DE3220727A1 - Method of producing a battery - Google Patents

Abstract

In a method of producing a flat cell having a zinc anode, an alkaline electrolyte and a cathode in the form of a brown haematite/carbon briquette (1) which is in contact with a metal closure (2), the brown haematite/carbon briquette is mounted on the negative metal closure (2) as a result of a clamping action along two oppositely situated edges of the metal closure which are bent over. This provides a satisfactory contact between the brown haematite/carbon briquette (1) and the metal closure (2) and at the same time a battery comprising a plurality of flat cells is suitable for mass production since the brown haematite/carbon briquette (1) can be pushed in from the side along two oppositely situated bent-over edges of the closure plate (2). The closure plate (2) has only to be bent over through slightly more than 90 DEG . <IMAGE>

Description

Method of manufacturing a battery

The invention relates to a method for manufacturing a battery from stacked flat cells with a zinc anode, an alkaline electrolyte and a cathode in the form of a brown iron stone carbon briquette, which is connected to a Metal termination is in contact.

The known 9V batteries with a height of approximately 40 mm have a Number of relatively long and narrow cylindrical bodies. These Bodies are relatively difficult to manufacture, i.e. that the cassation percentage is relatively high. Furthermore, a large part of the volume is not used, and one is bound in terms of dimensions.

Therefore, one now uses flat cells that are stacked on top of one another, See e.g. German patent application No. P 29 45 996. 9-45. This results in a 28% better utilization of the volume achieved. Each cell is in a plastic tray encapsulated. However, there is a particular problem with creating a satisfactory one Contact between the brown iron stone -Carbon briquette (the Cathode mass) and the relevant metal termination.

According to the invention it is shown how to easily create a satisfactory contact between the brown iron stone carbon briquette and the metal termination can bring about, and this object is achieved according to the invention by that the brown iron stone carbon briquette at the negative metal termination by a Clearing action along the edges of the metal termination, preferably along two opposing edges Edges, is attached. This makes the battery suitable for mass production at the same time, because the brown iron stone carbon briquette is then from the side of, along two opposite edges bent over, the end plate can be pushed in. The end plate only needs to be a little, preferably 1-3 °, over 900 along two opposing edges be bent over.

About the lateral insertion of the brown iron stone carbon briquettes To facilitate this, these briquettes can advantageously be rounded at the corners.

Since the brown iron stone carbon briquettes must be able to expand, when inserted, they are approximately 0.06-0.08 mm narrower than the metal termination.

The invention is explained in more detail below with reference to the drawing. It shows Fig. 1 part of a battery, one through a bushing to a metal finish that is covered with a brown iron stone carbon briquette in Contact is, and Figure 2 is the metal termination.

The alkaline battery shown in Fig. 1 has a number of stacked flat cells. Each cell has a zinc anode, an alkaline one Electrolyte and a cathode in the form of a brown iron stone carbon briquettes 1 on. The brown iron stone carbon briquette is 2 in. With a metal finish Contact. However, there must be a satisfactory contact between the brown iron stone carbon briquette 1 and the metal termination 2 are created, since this contact is the short-circuit current certainly. When using a square end with bends along all of them four edges will bend these bends outward and the contact will not sufficient. According to the invention, a bent piece of metal, see FIG. 2, with Bends applied along two opposite edges, which bends Turn inwards about 1-3 °. This ensures a sufficiently good clamping of the brown iron stone carbon briquette 1 reached. Degree 2 must of course be made of a suitably resilient material, such as nickel-plated iron. In this A short-circuit current of 3-5 A is achieved. The earlier round cells were not at all afflicted with this problem, since the electrode mass in question was introduced under pressure and thereby brought about the necessary contact. Here one took advantage of the fact that the cylindrical body was able to hold the relevant one Taking pressure without breaking the contact.

The method according to the invention is also suitable for mass production, because the closure body is symmetrical, and the brown iron stone carbon briquettes can be inserted from the side if only the corners are rounded.

The termination is optionally provided with a further bend 4, wherein a certain amount of contact with the floor surface is also achieved. The briquettes show a width that is approximately 0.06-0.08 mm smaller than the termination by allowing for will that the briquettes a little as a result of the release of tension when adding expand of electrolyte. According to a particular embodiment, the termination a height of 2.7 mm, a length of 17.5 mm and a width of 13.08 mm. the Material thickness is about 0.1-0.3mm.

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Claims (6)

Claims: 1. Method for producing a battery from on another stacked flat cells with a zinc anode, an alkaline electrolyte and a cathode in the form of a brown iron stone carbon briquette, which is connected to a Metal termination is in contact, by the fact that the brown iron stone carbon briquette (1) on the negative metal termination (2) by a clamping effect along the edges of the Metal termination, preferably along two opposing edges, attached will. 2. The method according to claim 1, characterized in that g e k e n n -z e i c h n e t that the metal termination (2) is a little over 900 along two opposing edges is bent. 3 The method according to claim 2, characterized in that it is indicated that the termination (2) along the two opposite edges 1-3 ° inwards is bent. 4. The method according to the preceding claims 1 to 3, g e k e n n z e i c h n e t by another bend (4) of approximately 900. 5. The method according to the preceding claims 1 to 4, through this it is not noted that the brown iron stone carbon briquettes (1) are a a little narrower than the metal termination (2) and rounded at the corners. 6. The method according to claim 5, characterized in that g e k e n n -z e i c h n e t that the brown iron stone carbon briquettes (1) 0.06-0.08 mm narrower than the Metal closure (2) are.