SE510008C2 - Anti-theft switch device for motor vehicle battery - Google Patents

Abstract

The switch device comprises semiconductor switches such as MOSFET-switches (11) connected in parallel between the middle battery cells (7, 9). The switch or switches are generally plate-shaped and comprise each one a main part of body and have one electrical terminal located on a large bottom side and another electrical terminal located on another side of the body. The switches are mounted in a line or a row on a large side of a first electrically and thermally conducting metal plate. A second conducting plate comprises two large sides on an edge connecting the large side. The edge extends in parallel to the switches and at one side of the switches. The second plate is arranged to form a gap between the two plates which are then the electrical terminals of the switch device. Electrical connection wires extend between the terminals located at the other sides of the switches and the second plate. For providing increased heat dissipation the first plate can be prolonged by a bent cooling flange. The switches are controlled by a processor (15) which can receive signals from the exterior, such as rf signals received by a receiver (25) for allowing a high but not too high current for powering a starter motor from the battery. In other cases only small currents can be drawn from the battery for powering the charge state and can block also small currents when there is too little charge left whereby also a sufficient charge can be left for starting the motor. For an interrupt in a lead to a power supply unit the control circuit can be provided with voltage from a reduced number of battery cells. Therefore, suitably placed diodes are provided in the interior supply lines to the power supply unit.

Description

510 008 2 battery cells, ie in two series-connected cells, in the two poles to which the arms would be permanently connected. These poles can in one embodiment be located at the same long side of the battery as the outer poles, which in some cases is achieved with a connection of these battery cells and the nearest adjacent cells deviating from the conventional one. From the outer poles, pole pieces can go up to longitudinal channels, which extend to a space for the switch device and the control circuits. In these channels, electrical wires are then connected to the control circuits and in particular to a power supply unit.

A battery with an anti-theft device comprises in a conventional way fl your cells, which are connected in series. In each cell there are positive and negative battery plates and these are connected by positive and negative plate bridges, respectively, which each then form a pole in the cell. An electrically controlled switch is connected between two series-connected, adjacent cells and is thus connected instead of the normal series connection between these cells, ie is connected to a positive pole of a cell and a negative pole of an adjacent cell. Control circuits actuate the switch to transmit it in the closed state, as no or little current can be drawn from the battery. Such a switch can, when conducting, develop a lot of energy through residual resistance in it and this energy in the form of heat can be dissipated, in that the switch is also in good thermal contact with the poles to which the switch is electrically connected. For this purpose, the switch is at least partially mounted on an electrically and ternically conductive plate and one electrical connection of the switch comprises a surface in contact with this plate. The connections of the switch may thus comprise conductive metal parts with lower surfaces, which form such a connection. The plate is then in turn in electrical and intimate thermal contact with one of the mentioned poles.

The battery is moreover arranged in the usual way with the plates in all cells substantially parallel to each other and it has outer poles, from which useful current can be extracted. If the cells are all substantially the same, then the battery takes the form of a substantially rectangular body with a longitudinal direction perpendicular to the plates. To enable the switch and its control circuits to be fitted with a short external connection, they should be located at the long side of the battery, which is parallel to the longitudinal direction and is adjacent to the outer poles, where this side can be called the front of the battery. Therefore, in this case, the outer poles and the said positive pole and the negative pole, to which the switch is connected, must lie at this long side or generally all lie on the same side of a center line in the longitudinal direction of the battery.

All poles of the battery cells except the poles of the cells to which the switch means is connected, and a pole of the cells closest to them can in this case be placed and connected in a conventional manner in a zigzag pattern, while the poles and flat bridges of the other cells can be designed with center connections.

In conventional lead batteries for 12 or 24 V, there are six and twelve cells, respectively, ie a number that is evenly divisible by six. The switch means is then preferably connected between the two middle adjacent cells, ie with its connections between a positive pole of a middle cell and a negative pole of the adjacent middle cell.

DESCRIPTION OF THE DRAWINGS The invention will now be described in more detail in connection with a non-limiting exemplary embodiment in connection with the accompanying drawings, in which: Fig. 1 shows a top view of an anti-theft battery, where the lid is partially removed over a space for switches and control circuits, - Fig. 2 is a section along the line H-IIi fi g. 1 of the upper part of the battery, - Fig. 3 is a section along the line III-l1Ii fi g. Fig. 4 is a section along the line IV-IV in fi g. Fig. 5 is a top view of a conventional battery with the lid removed, - Fig. 6 is a top view of a battery with the lid removed, where the connection between battery cells is modified, - Fig. 7 shows a top view of a anti-theft battery with a different location of switches and control circuits, where a cover plate is removed, and - Fig. 8 is a top view of a battery vessel with the lid removed and suitable for the design according to fi g. 7.

DESCRIPTION OF PREFERRED EMBODIMENTS I fi g. 1 is a top view of a battery equipped with an anti-theft circuit. From the battery itself, a cover 1 is seen here with a negative battery pole 3 and a positive battery pole 5. The polarity is indicated by signs on the top of the lid next to the respective battery pole. According to what is visible in the sections through the upper part of the battery in fi g. 3, the rear part 7 of the upper part or lid of the battery is raised in relation to the portions where the outer poles 3 and 5 of the battery are located.

In this rear upper part 7, plugs 9 are screwed into corresponding threads in the cover above each individual battery cell and they are located above a channel 10, which runs in the longitudinal direction of the battery and connects the spaces above the battery cells to each other. The plugs 9 can be unscrewed to control the electrolyte level in the individual cells. Between the outer battery poles 3 and 5 there is also in the front edge of the battery a raised portion 11, the upper part of which lies in the same plane as the rear portion 7. In this front raised portion 11 there are electronic circuits for checking the battery. Thus, electronic circuits are encapsulated in a dense and hard plastic material, shown at 13. A switch device 15 is also arranged in this portion 11 and is connected between the series-connected middle cells in the battery.

Since the switch device 15 is connected between two internal cells in the battery consisting of serie your series-connected cells, it is suitable with a connection deviating from the normal between the plate sets in the battery cells. I fi g. 5 is shown from above a standard starter battery with six series-connected cells 17. The negative plates 19 in each cell are connected at the top by a pole bridge 21 while the positive plates 23 are connected by means of pole bridges 25.

The pole bridges 21 and 25 are here alternately placed at one side of the upper edges of the plates and at the other, respectively, and thus also alternately at one and the other side of the battery vessel 26. As a result, when the battery cells 17 are placed next to each other with simple partitions 27 between each cell and with the plates in all cells parallel to each other and with the partitions 27 the positive pole bridge 25 in a battery cell to be close to the negative pole bridge 21 the nearest battery cell 17. With a suitable design of the pole bridges, so that they project slightly towards an adjacent pole bridge, when such a positive pole bridge 25 and negative pole bridge 21 can be easily connected, for example by means of welds shown at 29. A pole bridge 21 'and 25', respectively, in the outermost battery or 17 are connected however, not in this way but are provided with upwardly directed more or less cylindrical or slightly conical pole projections 31 and 33, respectively, also the section in fi g. 4.

However, as already pointed out, this placement of the pole pieces 21 and 25 is not suitable when one wants to place a switch device 15 between the two innermost cells in such a battery and at the same time you want the switch device placed at an edge, the front edge, of the battery. , along which the pole projections 31 and 33, respectively, for connection to the outer poles 3 and 5 are located. The connection between the negative and positive plate sets of the two lowest cells is in the simple zigzag configuration according to fi g. 5 located on the other side or side of the battery.

The pole bridges of the four lowest cells in a battery can then be modified in the way shown by the view from above in fi g. 6 of a battery with the cover removed. The battery cells are denoted here 17.1, 17.2, ..., 17.6 starting from the most negative battery cell. The outermost battery cells 17.1 and 17.6 are made here in the same way as in the prior art. However, the other battery cells have changed in terms of the pole bridges. In the second battery cell 17.2, its negative pole bridge 21.2 is unchanged, while its positive pole bridge 25.2 has a part which connects the various positive plates 23 to each other and which corresponds to the pole bridge 25 in an ordinary battery. The pole bridge 25.2 is here extended in the direction of the battery's perpendicular to the plate sets and terminates along this center line by a laterally projecting portion, in the direction of the center line, of the same type as on the other single pole pieces intended for connection to the pole piece in the adjacent battery cell. . In the next battery cell 17.3, its negative pole bridge 21.3 is designed in a corresponding manner and has exactly the same geometric shape as the described pole bridge 25.2 in the previous cell.

Furthermore, in the case of the third cell 17.3, the positive pole bridge 25.3 is not made with a lateral projection for connection to the next battery cell, but has a rising pole projection 35 of the same type, which is found on the outermost pole bridges 31 and 33, respectively, in the outer cells 17.1 and 17.6. This pole projection 35 can, as shown in the fi clock, be located on a part of the pole bridge 25 .3 which projects slightly towards the said cut-off line of the battery. The negative pole bridge 25.4 in the next battery cell 17.4 is designed in the same way as the positive pole bridge 25 .3 just described in the previous battery cell and, like this, has an upwardly projecting cylindrical or slightly tapered pole projection 37. The positive pole bridge 25.4 in this battery cell and the negative pole bridge 21.5 in the next battery cell, the fifth cell 17.5 are designed in the same way as the pole bridges 25 .2 and 21.3 with a series connection between the battery cells at the center line of the battery. The other pole bridges correspond to those found in a conventional battery according to fi g. 5.

The adjacent pole bridges 25.3 and 21.4 enable a simple connection of a switch device between them and in particular between their pole projections 35 and 37, see also the sections of the upper part of the battery in fi g. 2 and 3.

The same pole pieces 37 are further attached to the pole projections 35 and 37, see in particular fi g. 3 15 510 ÛÛ8 5 3. Such a pole piece 37 connects a pole projection 35 or 37 to the switch device 15 and for this purpose has bolts 41 which lie with their head downwards and with the threads of the bolts 41 directed upwards. The pole pieces 39 have an upper flat surface and are passed through holes for receiving pole projections 35 or 37. The pole pieces 41, like the pole bridges of a lead accumulator, are made of lead and are welded to the pole projections 35 or 37 with welds shown at 43 at the upper ends of the pole projections.

Against the upper surface of the pole pieces 39 rests a metal plate 45 of good heat-conducting and electrically conductive material such as copper or aluminum. The plates 45 are held in this position by means of nuts 47 threaded on the bolts 41, which pass through suitably received holes in the metal plate 45. The plates 45 have a rectangular shape and are positioned so as to have an inner edge or side parallel to a corresponding inner edge or side at the second plate and at a distance from it. Two other edges or sides of the tiles are aligned with each other. As a result, the plates 45 are electrically insulated from each other and one connection of the switch device, not shown, is connected to one plate, while the other connection is connected to the other plate.

Batteries with different capacities may have different numbers of plates in each plate set and therefore the distance between the pole projections 35 and 37 may be different for different battery types. However, the pole pieces 39 are rotatable about the pole projections before attachment and the connection to the pole projections, so that the cast-in bolts 41 can be placed at the same distance for varying types of batteries. Furthermore, the placement of the plates 45 against the large upper surface of the pole pieces 39 provides a good heat-conducting and electrically conductive connection between them. This is especially valuable in cases where the switch device 15 itself develops a lot of power, which in some way has to be transported away. The space around the switch device 15 and its connections to the plates 45 are protected by a metal lid 49, which is made of hardened sheet metal and has the shape of a downwardly open rectangular box. Other parts of the lid 1 and the battery vessel 26 are consistently made of suitable plastic material. A glued-on cover plate 50 forms a cover on the front raised portion and thus lies on top of the protective metal cover 49 and over the encapsulated electronics in the block 13. From this protrudes metal tongues 52 for, among other things, the electronic circuitry communication with other electrical devices .

The electronic devices in the block 13 are connected by means of a line 51 to the switch device 5 for controlling its on and off. The electronic circuits in the encapsulated block 13 also require contact with various poles in the battery, in particular its external connection poles for monitoring the battery. They are also connected to the poles of the middle cells, between which the switch device 15 is connected, by means of short wires 51 soldered to the plates 45.

For connection of the electronic loaders to the outer poles 3 and 5, the poles 3 and 5 are provided with pole pieces 53, see, inter alia, the section in fi g. 4. The pole pieces 55 are provided with through holes for receiving the pole projections 31 and 33, respectively. At the through hole, the pole pieces 55 are designed as a bushing with an outer cylindrical or slightly tapered shape 1010 20 25 35 510 ÛÛS 6. This outer surface then constitutes the actual battery pole for connecting the battery in, for example, a motor vehicle. Welders 58 electrically connect the pole projections 31 and 33 to the upper edge of the sleeve-like portion of the pole pieces 55.

The pole pieces 55 are extended in the direction of the center line of the battery, i.e. they lie in a direction substantially parallel to the plane of the cell plates. They terminate in a space 57 in the cover 1, which runs in the longitudinal direction of the battery adjacent to the channel 10 and extends to the front raised portion 11 of the battery, where the switch device 15 and the electronic circuits 13 are located. From this inner end in the space 57, loose wires 59 go to the encapsulated block 13, see also fi g. 1. These conduits 59 are connected to the pole pieces 55 by threaded holes in their innermost portions of the space 57, in which screws 61 with underlying contact plates 63 are screwed. Due to this design of the pole pieces 55 and the longitudinal space 57, the same pole pieces 55 can be used for batteries of different sizes with varying numbers of plates in the cells. The screws 61 and the plate 63 are accessible in that the channel 57 is open at its outer end. Possibly snap lids can be arranged here.

It is of course possible to also place the switch device 15 and the electronics in the other edge, the rear edge of the battery as illustrated by fi g. 7 and 8. Here, only two pole bridges in the middle cells 17.3 and 17.4 need to be modified compared to a conventional battery. Thus, in these lowest cells, the pole bridges 25 '.3 and 21'.4 to which these cells are normally connected are designed in a manner similar to the pole bridges with the pole projections 35 and 37 in the previous embodiment. Thus, these pole bridges are made of substantially normal pole bridges, which hinge projections to the side for series connection to the next battery cell but possibly with a slightly projecting part towards the center line of the battery. On this projecting part, the pole projections 35 'and 37' can then be located and suitably made in one piece when casting the pole bridges 2523 and 211.4.

Protrusions 35 'and 37' are attached to the pole bridges 35 'and 37', as before pole pieces 55, which can have substantially the same design as before. Electrically and thermally conductive plates 45 are then attached to pole pieces 55 as above by means of bolts 41 and nuts 47 and on the plates the switch device 15 is in electrical and thermal contact.

To the electronic circuits, which here are enclosed in a block 13 'also placed in the rear raised part 7 of the cover 1, go as above loose lines, partly a line 51' from the switch device 15 for controlling it in on and off position, wires 53 'from the plates 45 and finally wires 59' for contact with the outer poles 3 and 5 of the battery. These wires 59 'are screwed at the other end to the inner, rear end of pole pieces 64, which like the pole pieces 55 are attached to the pole projections 31 and 33 on the outermost pole bridges but extending further towards the rear side of the battery, past its center line and into the rear raised portion.

Claims (3)

10 15 510 008 7 PATENT REQUIREMENTS 1. A battery comprising cells, each comprising positive and negative battery plates, with plate bridges in each cell connecting battery plates of the same polarity and electrical series connections between plate bridges, so that the cells are interconnected in series, further including outer poles connected to plate bridges in outer cells, all the battery plates being substantially parallel to each other, the battery having a longitudinal radius perpendicular to the plates and the plate bridges lying along two lines on each side of a line in the longitudinal direction of the battery, and further including an electrically controlled switch means connected for the electrical series connection of these and thereby in electrical connection with a plate bridge connecting positive battery plates of a first of these cells and with a plate bridge connecting negative battery plates of a second of these cells, characterized in that the plate bridges in the first and second cell, which are not connected to the switch means, have projections which extend towards the center line and at their ends have electrical series connections with plate bridges in adjacent cells, which plate bridges similarly have projections which extend towards the center line, thereby enabling the plate bridges to be connected to the outer poles and the plate bridges connected to the switch means are located on the same side of the center line. Battery according to claim 1, characterized in that it comprises a six evenly divisible number of cells, wherein the switch means is connected between the two middle adjacent cells, i.e. with its connections between a positive bridge connecting positive battery plates of a central cell and a flat bridge connecting negative battery plates of the adjacent central cell. 3. A battery according to any one of claims 1-2, characterized in that all the flat bridges of the battery cells except the flat bridges of the cells to which the switch means is connected, and of the cells closest to them, are located and interconnected in a zigzag pattern.