SE436386B - ELECTROLYTE COOLING DEVICE BY ACCUMULATOR BATTERY CELL - Google Patents

Description

eso2i21-9 le for receiving the helically wound kyisiingan. This provides adequate support for the kyisiingan, while exposing the maximum of its surface to the electrode surface.

In order to obtain a seal with the electrode device and the battery cover in a simple and rational manner, the core can suitably have at its upper part a projecting radius projecting for sealing sealing against the said opening. In this case, the flange can provide the radially outer portion of a bushing for the inner and outer ends of the kyisiingan having an upper core end wall, whereby sealing at the kyisiing penetrations can be ensured in a simple manner. Furthermore, suitably the radially outer portion of the flange may be releasably pressed against the upper end of said opening surrounding, from the battery-projecting stub with a median stub and the flange actuating ring nut, through whose through opening said bushings extend, whereby The cooling device can easily be fixed in the desired rotating battery compartment. Preferably, the portion of the core located below the fixture and the indentation thereon may have a diameter less than the diameter of the opening in the cooling device so that the cooling device can be removed from the cooling device. and if necessary can be taken for inspection or exchange. With said advantage, said opening in the cell can be constituted by the battery surface of the battery surface, whereby the cooling device according to the invention requires minimal intervention in the battery construction and can possibly be applied to conventional previously liquid battery batteries. According to an advantageous alternative embodiment of the invention, the fan may be arranged to abut the inside of the cylinder and the cooling device may be insertable into the associated chamber through its electrode surface opening.

The cooling device according to the invention can advantageously be combined with devices with a different cooling function.

For example, in a preferred embodiment, said end wall of the core may be provided with an opening which is. covered by a gas-permeable but anti-emission porous lid, -ventueiit combined with an electro-droplet separator. azo2721-9 The invention will be described in more detail below with reference to a preferred embodiment shown in the accompanying drawing, but only as an example an embodiment thereof, whereby further features and advantages characteristic of the invention will appear. Fig. 1 is an electrolytic cooling device according to the invention shown partly in side view and partly in axial section.

Fig. 2 is a plan view of the device according to Fig. 1.

Figs. 3 and 4 are a view from below and a large-scale axial sectional view of a gas-permeable insert shown in Figs. 1 and 2 in the cooling device. The electrolyte cooling device shown in Figs. 1 and 2 comprises a core denoted by 10, around which is helically wound a tubular cooling loop 11 with inlet and outlet ends 12, 13 for a cooling medium flowing through cooling medium, for example water. The core 10 is built up of four right angles with each other forming walls, three of which are shown and are denoted by 14 and which are arranged in a radial plane relative to the axis 15 of the core 10. Each wall 14 has a radially outer edge extending parallel to the axis 15. , in which U-shaped recesses are arranged, in which the cooling loop 11 forming the tube 11 is received and whose center distance exceeds the outer diameter of said tube, so that the helical cooling loop will obtain a pitch exceeding the tube outer diameter.

Denoted by 16 is a portion of an accumulator battery cover located above a battery cell. Arranged in the lid portion 16 is an opening 17, which can be constituted by the cell's ordinary electrolyte filling opening and which is surrounded by an upright, externally threaded socket 18. The electrolyte level in the battery cell is indicated at 19.

At the upper end, the core 10 is provided with a circular, transverse end wall 20 with a peripheral flange portion 21, which is kept sealingly pressed against the outer end of the nozzle 18 by means of a retaining device 22 designed as an assault ring nut 22. The outer diameter of the winding 11 and the core 10 it is less than 17 cm below the flange 21, so that the cooling device can be removed from the cell after unscrewing the nut 22. Aasozvzi-90 In the end wall 20, formed bores 23 (Fig. 2) are formed for the cooling loop ends 12, 13, which bores open into an area of the core end wall 20 exposed through the central opening in the cover ring nut 22 and to which bores 23 adjoin in opposite directions are bent guides 24 for the keymines 12, 13. In addition, a central, internally threaded bore is arranged in the core end wall 20, in which is screwed in an insert 26 provided with an external thread 25, comprising a cylindrical plate provided with a perforated bottom and upper part 27, 28. container 29, which contains a filling of particulate material 30 as a drip catcher (Fig. 4), and a porous, 9êS9e fl0 m $ 1äPP “lig. but explosion-proof hood 31 or the like. The container 29 extends into a space 32 'in the recess 32' formed in the walls 14 in the upper part of the core 10. In the sheath of the container 29, formed slots 33, 34 are formed above and below the circumferential flange 35 projecting from the sheath 29 of the container 29, on which the hood 31 is mounted. The upper side of the flange 35 slopes downwards towards the container jacket and serves, together with the slots 33, 34, to return to the cell such electrolyte which may have passed through the drip-separating filling 30. Denoted by 36 is a 0-ring for sealing between the flange 35 underside and end wall 20.. The electrolyte cooling device shown in the drawing is primarily intended for large accumulator batteries, such as industrial and submarine batteries, and requires, as will be readily appreciated, minimal or no intervention in the battery construction in general.

By means of the helically wound cooling coil, excellent heat exchange is obtained between the electrolyte and the coolant, so that in the case of rapid charging of or large current outlet from the battery, heat generated can be efficiently dissipated. charge formed gases can escape via the drip separator 27-30 and the porous hood 31. Filling of electrolyte or accumulator water can take place either through the opening 17 or through the opening in the core end wall 20 after unscrewing the insert 26. After loosening the nut 22, the cooling device can be removed from the cell for inspection and or replacement, and likewise the arrangement shown allows rotation of the cooling device to align the controls of the cooling ends 12,13 to the free housing.

The invention is not limited to the arrangement described above and shown in the drawing, but the embodiment of the invention can of course be varied in any way within the scope of the inventive concept defined in the claims.

Thus, the end wall of the core 10 or the like can be arranged against the inside of the battery compartment and the electrostatic precipitator can be combined with means for performing functions other than gas discharge, e.g. with a device for indicating the electrolyte level in the cell. The electrical cooling device as a whole preferably consists of electrically conductive material, whereby undisturbed water or other conductive cooling medium can be used without risk of electrical overcurrent and short circuit between the battery cables.

Claims (9)

1. Azo2721-9 CLAIMS J. An electrolytic cooling device for an accumulator battery, comprising immersing in the electrolyte in the cell a tube (11) with tubes formed and cooled by coolant and having an inlet and outlet transmitting (12, 13) through the cell; The cell (16), characterized in that the cooling ring (11) is in a manner known per se substantially helical and in that the cooling ring is wound around a support for the same forming core (10) immersed in the electrolyte. the upper part of the cylinder is fixed in and which is substantially coaxial with an opening (17) arranged in the cell socket (16) for the passage of both cooling ends out of the cell, and the core supports the cooling only along smaller areas of each winding revolution, so that also ñuvudde1en_of de mot_kernas axe1 (15) facing the cooling parts are exposed to the electrolyte i.ce11en. Device according to claim 1, similar in that the cooling ring (11) is wound with a pitch exceeding the outer diameter of the loop forming the tube. _ 3. Device according to claim 1 or 2, characterized in that the core (102 has substantially in the radial plane relative to its axis1 (15) arranged walls (14) with a recess distributed along the outer edges of their radii for receiving the helically shaped cooling ring e (ii). "'' 4. A device according to any one of claims 1 - 3, characterized in that the core (10) at its upper part has a radially projecting, for sealing abutment against the said opening (17) surrounding the intended portion. (21). ' Device according to claim 4, not characterized in that the flange (21) forms the traditional outer portion of a bushing. (23) - for the inlet and outlet ends (12, ia) of the cooling ring (11) having the upper core wall (zo) ). '81302721 -9 7. Device according to claim 5, characterized in that the flange (21) is releasably pressed against the upper end of said opening (17) surrounding a nozzle (18) projecting from the non-lid cover by means of an assault ring nut (22 acting between the nozzle and the flange). ), through whose through-opening said bushings (23) extend. Device according to claim 5 or 6, characterized in that the portion of the core (10) located below the flange "(21) and the cooling coil (II) wound thereon have a diameter below the diameter of the opening (17) in the cell. lid (16). Device according to any one of claims 4 - 7, characterized in that said opening (17) in the cell cover (16) is constituted by the electrolyte filling opening of the cell. Device according to claim 4, characterized in that the flange is arranged to abut against the inside of the cell cover (15) and in that the electrolyte cooling device is insertable into the cell through its electrolyte filling opening.