DE3103534A1 - Plastic battery housing - Google Patents

Abstract

A battery housing, which is produced as an integral injection-moulded part, for accommodating galvanic elements, which can be stacked in the form of a column, especially button cells, is formed from two half shells which can be folded together and are connected to one another via a flexible film hinge. A contact spring which is guided over the outer wall of one half shell allows two columns which are arranged in parallel to be connected in series, while further contact elements connect the first and last cell in the overall fit of cells to the positive terminal and negative terminal at the ends of the battery housing. When they are folded together, the half shells are closed by means of a self-locking snap closure, in that the closure elements (14, 15, cf. Figure) engage in the closure opening (18) and lock the barbs (17). <IMAGE>

Description

Plastic battery case

The invention relates to a one-piece battery housing Made of plastic with two collapsible housing halves to accommodate several galvanic elements, in particular of button cells, and those used to conduct electricity required connection contacts.

Small portable devices with their own power supply for the well-known Areas of application in entertainment technology as well as cameras, dictation machines, computers require multi-cell compact batteries with integrated contact elements for electrical Connection of the individual cells used and also the contact connections for insertion the battery in the device. Essential consideration in the manufacture of modern Multi-cell batteries of the smallest dimensions are the use of non-conductive format stable Plastic housing with the smallest possible strip thickness for accommodating large useful primary cell volumes with active electrode materials and a resulting high energy density.

Furthermore, a rational assembly of the battery is taken into account simple, functionally reliable joining operations for the introduction of the individual cells, their electrical series connection with each other, the assembly of the battery connection contacts including an indissoluble housing lock to avoid function-disruptive contact lockerunv gen required. Taking into account international standards for dimensions of multi-cell batteries it is for the purpose of space-saving arrangements of the individual galvanic Cells, preferably from button cells mentioned above, are required, the same in one or to arrange several prismatic stacks.

From DE-PS 21 33 656 a multi-cell battery is known which the end consists of a two-part, electrically non-conductive housing.

There are recesses in the housing for receiving in series with one another switchable primary elements provided. The primary elements are at an oblique angle in With respect to the longitudinal axis of the housing and arranged parallel to one another. The two Housing halves can be molded as a unit including a joint from the start be.

In order to ensure that the mold halves fit together exactly when the cassette is closed to ensure that the covering mold half is out of the connecting plane with itself vertically extending retaining pins which fit into the retaining holes of the other Half-shell fit. In order to make contact with the primary elements, these are partially with Contact strips materially connected.

According to the arrangement described, the proportionate proves to be disadvantageous Complex assembly by centering using its own housing pins and retaining holes. The joint connecting the two mold halves must be within a certain range Be flexible within the tolerance range. Also leaves the oblique angle in relation to the housing axis Arrangement of the primary elements does not lead to an optimal energy density. After assembly the two halves of the mold must be inseparable from one another by means of a welding or gluing operation get connected.

The invention is based on the object of a housing for a multi-cell battery to develop that in a simple way with galvanic cells and their contact elements to be equipped and inexpensive to assemble.

The object is achieved in that the two housing shells over a flexible film hinge and are collapsible by a self-locking Snap lock are lockable.

The cylindrical single cells are in one or more cavities stacked in a columnar shape. The bending axis of the elastic film hinge runs parallel to the axis of the columnar cell stack. For a functionally reliable and cost-effective Adjustment and after completion of the cell assembly permanent lock of the battery housing contain the housing shells on the outer edge in the area of the Parting line each element of a self-locking snap lock.

In an alternative embodiment, the two end faces are the housing shells connected by means of a film hinge in the longitudinal axis as elements of a self-locking non-removable snap lock formed.

The following is the subject of the innovation with reference to FIGS to 10 explained in more detail.

Figure 1a shows the front-inside view in the open ready for assembly Battery case of the version provided with two stacking columns.

Figure Ib shows in section A-B according to Figure 1a, the opened housing.

In Figure 2, the side view is shown in longitudinal section.

Figure 3 shows the top view of the opened battery housing.

Figure 4 shows the rear view of the battery housing.

This is still incomplete in a perspective view in FIG closed housing with a view of the molded locking barbs and the they are shown receiving lid openings.

FIG. 6 shows a section of the barb that is engaged one of the two locking elements.

Figure 7 shows the front interior view in the open ready for assembly Battery housing of the version provided with only one stacking column.

In Figure 8, the side view is shown.

FIG. 9 shows the top view of the opened battery housing.

The self-locking snap lock is shown in FIGS. 10a and 10b this cell explained in more detail.

According to Figure 1a, the battery housing consists of the housing shells 2 and 3, which are articulated to one another via a hinge 1. In the Mold shells 2, 3 produced in an injection molding process together with the film hinge 1 thus a single plastic injection-molded part. The housing shell 2 contains two adjacent Cavities which are separated from one another by an intermediate web 4.

As a counterpart to this intermediate web, the housing part 3 contains in the center of its inside is one that runs from the top to the bottom Lead 5.

Inside the two cavities are the cylindrical galvanic Cells 6 housed in the form of a columnar stack arrangement. For current dissipation the top cell in the left cavity is pressed against a contact element 9, which a is led out through a housing slot and here for example forms the positive pole. To simplify assembly, it is possible to use the contact element 9 to be firmly connected to the top left cell. The formal design of the Half-shells with the intermediate webs 4 and 5 allow the assembly of the primary cells 6 in two parallel columns in series. The two front sides 7 and 8 of the half-shell 2 take the positive contact 9 and the negative contact 10 of the battery on. The arranged on the back of half-shell 2 contact spring 11 with the In the cavities protruding flags 12 and 13 takes over the series connection of the parallel arranged button cells and at the same time provides the frictional connection due to the spring action represent. At the edge of the right half-shell 3, the closure elements 14 and 15 are arranged, which in the recesses 18 of the left half-shell that can be seen in FIG. 1b 2 can intervene.

Spacer elements can be placed on the sides opposite the contact elements be arranged to adapt the voltage to the respective application purpose. In a In the preferred embodiment, the spacer elements are firmly connected to the housing; so they are produced together with the housing in one injection molding process. To the Series connection is used by the contact spring already described above, which both cell stacks press together if a series connection of all cells is desired. However, it is it is also possible to connect both cell stacks in parallel if necessary.

The lower cell in the right cavity is provided with a contact spring 10 connected, which also guided like the upper contact spring 9 through the housing is and serves as the pole of the battery housing. As galvanic cells are preferred Alkali / manganese type button cells are used. With 15 cells, for example Voltages of 22 to 23 volts can be achieved. An exact adaptation to the required Tension is possible by enlarging or reducing the spacer elements.

In Figure Ib is the inside view of the end face 7 with the positive Contact 9 and the flag 12 of the contact spring 11 shown, which for the negative Pole 10 leads. In the section is one of the two fastening pins 16 for fastening the contact spring 11 and the web-shaped formations 4 and 5 of the half-shells 2 and 3 can be seen.

Furthermore, one of the two closure elements 14/15 is integrally formed with the Barbs 17 and one of the two locking openings 18 are shown.

The upper and lower edge of the housing part 3 is reinforced and provides thus represents part of the housing cover or housing base after the closing process. On the left side edge of the housing part 2 is provided with recesses 18 into which when closing the barbs attached to the side edge of the other housing part 2 14.15 engage immovably in the area of the parting line. This snap lock also serves to adjust the individual cells when the two are folded together Housing parts. By engaging the Housing parts firmly enough connected, so that neither gluing nor thermal welding processes are required.

According to FIG. 1a, there are, for example, 14 cells in the two cavities housed. This results in a discharge voltage of 21 volts. Through the use of spacer elements the battery voltages can be between the cells and one end of the housing be adapted to the respective purpose. It is also possible during the Manufacturing process by changing the cores in the injection molding tool, the height of the spacer elements to adapt to the respective purpose.

In Figure 2 is the longitudinal section through that shown in Figure 1a opened housing shown. The two breakthroughs 19, 20 can be seen here, which are used to carry out the end contacts 12,13.

The closure elements 14 and 15 can also be seen.

Figure 3 shows a plan view of the battery contact 9 on the housing half 2 as well as the flexible hinge 1 and the housing half 3.

In Figure 4, the rear view of the opened housing is shown.

The lead-through openings 19, 20 through which the end contacts 12, 13 of the contact spring attached to the rear of the housing 11 are attached. The two pins 16 are used for fastening.

FIG. 5 shows the battery housing immediately before it is closed The closure elements 14,15 are designed so that they are in the closure openings 18 engage and lock the barbs 17.

The cells 6 can be seen within the cavities. The top cell 6 in the right cavity is firmly connected to the contact element 9.

To simplify assembly, it is possible to use the individual cells to be provided with concentric hollow cylinders, which on the end pole of each adjacent cell can be attached. All cells then form a continuous, mechanically and electrically connected, columnar cell stacks.

FIG. 6 shows the positioning of the barbs 17 in cross section in the closed battery housing with the two molded on half-shell 3 closure elements and the locking elements 14, 15 which are in engagement in half-shell 2.

In Figure 7 is a two-part battery case with a single Cavity is shown, which contains the cells 6 stacked in the form of a column. the cells resting on the two end faces are each provided with contact strips 9 and 10, which form the end terminals of the battery.

FIG. 8 shows a side view of the one already equipped with the cells 6 Battery part 2. The battery shown in this example contains ten primary batteries alkaline button cells, which give a discharge voltage of approx. 15 volts. To the The end poles 9 and 10 are used to draw power. Their design corresponds to the one based on the arrangements described in FIGS. 1a and 1b.

In Figure 9 is a lateral cross section of the to Figures 7 and 8 described battery housing shown. The two housing halves are 2,3 connected to one another by the flexible film hinge 1.

After equipping with the cells 6, the housing half 3 is on the Housing half 2 folded and then by self-locking locking elements locked.

According to the cross section in FIG. 10a, the in Figure 10b shown closure elements 21 and 22. These closure elements are provided with barbs 23, which enable a self-locking closing process, so that the battery housing can no longer be opened without the use of force after assembly is.

The described embodiments combine the advantages of saving space render the thinnest housing walls, as they are otherwise only possible with extruded hose designs are possible with the dimensionally stable, dimensionally stable and assembly-friendly component design of thermoplastic injection molded parts, with a simultaneous non-detachable fog connection of Battery housing without additional adhesive, welding or other thermal joining processes.

The battery housings are usually made of polypropylene, polyamide or other thermoplastics with sufficient resistance.

The ready-for-sale equipment of the multi-cell battery can be used as required either by means of known printing processes, e.g. screen printing, directly on the outside of the two housing shells.

The application of multicolored prints can also be done using labels, E.g. self-adhesive labels, which are applied as a band or by means of several blanks the housing shells are applied.

If necessary, the fully assembled battery can also use a plastic tube printed in one or more colors can be coated and shrunk. Also the combination with additionally printed metal envelopes, which on both The ends can be crimped, but for reasons of price with the proposed Plastic housing design with the non-detachable joint connection is not necessary.

Primary galvanic button cells of the silver oxide type are preferred used. However, it is also possible to use other cells, e.g.

Provide mercury oxide or rechargeable cells.

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Claims (6)

One-piece battery housing made of plastic with two collapsible housing halves to accommodate several gal vanic Elements and the connection contacts required for current dissipation, characterized in that that the two housing shells (2,3) can be folded together via a flexible film hinge (1) are and can be closed by a self-locking snap lock (14,15). 2. Battery housing according to claim 1, characterized in that at least a housing half (2,3) at least two adjacent cavities for receiving contains columnar stacked cylindrical galvanic elements (6) and that a contact element (11) is arranged outside the cavities, the end contacts of which (12,13) engage in the cavities. 3. Battery housing according to claim 1, characterized in that at least a housing half (2, 3) has a cavity for accommodating columnar stacked galvanic Has elements (6). 4. Battery case according to claim 3, characterized in that each Housing half (2,3) each half a hollow cylinder to accommodate the stacked Contains elements (6). 5. Battery housing according to one of claims 1 to 4, characterized in that that the bending axis of the flexible hinge (1) is parallel to the axes of the galvanic cells (6) formed element columns is arranged. 6. Battery housing according to one of claims 2 to 4, characterized in that that the prismatic columns of the galvanic elements (6) each on the front side are provided with an outwardly leading contact (9,10) and connected in series.