SE450312B - MULTIPLE CELL ELECTRIC ACCUMULATOR - Google Patents

Description

450512 thus corresponds to the tubular sheath of active material of a single-conducting frame of the same length as the sheath. Furthermore, the arrangement with cylindrical electrodes is relatively space-consuming in relation to the volume of active material used.

The present invention relates to a multicellular electric accumulator, in which the electrical conductivity of the active material is utilized to a significant degree, whereby the amount of internal conductors can be reduced and thus the weight.

The ratio of the thickness of the electrodes to the total area within a cell should be chosen according to the factor of electrolytic conductivity and electrolyte diffusion to and from the interior of the electrodes which requires the thinnest electrodes. These must therefore be no more than 10 mm thick and extend at least 5 times their average thickness from the wall to which they are connected.

The connections through the walls between the electrodes in the pairs described above are placed at a mutual distance, which is determined by the internal electrical conductivity of the active material in the electrode in the pair, where this is lowest. However, it has been found possible to place them at least 10 mm apart and in some cases at a distance of up to 50 mm.

Each connection is preferably a straight conductor. Its extent from the wall it passes through into resp. electrode depends on the electrical conductivity of its active material. It can always be made shorter than the extent of the electrode from the wall. Often less than half of this measure is sufficient.

The cross section of the said conductors is dimensioned on the basis of what is needed for them to resist corrosion during the life of the accumulator.

It should therefore be at least in the case of lead-acid accumulators at least 1 and preferably 3 mm. At least in the case of lead-acid accumulators also applies: The active material is used in a layer which extends from the outer surface of the electrode and as far in as the diffusion has time to replace spent electrolyte. The conductivity of the active material decreases sharply during discharge. Therefore, in order to facilitate the active material to cope with the role given here in the current transport, the electrodes can be given an outwardly from the partition wall with which they are connected, a tapered wedge-shaped cross section, seen in a substantially horizontal section through the electrode. 450 312 In now common lead-acid accumulators, lead alloys are widely used both as current collectors and mechanical support for the active material. To the extent that the latter requires mechanical support, this is carried out in the present invention with stronger and above all substantially lighter materials, such as plastic and fiberglass mats.

The present invention thus relates to a multicellular electric accumulator. where adjacent cells are separated by an insulating partition and where, in a cell electrodes, substantially shaped as plates and parallel to each other, emanate from each of the cell boundary partitions and in the end cells of the accumulator from the end walls and extend in their longitudinal direction almost through the cell and where the plates are arranged so that, within the cell, every other plate starts from one partition or an end wall and is of one polarity and every other plate starts from opposite wall and is of opposite polarity and so that, the electrode plates start in pairs from the partitions, wherein opposite a plate of one polarity on one side of the partition there is a plate of opposite polarity on the other side, and where the plates in each such pair are connected by means of at least one conductor sealed through the partition wall.

The invention is characterized in that corresponding parts of the electrode plates in each such pair are directly connected by means of a substantially rod-shaped conductor, in a known manner sealed through the partition, the active material's own electrical conductivity being used for the bulk of collecting or distributing the current within said electrode parts. and in that the size of said parts is adapted to said conductivity, wherein the surface of said parts in a longitudinal section, i.e. parallel to the plane of the plates, is at least 2 cmz and at most 50 cmz, preferably 10 - 15 cmz and in that said conductor inserts in each plate in its longitudinal direction, i.e. substantially parallel to the plane of the plate and in the direction from the partition wall, to only a part of the plate's length, the active material's own electrical conductivity being used to collect or distribute current within the non-conductor portions.

The invention is described in more detail below in connection with the accompanying drawing, in which - Fig. 1 schematically shows a horizontal section BB according to Fig. 2 through a part of two cells in an accumulator according to the invention with a first embodiment of electrode plates, 450 312 - Fig. 2 schematically shows a part of a section AA according to Fig. 1, Fig. 3 schematically shows a vertical section C-C according to Fig. 4 through a second embodiment of electrode plate according to the invention, Fig. Ä shows an electrode plate according to said second embodiment seen from above, - Fig. 5 schematically shows a gable (end wall) of an accumulator according to the invention with two embodiments of the connections for current collection from the electrodes and an embodiment of battery pole, - Fig. 6 schematically shows an embodiment of conductors arranged to connect two electrode plates of opposite polarity, and - Fig. 7 schematically shows an embodiment where the plates form an angle with partitions in the accumulator, where two adjacent cells are seen from above.

In Fig. 1, 1 denotes an outer wall of an accumulator according to the invention, against which outer wall partitions 2 limiting cells 3,4 of the accumulator are arranged. Fig. 1 is intended to show a horizontal section through an accumulator, where thus said outer walls and partitions are preferably vertical and where the partitions 2 are arranged perpendicular to the outer walls 1 and run between two mutually parallel outer walls. The accumulator is intended to be set up on a horizontal surface.

Each cell 3, Å, where the accumulator preferably comprises a plurality of cells, is bounded by two mutually parallel partitions 2 and mutually parallel outer walls 1.

In each cell there are electrodes 5,6 substantially formed as plates and mutually parallel protruding from the two partitions2, which delimit the cell.

5 denotes positive electrode plates and 6 negative electrode plates. The rails 5,6 are arranged so that, every second plate within a cell protrudes from one partition wall and is of one polarity and every other from opposite partition wall and is of opposite polarity and so that, the electrodes 5 or 6 protruding from a partition wall 2 in a cell 3 or Ä are connected to their respective electrodes 6 or 5 resp. of opposite polarity in the adjacent cell Ä or 3 resp. by means of a number of conductors 7 determined by the size of the electrode parts within which the current line is managed by the active material, which conductors are sealed through the partition wall 2 between the cells 3, b, as shown in Fig. 1. Electrode-Wu 450 312 plates 5, 6 thus starts in pairs from the partition wall 2, where the plates in each such pair are connected by means of at least one conductor 7 penetrated through the partition wall and where corresponding parts of the electrode plates 5,6 in each such pair 5,6 are directly connected by means of a conductor 7.

Each plate 5,6 may have outwardly from the partition wall 2, from which the plate protrudes, tapered, wedge-shaped cross-section seen in a substantially horizontal section through the plate as shown in Fig. 1. The plate 5,6 thus has at its free end 8 a thickness which is less than the thickness at the end adjacent the partition wall 2, from which the plate protrudes.

The above-mentioned conductor 7, which consists of, for example, lead rods, inserts into the plate 5,6 in its longitudinal direction, i.e. in the direction from the partition wall 2, to only a part of the length of the plate, often below 50% of the same.

The predominant part of the weight of each plate 5.6 consists of active material 9,10 of known kind, such as lead dioxide 9 resp. lead 10, where thus the active material is known to consist of hlydioxide 9 of the positive plates 5 and lead 10 of the negative 6.

At an accumulator acc. In the invention, where the conductors 7 are inserted into the plates only to a small extent, the conductivity of the active material 9,10 is used for current conduction to the conductors 7 from the plate portions 11 present outside the conductors 7. In Figs. 1 and 2 the conductors 7 have been plotted schematically. Fig. 6 shows an embodiment of conductor 7, where these are adapted to the need for current conduction and the conductivity of the active material so that the conductor is made shorter in the plate 12, which contains active material with the greatest conductivity compared to the conductor. length in the plate 13 containing active material with the lowest conductivity. Furthermore, the conductor has been made tapered towards its ends 14,15. In this way, the amount of conductor material is reduced so that no more conductor material than necessary is used. This reduces the weight of the accumulator.

Figs. 3 and Ä show an embodiment of plates according to the invention, wherein each plate comprises a frame 16 or the like of a low density material, such as plastic or the like. The frame has a substantially substantially rectangular or square outer contour in a plane substantially parallel to the plane of the plate. The frame 16 is clad with a casing 17, which is constituted by a porous mat or similarly permeable to the electrolyte of the accumulator, for example standing on a glass wool mat attached to a perforated plastic mat, where in the casing 17 thus form 5.6 side walls 18 of the plate and the active ma-,. the material is preferably arranged inside the frame 16 and the housing 17. 450 312 Acc. In one embodiment, the frame comprises at least one planar thickness direction filling the support profile 19 for the housing 17, whereby the plate in its height is divided into several, substantially equal, compartments 20, where preferably a conductor 7 is inserted in each compartment 20. In fig. 3, the frame 16 with support profiles 19 consists of a fork-like back piece, to which an end piece 21 is attached after raw material to active material has been filled into the plate. In this embodiment, the compartments 20 thus form the corresponding parts of the electrode plates 5,6 which are directly connected through the partition wall 2 by means of the conductor 7.

The plates 5,6 can of course also consist of a, also permeable, substantially cantilevered, possibly molded, casing 22, in which active material is arranged, i.e. essentially as in flg. 1 and 2. It is also possible to imagine electrodes with the shape and distribution of conductors, as described above, built up of self-supporting active material.

The electrode plates.5,6 can of course be varied considerably in terms of their length, thickness and height and also the extent to which the plates taper outwards. Thus, the length of the plates can be varied within at least the range 1-10 cm and the average thickness of the plates within at least interval 1 - 10 mm. Preferably, there are several conductors 7 distributed over u of each plate in height, where the distance between two adjacent conductors can be varied within at least the interval 1 - 5 cm.

' According to. in one embodiment each plate has a thickness of about 3 '3.5 mm at its free end 8 and cza Å, 5 - 5 mm next to the partition wall, from which it protrudes. Fig. 5 schematically shows a gable 22 of an accumulator according to the invention with two embodiments, one on the right and one on the left, of connections for current collection from electrode plates and an embodiment of a battery pole. In the figure, the end wall 22 is seen from the outside. Each connection point 23 on the outside of the end wire 22 connects to a conductor 7, a vertical row Zü, where such a row 24 is marked dashed in the figure, preferably corresponding to an electrode wire. 5.6. In the middle of the end wall 22 there is a vertical collecting conductor 25 comprising a battery pole 26 - at its preferably upper end. Each connection point 23 is connected to the collection conductor 25 "nearest path", i.e. with substantially horizontal wires or the like, either with a wire 27 for each connection point 23, as on the left in the figure, or with a common conductor 450 312 28, as on the right in the figure.

Preferably, the cross-sectional area of the collecting conductor 25 and the conductors 28 is adapted to the need for conductivity so that the cross-sectional area increases in the conduction direction towards the pole 26, as indicated in Fig. 5, whereby the weight of the conductors 25,28 is kept down. Both collection leaders and other leaders can “here be performed in e.g. copper, which has very good conductivity, whereby the weight is further significantly reduced. The battery pole 26 comprises a hole 29, through which a cable lug, busbar or other battery pole can be easily connected.

An accumulator acc. the invention is thus adapted to provide high capacity per unit weight compared to known accumulators, in that the conductivity of the active material is utilized optimally. Built-in electrical conductors can be dimensioned with regard mainly to corrosion and service life.

At the same time, the electrodes are designed with electrolyte diffusion and gas evolution in mind, and the current paths are generally the shortest possible.

With an accumulator acc. According to the invention, the weight of the built-in conductor material is only about 10% of the weight of the electrodes, which is to be compared with # 0 - 50% in conventional constructions.

The above has some embodiments of an accumulator according to the invention has been described. Of course, more embodiments as well as minor changes are conceivable without departing from the spirit of the invention.

Thus, the 5.6 side walls of the tiles can be supplemented with additional material for separating the tiles.

Furthermore, it is suitable for the longitudinal outer walls of the accumulator to protrude slightly outside the ends 22, as indicated in Fig. 5, whereby plastic or the like can be arranged as an enclosure for the collecting devices 23, 25, 27, 28 on the outside of the end wall.

It may also be appropriate in some cases for the plates 5,6 to form an angle with the plane of the partition wall, as indicated in Fig. 7, where parts of two adjacent cells 3, ü are shown.

Above, substantially rod-shaped, smooth conductors 7 have been indicated. In some cases it may be appropriate to design the conductors 7 with a variable in their longitudinal direction. cross section to increase the contact area with the surrounding active material in this way and thereby ensure contact between the conductor and the active material. Thus, the conductors can be formed rod-shaped with circumferentially 450 512 running and protruding annular or disc-shaped portions.

The invention is thus not to be considered limited to the above-mentioned embodiments, but can be varied within the scope of the appended claims. m ß

Claims (5)

450 312 9 Patent claims Multicellular electric accumulator, where adjacent cells are separated by an insulating partition and where, in a cell electrodes, substantially shaped as plates and mutually parallel, emanate from each of the cell delimiting partitions and in the end cells of the accumulator from the end walls and extend in their longitudinal direction almost through the cell and where the plates are arranged so that, within the cell, every other plate emanates from one partition or an end wall and is of one polarity and every other plate emanates from the opposite wall and is of opposite polarity and so that , the electrode plates start in pairs from the partitions, whereby opposite a plate of one polarity on one side the partition there is a plate of opposite polarity on the other side, and where the plates in each such pair are connected by at least one through the partition sealed conducted conductor, characterized in that corresponding parts (20) of the electrode plates (5,6) in each such pair (5,6) d is directly connected by means of a substantially rod-shaped conductor (7), in a known manner sealed through the partition wall (2), the active material's own electrical conductivity being used for the main part of collecting or distributing the current within said electrode parts and by said parts (20) ) size is adapted to said conductivity, wherein the surface of said parts (20) in a longitudinal section, i.e. parallel to the plane of the plates, is at least 2 cmz and at most 50 cmz, preferably 10 - 15 cmz and in that said conductor (7) inserts in each plate (5,6) in its longitudinal direction, i.e. substantially parallel to the plane of the plate and in the direction from the partition wall (2), to only a part of the length of the plate (5,6), the active material's own electrical conductivity being used for collecting or distributing current within the outside conductors (7) existing parties (11). 2. Accumulator acc. claim 1, characterized in that each plate (5,6) has an outwardly from the partition wall, from which the plate (5,6) emanates a tapered, wedge-shaped cross-section, seen in a substantially horizontal section through the plate ( 5.6). 3. Accumulator acc. claim 1 or 2, characterized in that each plate (5, 6) comprises a frame (16) of plastic or equivalent with a section substantially parallel to the plane of the plate in a substantially rectangular or square outer contour, where the frame (16) is clad with a porous and for the accumulator electrolyte and in the accumulator formed 450 312 m 'gases permeable casing (17) sauce 6) side walls (18), co: where said active material (9, 10) is arranged: inside the frame (16) and the housing (17). 4. U. Accumulator acc. claim 2 or 3, characterized in that each plate (5,6) has a thickness of e fi a 3 ~ 3.5 mm at its free end (8) and about ä, 5 ~ 5 mm adjacent the partition wall (2 ), from which it protrudes. Accumulator according to claim 3 or M, characterized in that each plate (5,6) comprises at least one plate rim (5,6) thickening pad filling support profile (19) for the housing (17), whereby the plate (5, 6) in height is divided into several, substantially equal, compartments (20) where, preferably, a conductor (7) is present in each compartment (20).