrical energy input/output terminal 102 at the bottom of the electrode plate 101 toward the top. One or more paths (shown in one direction in the drawings) are provided between the insulated divided flow conducting structures 104, and the insulation is in between a region close to the middle leading to the electrode plate 101 in the upward direction. A split flow conduction structure 104 is installed, and the above-described insulated split flow conduction structure 104 directly transmits electric current to and from the electrical energy input/output terminals 102 on both sides of the electrode plate 101 with relatively low impedance. The current input and output is directly transmitted between the area near the middle of the electrode plate 101 set to be and the electrical energy input/output terminal 102 connected to the other side of the insulated split flow conduction structure 104 both above and below it. .

86 is a 86th embodiment according to the present invention, as shown in FIG. 86, the electrode plate 101 is a structure of a laminate (Laminate), the configuration of the insulating split flow conducting structure 104 is shown in Figure 85 Same as

An electrode plate having an insulated split flow electrical overall diagram according to the present invention can be implemented on a rolled electrode plate, and an embodiment thereof is as follows.

87 is a 87th embodiment according to the present invention. As shown in FIG. 87, the electrode plate 101 has a grid sheet-like structure, and at least one electrical energy input/output terminal is disposed at the top of the electrode plate 101. (102) is installed and the electrical energy input/output terminal (102) along the left side of the electrode plate (101) extends to the bottom in the middle close to the insulated split flow conduction structure (104) to install the electrode plate. (101) Directly transmits the input/output current between the lower middle of the middle and the electrical energy input/output terminal 102, and the rightmost electrical energy input/output terminal 102 on the right side of the electrode plate is on the right side of the electrode plate 101. (Including the right side in the case of a single electric energy input/output terminal) and extends to the bottom in the downward direction, and installs the insulated split flow conduction structure 104 along the bottom to the bottom right and the electrical energy of the electrode plate 101. Directly transmitting and receiving current between the input and output terminals 102, the bottom end of the insulated split flow conduction structure 104 extending from the left to the bottom of the electrode plate 101 is connected to each other, and the insulated split flow conduction structure Between the bottom end of the 104 and the electrode plate 101, when two or more of the electrical energy input/output terminal 102 is installed, the electrical energy input/output terminal 102 installed in the middle is the electrode The electrical energy input/output terminal 102 installed at the lower end of the electrode plate 101 and the middle of the electrode plate 101 by installing the insulated divided flow conducting structure 104 in a place extending toward the bottom end of the plate 101. It is characterized in that a structure of a crimped type is constructed by directly transmitting and receiving current input and output between the electrode plate 101 and an electrode plate having a different polarity between the electrode plates. According to a 88th embodiment according to the present invention, as shown in FIG. 88, the electrode plate 101 is a structure of a laminate, and the insulating divided flow conducting structure 104 87) is configured as shown in FIG.

89 is a 89th embodiment according to the present invention. As shown in FIG. 89, at least one electrical energy input/output terminal 102 is installed on the top of the electrode plate 101, and the electrode plate 101 The insulated divided flow conducting structure 104 installed close to the lower end of the electrode plate 101 leading from the middle of the electrical energy input/output terminal 102 at the top to the electrode plate 101 in a downward direction has the electrode with a relatively low impedance. The current input/output between the electrical energy input/output terminals 102 connected to the other end of the insulated divided flow conducting structure 104 connected to an area near the bottom of the plate 101 is directly transferred, and different from the electrode plate 101. It is characterized in that a blocking body is interposed between electrode plates having different polarities to form a wound type structure.

90 is a 90th embodiment according to the present invention, as shown in FIG. 90, the electrode plate 101 is a structure of a laminate, and the structure of the insulating split flow conducting structure 104 is shown in FIG. Same as

91 is a 91st embodiment according to the present invention, as shown in FIG. 91, the electrode plate 101 is a grid sheet-shaped structure, the top of the electrode plate 101 is the same as the thickness of the electrode plate or Electrical energy input and output terminals 102 with adjacent thickness are installed,

In the middle of the electrical energy input/output terminal 102 on the upper end of the electrode plate 101, two or more paths (shown in both directions in the drawing) are installed, leading to the electrode plate 101 in a downward direction. Between the regions close to the bottom in excess of the insulating split flow conduction structure 104 is installed, the electrode plate 101 is set to transmit the electric energy input/output terminal 102 and the current directly from the electrode plate 101 with a relatively low impedance. Directly transmitting and receiving current input and output between the electrical energy input/output terminals 102 connected to the other end of the insulated split flow conducting structure 104 connected to a region near the bottom exceeding the middle, and the individual paths described above are directed downward. Between the regions close to the middle leading to the electrode plate 101, the insulating split flow conduction structure 104 is installed to directly connect the electric energy input/output terminal 102 and the current in the electrode plate 101 with a relatively low impedance. Directly transmits the current input and output between the electrical energy input/output terminals 102 connected to the other end of the insulated divided flow conducting structure 104 connected to an area near the middle exceeding the middle of the electrode plate set to be transmitted, and the electrode It is characterized in that the structure between the plate 101 and the electrode plate having a different polarity is formed by sandwiching a blocking body.

92 is a 92th embodiment according to the present invention, as shown in FIG. 92, the electrode plate 101 is a structure of a laminate, and the structure of the insulating divided flow conducting structure 104 is shown in FIG. Same as

93 is a 93th embodiment according to the present invention. As shown in FIG. 93, the electrode plate 101 has a grid sheet-like structure, and both of the electrode plates are provided on both the upper and lower sides of the electrode plate 101. Electrical energy input and output terminals 102 having the same or close thickness are installed,

Two or more paths (shown in three directions in the drawings) are installed on both sides of the electric energy input/output terminal 102 on the upper end of the electrode plate 101, and the electrode plate 101 is directed downward. ), an insulated split flow conduction structure 104 is installed between the regions close to the middle leading up to the upper end from the surface of the electrical energy input/output terminal 102 at the lower end of the electrode plate 101 toward the upper end. The insulation division between the regions in which one or more paths (indicated in both directions in the drawing) extends in the upward direction to close to the middle of the electrode plate 101 between the insulated division flow conducting structures 104. The flow conduction structure 104 is installed, and the above-described insulated division flow conduction structure 104 is set to directly transmit current with the electrical energy input/output terminals 102 on both sides of the electrode plate 101 with relatively low impedance. Directly transmitting and receiving current input and output between the electrical energy input/output terminals 102 connected to the other ends of the insulated split flow conducting structure 104 on both sides of the upper and lower sides connected to the region near the middle of the electrode plate 101, It is characterized in that the structure between the plate 101 and the electrode plate having a different polarity is formed by sandwiching a blocking body.

Figure 94 is a 94th embodiment according to the present invention, as shown in Figure 94, the electrode plate 101 is a structure of a laminate (Laminate), the structure of the insulating split flow conducting structure 104 is shown in Figure 93 Same as

In each embodiment of the leveling electrode plate having an insulated split flow conduction structure according to the present invention, the cross-sectional shape of the insulated split flow conduction structure 104 is as follows.

95 is an A-A cross-sectional view of an insulating split flow conduction structure 104 according to the present invention,

As shown in FIG. 95, the cross-sectional shape is a cross-sectional structure constituting the insulating divided flow conducting structure 104 as the insulator 1046 is coated on the outer surface of the electrical conductor 1045,

96 is a B-B cross-sectional view of an electrically conductive grid of an electrode plate according to the present invention,

As shown in FIG. 96, the cross-sectional shape is a cross-sectional structure constituting an electrically conductive grid of the electrode plate with a bar-shaped electrical conductor 1045,

97 is a C-C cross-sectional view of an insulating split flow conducting structure 104 according to the present invention,

As shown in Fig. 97, in the electrical conductor 1045 of the insulated divided flow conducting structure 104, one side thereof is a cross-sectional structure in which the insulator 1046 is not installed,

98 is a D-D cross-sectional view of an insulating split flow conducting structure 104 according to the present invention,

As shown in Fig. 98, in the electrical conductor 1045 of the insulated split flow conducting structure 104, the both ends of the electrical conductor are cross-sectional structures in which the insulator 1046 is not installed,

99 is an E-E cross-sectional view of a parallel insulated split flow conducting structure 104 according to the present invention,

As shown in FIG. 99, the insulated split flow conduction structure 104 is a cross-sectional structure in which the insulated split flow conduction structure 104 configured in both directions installed in parallel is installed,

100 is an insulator 1046 on at least one end of the electrical conductor 1045 of the insulation split flow conduction structure 104 in one direction in the insulation split flow conduction structures 1041 and 1042 parallel in both directions according to the present invention. With FF section not installed,

As shown in FIG. 100, in the two-way parallel divided split flow conducting structures 1041 and 1042, the insulated split flow conducting structures 104 in one direction are additionally installed with insulators and insulated split flows in the other direction. At least one of the electrical conductors 1045 of the conductive structure 104 is a cross-sectional structure in which the insulator 1046 is not installed,

101 is a G-G cross-sectional view in which the parallel insulated divided flow conducting structures 1041 and 1042 according to the present invention are stacked vertically.

As shown in FIG. 101, the insulating split flow conduction structure 104 is a cross-sectional structure in which an insulated split flow conduction structure 104 constructed in both directions is installed.

102 is a cross-sectional view in which an insulator is not installed on at least one end of the insulated split flow conduction structure 1041 and/or the insulated split flow conduction structure 1042 shown in FIG.

As shown in FIG. 102, a cross-sectional structure of an insulated split flow conduction structure 104 constructed in two directions overlapping and installed in the insulated split flow conduction structure 104, wherein at least one or both of the electrical conductors 1045 are provided with insulators It is not a cross section

103 is a cross-sectional view of an H-H in which an electrode plate is installed at one end of an insulating divided flow conducting structure 104 according to the present invention,

As shown in FIG. 103, a single side of the insulating divided flow conducting structure 104 composed of one layer is a cross-sectional structure attached to the electrode plate 103,

FIG. 104 is a sectional view in which an insulator is not installed on at least one end of the insulated split flow conduction structure 104 shown in FIG. 103,

As shown in FIG. 104, at least one side of the insulating divided flow conducting structure 104 composed of one layer is a cross-sectional structure attached to the electrode plate 101, and at least one side of the electrical conductor 1045 is an insulator Is a cross-sectional structure that is not installed

101: electrode plate
102: electrical energy input and output terminals
103: electrochemically active substance
104, 1041, 1042: Insulated split flow conduction structure
1023: Electrical energy input/output terminal that independently outputs electrical energy to the outside
1045: electrical conductor
1046: insulator

Claims (16)

As an electrode plate 101 having a uniform insulating split flow conduction structure,
It is provided with an electrical energy input and output terminal 102, an electrochemically active material 103, an insulating divided flow conducting structure 104,
The electrode plate 101 is a positive electrode or a negative electrode plate composed of at least one of a grid sheet electrode plate, a sheet electrode plate having a radial grid, a laminate electrode plate, and a wound electrode plate,
The input/output terminal 102 extends from the electrode plate or is additionally installed and is connected to and installed on at least one side of the electrode plate 101 as an interface for inputting and outputting electrical energy between the electrode plate and the outside. The electrically conductive material of the input/output terminal is made of the same or different material from the electrode plate,
The electrochemically active material 103 includes any one of the gaseous, liquid, gel, and solid phase electrochemical materials,
The insulated divided flow conducting structure 104 is composed of an electrical conductor 1045 of the same or different material as the electrode plate, and a part of the electrical conductor 1045 is covered and surrounded by an insulator 1046. One or more of the insulating divided flow conducting structures 104 are installed along side sides of the electrode plate and/or in an intermediate region of the electrode plate,
One end of the insulated split flow conducting structure 104, the input/output terminal 102 or at least one of welding, heat sealing, spot welding, mechanical riveting, locking, clamping and blocking as a method having an electrically conductive function, or It is connected to the electrical conductor of the electrode plate 101 between the two input and output terminals 102,
The other end of the insulated split flow conducting structure 104 is connected to the electrode plate in at least one of welding, heat sealing, spot welding, mechanical riveting, locking, clamping, and blocking as a method having an electrically conductive function,
The other end of the insulated split flow conducting structure 104, when the electrical energy output and / or input, in the electrode plate region having a longer current path and / or greater resistance of the current than the electrode plate region adjacent to the input/output terminal 102. Connected, transmitting electrical energy between them,
The electrode plate is a positive electrode and/or a negative electrode plate, a primary cell composed of at least one of a grid sheet type electrode plate, a sheet type electrode plate having a radial grid, a laminate electrode plate and a wound electrode plate, and a secondary battery that can be charged and discharged. , An electrode plate capable of constituting at least one of a capacitor, a supercapacitor or an electrode plate of a charge/discharge device or a fuel cell that converts electrical energy into chemical energy and/or converts chemical energy into electrical energy. According to claim 1,
The electrical conductor 1045 of the insulated divided flow conducting structure 104,
(1) It is made of the same material as the electrode plate, or
(2) It is made of a material different from the electrode plate material and having a resistance coefficient lower than that of the electrode plate, or
(3) The electrode plate is formed by any one of the methods that are formed by coating a material having a lower coefficient of resistance than an electrical conductor of the electrode plate material. According to claim 1,
The insulating split flow conducting structure 104 and the configuration method of the electrode plate 101,
The insulating divided flow conducting structure 104 and the electrode plate 101 are integrally assembled,
Surrounding the periphery of the electrical conductor 1045 of the insulated split flow conducting structure 104 with the insulator 1046, or covered with the insulator 1046,
The insulating divided flow conducting structure 104 forms an area of the electrode plate according to the shape of the flat or curved surface of the electrode plate 101, the electrode plate. According to claim 1,
The insulating split flow conducting structure 104 and the configuration method of the electrode plate 101,
The insulated split flow conductive structure 104 constitutes the electrical conductor 1045 as an independent conductive line or conductive sheet, and is parallel to the electrode plate 101 in planar manner, and surrounds the electrical conductor 1045 with the insulator. Surrounded by (1046) or covered with the insulator (1046),
The insulating divided flow conducting structure 104 forms an area of the electrode plate according to the shape of the flat or curved surface of the electrode plate 101, the electrode plate. According to claim 1,
The insulating split flow conducting structure 104 and the configuration method of the electrode plate 101,
Insulating split flow conduction structure 104 is an independent conducting line or a conductive sheet, the insulated split flow conduction structure 104 constitutes the electrical conductor 1045, and the insulated split flow conduction structure 104 includes the electrode plate ( 101) is installed on one side or both sides, or the electrode plate 101 is installed so as to overlap, surrounding the electrical conductor 1045 with the insulator 1046 or surrounding it, or covered with the insulator 1046 and,
The insulating divided flow conducting structure 104 forms an area of the electrode plate according to the shape of the flat or curved surface of the electrode plate 101, the electrode plate. As an electrode plate 101 having a uniform insulating split flow conduction structure,
It is provided with an electrical energy input and output terminal 102, an electrochemically active material 103, an insulating divided flow conducting structure 104,
The electrode plate 101 is a positive electrode or a negative electrode plate composed of at least one of a grid sheet electrode plate, a sheet electrode plate having a radial grid, a laminate electrode plate, and a wound electrode plate,
The input/output terminal 102 extends from the electrode plate or is additionally installed and is connected to and installed on at least one side of the electrode plate 101 as an interface for inputting and outputting electrical energy between the electrode plate and the outside. The electrically conductive material of the input/output terminal is made of the same or different material from the electrode plate,
The electrochemically active material 103 includes any one of the gaseous, liquid, gel, and solid phase electrochemical materials,
The insulating divided flow conducting structure 104 is composed of an electrical conductor 1045 of the same material or different material from the electrode plate,
The insulating split flow conducting structure 104 and the configuration method of the electrode plate 101,
The insulating divided flow conducting structure 104, which is a member different from the member on which the input/output terminal 102 is formed, is installed at the edge of the electrode plate,
The insulated split flow conducting structure 104 has an electrical conductor 1045,
Another input/output terminal 1023 is formed at one end of the electrical conductor 1045,
The outside of the electrical conductor 1045 is covered with an insulator 1046,
The other end of the electrical conductor 1045 is a method having an electrical conductivity function, and is connected to the electrode plate by at least one of welding, heat sealing, spot welding, mechanical riveting, locking, clamping and blocking,
The other end of the insulated split flow conducting structure 104, when the electrical energy output and / or input, in the electrode plate region having a longer current path and / or greater resistance of the current than the electrode plate region adjacent to the input/output terminal 102 Connected, transmitting electrical energy between them,
The electrode plate is a positive electrode and/or a negative electrode plate, a primary battery composed of at least one of a grid sheet electrode plate, a sheet electrode plate having a radial grid, a laminate electrode plate and a wound electrode plate, and a secondary battery that can be charged and discharged. , An electrode plate constituting at least one of a capacitor, a supercapacitor or an electrode plate of a charge/discharge device or a fuel cell that converts electrical energy into chemical energy and/or converts chemical energy into electrical energy. According to claim 1,
One or more of the input/output terminals 102 are provided on at least one side of the electrode plate 101, and the one extending on one side or both sides of the electrode plate 101 from the input/output terminal 102 The insulated divided flow conducting structure 104 is installed in parallel, and the insulated divided flow conducting structure 104 further extends to the middle of the side edge of the electrode plate 101, and/or the side edge of the electrode plate 101. An electrode plate extending to a hem and/or extending to a lateral side hem of the electrode plate 101 and also extending to a lower middle of the electrode plate 101. According to claim 1,
Electricity of the electrode plate 101 between the input/output terminal 102 or the electrode plate 101, or between the two input/output terminals 102, in an electrode plate area excluding side edges of the electrode plate 101. Extending downward from the conductor to install the insulated divided flow conducting structure 104,
The insulating split flow conduction structure 104,
It extends to the middle region of the electrode plate, or extends downward through the middle region of the electrode plate 101 to the bottom of the electrode plate 101, or downwards through the middle region of the electrode plate 101 Extending to the bottom of the electrode plate 101 and further along the bottom, and/or
From the input/output terminal 102, one side or both sides of the electrode plate 101 extend downward, and extend to an intermediate portion of the side of the electrode plate 101, and/or the electrode plate 101 An electrode plate that extends to the side edge and/or extends to the side edge of the electrode plate 101 and then extends along the bottom of the electrode plate 101. The method of claim 6,
The insulated divided flow conducting structure 104 extends from the other input/output terminal 1023 to the bottom of one side of the electrode plate 101 along one side of the electrode plate 101, or the other input/output terminal. It extends from (1023) to one side of the electrode plate 101 and the lower middle of the electrode plate 101 along the lower end of the electrode plate 101, or from the other input/output terminal 1023 to the electrode plate. An electrode plate extending along one side of 101 and the lower end of the electrode plate 101 to the bottom of the other side of the electrode plate 101. The method according to claim 1 or 6,
Two of the input/output terminals 102 are provided, one on each of the upper left and right sides of the electrode plate 101,
Two of the input/output terminals 102 are installed on the lower left and right sides of the electrode plate 101, respectively.
The insulated divided flow conducting structure 104 is directed downward along the right side of the electrode plate 101 from the input/output terminal 102 installed on the upper right and extends to the middle portion of the right side of the electrode plate 101. Is, the input and output current is directly transferred between the middle part of the right side of the electrode plate 101 and the input/output terminal 102 installed on the upper right,
The insulated divided flow conducting structure 104 is directed upward from the input/output terminal 102 installed on the lower left along the left side of the electrode plate 101, and extended to the middle portion of the left side of the electrode plate 101. The electrode plate directly transmits input/output current between the middle portion of the left side of the electrode plate 101 and the input/output terminal 102 provided on the lower left side. The method according to claim 1 or 6,
An electrode plate having at least one side of the electrode plate having the input/output terminals having the same width as the electrode plate. The method according to claim 1 or 6,
At least one of the input/output terminals 102 is installed on the upper end of the electrode plate 101, and the insulating divided flow conduction structure 104 is downward along the left side of the electrode plate 101 from the input/output terminals 102. Toward the middle part of the lower end, and directly transmits input/output current between the middle part of the lower end of the electrode plate 101 and the input/output terminal 102,
An electrode from the input/output terminal 102 on which the insulating divided flow conducting structure 104 is provided on the rightmost side of the electrode plate, or from the input/output terminal 102 on the right side when the input/output terminal 102 is single. Along the right side of the plate 101, extends downward to the bottom, and is also installed along the bottom, to directly transmit the input/output current between the lower right side of the electrode plate 101 and the input/output terminal 102,
The insulating divided flow conducting structure 104 extending to the lower left of the electrode plate 101 and the insulating divided flow conducting structure 104 extending to the lower right of the electrode plate 101 are the electrode plate 101 ) Is electrically connected at the bottom,
When three or more of the input/output terminals 102 are installed, the insulating split flow conduction structure 104 is installed extending from the input/output terminals 102 in the middle toward the lower end of the electrode plate 101, so that the electrode An electrode plate that directly transfers input/output electrical energy between the input/output terminals 102 at the lower and middle portions of the plate 101. The method according to claim 1 or 6,
At least one of the input/output terminals 102 is installed on the upper end of the electrode plate 101, and the insulating divided flow conduction structure 104 is downward from the input/output terminals 102 on the upper end of the electrode plate 101. Toward the lower end of the electrode plate 101, and the other end of the insulated divided flow conducting structure 104 connected to the region and the bottom side of the electrode plate 101. An electrode plate for electrically connecting the input/output terminal 102 to be connected. The method according to claim 1 or 6,
The input/output terminal 102 having the same width as the electrode plate is installed on the top of the electrode plate 101,
Some of the insulating split flow conduction structures 104,
The electrode plate 101 extends from the middle of the input/output terminal 102 downward to the lower region from the middle of the electrode plate 101 in the extending direction of the insulating divided flow conducting structure 104. ) Electrically connected to the input/output terminal 102 connecting the region beyond the middle of the side and the other end of the insulated split flow conduction structure 104 connected to the region,
In addition,
Other said insulated divided flow conducting structure 104,
It extends from the input/output terminal 102 downward to the middle of the electrode plate 101 in the extending direction of the insulated split flow conducting structure 104, and is installed in the middle of the electrode plate 101. And an electrode plate electrically connecting the input/output terminal 102 connecting another end of the insulated divided flow conducting structure 104 connected to the zone. The method according to any one of claims 3 to 6,
The insulator 1046 comprises an epoxy resin, insulating rubber, insulating paint, varnish or PVF, electrode plate. A charging and discharging device in which a plurality of electrode pairs comprising the electrode plate according to any one of claims 1 to 9 are formed by positive and negative electrode plates, and/or connected in series.

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