HU204937B - Zinc electrode construction for silver-zinc chemical supply source - Google Patents

Abstract

Zinc electrode assembly for silver-zinc chemical electricity sources comprises a metallic outlet lead (1) a separator (2) enveloping the assembly and a zinc active cpd. (3) inbetween (1) and (2). Cpd. (3) is impregnable or is impregnated by electrolyte. - The electrode assembly also contains a fibrous, thin, flexible sheet-like structure (4) prepd. from cellulose, cellulose derived fibres or synthetic fibres pref. of polyamide, P/P, PVC or PTFE or a mixt. of these. This structure (4) situated between (1) and (2) traverses at least half of the cross section of the ionic current developing between (1) and (2). The structure is either impregnated or impregnable by electrolyte and at least one of its surfaces is in contact with the electrode's active zinc cpd. (3). (-pp Dwg.No.1/1)

Description

FIELD OF THE INVENTION The present invention relates to a zinc electrode structure for silver-zinc chemical power sources having a metal outlet, an electrolyte impregnated or impregnated zinc active agent 5 disposed between the separator and the terminal and the separator.

During the operation of zinc-silver chemical power sources, the structure and density of the zinc electrode undergoes significant changes, and the specific volume of the electrode material in the charged and discharged state differs significantly. This effect is enhanced by the partial solubility of the electrode material in the electrolyte. In the case of batteries, the zinc electrode material is rearranged during the charge and discharge cycles, because the zinc released into solution during discharge is deposited elsewhere during charging. Taking into account that, in order to avoid gas evolution in hermetically sealed chemical power sources, the zinc active ingredient used as an anode is about 1% of the nominal charge to be marketed. double electrochemical equivalent, it becomes clear that only half of the amount of zinc in the charge-discharge cycles is circulated, primarily at the electrode side in contact with the separator.

As a result of these two effects, the non-circulating portion of the electrode material of the anode 25 is asymmetrically passivated, and when excess zinc is required during operation, it is no longer able to do so, and the cell capacity is reduced. During cell operation, probably due to the anode material being restructured, the distribution of the electrolyte becomes uneven, distant from the separator, so near the outlet, the electrolyte content is reduced and the passivated zinc is also concentrated there. The degree of ionic conductivity between the surface 35 of the terminating metal and the material of the anode is reduced, which is also reflected in an increase in internal resistance. As the material of the zinc electrode rearranges, the density of the material becomes uneven and dangerous needle-like dendritic crystals are formed which, in extreme cases, puncture the separator and thereby destroy the cell.

There are many known solutions for forming zinc electrodes in zinc-silver chemical power sources. Several variants of zinc electrode design are disclosed in U.S. Pat. HU patent specification. In the process described therein, the reduction in the activity of the zinc active ingredient during use and storage is reduced by uniformly adding to the zinc or zinc compound feedstock 1 a short proportion of short filamentous fibrous additive, in particular cellulose. I will. The addition of high-absorbency fibrous substrate s improved the contact between the electrolyte and the zinc particles r, which in turn favorably influenced the electrical parameters of the chemical power source r and enabled longer cycle life b for batteries prior to prior art. . e

The presence of v short, absorbent, fibrous additives could not substantially alter the development of the above-described adverse events, and the rearrangement of the zinc active agent also occurred at such chemical sources. No. 156,047, incorporated herein by reference. Since the filing of the patent, substantial changes have been made in the design of the chemical power sources for zinc silver, which primarily concerned the training of the separatum system with a Modem zinc silver battery. HU patent.

The fact that due to the above mentioned properties of the zinc electrode, even in the case of an excess of zinc, the life of the zinc-silver batteries is limited by the properties of the zinc electrode, is well illustrated in the Proceedings of the Hungarian Academy of Sciences. 47, (1973), also published in a summary article by two inventors of the present invention: "Silver (I) oxide (Ag ₂ O) phase sealed silver-zinc battery".

In the case of primary power sources, the problem is the uneven distribution of the electrolyte, which is primarily due to the reduced value of the removable capacity relative to the chemical capacity.

No. 2,422,046, Issue 2 U.S. Pat. No. 5,123,115 discloses a dry alkaline primary power source containing a zinc foil electrode material, wherein the effective excess of the anode electrode is increased by applying the film to an electrolyte impregnated thin support sheet and then winding the structure. The oxide cathode used as a depolarizer is located at one end of the winding and is separated by a separator ¹ perpendicular to the axis. In all cases, the ion flow is in the direction parallel to the sheet plane of the zinc film, the role of the electrolyte impregnated paper involved in the winding is to separate the opposite zinc surfaces and to hold the electrolyte. The effective surface area of the zinc electrode structure thus formed is substantially smaller than that of the porous structure and cannot be used to provide rechargeable power sources (batteries).

SUMMARY OF THE INVENTION It is an object of the present invention to provide a zinc electrode structure for zinc-silver chemical power sources in which the rearrangement and passivation of the zinc electrode is substantially reduced compared to prior art solutions.

It was discovered that the addition of electrolyte-wetted fibrous material was not able to exert its beneficial effect permanently because the short, discrete fibers followed the rearrangement of the electrode material and initially became uneven during use.

When a zinc electrode is prepared using a sheet-like structure for fixing the zinc drug, the fibers of which are resistant to both the zinc drug and the alkaline, usually potassium hydroxide electrolyte, and can be wetted by the electrolyte, its texture can prevent the zinc electrode from rearranging. ensuring that the electrode material is in uniform contact with the electrolyte, which prevents passivation of the electrode material. The fibers may be made of natural fibrous material, e.g. cellulose and cellu2

EN 204 937 Β of horsehair; suitable plastic fibers such as polyamide, polypropylene, polyvinyl chloride, Teflon and / or a mixture of these materials,

The absorbent properties of the material used as the backbone structure are particularly advantageous if it has a non-woven, non-woven, non-woven structure, that is to say made of non-woven, knitted or other textile materials whose filaments are loosely joined to one another.

The shape of this plate-like structure is suitably adapted to the geometry of the electrode, so that in the case of a tapered or disk-shaped outlet with a truncated cone, the structure is disc-shaped. The sheet-like structure is preferably thin with a maximum thickness of up to half the thickness of the zinc active ingredient.

The plate-like structure thus made can be located anywhere in the structure of the zinc electrode, i.e. near or at the outlet or the separator. From the manufacturing point of view, it is advantageous for the plate-like structure to be located directly at the outlet and to press the electrode active agent, such as zinc powder, in this state. In this case, it is preferable for the plate-like structure to cross the entire ion flow cross-section.

For long-term operation, it is advantageous to soak the fibrous material in the electrolyte before saturation.

In a preferred embodiment, the outlet is formed by a plurality of curved wires surrounded by zinc on all sides, and the plate-like structure surrounds the surface defined by the wire on one or two sides. In this case, it may be sufficient if the plate-like structure crosses only half of the ion flow cross-section.

The resulting structure of interconnected fibers is organically incorporated with the active substance during electrode operation and, due to its hydrophilic properties, plays an important role in retaining the electrolyte. This property allows the removable capacity to be closer to the electrochemically determined peak when used in primary power sources. The use of the present invention does not preclude the use of metallic power distributors, conductors, and additives in the zinc active ingredient in a manner known per se.

The construction of the electrode according to the invention will now be described by way of example only, with reference to the drawing. The drawing shows:

Figure 1 is an enlarged sectional view of a button battery incorporating a first embodiment of the zinc electrode assembly of the present invention;

Fig. 2 is a sectional view similar to Fig. 1 illustrating a second embodiment, a

Figure 3 is a sectional view similar to Figure 1 illustrating a third embodiment, a

Figure 4 is a schematic front view of an electrode assembly having a wire terminal and

Figure 5 is a side view of the electrode assembly of Figure 4, partially in section along the line V-V of the figure.

1-3. Figures 1 to 5 show the structure of a zinc electrode of three embodiments of silver-zinc button batteries. The battery housing of the button battery has two pan-shaped halves, of which the drawing shows only a representative detail of the negative terminal (1). The interior of the outlet (1) is closed by a separator (2) consisting of a plurality of thin separator plates arranged on top of each other, for example cellulose.

The defined space between terminal (1) and separator (2) is filled by the zinc active ingredient of the zinc electrode (3). The zinc active ingredient (3) is a known zinc paste impregnated with an electrolyte.

In order to prevent zinc migration, a thin, flexible (4) sheet-like structure of fibers is disposed inside the zinc electrode. The three similar embodiments differ in the position of the plate-like structure (4).

The plate-like structure (4) is formed, in this case, by a sheet of 0.5 mm thick felted cellulosic fibrous material, the size of which fits into the inner surface of the slightly pan-shaped outlet (1). The plate-like structure (4) was soaked in potassium hydroxide for about 30 minutes before being placed and then applied to the inner surface of the outlet (1) to give the shape shown in Figure 1.

Subsequently, the zinc drug (zinc paste) (3) is pressed into the pan-shaped inner part of the outlet (1). The thickness of the formed drug layer varied from 1 to 4 mm depending on the depth of the outlet (1). As a result of the compression force, the zinc paste was uniformly filled between the fibers forming the sheet-like structure (4). The button battery is then assembled in a known manner.

In a second embodiment, the plate-like structure (4) is made of an electrolyte-saturated disc of this size, but the zinc agent (3) has been pressed to the inner surface of the outlet (1) and then pressed externally to the surface of the plastic electrode. The pressure was maintained until the disk, i.e. the plate-like structure (4), was completely immersed in the electrode material. The separator (2) is fitted to the surface of the disc (3) which is opposed to the zinc active ingredient. This zinc electrode structure is shown in Figure 2. The button battery is now ready for use.

In a third embodiment (Fig. 3), a portion of the zinc active ingredient (3) was pressed into the interior of the outlet (1) as outlined in Fig. 2, whereupon the plate-like structure (4) was placed and the remaining zinc active ingredient was pressed and finally the separator (2) was placed. The button battery is now ready for use.

The structure of the zinc electrode shown in Figures 4 and 5 differs in that of Figures 1-3. 1 to 4, the outlet (1) is formed by an outlet wire, the end of which, after being bent in S or V shape, is surrounded on both sides by a plate-like structure (4). The zinc active ingredient (3) is an extruded zinc powder mixture which can be compressed and the outlet (1) and the plate-like structure (4) around it are located inside the compressed electrode (3). The separator (2) completely surrounds the structure. The battery is then assembled in a known manner.

The batteries thus obtained are characterized in that their charge storage capacity is significantly smaller and decreases as the number of unrelated batteries with zinc electrodes containing only short cellulose fibers increases with the number of cycles.

Disassembling the battery operated over several charge-discharge cycles, we found that the electrode material distribution was uniform and no passive "islands" were encountered. This proves that the felted material from the cabbage Tim zinc solution produces crystalline nodules of excellent zinc during charging, thereby providing good distribution and inhibiting passivation and dendritic formation. Due to its good hydrophilic properties, the skeletal material facilitates the electrolyte supply within the electrode and thus uniform ion conductivity. Due to this feature, high capacity was measured when used in a primary power source.

Benefits include longer life, better amperage for batteries, and a slight reduction in capacity with the number of charge / discharge cycles.

Claims (7)

PATENT CLAIMS 1. A zinc electrode structure for chemical sources of silver-zinc, having a metal terminal, a metal separator and a zinc active agent impregnated with or between the terminal and the electrolyte impregnated between the terminal and the separator, characterized in that it is derived from cellulose, cellulose derivatives or comprising a thin flexible sheet-like structure (4) of fibers made of polypropylene, polyvinyl chloride, teflon and / or a mixture of these materials, which crosses at least half of the ion flow cross section between the outlet (1) and the separator (2) and passes through the electrolyte or at least one of its surfaces is in contact with the active ingredient (3) of the electrode zinc. Zinc electrode assembly according to claim 1, characterized in that the plate-like structure (4) consists of disordered filaments. Zinc electrode structure according to claim 1 or 2, characterized in that the plate-like structure (4) is located directly on the inner surface of the outlet (1). A zinc electrode structure according to claim 1 or 2, characterized in that the plate-like structure (4) is located on the side of the electrode facing the separator (2). The zinc electrode structure according to claim 1 or 2, characterized in that the plate-like structure (4) is located centrally between the outlet (I) and the separator (2). 6. Zinc electrode structure according to any one of claims 1 to 3, characterized in that the flexible plate-like structure (4) crosses the entire ion flow cross-section. The zinc electrode assembly according to claim 1 or 2, characterized in that the outlet (1) is formed by a plurality of bended wires surrounded on each side by the zinc agent (3), and the plate-like structure (4) is formed by a surface defined by the wire. or surrounded by two sides.