RU175936U1 - SUPERCAPACITOR - Google Patents

Abstract

The utility model relates to electrical engineering and electrochemistry, namely to a supercapacitor with an inorganic liquid electrolyte, which can be used in various devices as a power source, due to the electric charge accumulated in it. The supercapacitor consists of a housing in which at least one section of electrodes is impregnated with an electrolyte and separated by an ion-permeable separator, while the electrodes are made of a material comprising an aluminum tape coated with an active carbon base, consisting of a mixture of activated carbon, an electronically conductive additive and a polymer a binder in the following ratio, wt.%: activated carbon 70-90, conductive additive 5-20, binder 5-10, characterized in that the conductive additive consists of nanofibers th carbon and as active charcoal used thermally expanded graphite. The technical result is an increase in the specific electric capacitance of the supercapacitor.

Description

The utility model relates to electrical engineering and electrochemistry, namely to a supercapacitor with an inorganic liquid electrolyte, which can be used in various devices as a power source, due to the electric charge accumulated in it.

In supercapacitors based on the capacitance of a double electric layer, the total capacitance increases with an increase in the specific surface area of the electrode material due to a decrease in pore size and an increase in the area of the interface.

Electrode materials for this type of supercapacitor are various carbon materials, for example, such as carbon nanotubes, carbon black, porous graphite, activated carbon, and others. Active development of technologies for producing new carbon materials with a developed specific surface and high porosity allows them to be successfully used as an electrode material of a supercapacitor.

A supercapacitor is known (RF Patent No. 2528010 of 09/10/2014), which contains two electrodes and a dielectric layer placed between them, while the lower electrode is made of a material with a large specific surface area, the dielectric layer is conformally and uniformly located on the lower electrode, the upper the electrode is conformally and uniformly located on the dielectric layer and is made of zinc oxide alloyed with aluminum, while the dielectric layer is made of a multicomponent oxide containing a mixture of at least two oxide Selected from the series TiO _2, HfO _3, ZrO _2, Al ₂ O _3, Ta ₂ O _5, Nb ₂ O _5, Y ₂ O ₃ and oxides of elements of the lanthanide group.

However, a significant drawback of this supercapacitor is its low specific capacity.

Known supercapacitor of high power on a double electric layer, consisting of compressed into a single block of polarizable electrodes, including a metallized active carbon base, a separator and a water-based electrolyte, placed in the housing. As an active carbon base, carbon fibers with a perfect hexagonal crystalline structure of graphite and an ordered system of internal pores with characteristic double wells of adiabatic potential are used, the surface of the fibers is directly coated with thin conductive metal films by deposition from the gas phase without the use of a binder (RF Patent No. 2098879 dated 10.12 .1997).

The disadvantage of this known supercapacitor is the low mechanical strength of the electrodes, creating the problem of maintaining their integrity and complicating the assembly of the blocks. In addition, limited technical capabilities for the design of blocks and the use of water-based electrolytes, as well as the low specific capacity of this supercapacitor.

A supercapacitor is also known (RF Patent No. 2427052 of 08/20/2011), which is a prototype that consists of a housing in which at least one section of electrodes is impregnated with an electrolyte and separated by an ion-permeable separator, while the electrodes are made of material comprising an aluminum tape coated with an active carbon base, consisting of a mixture of activated carbon, an electron-conductive additive and a polymer binder in the following ratio, wt.%: activated carbon 70-90, electron-conductive additive 5-20, floor dimensional 5-10 binder and electron-conductive additive consists of multi-walled carbon nanotubes and / or carbon black.

However, the indicated supercapacitor has the disadvantage of using expensive multi-walled carbon nanotubes, as well as the use of a large amount of binder material, which can degrade the strength characteristics of the electrode, while using a larger amount of binder leads to a corresponding decrease in the amount of carbon material contained in the electrode. Reducing the amount of activated carbon present in the electrode subsequently reduces the specific electric capacity of the supercapacitor.

The objective (technical result) of the proposed utility model is to increase the specific electric capacity of the supercapacitor.

The objective is achieved in that the supercapacitor consists of a housing in which at least one section of electrodes is impregnated with an electrolyte and separated by an ion-permeable separator, while the electrodes are made of a material comprising an aluminum tape coated with active carbon base, consisting of a mixture of active carbon , an electrically conductive additive and a polymer binder in the following ratio, wt.%: activated carbon 70-90, electrically conductive additive 5-20, binder 5-10, where the electrically conductive additive consists of nan carbon fiber and active carbon as used thermally expanded graphite.

The drawing shows a supercapacitor, which consists of a housing (1), which houses at least one section of electrodes (2) made of aluminum tape (3) and active carbon base (4), impregnated with an electrolyte (5) and separated ion permeable separator (6).

Supercapacitor works as follows. When a supercapacitor is inserted into the power circuit under the action of an electric current on the electrodes (2), which are located inside the supercapacitor case (1), a charge accumulates. An active carbon base (4), consisting of a mixture of activated carbon, an electrically conductive additive and a binder, can be formed into a tape by pressing with aluminum foil (3).

Thermally expanded graphite can be used as activated carbon, whose morphology resembles a graphite structure with a distinctly noticeable porous skeleton. The texture characteristics are as follows: specific surface area from 150 to 700 m ² / g, specific pore volume is 0.18-0.31 cm ³ / g.

As an electrically conductive additive, you can use nanofiber carbon (NVU) with a fiber diameter of 5 to 200 nm, and a length of 1-10 microns. The morphology of NVU is diverse and differs in the arrangement of graphene layers relative to the fiber axis. НВУ can have the following texture characteristics: specific surface area from 80 to 400 m ² / g, specific pore volume is from 0.1 to 0.4 cm ³ / g.

An electrolyte (5) can be an aqueous, solid or crystalline solution of alkali or acid, which impregnates the active carbon base, providing the appearance of charge carriers with its subsequent accumulation.

As a binder of activated carbon and an electrically conductive additive, liquid paraffin, polyvinyl alcohol or rubbers can be used.

In order to prevent a short circuit of the electrodes, as well as an ion-conducting material, an ion-conducting separator is installed in the casing between the electrodes of the supercapacitor (6).

When the power source is disconnected and the load is connected, the charge is redistributed, and if the electrodes are connected to the load source, the process of discharge of the supercapacitor will occur, i.e. delivery of an electric charge to a load source, for example, light bulbs.

Thus, it is used as an active carbon base, consisting of a mixture of active carbon and an electrically conductive additive, where thermally expanded graphite with the indicated characteristics acts as active carbon, and nanofiber carbon with the indicated characteristics as the electrically conductive additive, the task is achieved, namely, an increase specific capacitance of the supercapacitor.

Example 1. The active carbon mass, consisting of thermally expanded graphite (90 wt.%) And paraffin oil (10 wt.%), Was mixed to a paste-like state for 5 min at 1000 rpm at a temperature of 20 ° C. After compaction and rolling up to 150 μm, the active mass was deposited on an electrode with an area of 10 cm ² . As an electrolyte, a solution of 3.5 M H ₂ SO _{4 was used} . The resulting supercapacitor has a specific electrode material capacity of 90-100 F / g.

Example 2. The active carbon mass, consisting of thermally expanded graphite (70-80 wt.%), HBI (20-10 wt.%) And liquid paraffin (10 wt.%), Was mixed to a pasty state for 5 min at 1000 rpm / min at a temperature of 20 ° C. After compaction and rolling up to 150 μm, the active mass was applied to an electrode with an area of 10 cm ² . As an electrolyte, a solution of 3.5 M H ₂ SO _{4 was used} . The resulting supercapacitor has a specific capacitance of electrode material of 100-120 F / g.

Example 3. The active carbon mass, consisting of thermally expanded graphite (70-90 wt.%), HBI (20-5 wt.%) And liquid paraffin (5 wt.%), Was mixed to a pasty state for 5 min at 1000 rpm / min at a temperature of 20 ° C. After compaction and rolling up to 150 μm, the active mass was deposited on an electrode with an area of 10 cm ² . As an electrolyte, a solution of 3.5 M H ₂ SO _{4 was used} . The resulting supercapacitor has a specific capacitance of electrode material of 125-160 F / g.

Claims (1)

A supercapacitor consisting of a housing in which at least one section of electrodes is impregnated with an electrolyte and separated by an ion-permeable separator, wherein the electrodes are made of a material comprising an aluminum tape coated with an active carbon base, consisting of a mixture of active carbon, an electronically conductive additive, and polymer binder in the following ratio, wt.%: activated carbon 70-90, conductive additive 5-20, binder 5-10, characterized in that the conductive additive consists of nanofibres carbon, and thermally expanded graphite was used as activated carbon.

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