DE2321842C3 - Electrochemical cell - Google Patents

Description

The invention relates to an electrochemical cell with a metal housing forming a pole of the cell, with an upper closure part for the housing, which forms the other pole of the cell, with a first sealing insulator, with a second sealing insulator having an elasticity higher than that of the first sealing insulator, with a gas ventilation device, and a metal housing enclosing plastic jacket.

Such an electrochemical cell is known from DE-O.S 16 71421. With this well-known During the electrochemical cell, the first sealing insulator is made of a relatively hard plastic the second sealing insulator is made of a relatively plastic material. Between the two Insulators are located on an inner electrode

3 »external flange formed by the isolator a relatively hard plastic is supported. The second insulator made of a soft plastic is used as a seal for the metal housing of the cell that forms the outer electrode.

^ From DE-OS 20 08 727 a device for sealing the electrodes of electrolytic cells is also known, which has two insulators designed in the form of sealing rings with different hardness, of which the insulator with the

«Ο less hardness due to the pressure of the seal rests closely on the electrode and the housing part carrying the electrode and thereby the inner gas space seals tightly, while the harder insulator transfers the sealing pressure from a pressure ring to the softer one Insulator transmits, giving the electrode a firm hold and a secure position. The pressure ring distributes the pressure force evenly on the insulators, thereby spreading the electrode evenly to press.

In the practical use of electrochemical cells, it is desirable that the cells im are liquid- and gas-tight during normal operation, while in the event of unusual gas development in the cells and a resulting overpressure, the resulting gas is released.

The object underlying the invention is to provide an electrochemical cell of the initially mentioned type so that the gas ventilation device and thus the entire cell one have a simple structure.

This object is achieved according to the invention by the features of the characterizing part of the claim 1 solved.

Preferred developments of the invention are

^ Subject of claims 2 to 6.

In the following, preferred exemplary embodiments of the invention are explained in more detail with reference to the drawing

F i g. 1 shows in a vertical sectional view an alkaline cell as an embodiment of the invention electrochemical cell.

F i g. FIG. 2 shows, in an enlarged sectional view, the upper peripheral area of the cell shown in FIG. 1.

3 shows an enlarged sectional view the same area that is shown in Fig.2, where however, a gas venting passage is formed between the housing and a sealing insulator.

F i g. 4 shows in an enlarged sectional view upper peripheral area of a further embodiment of the cell according to the invention.

FIG. 5 shows in an enlarged sectional view the same area that is shown in FIG. 4 is shown, where a gas ventilation passage is formed between the housing and a sealing insulator.

According to FIG. 1, an alkaline cell as a first embodiment of the invention has a cylindrical, nickel-plated metal case 1, which is open at its upper end, an annular cathode 2, which is shown in Contact with the inner surface of the housing 1 contained in the housing 1, an annular separator 3, a gel anode 4 and 4 contained in the central portion of the housing within the annular separator 3 a rail-shaped current collector 5 made of brass, which is partially in the anode 4 along the axis of the Cell protrudes. The cathode 2 is formed by using a binder such as carboxymethyl cellulose, polyvinyl alcohol or sodium polyacrylic acid or sodium polyacrylate, a mixture of manganese dioxide and grr.phit is admitted. The separator 3 is made of a vinyl plate or of wrapped, layered vinyl and cotton sheets. The Gelanodc 4 consists of a mixture of zinc powder, potassium hydroxide, Water and carboxymethyl cellulose. At the bottom of the metal housing 1 is to receive the lower end the anode 4 a plate-shaped part 6 is arranged, which consists of a plate, for example made of polyethylene, Polypropylene or nylon, or made of a woven or non-woven material. At the The lower outer surface of the metal housing is a cap-shaped pole piece 7 with the aid of spot welding appropriate.

The open end of the housing is through a first sealing insulator 8, a metallic, plate-shaped, upper closure part 9 and a second sealing insulator 10 closed. The first sealing insulator 8 has a cylindrical, central portion which the current collector 5 penetrates and is through a Spot welding attached to the upper closure part 9. So that the upper closure part 9 forms the anode of the Cell. The cylindrical portion of the first sealing insulator 8 is through a cap 11 from a pressed tin plate against the rail-shaped current collector 5.

As is shown in detail in FIG. 2, the metal housing 1 comprises, as a continuation of a cylindrical main body, a first, inwardly bent section la, a second » ^1, outwardly bent section Xb and a d: \ .. cn, inwardly bent , Open End Portions Ic The first and second bent portions Xa and Xb define an annular indentation on the upper portion of the housing 1.

The first sealing insulator 8 is enclosed between the plate-shaped, upper closure part 9 and the second, finely curved section Xb , which supports the lower annular surface of the sealing insulator 8. The first sealing insulator S consists of a molded plastic such as polyethylene, polypropylene or Nylon.

The second sealing insulator 10 is between the third, inwardly bent, open end portion Ic and the edge portion of the upper closure part 9 included. The second sealing insulator 10 is preferably made of a rubber material such as

ίο natural rubber or synthetic rubber and has a Elasticity higher than that of the first sealing insulator 8. However, if nylon for the first sealing insulator 8 is related, a second sealing insulator 10 made of polyethylene or polypropylene be used.

Both insulators are pressed through the third, open end section Xc against the second, curved section of the housing.

An annular gap 12 is delimited and formed by the upper, circumferential edge of the first sealing insulator 8, the lower peripheral surface of the second sealing insulator 10 and the inner surface of the second, curved section Xb of the housing 1. In connection with the annular intermediate space 12, a number of gas ventilation openings 13 are formed through the housing 1. The gas ventilation opening 13 can consist of a single opening which is connected to the annular intermediate space 12.

Inside the housing 1 below the first curved section la is a metallic reinforcing ring 14 is provided, which simplifies the formation of the curved portions of the housing and is made safer.

js The metal case 1 is heat-shrunk from a Vinyl jacket or tube 15 except for the lower, central portion of the housing. on which the cathode pole piece 7 protrudes.

Between the vinyl pipe 15 and the metal housing I, a cylindrical paper 16 is provided, which consists of the gas ventilation opening 13 absorbs outflowing alkali electrolyte.

The heat-shrunk vinyl tube 15 preferably consists of a gas-permeable, but liquid-tight Plastic material and is at one end to the upper Endabschnittl Ic of the housing or the second sealing insulator 10 by an adhesive such as polyvinyl chloride resin, or by a Weld tightly connected.

so in order to increase the gas tightness of the cell in the normal state, the curved sections of the Housings, which are in contact with the first sealing insulator 8, with a liquid sealing material, coated with fat, paraffin, wax or the like.

During the operation of this alkaline cell, which is an embodiment of the present invention, the cell is usually kept liquid-tight and gas-tight, since the first and second sealing insulators 8 and 10 and the edge portion of the upper closure part 9 through the third, open end Ic of the housing 1 pressed against the second bent portion Xb. However, when the internal pressure of the cell abnormally increases due to gas evolution in the cell, the first sealing insulator 8 and the upper closure member are pushed up to compress the elastic second sealing insulator 10. A gap develops accordingly

or a gas venting passage 17 between the first sealing insulator 8 and the second bent portion ibdes housing 1, which is in communication with the annular space 12, as shown in Figure 3, so that the gas in the cell through the space ¹ 17 and the annular gap 12 flows and is discharged from the housing 1 through the gas vent 13 to the outside.

When the internal pressure of the cell falls to the normal value, take the upper plug 9 and the The first sealing insulator 8 regains its normal position as a result of the elasticity of the second sealing insulator 10 a, whereby the cell is kept liquid-tight and gas-tight.

Since the second sealing insulator 10 has an elasticity higher than that of the first sealing Is insulator 8, the gas ventilation during this embodiment of the cell according to the invention abnormal development of gas in the cell and reinsertion of the sealing insulators in theirs normal, sealing state after the gas has been released reliably and without disturbance.

Since, in addition, the annular space 12 in connection with the gas ventilation opening 13 is formed, the gas is when the gap 17 is partially between the first sealing insulator 8 and the second bent portion Ibdes housing 1 is formed, effectively drained out of the housing.

Even if alkali electrolyte is passed through the gas vent 13 together with the discharged gas is drained from the cell to the outside, the escaped alkali electrolyte is directed to the cathode side, this path being long enough for the alkali electrolyte to leak out of the vinyl tube 15 to avoid.

Investigations have shown that the cells in which a heat-shrunk vinyl tube on a End is glued to the second sealing insulator with a polyvinyl chloride adhesive, and at the Cells in which the heat-shrunk vinyl tube is attached at one end to the second sealing insulator is welded, alkali electrolyte leakage never occurred when the cells are below a temperature of 77 ° C with an electrical resistance of 1 Ω for six months.

In the second embodiment of the invention shown in Figure 4 and 5 extends a

ίο first, inwardly curved section la 'almost in the horizontal and radial direction of the cell and a second, outwardly curved section Ib' is folded back at the inner end of the first curved section and stored over it. The first and second bent portions la 'and \ b' extending inside the cell are longer than the first and second bent portions la and Xb of the first embodiment. An annular gap 12 is formed between the lower, circumferential edge of the first sealing insulator 8 'and the inner surface of the second, curved section Xb' of the housing. Gas ventilation openings 13 'are formed through the second curved portion Xb' in connection with the annular space 12 '. The remaining structure is essentially the same as that of the first embodiment.

In the second embodiment of the cell according to the invention, the first and second curved sections 1 a 'and Ift' have greater elasticity than the corresponding sections of the first embodiment, so that both sealing insulators 8 and 10 are pressed together much more strongly with a higher sealing effect. In addition, since the first and second bent portions la 'and Xb' extend relatively far into the interior of the cell, the gas and the alkali electrolyte developed in the cell have to travel a relatively long distance, with the result that the sealing effect against the Alkali electrolyte is far better

1 sheet of drawings

Claims (6)

Patent claims: 1. Electrochemical cell with a, one pole of the cell forming metal housing, with an upper closure part for the housing, which forms the other pole of the cell, with a first sealing insulator, with a second sealing insulator, which has an elasticity higher than that of the first sealing insulator is provided with a gas venting means, and a metal housing enclosing plastic sheath, characterized GEK e η η ζ calibration η et, that the metal housing (1,1 ') zh continuation of a cylindrical main body has a first, inwardly bent portion (la . la '), a second, outwardly curved section (Xb, Xb') and a third, inwardly curved, open end section (Xc, Xc ') , the first and the second curved section having an annular indentation at the upper section determine this housing, this first sealing insulator (8, 8 ') between this second curved section of the housing and this upper closure part (9,9') is enclosed, this second sealing insulator (10, 10 ') is enclosed between this third, inwardly bent, open end portion and an edge portion of the upper closure part, these first and second insulators through the third, open end portion of the housing against the second, bent portion of the housing are pressed, and that this gas venting device has at least one gas vent opening (13, 13 ') which is formed by the second, bent portion of this housing adjacent to the circumferential surface of the first, sealing insulator, with an abnormal increase in the internal pressure this cell, as a result of gas evolution in this cell, this first sealing insulator (8,8 ') and the upper closure part (9, 9') are pressed upwards so that this second sealing insulator (10, 10 ') is compressed, whereby a gap or gas ventilation passage (17) between this first sealing insulator and this second bent portion (Xb, Xb ') d' \ eses housing forms so that the gas can be discharged to the outside through this gas vent. 2. Electrochemical cell according to claim 1, characterized in that an annular Interstice (12, 12 ') along the edge of the first, sealing insulator (8, 8') in connection is formed with the gas vent opening (13, 13 '). 3. Electrochemical cell according to claim 1 or 2, characterized in that the first and the second curved section (Xa ', Xb') of the housing (X ') extend almost in the horizontal and radial directions of the cell, and the second, outward curved section [Xb ') is folded back at the inner end of the first curved section (Xa') and is supported over this. 4. Electrochemical cell according to claim 1, 2 or 3, characterized in that the plastic jacket (15, 15 ') is a heat-shrunk plastic tube that is sealed at its end to the second Is insulator (10, 10 ') glued with the help of a polyvinyl chloride adhesive. 5. Electrochemical cell according to claim 1. 2 or 3, characterized in that the plastic jacket (15, 15 ') is a heat-shrunk plastic tube is, the liquid-tight at its one end by a weld with the second, sealing Isolator (10,10 ') is connected 6. Electrochemical cell according to one or more of the preceding claims, characterized characterized in that the second sealing insulator (10,10 ') is made of a rubber material.