FR2482788A2 - Battery electrode mfr. - by chemically plating copper or nickel on a porous or fibrous mineral or organic eliminatable substrate - Google Patents

Abstract

The parent patent described battery electrodes obtd. by metallising a microporous thin, non-conductive substate of fibrous structure, woven or non-woven. then applying the active material over the whole of the metallised surface and into the metallised pores of the substrate. In this addition, the substrate is a mineral or organic material, (carbon or graphite, cellulose, polyester, polyamide etc.) the porous or fibrous texture of which is such that the ratio between the surface developed and the apparent surface is large, the pore size of the interstices increasing in size with increase in thickness. The essential part of the current collector is formed by electroplating of Ni onto a previous deposit of Cu which may be electroplated or electroless deposited, and which may be reinforced by electroplating. A larger electrode structures can be formed than foreseen in the parent patent due to the increased thickness and strength of the electrodes while maintaining the porosity and proportion of collecting surface of the electrode. Use of a precoating of copper increases the electrical conductivity of the electrode grid.

Description

 The present invention relates to improvements and improvements made to French patent application No. 79.17340 taken on July 6, 1979 for "Structure 8'electrode. For electro trochemical generator".

 The main patent describes a new design and embodiment of electrodes intended for the other used in generators. According to the invention which is the subject of said patent, the electrodes are produced by metallization then despite the active electrode material over the entire developed surface and therefore throughout the thickness of a thin porous support.

 The purpose of this addition certificate is the contribution.

new improvements and additional details concerning the production of the type of electrodes described in the main patent.

 According to the principle described in the main patent, the substrate used during the constitution of the electrode is a non-conductive microporous structure of small thickness I1 can act thus in particular of a microporous film or of a woven or nonwoven fibrous structure . In such cases and depending on a very small pore size, it appears necessary, so that the production of the electrode within this substrate can be carried out under other conditions, that its thickness is very small and by example limited to about 500 microns, if the pores have a diameter of between about 3 and 30 microns.

 These constraints, as well as the search for high surface energy and capacity characteristics of the electrode, have led to applying and adapting the principle of embodiment described in the main patent to substrates which may have a pore size and therefore a greater thickness. .

 In fact, increasing the size of the pores or interstices of a porous support makes it possible to facilitate the production of deposits, whether chemical or electrochemical, over the entire developed surface and therefore throughout the thickness of the substrate. . It therefore becomes possible to increase its thickness without harming the quality of the deposits made in order to produce the current collector and then the electrode in its electrochemically active part itself. The terms of "thin" and "microporous" substrates must therefore be understood in a broad sense, the size of the pores, like the thickness, which can vary in relatively large proportions, without however preferably exceeding a few tenths of a millimeter for the diameters of the pores or interstices or a few millimeters for the thickness of the substrate.

Thus it is appropriate, according to the invention which is the subject of this certificate of addition, to retain, in addition to
microporous substrates described in the main patent, porous structures whose dimensional characteristics can be significantly superior. Here again, it may be fibrous or non-fibrous structures. In any event, the thickness to be given to the substrate is determined as a function of its porosity and the size of its internal pores or interstices, the thickness being able to spatter if a structure which is more broadly "aerated" is chosen, so that the deposits to be made on the substrate can other carried out throughout the thickness of the initial support and without clogging thereof.

A second aspect is the subject of this certificate of addition and contributes to completing and improving the invention described in the main patent. It relates to the mode of treatment of the initial substrate and more precisely all the operations which lead to the production of the current collector and then of the electrode proper according to the main patent. This describes the steps which make it possible to constitute the current collector by metallization of the sub
strat, then the electrode itself by deposition of the active material. The description of the preparation of the current collector reveals that it is made in any thickness of the substrate over its entire surface developed by metallic spite. According to the main patent, the collector is thus- consisting of nickel and can be formed from two successive deposits, the first being chemical and the second electrochemical.

In order to improve the conductivity of the collector and to lower its cost, it may appear desirable to carry out an "initial layer" or initial departure of copper on the porous substrate. -When the substrate is itself conductive, for example when it is made of a felt or fabric of carbon or graphite, this first deposit can be made by chemical or electrochemical means. In most of the cases, when the substrate is not # itself # same conductor, this first spite of copper is chemical. In order to obtain a significant advantage in electrical conductivity compared to a collector only made up of nickel, it can in some cases appear interesting to complete the first chemical copper deposit, which by
its embodiment is necessarily very thin, by a second depat of copper carried out electrochemically which it is possible to produce in a greater thickness.

Depending on the use for which the electrode that is to be used is intended, in this case depending on the nature of the active electrode material, the electrolytic medium in which it will be called to operate, and the desired electrical and electrochemical characteristics, - it will be possible or not to supplement this or these copper outlets with another metallic spite and in particular of nickel to perfect the elaboration of the current collector. This deposit, especially if it is nickel, may advantageously be made other electrochemically.

 Thus, the production of the current collector can be carried out according to a number of variants concerning the metal deposits. By way of nonlimiting examples of the invention, the following may be preferred: offset of chemical nickel followed by deposition of electrochemical nickel.

This path described in the main patent is in particular capable of serving as a collector both for a nickel electrode and for a cadmium electrode.

- departure of chemical copper followed by an departure of electrochemical copper, itself covered with a thin start of electrochemical nickel.

 - chemical copper deposit followed by electrochemical nickel deposition.

These two ways apply in particular .particularly well to the production of a collector for nickel electrodes.

- chemical copper deposition followed by electrochemical copper spite.

The latter route is particularly suitable for making # a collector for a cadmium electrode.

 This addition certificate also relates to another improvement made to the main patent to which it relates. It has been said in this that its object is to offer a new response to the search for generators capable of supplying high mass energy and power, by innovating at the level of the same structure of the electrodes. Thus the main patent is devoted to the use of electrodes whose substrates are chosen in particular for their low density; their weight must be low compared to that of the electrode material: this is what appears in the exemplary embodiments cited in this patent concerning cadmium and nickel electrodes. This certificate provides an additional improvement in this direction. This improvement consists, when the structure of the substrate makes this operation conceivable, in oxidizing the latter after the metal deposits necessary for producing the current collector have been made. This oxidation should preferably be sudden in order to rapidly lead to the elimination of the initial substrate. The preferred method of oxidation is thermal oxidation which causes calcination of the substrate. In the case, for example, of polyester substrates, in particular fibrous, the oxidation can be carried out in an oxidizing atmosphere in an oven brought to a temperature of about 300 to 350 C.

When the initial substrate is thus removed, the metal current collector which has been previously produced, retains the apparent structure of the substrate but without the skeleton formed by it remaining. O 'essential advantage which one draws from this technique is the disappearance or quasi-disappearance by weight of the initial substrate, which makes it possible to achieve, for example for nickel or cadmium electrodes, a gain of approximately 10 to 15 $ of specific capacity compared to the nickel or cadmium electrodes produced according to the main patent, ie without removing the substrate after formation of the collector. A secondary advantage lies in the fact that the adhesion of the active material the electrode on the collector is increased due to the higher porosity of the collector
Such a treatment is particularly recommended when the material composing the initial porous substrate, whether organic or mineral, is likely not to have perfect physicochemical stability in the electrolytic medium in which the electrode, once produced, will be intended to operate. Thus, for example, porous substrates based in particular on polyesters may advantageously other thermally oxidized when the electrode is called upon to operate in basic medium.

 Finally, this addition certificate brings a final improvement to the main patent, which touches on the mechanical qualities of the current collector.

 Once the metal deposits intended to constitute the collector have been produced, the latter exhibits, particularly when it is essentially constituted of nickel electrodeposited from a nickel bath based on sulphate, a very high rigidity which can constitute a discomfort for its subsequent manipulations, whether it involves depositing the active electrode material, shaping or positioning within an electrolytic cell. In fact, this high rigidity removes all flexibility from the collector and therefore from the electrode and constitutes a cause of fragility.

 To overcome this possible drawback, and according to one of the improvements to the main patent, which are the subject of this certificate of addition, it is possible to carry out on the collector once produced, an operation of annealing the metallic deposits. The effect of such an operation is to give the collector greater flexibility and consequently to considerably reduce the risks of rupture of this structure. In the case of a collector essentially made of nickel, for example, the annealing operation may other than be carried out in a neutral or reducing atmosphere in an oven brought to about 8500 C for a period close to one hour.

 Naturally, and as it moreover largely follows from the above, the invention is not limited neither to the exemplary embodiments nor to the methods of obtaining which have been described, but embraces all the variants.

Claims (10)

 REEDICATIONS  I - Electrode structure according to the first claim of French patent application No. 79.17540, characterized in that the substrate consists of an inorganic or organic material (carbon or graphite, celluloses, polyesters, polyamides, etc.) of which the porous or fibrous texture is such that the ratio between the developed surface and the apparent surface is large, the size of the pores or interstices being all the more important the greater the thickness.  2 - Electrode structure according to the first claim of French patent application No. 79.17540 and claim I of this certificate of addition, characterized in that the essential part of the collector is produced by depositing nickel electrochemically preceded by a copper deposit.  3 - Electrode structure according to the first claim of French patent application No. 79.17540 and claims I and 2 of this certificate of addition, characterized in that the essential part of the collector is produced by ddp8t of nickel electrochemically preceded by a first deposit of copper obtained by chemical means.  4 - Electrode structure according to the first claim of French patent application No. 79.17540 and the claim I of this certificate of addition, characterized in that the current collector is formed on the initial substrate by a deposit of electrochemical nickel preceded by a first departure of chemical copper reinforced by a second deposit of copper carried out electrochemically.  5 - Electrode structure according to the first claim of French patent application No. 79.17540 and claim I of this certificate of addition, characterized in that the current collector is formed on the initial substrate by deposition of chemical copper reinforced by an electrochemical copper deposit.  6 - Electrode structure according to the first claim of French patent application no 79.I7540 and the claim I of this certificate of addition, characterized in that the current collector is formed on the initial porous substrate by a first spite of chemical nickel followed by a deposit of electrochemical copper.  7 - electrode structure according to the first claim of French patent application no 79.I7540 and claim I of this certificate of addition, characterized in that the current reader neck is formed on the initial porous substrate by the realization a first deposit of chemical nickel, a deposit of electrochemical copper and finally a deposit of electrochemical nickel.  8 - electrode structure according to the first claim of French patent application no. 79.17540 and any one of claims I, 2, 3, 4, 5, 6, of this certificate of addition, characterized in that the initial porous substrate, once the current collector has been made by metallization, is thermally oxidized in order to obtain its elimination.  9 - electrode structure according to the first claim of French patent application no 79.I7540 and any one of claims I, 2, 3, 4, 7, 8, of this certificate of addition, characterized in that an electrode based on nickel oxide or hydroxide is produced by electrochemical formation of the active material on the current collector.  10 - electrode structure according to the first claim of the French patent application no 79.17540 and any one of claims I, 2, 3, 4, 5, 6, 7, 8, of this certificate of addition, characterized in what a cadmium electrode is made by electrochemical deposition of cadmium, the active material of the electrode, on the current collector.  Il - Electrode structure according to the first claim of French patent application no 79.il540 and any one of claims I, 2, 3, 4, 5, 6, 7, 8, ga IO, of this certificate d addition, characterized in that, once the current collector has been produced, an annealing operation is carried out on the metallic deposit or deposits constituting it.