DE1004690B - Filling stack battery - Google Patents

Description

The invention relates to a filling battery. This is understood to mean batteries in which the electrolyte does not take effect on the associated components until certain operations have been carried out are.

The aim of the invention is to create a light battery that is simple, inexpensive and economical and is capable of producing longer-lasting currents even after prolonged storage after activation to give off relatively great strength at both high and low temperatures.

For such filling batteries to work properly, it is essential that adjacent cells are against each other are sealed, but they must remain open at the top and bottom so that the electrolyte solution can enter can. A large number of cell partitions have already been proposed for this purpose, however, all of which have disadvantages, whether in terms of sealing and weight or in terms of the convenience and cheapness of mass production. One of the last developed partitions, is a continuous zigzag strip that is passed between adjacent cells therefore particularly unsatisfactory, since the continuous strip is difficult to assemble is handled and provides a termination only on one side of each cell, so that it is necessary to provide a frame and a thick layer of adhesive to seal the second side of each cell. The invention avoids these difficulties by using individual partitions, the protruding Have side parts that overlap and adjoin the side parts of the next adjacent cell or cells are held in place by means of a retaining strap.

The invention will now be explained in more detail with reference to the drawing showing it, for example, namely shows

Fig. 1 is a plan view of a filling battery according to the invention, with part of the cover of the battery housing shown broken away to reveal the open sides of the cells,

FIG. 2 shows a section along the section line 2-2 in FIG. 1,

Fig. 3 is a diagrammatic representation of the individual components, in an exploded state, a complete Form cell, as well as part of an adjacent cell of a high voltage Battery capable of transmitting an anode voltage to an electron discharge tube,

Fig. 4 is a diagrammatic representation of the positive terminal components and the insulation head pieces on the one end of an anode battery, which components are in surface contact with one another during final assembly to be brought,

Filling stack battery

Applicant:

Ray-O-Vac Company, Madison,
Wis. (V. St. A.)

Representative: Dipl.-Ing. E. Schubert, patent attorney,
Siegen (Westphalia), Oranienstr. 14th

Claimed priority:
V. St. v. America September 28, 1951

Lee John Lockwood, Wonewoc, Wis. (V. St. A.),
has been named as the inventor

FIG. 5 shows a representation similar to that of FIG. 4 for the negative terminal components;

6 shows a three-dimensional representation of a stack of cells which are assembled to form an anode battery are,

7 shows a section along the section line 7-7 in FIG. 1,

8 shows a plan view of the cells of an anode battery, in which the overlapping of the sides of the resilient partitions between the cells and her Closure is illustrated on the wrapping non-conductive tape,

Fig. 9 in a spatial representation some of the components, in exploded form, from which one Low-voltage battery or heating battery is to be produced, which is used to heat the filament of an electron discharge tube serves while

Fig. 10 shows a three-dimensional representation of a heating battery which has two sections, one of which provides a relatively lower voltage.

As can be seen from Fig. 1, a battery pack 10 consists of a heating battery 11 and an anode battery 12, the latter being composed of three stacks 12 ', 12 "and 12"', with the two batteries are connected to each other by a band 13 and within a covered with a Cardboard or paper housing 14 sit. The heating battery 11 and the three stacks 12 ', 12 "and 12'" of the anode battery are kept separated by insulating body 23 (Fig. 1 and 2) made of electrolyte-resistant plastic.

3 to 8 show an anode battery stack in different representations, both in not assembled as well as in the assembled state. The individual cells of each stack are

609 840/182

according to the invention by appropriate non-conductive flexible partitions 25 separated from one another. The partition walls 25 are formed as rectangular sheets and consist of polyvinyl chloride, polyvinylidene chloride, polyethylene or chlorinated rubber.

Each partition 25 holds a relatively small negative electrode 26 and one in its center positive electrode 27, with electrodes 26 and tight (Figs. 4 and 5) against opposite sides of the

are both long and arduous and the undesired leakage of the electrolyte in more effective Way is prevented. On the other hand, the top and bottom sides of the partition walls 25 protrude considerably 5 and under the electrolyte disk 29 out.

A particularly useful positive power connection for a stack of series-connected To create cells of an anode battery, a copper plate 36 (Fig. 4) between the at the end of the stack

Partition wall 25 are pressed, by means of a io positive electrode 38 and the adjacent insulating electrical conductive bracket 28, which is inserted through 30 stripes through it. This copper plate 36, which is leads. Each negative electrode 26 is a thin, right-hand contact with the positive electrode 38 angular magnesium plate, while each has positive elec- tric and a soldered wire 37, it makes trode 27 a rectangular bronze grid or sieve superfluous that the coating of the grid electrode body is. The grid electrodes 27 can be removed with a 15 38 what a corresponding Be-Cuprochloridpaste be overdone, as this will result in the battery having a negative impact on the functioning of the battery is described below. would have. The corresponding negative connection

The bracket 28, which serve the neighboring (Fig. 5) for a cell stack consists of a wire To connect cells in series, and preferably from 40, which is attached to the negative end plate 39 by means of two Bronze exist are in firm contact with 20 bronze brackets 28 and a soldering point 41 is attached. the associated negative electrodes 26 and the connection point is covered with an insulating, positive grid electrodes 27 to voltage fluctuating water-resistant varnish coating, which at 24 to keep the effects as small as possible. A suitable one is indicated.

insulating, water-resistant paint coating 24 and the heating battery section 11 of the battery pack,

24 '(Figs. 4 and 5) is best seen in Figs. 9 and 10 on each bracket after the 25 is something Assembly applied to a chemical one larger than any of the anode battery stacks, but im effect on the bracket during operation of the essentially built in the same way. There Battery to prevent. however, the battery 11 has much larger dimensions

After a number of sets of the components 25, have been stacked together an insulating tape 48 at their central part 26 and 27, they are fixed 30 in such a way that their insulating end strips are bridged with a corresponding number of rectangular 47, creating a particularly solid gel electrolyte adsorbing discs 29 assembled. velvet association is created. The battery 11 is divided into The disks 29 consist of a substance that has two sections A and A ', whose current from the two electrolytes after the battery is started to positive drainage wires 49 and 50, which is capable of adsorbing. A particularly useful electrically scratched or exposed section of the outer positrolyte-adsorbing substance is an electrolyte-resistant tive electrode that is soldered on, and of which

Cellulosic material. Each assembled cell thus consists of a positive electrode 27 (or 27 '), an electrolyte adsorbing disk 29 (or 29 ') with the adsorbed electrolyte and a negative one Electrode 26 (or 26 '). The neighboring cells are separated from each other by the partitions 25 (or 25 ') completed and are connected to one another in series via the bracket 28 (or 28 ').

seed negative current dissipation wire 51, which is connected to a negative electrode at the point shown in FIG is riveted, can be removed.

As mentioned earlier, the positive grid electrodes are both of the heater and anode batteries coated with a cuprous chloride paste. This paste is, for both battery parts, with the help made of a polystyrene solution z. B. how

As Fig. 6 shows, a stiff insulating strip at 45 is composed as follows: 831 g polystyrene, 101.1 g each end of a cell stack provided, and the chlorinated bi-phenyl, 39.75 g bi-hexyl-sodium-sulfo overall assembly is in A resilient, electrosuccinate, 1721 cm ⁸ toluene, 115 cm ⁸ benzene, trolyte-resistant, non-conductive tape31 is wrapped. Chlorinated bi-phenyl includes chlorinated aromatic

The band 31, the inner surface of which is to be understood with an electrolytic hydrocarbons, bi-hexyl-resistant Non-conductive adhesive is coated, 50 Sodium Sulphosuccinate is a well known cleaning agent not just the stacked cells together, but medium.

dern also lays the protruding edges of the separating When this solution is used, the paste settles

walls 25 firmly in a bent position in order to be effective for the positive electrode of the anode battery such as ensure the same seal between the cells. follows together: 75.31% cuprous chloride, 23.20% poly-one Passing the electrolyte from cell to cell, and 55 styrene solution, 1.49% cadmium chloride. thus short-circuiting, the paste for the positive electrode of the heating

battery is essentially the same as that for the anode battery, except that soot is added to greatly improve the voltage rise after activating the battery. One Particularly useful heating battery paste is composed as follows: 71.7% cuprous chloride, 21.7% polystyrene solution, 4.7% cadmium chloride, 2% carbon black.

As can be seen from FIGS. 1 and 2, the

Partition 25 for the cell 32 up to point α in the 65 different subsections of the filling battery electrically close to the cell 34, that is, two cells away from the cell can be switched in any desired manner. The 32. In a corresponding manner extend the edges of current lead wires will summarized in a cable 19 Zuder partition 25 "for the next cell 33 to that at the top of a slot 18 to a point b in the vicinity of a cell 35, also part of the paper casing 14 exits and is removed from one cell in two so that the connecting paths 70 lead speaking connector 54. In the housing 14

prevents, while at the same time the top and bottom sides of the cells remain open, so that an activating Electrolyte introduced and the excess can be removed.

The overlapping of the various partitions 25 according to the invention is shown in Fig. 6 and more clearly can be seen from FIG. 8. As can be seen from Fig. 8, the bent edges of the extend

Claims (11)

the respective battery part sections stand at the bottom on the foot parts of the insulating end pieces 30 and 47, which in turn rest on a base plate 16 which is adapted to the housing 14 and provided with recesses 17. The battery can be activated with natural water such as seawater; however, in the exemplary embodiment described, it is expedient to use pure water for this purpose. The water is poured through a recess 21 in the cover 15 of the housing 14 and, after pouring, spreads over a flat intermediate body 20 which sits on the underside of the cover 14, as indicated at 15 '. The intermediate body 20 contains salts, such as for example cadmium chloride, which go into solution and form an electrolyte when the water seeps through. In this way, the battery is filled with the electrolyte up to a level which is determined by the recesses 22 (FIG. 1) in the upper part of the housing 14. ao The electrolyte is then adsorbed by the disks 29, making them conductive. After about 3 minutes, the excess water is poured out of the opening 22 and suitable measures are taken to ensure that all excess water is removed so that the open areas of the cells are not bridged. The battery is then electrically connected to a normal load for 15 minutes, after which it is ready for use. In addition to the various embodiments described above, the salts for the activation can already be contained in the adsorption disks 29, but they can also be located in an intermediate strip of salt which lies against the disks 29. The battery can also be designed without a container, the activation being effected in that the battery is immersed in the activation liquid or in that the liquid is poured over it. Even if the above-described embodiment of the invention relates to a magnesium cuprochloride cell, it can also be used in other cell types, for example in magnesium-silver chloride or zinc cuprochloride cells. The battery described above is particularly suitable for supplying current and voltage for meteorological devices, since it has small dimensions and a low weight. According to one exemplary embodiment, a battery designed according to the invention is only 125 mm long, 113 mm wide and 62 mm high. The dry weight of this battery is 357 g, the weight after activation is only 572 g. This relatively low weight is largely a result of the use of the thin plastic partitions 25 with which the lap seal type of the invention is used. Γ A TE N T A N S P R C C H E: 1. Filling stack battery with a number of Cells that are stacked flat together and supported by a number of resilient, insulating, electrolyte-resistant Partition walls are kept separate from each other, which are provided between adjacent cells are, characterized in that the partitions (25) along the edges of opposite one another Sides are bent at right angles and at least the corresponding part of the partition for the next neighboring cell overlap in such a way that a sealing connection between these two partitions is made, advantageously the upper and lower edges of the Partition walls protrude above and below the cells and these in open, unsealed State for the purpose of supplying and withdrawing the activation liquid are maintained. 2. Battery according to claim 1, characterized in that the edges of the partition walls in one Overlap sealing position by a tape (31) wound around the battery made of flexible, insulating, electrolyte-resistant material are held. 3. Battery according to claim 2, characterized in that the wrapped tape on the overlapped partitions is held by means of an insulating, electrolyte-resistant adhesive. 4. Battery according to one of claims 1 to 3, characterized in that the flat cells and the partitions are rectangular in shape and the two overlapping edges of each Partition wall extend at least to the next but one cell. 5. Battery according to one of claims 1 to 4, characterized in that the negative electrode each cell is made of magnesium, while the positive electrode is a grid body is formed and coated with a paste containing cuprochloride. 6. Battery according to claim 5, characterized in that the grid body is in the form of a Bronze mesh or lattice formed and coated with the dried solid end product of a paste which is composed of a polystyrene solution, cuprous chloride, cadmium chloride and Soot. 7. Battery according to one of claims 1 to 6, characterized in that the positive pole is one each cell stack consists of a metallic plate provided with a connecting wire, the is in frontal contact with the positive grid electrode. 8. Battery according to one of claims 1 to 7, characterized in that the battery of one Housing (14) is surrounded, which absorb and retain the liquid for the activation of the cells can. 9. Battery according to claim 8, characterized in that a flat one under the cover Intermediate body (20) is connected to the housing, which contains activating substances, which by Water will be dissolved in the housing to form the liquid for activating the Battery is poured. 10. Battery according to claim 9, characterized in that the intermediate body is cadmium chloride contains. 11. Battery according to one of claims 1 to 10, characterized in that a heating battery and an anode battery are housed in the same case. Documents considered: German Patent No. 462 522; British Patent Nos. 549 036, 558 207; U.S. Patent Nos. 2,307,766, 2,416,576. 1 sheet of drawings © 609 840/182 3.57