CELL MODULE AND METHOD FOR OPERATING THE CELL MODULE

Abstract

A cell module is provided, in particular for a traction battery of a vehicle, including a plurality of cells, which are arranged in a series circuit; including at least two cell monitoring circuits for identifying a voltage applied between two poles of cells, wherein each circuit has two voltage supply connections, wherein a first voltage supply connection is coupled to a positive pole of a first cell and a second voltage supply connection is coupled to a negative pole of a second cell; and including a switching apparatus, which is configured to selectively couple the first voltage supply connection of a first cell monitoring circuit and the second voltage supply connection at least of a second cell monitoring circuit to a respective one of two positive poles or to one of two negative poles of different cells.

Claims

1. A cell module for a traction battery of a vehicle, including: a plurality of cells, which are arranged in a series circuit; at least two cell monitoring circuits for identifying a voltage applied between two poles of cells, wherein each cell monitoring circuit has two voltage supply connections, wherein a first voltage supply connection is coupled to a positive pole of a cell and a second voltage supply connection is coupled to a negative pole of a cell; a switching apparatus configured to selectively couple the first voltage supply connection of a first cell monitoring circuit and the second voltage supply connection of a second cell monitoring circuit to a respective one of two positive poles or to one of two negative poles of different cells.

2. The cell module of claim 1, wherein the switching apparatus has a first switch configured to couple the first voltage supply connection of the first cell monitoring circuit to a respective one of two positive poles of two first cells, and a second switch configured to couple the second voltage supply connection of the second cell monitoring circuit to a respective one of two negative poles of two second cells, wherein the first cells are shifted by one cell with respect to the second cells in the series circuit of cells.

3. The cell module of claim 1, wherein the first voltage supply connection of the first cell monitoring circuit and the second voltage supply connection of the second cell monitoring circuit are coupled to one another and form a combined voltage supply connection; and the switching apparatus has a combined switch configured to couple the combined voltage supply point to a respective one of two connection points, of which one is connected to one pole of one cell and the other is connected to the other pole of the same cell.

4. The cell module of claim 3, wherein a buffer capacitance is coupled to each switchable voltage supply connection of a cell monitoring circuit, the buffer capacitance being dimensioned in such a way that the connection point of each of the switchable voltage supply connections can be switched over during operation of the cell monitoring circuit.

5. The cell module of claim 4, wherein each cell monitoring circuit has plural measurement inputs, each of which is coupled to at least one pole of a cell; and an activation switch is arranged between one of the measurement inputs of each cell monitoring circuit, in which a voltage supply connection is designed to be switchable, and the corresponding connection point thereof to a pole of a cell.

6. The cell module of claim 1, wherein a buffer capacitance is coupled to each switchable voltage supply connection of a cell monitoring circuit, the buffer capacitance being dimensioned in such a way that the connection point of each of the switchable voltage supply connections can be switched over during operation of the cell monitoring circuit.

7. The cell module of claim 1, wherein each cell monitoring circuit has plural measurement inputs, each of which is coupled to at least one pole of a cell; and an activation switch is arranged between one of the measurement inputs of each cell monitoring circuit, in which a voltage supply connection is designed to be switchable, and the corresponding connection point thereof to a pole of a cell.

8. A battery traction battery of a vehicle that has at least one of the cell modules of claim 1.

9. A method for operating the cell module of claim 1, comprising: switching over the switching apparatus to change a switching state of a respective one of the two voltage supply connections of at least two cell monitoring circuits with respect to the poles of the cells.

10. The method as claimed in claim 9, furthermore including: switching over the activation switches of those cell monitoring circuits in which the switching state of the voltage supply connections has been changed by means of the switching apparatus, preferably at the same time as the switching over of the switching apparatus.

11. The method of claim 10, wherein the battery is a traction battery of a vehicle; and the switching over takes place cyclically upon each restart of the vehicle.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0021] FIG. 1 shows a circuit diagram of a prior art cell module.

[0022] FIG. 2 shows a first switching state of a cell module according to an exemplary embodiment of the invention.

[0023] FIG. 3 shows a second switching state of a cell module according to an exemplary embodiment of the invention.

DETAILED DESCRIPTION

[0024] FIG. 1 shows a circuit diagram of a conventional cell module 1 from the prior art. A series circuit 4 of five cells 41-45, namely a first cell 41, a second cell 42, a third cell 43, a fourth cell 44 and a fifth cell 45 connected in series, is arranged between a first connection contact 2 and a second connection contact 3 of the cell module 1. Except for the first cell 41 and the fifth cell 45, which constitute edge cells or outer cells of the series circuit 4, the inner cells are coupled to one another by way of their opposite poles. A first cell monitoring circuit 5 and a second cell monitoring circuit 6 are provided to monitor the cell voltage of the cells 41-45. The first cell monitoring circuit 5 has four measurement inputs 51-54, of which the last three measurement inputs 52-54 are coupled to a respective pole of a cell. It should be considered here that for example the third measurement inputs 53 fulfils a double function since it is coupled both to the positive pole of the first cell 41 and to the negative pole 42 of the second cell 42. The first cell monitoring circuit 5 has a first voltage supply connection 55, which is coupled to the positive pole of the second cell 42, and a second voltage supply connection 56, which is coupled to the negative pole of the first cell 41. Therefore, the first two cells 41, 42 provide the operating voltage for the first cell monitoring circuit 5 and at the same time are assigned to the first cell monitoring circuit 5 for monitoring the cell voltage. Since the first cell monitoring circuit 5 is configured to determine the cell voltage of a total of three cells, one of the measurement inputs (in this case the first measurement input 51) is not used.

[0025] The second cell monitoring circuit 6 likewise has four measurement inputs 61-64 and is coupled to the series circuit 4 of the cells 61-64 in a manner analogous to the first cell monitoring circuit 5: the first voltage supply connection 65 of said second cell monitoring circuit is coupled to the positive pole of the fifth cell 45 and the second voltage supply connection 66 of said second cell monitoring circuit is coupled to the negative pole of the third cell 43. Therefore, the third, fourth and fifth cell 43-45 provide the operating voltage for the second cell monitoring circuit 6 and at the same time are assigned to the second cell monitoring circuit 6 for monitoring the cell voltage.

[0026] The scenario in FIG. 1 illustrates the case of uneven loading of the cells 41-45 that has already been discussed. Since the first cell monitoring circuit 5 is supplied only from two cells 41, 42 but the second cell monitoring circuit 6 is supplied from three cells 43-45, the first two cells 41, 42 are loaded to a greater extent overall than the other three cells 43-45. This leads to higher loading and therefore to premature aging of the first and second cell 41, 42.

[0027] To prevent uneven loading, a cell module 10 with a circuitry construction according to FIG. 2 is provided. The cell module 10 according to the invention is modified with respect to the cell module 1 shown in FIG. 1 to the extent that a cyclic switchover of the voltage supply of the cell monitoring circuits 5, 6 is possible, with the result that the cells of a cell module undergo on average even loading. Since the construction of the cell module 10 according to the invention is similar in terms of essential features to the construction shown in FIG. 1, the same elements have been provided with the same reference signs and are not described again in detail.

[0028] The cell module 10 according to the invention has been expanded with respect to the cell module known from the prior art (FIG. 1) by means of four switchesa first switch S1, a second switch S2, a third switch S3 and a fourth switch S4, wherein the first and the second switch S1, S2 form the switching apparatus defined above. The first voltage supply connection 55 of the first cell monitoring circuit 5 can be coupled selectively to the positive pole of the second cell 42 or to the positive pole of the third cell 43 by means of the first switch S1. Analogously thereto, the second voltage supply connection 66 of the second cell monitoring circuit 6 can be coupled selectively to the negative pole of the third cell 43 or to the negative pole of the fourth cell 44 by means of the second switch S2.

[0029] The switching position of the switches S1, S2 that is shown in FIG. 2 corresponds to a first switching state of the cell module 10 or to the switching apparatus and at the same time to the invariable state of the cell module 1 according to the prior art illustrated in FIG. 1. In addition, the third switch S3 and the fourth switch S4 are provided in the cell module 10 in order to deactivate unnecessary measurement inputs of the cell monitoring circuits 5, 6. In the first switching position, the third switch S3 is thus open since only the first two cells 41, 42 are assigned to the first cell monitoring circuit 5 and the third cell 43 is monitored not by the first but by the second cell monitoring circuit 6. The fourth switch S4 is therefore closed at the same time. The third and fourth switch S3, S4 do not have to be present as separate components but can also be integrated into the associated cell monitoring circuit 5, 6 or the functionality thereof can be integrated into the associated cell monitoring circuit 5, 6 by virtue of the corresponding measurement inputs being configured so as to be switchable.

[0030] FIG. 3 shows a second switching position of the cell module 10 or of the switches, which proceeds from the first switching position shown in FIG. 2 by changing over the four switches S1-S4 and defines a second switching state of the cell module 10. The switchover of the four switches S1-S4 now causes the first voltage supply connection 55 of the first cell monitoring circuit 5 to be coupled to the positive pole of the third cell 43 and at the same time the second voltage supply connection 66 of the second cell monitoring circuit 6 to be coupled to the negative pole of the fourth cell 44. In addition, the third and fourth switch S3, S4 are switched over in order to switch the again necessary first measurement input 51 of the first cell monitoring circuit 5 to be operationally ready and to deactivate the unnecessary fourth measurement input 64 of the second cell monitoring circuit 6.

[0031] From the comparison of the two switching positions illustrated in FIGS. 2 and 3, it is clear that a switching process of the switching apparatus causes a cellin this case the third cell 43to be transferred so to speak from one cell monitoring circuit to another cell monitoring circuit, for example to a cell monitoring circuit that is provided for monitoring adjacent cells. In this case, the assignment of the cells to a cell monitoring circuit is defined by means of the position of the voltage supply connections thereof, wherein all of the cells that are arranged in the series circuit 4 of the cells 41-45 between the voltage supply connections of a cell monitoring circuit are considered as assigned thereto. In other words, a switchover of the switching apparatus causes the connection point of a voltage supply connection of a cell monitoring circuit and a connection point of a voltage supply connection of a further cell monitoring circuit with opposite polarity thereto to be transferred together in the same direction (that is to say for example along the potential drop or potential rise within the series circuit 4 of the cells) from their position between a cell pair to a position between a cell of said cell pair and a cell adjacent thereto.

[0032] Consequently, the switching apparatus is configured to cause an offset, in the same direction, of the connection points of opposite-pole voltage supply connections of two cell monitoring circuits that preferably monitor connected adjacent subgroups of cells in the series circuit 4. Through temporally compensated operation of the cell module 10 in both switching states, loading of the cells 41-45 that is on average balanced or even can be achieved by way of the ASICs. As a result, even aging of the cells can be achieved, which leads to an increase in the lifetime of the cell module and the degree of utilization of the cell modules. When the cell module according to the invention described here and the operating method associated therewith are used, the necessary balancing times can also be reduced since the construction is already configured for even loading of the cells. The mentioned advantages can be realized by way of a comparatively simple conversion of the known cell module topology when only a few additional elements are used.