DE2452544A1 - DOTTED SUBSTRATE FOR PRESSED BATTERY PLATES - Google Patents

Description

Dr. Horst SchUler kW ^19? *

Patent attorney

6 Frankfurt / Main 1

2797-56-BA-3237

GENERAL ELECTRIC COMPANY

1 River Road
See ectady, NY / USA

Dotted substrate for pressed battery plates

The present invention relates to improved electrochemical cells or batteries, and more particularly to an electrochemical cell with a new material for use as a current collecting substrate, to support the active material in a pasted or pressed plate construction.

A cell plate or electrode in an electrochemical cell is composed of a substrate made of thin sheet-like material Material with a layer of active material on each side. This can be done in a so-called "pasted" panel construction active material smeared on the substrate or by others known methods are applied. Usually, the active material is applied in paste form with a doctor blade.

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applied lubricates, or by calendering, so that the paste is distributed evenly over the surface of the substrate, the electrochemically in the charge and the cell active Fntladungszyklen be Soll ₀

Stretched metal and woven screens or nets of electrically conductive Material are examples of known substrate materials for pasted plates. The choice between the different substrate constructions is guided by the fact that the composition of the active material has a tendency to be due to to separate the vibrations occurring during manufacture or use from the substrate Changes during the charge and discharge cycles after a long period of time Used to cause the composition to separate from the substrate. For this reason, wire mesh and expanded metal materials are almost uniform in the pressed panel construction industry been used for substrate constructions "

A commercially available form of these materials are wide sheets. But since most cell plates have at least a small Dimensions, the wide sheets must be cut into strips, which leads to an unprocessed edge part, which is defined by the sharp ends of the severed mesh wires or expanded metal segments. These constructions have been found to be unsuitable as the raw edge further complicates the treatment of the cell, especially by it penetrates the separator and causes an electrical short circuit between the cell plates.

To date there is no known solution to the problems that caused by the raw edge construction when using stretched metal materials.

With regard to the mesh wire construction, these problems are due to the special manufacture of the screen in narrow strips with a Selvedge, i.e. that which runs parallel to the narrow dimension

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Wires are woven from a continuous strand so that the edge of the strip through loop portions of the single strand has been formed, has been resolved. However, this construction leads to that the cost of the screen is very high. Further, if a wire with a small diameter is used, the mesh will break, light and can cause a short between the plates, an open circuit, or an increase in impedance. In addition, the small diameter of the wires naturally leads to a substrate with a relatively high impedance «

It is therefore an object of the present invention to provide a new one and to provide improved electrochemical cells. This cell is said to further feature a new and improved substrate design have a surface to which the active material easily adheres. After all, the substrate construction should be reliable, be more solid and economical, as well as a lower electrical Have resistance.

These objects are achieved by the invention in that a Electronic cell is provided which comprises a plate formed from an electrically conductive, perforated substrate with raised surfaces is constructed with a layer of pasted active material adhered to each surface.

These and other objects of the present invention are set out below explained in more detail with reference to the drawing. Show in detail:

Figure 1A is a fragmentary perspective view of a substrate for a pasted electrode according to the present invention Invention,

Figure 1 B shows a cross section of the substrate along the line 1 B - 1 B of Figure 1 A,

FIG. 2 shows a cross section, partially broken away, of a battery with an electrode, which has a substrate according to FIG

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452544

Figure 1 has, and

Figure 3 is a cross section of another embodiment of a Battery ^ in which a pasted electrode with a substrate according to FIG. 1 can be installed «,

In the figures IA and IB an engineered substrate of the present invention is generally designated by 1 "denotes the for" this substrate material used is preferably perforated nickel or nickel-plated steel having a thickness of about O ₉ OS to 0.1 mm (corresponding to 2 ■ = 4/1000 inch) ,, The major surfaces 3 and 5 of the substrate have been completely bumped or bulged with any available conventional means, not shown, such as are typically used for corrugating or embossing thick metallic materials create adjacent elevations 4 at a distance of about 1 mm (corresponding to 4/100 inch) from one another that the recess 9 of one of the elevations in a main surface adjacent to the protruding part 2 of another elevation The elevation 2 and the depression 9 are offset from one another in such a way that the material does not have a preferred side _o D _o h _o that the arrangement of the elevations is introduced so that the main surfaces 3 and 5 are interchangeable in terms of their operating properties according to the present invention _o '

According to a further feature of the present induction, perforations 6 are present in the main surfaces 3 and 5 of the substrate. The main surfaces have edge parts 7 and 8 which remain imperforate. While not critical, the

2 2

Perforations have an area of about 3 mm (corresponding to 5000 mils) and are spaced about 2.8 mm (corresponding to 11/100 inch) be arranged. You can use any conventional method

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drive to be introduced into the substrate. Because the respective distances of the perforations 6 and the elevations 4 are different, the perforations 6 penetrate the elevations 4 at different ones Make over the main surfaces.

The substrate 1 acts as a conductive support for the composition used, which contains the electrochemically active material that

or together with the substrate it forms the plates of a cell ^ battery. Because of the nature of the composition or paste, it has heretofore been observed that the paste does not readily adhere to some substrates adheres. According to the present invention, the substrate 1 is arranged with perforations 6 and closely spaced from one another Elevations 4 are provided in the main surfaces 3 and 5, which greatly improves the adhesion of the paste to the substrate leads. Furthermore, the paste adheres equally well to the major surfaces 3 and 5 of the substrate 1, since the substrate does not have a preferred side. This allows cells to be made with a more uniform quality and, in particular, a longer service life.

Although the dimensions mentioned are preferred for the substrate and the perforations as well as the elevations in the substrate and enhance the adhesion of a sufficiently large amount of paste, these dimensions can be varied within the scope of the present invention .

The paste is composed of an active material and binders for as is known in this field. A suitable binder is aB. Teflon. After making the paste can are spread on the substrate 1 with a doctor blade by calendering or in any other known manner, so that the paste over the major surface areas of the substrate, which is electrochemical in the charge and discharge cycles of the cell should be active, is evenly distributed. Other known methods of evenly distributing the paste can also be used be applied.

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A plate having a substrate according to the present invention avoids many problems _s associated with the known constructions, particularly the wire mesh substrate _o In particular, the plates erf indungsgemäßeia solid and have a smaller electrical resistance than the known en Platt. One of the most important advantages of a plate with a substrate according to the present invention is that it is more economical than a substrate made from a wire mesh.

In applying the present invention to specific cell or battery constructions of known conventional configurations may be used any "Thus, the flat-plate construction and the spiral plate construction as in the figures or 2" 3 are shown _o

In Figure 2, a rechargeable "is sealed _s secondary battery 10 is shown to illustrate diejParallelplatten-Kons'truktion. The cell 10 has a housing 11 which comprises a container part 12 which is open at the top and which has a generally rectangular configuration and which can be made of electrically insulating material or of metal, as shown. The open upper part of the housing part 12 is sealed by a cover which can be made of electrically insulating material or metal. The cover 13 carries a positive terminal 14 and a negative terminal 15; The connections 14 and 15 have conductive sections 16 and 17 which extend through the cover

13 extend down into the container and connect strips

as

18 and 19 have. Since the cover 13 "is shown consisting of metal the structure of the terminals includes an electrically insulating gasket 20 between the cover 13 and each terminal

14 and 15 on.

A negative plate 21 comprises the substrate 2 to which a connecting strip 22 is connected in a suitable manner. A positive plate 23 comprises the substrate 2 with a suitable one Connecting strips 24 attached in a manner. The substrates 2

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the negative and positive plates are with a paste composition 30 coated that is applied to each side, like described above. The connecting strips 22 and 24 are connected to the strips 18 and 19 by any conventional method. The separator 25 is made of a suitable, chemically inert material, such as an unwoven nylon fabric is placed between adjacent panels. The separator 25 is preferably in the form of a strip and is around the stack of plates wrapped to hold the separator material in place between the plates. A suitable electrolyte such as potassium hydroxide is filled in the separator and thereby an electrolytic connection is established between the negative plates 21 and the positive plates 23 made. A binding tape 26 off electrically insulating material is preferably used to keep the plates and separator within the minimum volume keep. A two-piece, electrically insulated plastic cell liner 27 surrounds the plate, separator material, and binding tape, thereby making these components into a compact arrangement and are electrically isolated from the metal housing 12. When the housing part is made electrically is made of insulating material, such a plastic lining can of course be omitted. A ventilation cap 29 closes the opening 28 and thereby creates a sealed one or non-ventilated cell.

A spiral plate construction is illustrated in FIG. The battery has an electrically conductive housing 40 that the forms a connection of the cell. A winding spindle 41 made of insulating material is mounted inside the cell and they has a four-layer assembly spirally wound thereon consisting of a first layer 42, the negative plate, a second layer 43, a porous insulating separator, a third layer 44, a positive plate and a fourth Layer 45, a porous insulating separator. The positive and negative plates include as in the flat plate construction FIG. 2 shows a substrate 2 with an active material

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containing paste 55 applied to each side of the substrate is. To prevent short-circuiting between the edges of the plates and the cell housing, annular insulating disks 46 and 47 are provided. The negative plate 42 is through the line 48 is connected to the cell housing 40. An insulating element is used to create a negative cell connection attached by crimping to the upper end of the conductive housing. The positive terminal 50 is by means of the line 51 with the positive plate 44 connected. An opening 52 is provided in the insulating member to any conventional one To be able to fill electrolytes into the cell. The opening is provided with a plug 53, as shown. The electrolyte is drawn between the plates by capillary action of the porous insulating spacers. Excess electrolyte fills the Bottom of the housing and can move upwards into the winding spindle extend to a height of 54.

The batteries shown in Figures 2 and 3 preferably comprise rechargeable nickel cadmium secondary cells. Such a The cell in its discharged state has a negative plate comprising cadmium hydroxide as an active material which is mixed with the paste composition to be applied to the substrate 1 and a positive plate serving as the active material bivalent nickel hydroxide included with the paste composition is mixed and attached to the substrate 1 in a similar manner. They are natural within the scope of the present invention other active materials can also be used.

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Claims (8)

Claims 1. A substrate material for a plate structure for an electrolytic cell comprising a relatively thin conductive sheet having opposite major surfaces, wherein the sheet metal has a series of perforations and the surfaces an arrangement of at a short distance from one another has embossed elevations. 2. Substrate according to claim 1, characterized in that a paste substantially covers the surfaces of the sheet, the paste being an active one Includes material and a binder. 3. Substrate according to claim 2, characterized in that there are two opposite edge parts that are free of perforations. 4. Electrolytic cell with a housing and arranged therein a positive plate, a negative plate and a separator between the positive and negative plates, as well an electrolyte filling part of the housing, characterized in that at least one of the plates comprises a thin conductive sheet with opposite major surfaces which acts as a substrate and includes an array of perforations, the surface having a series of closely spaced press-fit bumps and an active paste material substantially covering the surfaces of the sheet. 5. Cell according to claim 4, characterized in that each of the perforations has an area 2 2 of about 3 mm (corresponding to 5000 thousandths of an inch), 509820/1005 • - 10 - 6. Cell according to claim 4 _9, characterized in that the sheet metal consists of 'nickel-plated steel era. 7. Cell according to claim 4, characterized in that the sheet consists of nickel. 8. Cell according to claim 4, characterized that the sheet is 0.05 to 0.1 mm (corresponding to 2/1000 - 4/1000 inches) thick. 509820/1005