RU2578129C1 - Film condenser - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: film condenser comprises packaged electrodes separated by dielectric; polymer base of these electrodes is made of highly porous corrugated material covered with current conductive layer equipped with current lead. Polymer base of the condenser structure is made of busofite carbon fibres metallised at their surface with porous layer of titanium with thickness of 0.2-2 mcm and current leads with thickness of 5-20 mcm are made composite: busofite and titanium layer with coating of highly conductive metal, mainly copper and silver.

EFFECT: improved specific energy intensity of multilayer film structure of the condenser at reduction of inner ohmic resistance.

1 dwg

Description

The invention relates to electrical engineering, and more particularly to layered film storage of electrical energy - electrolytic capacitors, the composite layers of which differ significantly in composition and physical structure.

The level of this technical field characterizes described in patent RU 2296055 C2, H01G 9/00; B82B 1/00, 2007 a film anode of an electrolytic capacitor made of a nanostructured composite material based on high molecular weight compounds using carbon.

The nanostructured current-carrying coating of the carrier carbon base of the film anode is made of polyethylene terephthalate with a highly developed surface, including corrugations with a depth of 10-30 nm and / or pores of 0.2-6 microns with a total volume of 10-60%, with 1 / 5-1 / 3 of the pores made through.

The coating of the carrier base is directly related to the layer (5-50 nm) of amorphous carbon sp-3 of the hybridized state of carbon atoms and additionally has a metal layer 25-250 nm thick deposited from the vapor phase in argon, ensuring maximum adhesion to the substrate.

A solid electrolyte is applied to the current-carrying coating of aluminum or copper, forming an anode for compact and electrically capacitive capacitors, in which the applied energy is stored in a thin layer of space charge at the electrode-electrolyte interface.

Electrolytic capacitors, which use anodes from a polyethylene terephthalate film with a nanostructured composite coating on a modified surface, are characterized by high specific power and stability of charge-discharge characteristics in a wide temperature range of operation.

The disadvantage of the described capacitor is the functional unreliability due to possible delamination of autonomous inclusions of the porous valve metal at the interfaces through which the migration processes of interdiffusion pass during operation, which leads to instability of the purpose of the electrolytic capacitor and significantly reduces its service life.

A more perfect film capacitor is described in patent RU 2308112, H01G 9/04; B32B 15/04, 2007, which contains a layer of solid electrolyte placed on a multilayer anode film, adhesive bonded to an oxide coating having valve metal inclusions.

The anode film includes a physically activated conductive substrate with a developed surface and an oxide coating on a conformal layer of electrochemically active aluminum having an adjustable bulk porosity, bonded to the surface of the substrate by a heterojunction, which is a nanostructured composition of the substrate material and the deposited valve metal.

The inclusion of porous aluminum in the form of a conformal layer similar to the profile of the substrate in the oxide coating multiplies the contact surface of interaction with the solid electrolyte of the film capacitor.

The oxide coating in the structure of the film capacitor acts as a dielectric.

Here, a dielectric should also be understood as a double electric layer arising between two adjacent media - the anode and cathode in the form of a solid electrolyte.

Valve metal in the form of a coating layer provided openness of a highly porous surface accessible for filling with electrolyte, which makes it possible to use solid electrolyte in the capacitor, thereby expanding the technological possibilities of application.

The presence of bulk porosity and the creation of ionizing radiation defects in the valve metal layer leads to an increase in the electrochemical activity of the material, which is controlled by controlling the number and size of pores in the volume of sprayed aluminum.

The porous structure of the deposited aluminum layer thus formed is more easily subjected to electrochemical oxidation, forming a dielectric layer less mechanically stressed, which increases the functionality of the capacitor as a whole.

At the same time, the activity of the valve metal ensures the creation of a thicker layer of high-quality oxide to increase the operating voltage of the high-capacity film capacitor.

Due to the improvement of mechanical characteristics, ductility and adhesive strength of monolithic compounds of structural components, this film capacitor has an increased specific capacitance and functioning voltage of more than 600 V.

However, a further increase in the specific capacitance of the described film capacitor is limited by the laws of electrical engineering.

The noted drawback is eliminated in an improved design of the film capacitor, which is made using standard roll technology of the existing electric arc vacuum equipment, characterized by a multiple of increased specific electric capacity, is described in patent RU 2402830 C1, H01G 4/33; B82B 1/00, 2009, which, according to the technical nature and the number of matching features, is selected as the closest analogue to the proposed

Known film capacitor contains a multilayer anode foil with a highly developed surface on which a dielectric coating coated with a solid electrolyte is adhesively attached.

Metal clusters with a size of 0.5-50 nm are dispersed in a dielectric layer 2-100 nm thick, while at least two dielectric layers separated by a layer of metal clusters are placed between the anode foil and the solid dielectric layer.

The dielectric layer is formed by the deposition of metal clusters from a hydrosol by means of pulsed arc discharges in series of silver clusters and aluminum and / or titanium clusters, which are then oxidized on the surface of the shell, respectively, in the amount (wt.%): 1-30 and 70-99.

The structurally known film electrode includes a polymer base with a corrugated highly porous surface of a diamond-like nanolayer, on which a layer of conductive aluminum and a sponge valve metal are sequentially applied through heterojunctions, silver interlayers separated by a dielectric (aluminum oxide, polymer) and a solid electrolyte coating.

Each dielectric layer is formed with a thickness of 2-100 nm to increase the electrical capacitance of the anode foil, the functional layer of aluminum of which is deposited from the technological hydrosol in the form of clusters of 0.5-50 nm in size.

The minimum size of the deposited aluminum clusters is limited for the practical formation of a dielectric shell, in which contacts of adjacent layers (metal anode and electrolyte) are excluded.

Clusters of metal with a size of 50 nm are guaranteed to be placed in a 100 nm thick dielectric shell, and it is not advisable to increase the dielectric layer because the electrical characteristics of the sponge metal do not change significantly.

The deposition of metal clusters on a substrate is carried out by deposition from a technological hydrosol; therefore, metal clusters larger than 100 nm form a sedimentation-unstable suspension.

Metal clusters less than 2 nm do not provide continuity of the formed layer, and their manufacturing is technologically difficult.

Separation of layers in a dielectric shell by interlayers of metal clusters provides a corresponding increase in its dielectric constant due to an increase in polarizability and, as a result, an increase in the specific electric capacitance of a multilayer film capacitor.

The implementation of the conformal dielectric layer on the surface of the spongy metal of the anode film by successive deposition of silver clusters (1-30 wt.%), And then aluminum and / or titanium clusters (70-99 wt.%), Which oxidize from the surface, was experimentally worked out and is due to the following .

The non-conductive oxide layer serves as a dielectric matrix in which metal clusters are distributed.

Silver clusters serve as a barrier forming a clear boundary between adjacent materials of various functions: sponge metal - silver - dielectric, which is formed by the oxidation of aluminum and titanium located on the surface of the dielectric shell.

A silver content of less than 1 wt.% Does not significantly increase the electrical characteristics of the dielectric, in particular dielectric constant, and does not form a barrier layer at the interface.

With an increase in the mass content of silver in the layer over 30 wt.%, The breakdown voltage decreases, which worsens the purpose of the film capacitor.

A continuation of the advantages of the well-known multilayer film capacitor is its inherent disadvantages: the technological complexity of manufacturing, at high consumer cost due to large capital investments in special equipment, and the limitation of the growth of the electrical parameters of the capacitor.

The technical problem to which the present invention is directed, is a multiple increase in the purpose of technological film capacitor, suitable for serial production.

The required technical result is achieved in that in the known film capacitor containing dielectric-separated packet electrodes, the polymer base of which is made of a highly porous corrugated material coated with a conductive layer equipped with a current collector according to the invention, the polymer base is made of carbon fiber busofite metallized from the surface with a porous layer titanium with a thickness of 0.2-2 microns, and down conductors with a thickness of 5-20 microns are made of composite: busofit and a titanium layer coated with high aqueous metal, preferably copper, silver.

Distinctive features of the proposed technical solution have repeatedly increased the specific energy consumption of the capacitor structure (at least 40 W · h / kg), while reducing the internal ohmic resistance.

The metallization of the surface of carbon fibers of the base of a capacitor packet structure, consisting of several layers, provided a multiple increase in specific energy consumption (W · h / kg), with a decrease in internal resistance (Ohm).

The implementation of the polymer base of the film capacitor of carbon fiber busofit 40 provides a high specific energy consumption of the electrolytic cell (more than 10 W · h / kg) and manufacturability of its manufacture.

Metallization of busofit fibers from the surface with a porous titanium layer is aimed at reducing the internal electrical resistance of the capacitor to maximize the transfer of electrical energy to the load.

The porous layer of titanium on the inner surface of the fiber structure of the capacitor package is necessary so that the electrolyte that impregnates the highly porous busofit provides electrical contact between the adjacent layers of the titanium coating and with each fiber of the busofit. Titanium is selected as a metal that does not chemically interact with electrolyte.

The thickness of the titanium coating on the surface of the carbon fibers of the base was determined empirically to achieve maximum values of the destination indicators, according to calculations by the mathematical model of the experimental design, the results of which were confirmed in an optimized range of thicknesses of the adhesive conductive layer.

If you use a coating layer of busofit fibers with porous titanium with a thickness of less than 0.2 microns, it is not possible to obtain a stable minimum electrical resistance at the contact between two adjacent layers of busofit.

If the porous titanium layer in the coating is more than 2 μm, then the contact resistance of two conjugated busofit layers ceases to depend on the thickness of the porous titanium layer and a further increase in its thickness becomes economically and technically impractical.

The choice of the thickness of the down conductors in the range of 5-20 μm is determined in accordance with the achieved current load with a minimum discharge time of the capacitor cell.

The down conductors of the selected thickness ensure the passage of the maximum current through it at an operating temperature of 50 ° C.

The execution of down conductors with composite, in the form of successive highly porous layers of busofit, titanium and copper / silver, creates a minimum electrical resistance at the busophyt-metal contact, compared with overhead down conductors, and provides an increase of one and a half to two times the specific capacity of the electrolytic cell.

The adjacent thick layer of porous titanium on the surface of the busofit provides good electrical contact with the carbon base material.

The proposed design of the current collector ensures the absence of stray electric capacitances, which inevitably appear when using clamping current-collecting devices, thereby reducing the overall resistance of the electrolytic cell and its weight and size characteristics.

Therefore, each essential feature is necessary, and their combination in a stable relationship is sufficient to achieve a novelty of quality that is not inherent in the characteristics of disunity, that is, the technical problem posed in the invention is not solved by the sum of the effects, but by a new super-effect of the sum of the attributes.

The essence of the proposed technical solution is illustrated by the drawing, which serves purely illustrative purposes and does not limit the scope of claims of the totality of the essential features of the formula.

The drawing shows a structural diagram of the proposed capacitor.

Each packet electrode 1 includes several layers 2 of carbon fiber - busofit 40, from the surface of highly porous titanium coated with interlayers 3 with a thickness of 0.2-2 microns.

The electrodes 1 are insulated with each other by a dielectric 4 made, for example, of capacitor paper or a polymer membrane.

A thick (5-20 μm total) layer 5 of copper or silver is formed on the outer layer 3 of titanium of each electrode 1 by ion-arc deposition, which serves as a collector 6.

A comparison of the proposed technical solution with the identified analogues of the prior art did not reveal an identical match of the totality of the essential features of the invention.

Significant differences of the film capacitor are not obvious to specialists in electrical engineering who do not directly follow from the statement of the technical problem.

The manufacture of multilayer film capacitors of the proposed structure in a stable interconnection of constituent elements can be carried out at the existing automatic production in series for use as industrial current sources.

From the foregoing, we can conclude that the invention meets the conditions of patentability.

Claims (1)

A film capacitor containing dielectric-separated packet electrodes, the polymer base of which is made of highly porous corrugated material coated with a conductive layer equipped with a down conductor, characterized in that the polymer base is made of busofit carbon fibers metallized from the surface with a 0.2-2 μm thick porous titanium layer and down conductors with a thickness of 5-20 microns are made composite: busofit and a titanium layer coated with a highly conductive metal, mainly copper, silver.