RU2726945C1 - Flat supercapacitor based on carbon-carbon nanocomposite and method of its production - Google Patents

Abstract

FIELD: electrical engineering.SUBSTANCE: invention relates to electrical engineering, particularly, to flat thin supercapacitor, which can be used in electronics as miniature low-current power supply source. Flat supercapacitor based on carbon-carbon nanocomposite comprises accumulating charge combined electrode consisting of thin layer of carbon materials impregnated with organic electrolyte, wherein the supercapacitor electrode consists of a porous carbon material, a carbon-carbon nanocomposite, an electroconductive additive in the form of acetylene black and a binder mixed in proportions of 30:20:1:5, wherein the carbon-carbon nanocomposite is an electrically conductive additive and an active component owing to the developed specific surface area.EFFECT: reduction of equivalent series resistance to 55 mOhm.1 cl, 1 dwg

Description

The invention relates to the field of supercapacitors and can be used in systems and units of microcircuitry, in biomedical equipment, as autonomous mobile miniature power supplies, in communication systems, energy and other devices operating due to electrical energy stored in a supercapacitor.

Known supercapacitor (see application PCT WO 2014191529, IPC H01G 11/24, H01M 10/056, H01M 10/58, publ. 04.12.2014), containing two electrodes, between which is a layer of active material from an electrolyte, separator and film from graphene nanoparticles. The supercapacitor has a specific power of 25 kW / kg and a specific energy capacity of over 1 Wh / kg.

The disadvantage of the known supercapacitor is its low electrical capacity, which is a consequence of the incomplete use of the potential of graphene, and the high cost and labor intensity of using graphene limit the production of such supercapacitors.

A known supercapacitor (see application KR 20140075845, IPC H01G 9/042, H01G 11/22, publ. 20.06.2014), in which one of the electrodes includes a graphene layer formed on one or two sides of the current collector, which increases the capacity of the supercapacitor and reduces the equivalent series resistance (ESR).

A well-known supercapacitor (see RF patent 175936 IPC H01G 11/34, H01G 9/042, SPK H01G 11/34, H01G 9/042), consisting of a housing in which at least one section of electrodes is located, which are impregnated with electrolyte and separated by a porous separator. The electrodes are made of a material in the form of an aluminum tape coated with an active carbon base consisting of a mixture of active carbon, an electronically conductive additive and a polymer binder. In this case, the mass ratio of the components is as follows: activated carbon 70-90%, electrically conductive additive 5-20%, binder 5-10%.

This type of design has a number of technical disadvantages, namely: vaseline oil is used as a binder, which solidifies at temperatures below minus 8 ° C, which can lead to the destruction of the electrode; also, vaseline oil is liquid under normal conditions, and this will lead to deformation of the electrodes during assembly of the device, since in the final device they must be pressed against each other; the use of sulfuric acid reduces the operating voltage, therefore, even with high capacities, the total energy consumption remains low: at the level of 2-4 Wh / kg of pure material, excluding the case and electrolyte.

A super capacitor is known (see RF patent 2427052, IPC H01G 9/058, H01G 9/155, publ. 08/20/2011), which coincides with the present solution in terms of the largest number of essential features and is taken as a prototype. The prototype supercapacitor contains electrodes made of activated carbon, carbon nanotubes or carbon black and a fluoroplastic binder.

The disadvantage of the known prototype supercapacitor is the poor contact of the active mass with the current collector, due to the fact that the electrode mass is prepared separately, and then pressed against the aluminum tape. The technique also involves the use of either expensive carbon nanotubes in large quantities (about 10 wt%) or a large amount of carbon black (up to 20 wt%), which, due to its poorly developed surface, greatly reduces the specific characteristics of the electrode. Also, the prototype form factor (namely, the cylindrical shape or the tablet type) does not allow the use of these drives in surface mount boards and in devices where thickness is critical.

The aim of the invention is to provide flat supercapacitors with a low equivalent series resistance.

The essence of the invention, as a technical solution, is expressed in the following set of essential features, sufficient to achieve the above result:

- use as an electrically conductive additive and an active material of a carbon-carbon nanocomposite based on carbon black. This material not only has a large specific surface area, but also has an extremely low equivalent series electrical resistance;

- the use of a fluoroplastic binder, organic solvent and ultrasonic treatment, since this combination allows to obtain a high homogeneity of the mixture of carbon-carbon nanocomposite with a binder;

- the design of the supercapacitor in the form of a flat thin device allows it to be used in surface mounting of printed circuit boards, where the thickness of the board is important, for example, for portable devices.

The method of manufacturing a supercapacitor also includes making electrodes from the resulting paste, impregnating them and assembling them by vacuum lamination.

The technical result achieved by using the essential features of the invention is that:

- the use of a porous carbon material as an electrically conductive additive does not reduce the specific surface area, but at the same time increases the conductivity of the electrode;

- Slim design allows these supercapacitors to be used in various portable devices;

- low series equivalent resistance, which reduces energy losses when using these drives.

A cross-sectional view of the supercapacitor is shown in FIG. 1, where 1 is an electrode (aluminum foil with a layer of porous carbon material); 2 - aluminum laminating foil; 3 - separator. The arrangement of the elements during assembly is important to get the device working.

The claimed method of manufacturing supercapacitors is as follows. A batch of porous carbon material Kuroray YP-80 (manufactured by Kuraray Chemical Co., Ltd) weighing 60 g is mixed with 100 ml of 2% PVDF (polyvinylidene fluoride or fluoroplastic-2) in NMP (N-methylpyrrolidone) using an overhead stirrer for 1 hour ... Carbon black P267E coated with a layer of 20-60 nm pyrocarbon at 900 ° C and activated at 600 ° C in water vapor (carbon-carbon nanocomposite) weighing 40 g and 2 g of an electrically conductive additive (acetylene soot) is dispersed by ultrasound in 400 ml of NMP until homogeneous mass, after which it is mixed with the suspension of Kuroray YP-80 and mixed using an overhead stirrer for 48 hours. Thus, the ratio of the components is 30: 20: 1: 5 for the porous carbon material, carbon-carbon nanocomposite, electrically conductive additive and binder, respectively. After the resulting paste is mixed for 10 minutes on a vacuum mixer to remove bubbles and spread using a squeegee on aluminum foil. The thickness of the smeared layer is 600 microns, the width is 20 mm. Drying of the smeared electrode is carried out in air for 24 hours at a temperature of 100 ° C and then in a vacuum at a temperature of 120 ° C for 24 hours. Then, calendering was carried out (compaction of the coating by passing it through heated rollers) to a thickness of 250 μm at a temperature of 80 ° C. The final electrode thickness is 150 microns.

Next, the electrodes were cut into elements with a size of 17 × 23 mm (the size of the part of the electrode with a coating is 17 × 17 mm) and laminated in the following sequence: laminating aluminum foil (113 μm), electrode (150 μm), Celgard separator made of polypropylene (16 μm) , electrode (150 μm) and laminating foil (113 μm). The arrangement of the elements relative to each other is shown in FIG. 1. The electrolyte used was a 1 M solution of TEABF4 (tetraethylammonium tetrafluoroborate) in acetonitrile.

The cell capacity is 110-130 mF at a rated current of 1 A, a voltage of 2.7 V, and a resistance of 55 mOhm.

Reducing the resistance by more than 5 times compared to the prototype having a similar electrode area (in this case, the prototype has a resistance of 0.3 Ohm) is the technical result of this invention.

Claims (1)

Flat supercapacitor based on carbon-carbon nanocomposite, including a charge-accumulating combined electrode, consisting of a thin layer of carbon materials impregnated with an organic electrolyte, characterized in that the supercapacitor electrode consists of a porous carbon material, a carbon-carbon nanocomposite, an electrically conductive additive in the form of acetylene black and binder, mixed in proportions of 30: 20: 1: 5, while the carbon-carbon nanocomposite is both an electrically conductive additive and an active component due to the developed specific surface area, and the supercapacitor itself is made in the form of a flat thin device.

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