SE442565B - Multicellular lead accumulator with electrode block of zigzag-shaped collapsed band electrodes as well as process for making the accumulator - Google Patents

Description

7808102-3 More rational work techniques have only been introduced in the so-called the small accumulators, which were previously still predestined for mass production. This includes the often used equipment of both alkaline small accumulators and small lead cells with winding electrode sets. In these, a positive and a negative electrode band are rolled together between a separator and an electrode wrap which is inserted into the cell container. The edges of the electrodes are provided with current arresters for drawing through the container. Due to the complicated nature of the bushings for the current arresters, such winding electrode sets are generally used only for single-cell accumulators. .

Even with the electrode plates, a clear trend towards the replacement of the heavy mass carriers, ie. the cast lead grids, with lighter load-bearing structures such as expanded metals. Expanded metals can also be manufactured as an endless belt.

Electrode plates made on expanded metal base only, as laid on stacks in the usual way, are inserted into the upwardly open block vessels, whereby these must be provided with lids in the usual way, still does not mean radical progress for a flexible working process.

According to US-PS 3,844,841, a more convenient aggregation of accumulator cells into compact cell blocks has been sought to be achieved in such a way that an arbitrary number of cells are connected to each other and thereby in each case refraining from the end wall of the individual cell. The interconnection is made possible by a slight cup-like extension of the side walls of a cell, the side walls with the widened edge engaging over the side walls of the subsequent neighboring cell placed with the same orientation. However, the connection obtained becomes problematic in terms of the electrolyte density of the housing and a faultless electrical contact.

The invention is therefore based on the problem of providing a lead-acid accumulator which in a better way than before satisfies the requirement for a rational mass production.

An additional problem is to develop a manufacturing procedure for such an accumulator. 7808102-3 The problem has been solved in that the adjacent cells are electrically connected by means of one of the electrode support frames of one of the band electrodes, which is passed as a wide band through the cell partition and that the closure of the block vessel is formed by a side wall.

In a preferred embodiment of the accumulator according to the invention, each plate block belonging to a cell consists of a package of zigzag-folded positive and negative band electrodes with an intermediate band-shaped separator.

Both the connection of the cells to each other and the external electrical connection are effected by means of parts of one of the two electrode support frames carried by a wide band.

These parts lie at the same time in the sealing plane of the block vessel, which by means of a side wall is liquid-tight closed by mirror welding.

The object of the invention and the method for its manufacture will be described in more detail with reference to the drawing, in which Fig. 1 shows the object of the invention from above and Fig. 2 a perspective view of a two-cell accumulator block box open at the front, the figure also being intended to illustrate the procedure.

According to the invention, the block vessel 1 is filled with an electrode set consisting of a strip electrode 12, a strip electrode 13 and an intermediate separator strip 4 with ribs or struts 5.

These are zigzagged in the form of packages and are inserted in packages from the side into the accumulator cells. The folding edges 6 of the electrode package are perpendicular to the bearing surface of the accumulator so that gas bubbles between the electrode can rise unhindered.

According to the invention, both the connection of the cells to each other and the current diversion outwards are effected by means of wide bands 9 of the electrode support frame of one band electrode passed over the cell partition cell 7 and end walls 8, respectively.

In the figures, for example, the outer electrical connections 16 and 17 are formed by the electrode support 2 of the strip electrode 12, while the connection between the cells is made by the electrode support 3 of the strip electrode 13. However, the electrode strip in question can also be wound over a lead pin and leading connection with this by, for example, press welding.

From this pin, a pole passage can take place in a known manner.

The motel electrode and separator are interrupted in the transition areas between the cells.

For the production of a zigzag-shaped pleated electrode package according to the invention for a multicellular accumulator, the starting point is preferably as endless belts wound on rollers 10, 11, electrode support frames 2, 3, which have the shape of an ordinary grid frame of lead and can also consist of lead stretch pine, each electrode band possibly having a continuous brace at the edge. In these electrode support frames a unit mass is pasted as active material. This is advantageous as the finished strip electrodes in battery operation change polarity from cell to cell. The electrode support frames 2, 3 thus merge into the band electrodes 12, 13.

During the interposition of a highly porous, but pressure-sensitive insensitive separator strip 4, which is unwound from a roll 14, the electrode strips then merge over a break roll 15 and can then be folded.

Immediately before the folding procedure, the areas 9 of the strip electrodes 12 and 13 and the separator 4 are cut out, which after insertion into the block vessel would have passed over one of the walls 7 or 8 and are superfluous there (except for the transition over a partition in in each case the required electrode support frame).

The active mass can be removed by blowing out, rinsing or possibly also by leaving a corresponding part of the electrode body free of pasteurized mass already during the pasteurization.

For the completion of the accumulator, all that remains now is to close the housing, which can be done surprisingly easily by welding a side wall 18 according to a mirror welding method known per se. By heat action, the plastic penetrates both in the cell partition wall 7 and end walls 8 as well as the corresponding continuations 19 and 20 in the side wall 18, respectively, of the electrode body so that a solid and liquid-tight connection is obtained. Prior to this welding of a lid, it may be even- _., A .._._._....._..._ ..,. , .. __.........._.-. _. ......_.._...___. -i _ _.-.._ .., ....- 7808102-3 it is expedient to press the electrode body against the partition wall by means of a stamp and in this step of the process possibly also to carry out an additional heating, in order to already have a some penetration of the electrode body into the edge of the cell partition 7 must be achieved before the final welding of the cover.

The usual filling and degassing openings are then placed on the upper side of the block vessel, which in the figure coincide with the image plane.

Parallel to this is also the plane of the electrolyte level, while the sealing plane, denoted by the line A-A, is perpendicular to the electrolyte level.

The necessary end pole connections of such an accumulator can be formed inside or outside the cell of the protruding part of the electrode body by compressing and, for example, welding on an end pole.

It is obvious that the usual procedure steps hardening, forming, preserving (eg by treatment with boric acid) With regard to the continuity of the manufacturing process, it is particularly advantageous if the steps after insertion of the electrode package into the block vessel can be carried out outside the block vessel. carried in this.

The advantage of the described accumulator lies in the fact that its manufacturing process has a particularly favorable material flow.

Claims (9)

7808102-3 PATENT REQUIREMENTS A multicellular lead-acid accumulator with electrode blocks of zigzag-shaped positive and negative band electrodes (12,13) folded into a package, each containing an electrode support and with an intermediate separator (4), characterized in that the adjacent cells are electrically connected by means of one of the electrode support bodies of the band electrodes (12, 13), which is passed as a wide band through the cell partition (7), and that the closure of the block vessel is formed by a side wall (18). A multicellular lead-acid battery according to claim 1, characterized in that the electrode support frames (2,3) are formed of endless expanded metal strips. A multicellular lead-acid battery according to claim 1 or 2, characterized in that the band ends of the electrode packets are electron-likely connected to pin-shaped lead rods, e.g. by winding and press welding and that these pins form the basis for the pole bushing. Multicellular lead-acid battery according to Claims 1 to 5, characterized in that the outer electrical connections (16, 17) are formed by the large-surface electrode support (2 or 3) of the electrode support (2 or 3) passed through the block walls (1) in each particular case only one of the band electrodes (12 and 13, respectively). A method of manufacturing a multicellular accumulator, in which electrode blocks of positive and negative band electrodes with intermediate separators are zigzaggedly folded into a package and a block vessel is inserted through side openings therein, characterized in that the electrode carrier body which in shape of a wide band is intended to pass through a cell partition or the end wall (8) of the block vessel (1), is provided with corresponding divided areas, which are free from active mass, that the parallel corresponding sections of the counter electrode and the separator are completely removed and that the side openings of the block vessel (1) are then sealed in a liquid-tight manner by welding on a side wall (18). 7808102-3 6. A method according to claim 5, characterized in that the sealing is performed by means of mirror welding and that before the welding operation one of the strip electrodes free from the active mass of the active electrode carrier body is easily pressed into the cell partition or end wall. 7. A method according to claim 6, characterized in that the area of the electrode carrier body for pressing is heated before the pressing operation. 8. A method according to any one of claims 5-7, characterized in that the electrode carrier bodies are treated with a unit paste. 9. A method according to any one of claims 5-8, characterized in that the strip electrodes are formed in the closed bio-vessel.