KR20180101285A - electric double layer capacitor with separating objects included electrodes - Google Patents

Abstract

The present invention relates to an electric double layer capacitor basic cell with an electrode including a separator with excellent electric energy storage and output performance. According to the present invention, the electric double layer capacitor basic cell with an electrode including a separator comprises: a current collecting plate; and the separator protruding from the current collecting plate in a predetermined continuous pattern to have a convex shape having a pattern repeated in longitudinal and lateral directions of the current collecting plate, or have a pattern continuously protruding in the longitudinal direction of the current collecting plate and repeated in the lateral direction of the current collecting plate.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an electric double layer capacitor

More particularly, the present invention relates to an electric energy storage device, and more particularly, to an electric double layer capacitor using an electrode having a separator to physically separate and electrically contact an anode electrode and a cathode electrode in an electric double layer capacitor without a separator And the anode electrode and the cathode electrode are arranged so as to be close to each other so as to be opposed to each other so as to ionically connect the positive ions of the electrolyte with the anions without interfering with the movement of the anion to improve the conductivity and improve the energy storage and output characteristics. To an electric double layer capacitor.

2. Description of the Related Art Generally, an electric double layer capacitor is formed on a conductor substrate serving as a current collector plate in a capacitor container, in order to obtain a large electric energy storage capacity, a porous separator having an insulator for electrically isolating the two electrodes from each other and electrically insulating the two electrodes, and a porous separator having an inner fine porous passageway. ) Is disposed between the two electrode layers, and the electrolyte is filled in the capacitor container, so that the dissociated positive and negative ions move through the porous channel of the separator to connect the two electrodes and are sealed with a capacitor container cap And is operated as an electric double layer capacitor basic cell.

BRIEF DESCRIPTION OF DRAWINGS FIG. 1 is a schematic view showing a conventional electric double layer capacitor basic cell. FIG.

1, a conventional electric double layer capacitor basic cell 100 includes a positive electrode collector plate (positive electrode layer) 122 having a positive electrode layer 122 formed on a surface of a capacitor container 110, a negative current collector plate 128 having a negative electrode layer 124 formed on one surface thereof with activated carbon or the like is formed on the positive electrode layer 122 and the negative electrode layer 122, A porous separator 140 is disposed between the anode electrode layer 122 and the cathode electrode layer 124 so that the anode electrode layer 122 and the cathode electrode layer 124 are separated from each other And the electrolyte 160 is filled in the capacitor vessel 110, so that the dissociated positive and negative ions move through the porous passage of the separator 140 and are connected to each other. When the electrolyte 160 is filled in the capacitor vessel 110, the solvent molecules of the electrolyte 160 are adsorbed on the surface of the active electrode surface of the anode electrode layer 122 and the cathode electrode layer 124 and the solvent molecules of the adsorbed electrolyte 160 And the positive charge of the anode electrode layer 122 and the electrolyte 160 anions are formed on the anode electrode layer 122 and the negative charges (electrons) of the cathode electrode layer 124 and the cathodes of the electrolyte 160 are aligned and accumulated on the cathode electrode layer 124 A Helmholtz layer having a solvent molecule thickness of from 0.1 to 0.8 nm is formed on the interface between the anode electrode layer 122 and the cathode electrode layer 124 to form a double layer and an external load A positive electrical lead 172 is connected to the positive electrode collector plate 126 and a negative electrode collector plate 128 through the capacitor container lid 112 for connection to a charger (not shown) (negative electrical lead) 174 connected thereto. When the negative electrode electrical lead 172 and the negative electrode electrical lead 174 of the conventional electric double layer capacitor basic cell 100 are connected to both ends of the negative electrode electrical lead 174 and negative electric charge is applied to the negative electrode electrode layer 124, The electrons distributed randomly in the electrolyte 160 in contact with the Helmholtz layer formed on the interface between the electrolyte membrane 160 and the separator 140 move in the porous channel of the separator 140, And a positive charge proportional to electrons accumulated in the cathode electrode layer 124 is accumulated in the anode electrode layer 122 so that the anion moves to the Helmholtz layer formed on the interface between the anode electrode layer 122 and the electrolyte 160 The electric energy is stored and charged to the load. When the electric energy is stored and connected to the load, the Helmholtz layer (122) of each of the anode electrode layer (122) and the cathode electrode layer (124) A negative charge (electrons) accumulated in the cathode electrode layer 124 works through the load due to the potential difference of the electric energy stored in the anode electrode layer 122 and the positive electrode of the anode electrode layer 122, ) Cation and anions physically aligned and restrained in the Helmholtz double layer at the surface boundary are separated from the Helmholtz double layer and are discharged randomly through the process of random distribution.

However, the conventional electric double layer capacitor basic cell 100 is disposed between the anode electrode layer 122 and the cathode electrode layer 124 to prevent direct contact between the two electrodes and the separator 140 through which the ions pass through the porous pores, Possible to move cation and anion with hundreds of thousands times thicker layer than the Helmholtz layer of solvent molecule thickness (Angstrom, 0.3 ~ 0.8nm), which directly accumulates charge in the thickness of 30 ~ 50% ~ 20 ~ 50㎛ And at the same time causes a decrease in the conductivity of the electric double layer capacitor base cell 100 acting as a resistor. Further, when the thickness of the separation membrane 140 is increased to improve the porosity that may cause deterioration of the insulation characteristics or to increase the easiness of the manufacturing process, the Helmholtz double layer inter-ion migration distance formed in the anode electrode layer 122 and the cathode electrode layer 124, Which increases in proportion to an increase in thickness of the electric double layer capacitor basic cell 100 and further decreases the conductivity of the electric double layer capacitor basic cell 100, resulting in a decrease in energy storage efficiency and output characteristics of the electric double layer capacitor basic cell 100.

FIGS. 2 and 3 are schematic views of a conventional electric double layer capacitor cell and electrode stacking schematics.

As shown in FIGS. 2 and 3, the conventional electric double layer capacitor cell 200 has a structure in which electrode pairs of the electric double layer capacitor basic cell 100 are stacked to increase electric energy storage capacity, The separator 140 may be disposed to connect the positive electrode lead 172 and the negative electrode lead 174 of each electrode pair to the positive connector 210 and the negative connector 220, The pair of positive electrode electrical leads 172 and negative electrode electrical leads 174 are directly connected to each other and configured to be connected in parallel. The electrode pair of the basic cell 100 of the electric double layer capacitor increases the capacitor capacity as the electrode area increases according to the characteristics of the capacitor and the electrode pair of the stacked electrode pairs of the electric double layer capacitor cell 200 is connected in parallel, Capacity is expanded.

However, there is a disadvantage in that the separation membrane 140 is disposed between the electrode pairs of the electric double layer capacitor basic cell 100 stacked for the purpose of expanding the electric energy storage capacity, thereby limiting capacity expansion per unit area.

4 is a schematic view illustrating an energy storage device in which a plurality of conventional double-layer capacitor cells are connected in series.

4, an energy storage device 400 in which a plurality of conventional double-layer capacitor cells 200 are connected in series may include an electrolyte 160 in which a series-connected electric double-layer capacitor cell 200 is used, In the case of water-soluble electrolytes, cell voltages of 1 to 1.5 V are used. Organic electrolytes have cell voltages of 2 to 3 V. In general, in order to use them for energy storage devices requiring high voltage, a plurality of electric double-layer capacitor cells 200) are connected in series and the voltage used is configured to have a high voltage suitable for the load. An energy storage pack positive terminal 420, an energy storage pack negative terminal 440, and a plurality of individual electric double layer capacitor cells 400, such that a plurality of electric double layer capacitor cells 200 are connected in series. A separate circuit board 416, which is composed of a positive electrical lead solder hole 412, a negative electrical lead solder hole 414, and a connection metal plate 416 for attaching the lead- (double layer capacitor positive lead) 250 and a double layer capacitor negative lead 260 by using a printed circuit board (not shown) to connect each of the electric double layer capacitor positive lead 250 and the electric double layer capacitor negative lead 260. [ do.

The electric double layer capacitor cell 210 by the separator 140 is connected to the circuit board 410 which is separately formed on the exterior by using the electric double layer capacitor cell anode lead 250 and the electric double layer capacitor cell anode lead 260, The contact resistance components of the electric double layer capacitor cell anode lead 250 and the electric double layer capacitor cell anode lead 260 in addition to the internal resistance of the positive electrode wire solder 412 The total connection resistance of the electric double layer capacitor cell 200 is greatly increased by the connection resistance of the negative electrode wire solder 414 and the resistance component by the connecting metal plate 416, When a high voltage is used in series connection, the capacitor capacitance component and the characteristic variation of the resistance component between the electric double layer capacitor cells 200 according to the manufacturing process The charging characteristic deviation of the electric double layer capacitor cell 200 can be increased according to the increase of the time constant proportional to the applied connection resistance and consequently a large number of the electric double layer capacitor cells 200 are connected to the series connected energy storage device 400 in a short time A charge deviation phenomenon may occur in a cell in which charging is completed and in a cell requiring a long time to complete charging.

When a plurality of electric double layer capacitor cells 200 capable of causing the charge deviation intensification phenomenon are continuously charged in all the cells of the energy storage device 400 connected in series, the electric double layer capacitor cell 200, The resistance of the cell is further increased according to the completion of the charging so that a plurality of electric double layer capacitor cells 200 are connected in series to the high voltage applied to the positive terminal 420 and the negative terminal 440 of the energy storage device 400, A high voltage is concentrated on the electric double layer capacitor cell 200 which is not uniformly divided into cells and is increased in resistance due to the full charge. As a result, the electric double layer capacitor cell 200 is made of polypropylene, polyethylene the insulation breakdown of the porous separator 140, which is made of polyethylene or polyamide, may occur, Since the operation function of the energy storage device 400 connected in series with the transformer 200 is lost, the characteristic deviation due to the increase of the connection resistance is corrected for the electric double layer capacitor cells 200 on the external circuit board 410 And the added smoothing circuit consumes the electric energy charged in the process of correcting the charge deviation of the plurality of cells and delays the charging time to prevent the electric double layer capacitor cell 200 from being damaged. There is a problem that the efficiency, lifetime and characteristics of the energy storage device 400 connected in series are further deteriorated by the function of the smoothing circuit.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a basic cell of an electric double layer capacitor comprising an electrode having a separator and an electrode having a separator without a separator.

It is another object of the present invention to provide an electrode electric double layer capacitor cell having a separator in which a plurality of basic electrode electrode pairs having a plurality of separators are stacked and connected in parallel, and a cathode current collector plate having a separator- The negative electrode current collector plate having the negative electrode current collector plate and the positive electrode current collector plate of the other electrode pair laminated in the opposite direction so that the negative current collector plate of the opposite electrode pair and the negative electrode current collector plate of the other electrode pair to be laminated are connected, A plurality of electrode pairs are alternately stacked in the opposite direction so as to be adjacent to the positive electrode current collecting plate so that the same polarities are in contact with each other; Of the electrode electric double layer capacitor cell having the separator will be.

It is still another object of the present invention to provide an energy storage device in which a plurality of electrode electric double layer capacitor cells having a plurality of separators are connected in series, And a separator electrically connected to a front end of the anode current collecting plate of the other separator-equipped electrode electric double layer capacitor cell so that the front ends of the positive electrode current collector plates of the adjacent electrode electric double layer capacitor cells are stacked and connected in series, A cell having a cell sill around the edge of the front contact surface of the electrode electric double layer capacitor cell is provided so that the cell can be separately connected in series Electrode with multiple separators without connection circuit board To provide a series-connected energy storage device, the double-layer capacitor cell.

In order to achieve the above object, the basic cell of an electrode electric double layer capacitor having a separator according to the present invention comprises: a capacitor container; A positive electrode current collecting plate in the capacitor container; A separator of a high-height insulator material having a convexly protruding pattern protruding convexly in a continuous pattern of a predetermined pattern on one surface of the positive electrode current collector plate and repeated in the length and width direction of the positive electrode current collector plate An anode electrode layer and a cathode current collector; A separator of a high-height insulator material which is convexly protruded in a continuous pattern of a predetermined pattern on one surface of the negative electrode collector plate to form a repeated pattern in the length and width direction of the negative electrode collector plate And the upper ends of the insulating separators, which are disposed higher in the anode electrode layer and the cathode electrode layer, are in contact with each other to physically separate the anode electrode layer and the cathode electrode layer, And the electrolyte is filled in the capacitor container so that the positive electrode layer and the negative electrode front side layer are connected by positive and negative ion movements of the electrolyte.

The separator of the insulator material is protruded higher than the electrode layer in the form of a circular or polygonal shape, and the size and spacing of the insulator material protruding higher than the electrode layer are different from each other, .

In order to accomplish the above object, an electrode electric double layer capacitor cell of the present invention in which a plurality of electrode electric double layer capacitor cell electrode pairs are stacked and connected in parallel is comprised of a capacitor container; A cathode current collector plate having a cathode current collector plate having an anode electrode layer with a separator formed in the capacitor container and a cathode current collector plate having a cathode electrode layer having a separator formed thereon, and a cathode current collector plate of an opposite electrode pair, And the positive electrode current collecting plates of another pair of electrodes stacked adjacent to the positive electrode current collecting plates of the other electrode pair are adjacent to each other so that the other pairs of electrodes are alternately alternately arranged in the opposite direction, A plurality of electrode double-layer capacitor basic cell electrodes of the separator according to the present invention are stacked and arranged, and the positive electrode leads and the negative electrode leads of each electrode pair are connected to form a parallel connection, and the capacitor container is filled with an electrolyte .

According to another aspect of the present invention, there is provided an energy storage device in which a plurality of electrode electric double-layer capacitor cells connected in series are connected in series. The other end of the negative electrode current collector plate of the electrode electric double layer capacitor cell having the separator in the energy storage container is connected to the other end of the negative electrode current collector plate, The separator-equipped electrode of the electric double-layer capacitor cell, and the other separator connected adjacent to the entire surface of the negative electrode current collector plate of the end portion of the electric double-layer capacitor cell. And a cell is provided around the edge of the front contact surface of the separator-equipped electrode double-layer capacitor cell of the present invention connected in series so that each of the electrode electric double-layer capacitor cells having the separator is divided.

The separator-equipped electrode electric double-layer capacitor basic cell according to the present invention is characterized in that the separator ends of the insulator material having the higher anode electrode layer and the cathode electrode layer facing each other form a gap to be physically separated from each other, ≪ / RTI > Therefore, if the step between the separator and the electrode layer is limited to a range of several micrometers or less, the gap between the opposing two electrodes can be reduced to a few microns or less, so that the distance between the positive and negative ions of the electrolyte can be relatively reduced, There is no obstacle between the electrode layer and the cathode electrode layer, and the conductivity is greatly improved as compared with the conventional electric double layer capacitor basic cell using the conventional porous separator of several tens of micro-thickness, and thus the electric energy storage and output performance is excellent. Further, since the porous separation membrane having a complicated manufacturing process is not used, the limit of durability due to the separation membrane can be improved and the manufacturing cost can be reduced.

Electrode separator according to the present invention is provided with a separator for separating the basic cell electrode pairs and connected in parallel to each other. The electrode electric double layer capacitor cell includes a separator. The electric double layer capacitor includes a separator, Layered capacitor is laminated in the opposite direction so that the negative current collecting plates of the basic cell electrode pairs are connected to each other, and further separated and laminated adjacent to the positive electrode current collecting plate of the above-described other separator-equipped electrode double- Layered capacitor of the capacitor basic cell electrode pair so as to be adjacent to each other in the same polarity so as to be alternately stacked in the opposite direction so as to be stacked, Cell stacked in a unit area There is an effect of further improving the electric energy storage density in improving the electric energy storage and output performance as the electrode pair is increased and the conductivity of the unit electrode pair is improved. In addition, since a plurality of separation membranes necessary for the lamination are not used, the limit of durability due to the separation membrane can be improved and the manufacturing cost can be reduced.

An energy storage device in which a plurality of separator-equipped electrode electric double-layer capacitor cells according to the present invention are connected in series is formed in the energy storage device container in such a manner that an electrode electric double- The front surface of the positive electrode current collecting plate, which is the starting end of the separator-equipped electrode electric double layer capacitor cell of the present invention connected in series, is in direct contact with the other end of the negative electrode current collecting plate of the electrode double- A first electrode of the first electrode of the electric double layer capacitor cell of the present invention is connected to the first electrode of the second electrode of the separator of the present invention, A cell sill is provided in the energy storage vessel Series connection of a plurality of electric double-layer capacitor cells to an energy storage device in which a plurality of electric double-layer capacitor cells are connected in series using a separate external circuit board, thereby remarkably reducing characteristic distortion due to an increase in connection resistance due to connection of an external circuit board, The necessity can be remarkably reduced and the durability limit due to use of the external circuit board can be improved. In addition, there is no need for separate equipment to protect the external circuit, thus reducing manufacturing cost and improving durability.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic view showing a conventional electric double layer capacitor basic cell. FIG.
2 is a schematic view showing a conventional electric double layer capacitor cell.
3 is a schematic diagram schematically showing electrode stacking of a conventional electric double layer capacitor cell.
FIG. 4 is a schematic diagram showing a conventional energy storage device in which a plurality of electric double-layer capacitor cells are connected in series. FIG.
5A is a schematic view illustrating a basic cell of an electrode electric double layer capacitor having a separator according to a first embodiment of the present invention.
FIG. 5B is a side view of an electrode structure having a separator according to the first embodiment of the present invention. FIG.
5c is a plan view of the electrode structure with a separator according to the first embodiment of the present invention.
FIG. 5D is a side view of a dual electrode current collector plate structure according to a second embodiment of the present invention. FIG.
FIG. 5E is a side view of a structure of a current collector plate having a longitudinal strip separator according to a third embodiment of the present invention. FIG.
FIG. 5F is a plan view of a structure of a current collector plate having a longitudinal strip separator according to a third embodiment of the present invention. FIG.
FIG. 5G is a side view of a structure of a dual electrode current collector plate having a longitudinal strip separator according to a fourth embodiment of the present invention; FIG.
FIG. 6A is a schematic view illustrating an electrode electric double layer capacitor cell having a separator according to the first embodiment of the present invention. FIG.
FIG. 6B is a schematic diagram illustrating electrode pair stacking of an electrode electric double layer capacitor cell having a separator according to the first embodiment of the present invention. FIG.
FIG. 7A is a schematic view illustrating a double-electrode electric double layer capacitor cell having a separator according to a second embodiment of the present invention. FIG.
FIG. 7B is a schematic view schematically showing electrode pair stacking of a double-electrode electric double layer capacitor cell having a separator according to a second embodiment of the present invention; FIG.
FIG. 8A is a schematic structural view of an energy storage device in which a plurality of separator-equipped electrode electric double-layer capacitor cells are connected in series according to a first embodiment of the present invention; FIG.
FIG. 8B is a schematic internal structure side view of an energy storage container in which a plurality of separator-equipped electrode electric double-layer capacitor cells of the present invention are connected in series. FIG.
FIG. 8C is a schematic diagram of an energy storage device vessel in which a plurality of separator-equipped electrode electric double-layer capacitor cells of the present invention are connected in series. FIG.
FIG. 9 is a schematic structural view of an energy storage device in which a plurality of double-electrode electric double-layer capacitor cells having a plurality of separators according to a second embodiment of the present invention are connected in series. FIG.

And a vertical line separator 541.

The current collecting plate 540 having the strip line separator according to the third embodiment of the present invention is connected to the separator-equipped electrode electric double layer capacitor basic cell 500, the separator electrode electric double layer capacitor cell 600, The separator-equipped electrode 520, the separator-equipped electrode 520, and the negative electrode collector plate 527 in the energy storage device 800 in which the separator-equipped electrode electric double layer capacitor cell 600 is connected in series. ).

FIG. 5G is a side view of a dual electrode current collector plate structure having a longitudinal strip separator according to a fourth embodiment of the present invention.

Referring to FIG. 5G, the dual electrode current collector plate 550 having the longitudinal strip separator according to the fourth embodiment includes a current collector plate 527; An electrode layer 523 formed on both sides of the current collector plate 527; The height of the current collecting plate 527 is larger than the height of the electrode layer 523 in the longitudinal direction of the current collecting plate 527 with a predetermined distance in the width direction. .

 The dual electrode current collector plate 550 having the longitudinal strip separator according to the fourth embodiment of the present invention is connected to the double electrode electric double layer capacitor cell 700 having the separator and the double electrode electric double layer capacitor cell 700 may be replaced with a separator-equipped double electrode current collector plate 530 in an energy storage device 900 connected in series.

100: electric double layer capacitor base cell
110, 510: Capacitor vessel 112: Capacitor vessel lid
122, 522: anode electrode layer 124, 524: cathode electrode layer
126, 526: positive electrode collector plate 128, 528: negative collector plate
140: separator 160, 560: electrolyte
172, 572: positive electrode electrical lead 174, 574: negative electrode electrical lead
200: electric double layer capacitor cell
210: positive electrode connector 220: negative electrode connector
250: Electric double layer capacitor cell anode lead
260: Electric double layer capacitor cell cathode lead
400: a plurality of electric double-layer capacitor cells connected in series to an energy storage device
410: circuit board 412: positive lead wire solder
414: negative electrode wire soldering hole 416: connecting metal plate
420: Energy storage device bipolar terminal
440: Energy storage negative terminal
500: Electrode with separator Electrode Electric double layer capacitor Basic cell
520: Electrode with separator 521:
530: Double electrode collector plate with separator
540: Electrode collecting plate with vertical line separator
541: Vertical line separator
550: Double electrode collector plate with vertical strip separator
600: separator-equipped electrode electric double layer capacitor cell
610: anode electrical lead connection 620: cathode electrical lead connection
650: Electric double layer capacitor cell anode lead
660: Electric double layer capacitor cell cathode lead
700: Separate Double-Electrode Electric Double-Layer Capacitor Cell
800: Electrodes with a plurality of separators Electrolytic energy storage device
810: Energy storage container
812: Energy storage container lid
814: Sable
850: Electrode with separation body Electric double layer capacitor Energy storage device Anode connection terminal
860: Electrode with separation body Electric double layer capacitor Energy storage device Cathode connection terminal
900: Energy storage device in which a plurality of separator-equipped double-electrode electric double-layer capacitor cells are connected in series

Claims (8)

Electrode pair; Wherein at least one of the electrode pairs is laminated and connected in parallel so that the current collector plates of the same polarity are connected to each other. The electric double layer capacitor according to claim 1, further comprising: a separator which is convexly protruded in a continuous pattern of a predetermined pattern on one surface of the current collector plate to form a repeated pattern in the length and width direction of the current collector plate, Capacitor. The electric double layer capacitor according to claim 2, wherein the separator is protruded from the current collector in the form of a circular or polygonal shape. [5] The separator according to claim 3, wherein the separator is formed in one collector plate having different sizes and spacings by varying the size and spacing of the separator iron projections formed on the current collector plate, Lt; / RTI > The electric double layer device according to claim 1, further comprising: a separator which is convexly protruded in a continuous pattern of a predetermined pattern on both sides of the current collector plate to form a repeated pattern in the length and width direction of the current collector plate, Capacitor. The method of claim 1, further comprising: And a separator which protrudes convexly in a pattern continuous in the longitudinal direction of the current collector plate and has a pattern repeated in the width direction on one surface of the current collector plate. 7. The electric double layer capacitor according to claim 6, wherein the separator is formed protruding from the current collector in the form of a rod or polygon. 10. The electric double layer capacitor according to claim 9, wherein the separator has a plurality of separators having different sizes and spacing in different sizes and spacings of the separator formed on the current collector plate, .

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