BATTERY SENSOR ARRANGEMENT AND METHOD OF BALANCING BATTERIES

Abstract

A sensor arrangement for a network of busbar links of a battery module is provided, the sensor arrangement comprising: an array of sensors, each sensor having an output arranged to provide an indication of current in a respective busbar link of the network; a processor coupled to the outputs of the sensors and configured to: receive data from the sensor outputs; process the data to determine a current in each of a set of busbar links that are connected at a node of the network; and compare the currents in the busbar links of the set to determine an overall current at the node.

Claims

1. A sensor arrangement for a network of busbar links of a battery module, the sensor arrangement comprising: an array of sensors, each sensor having an output arranged to provide an indication of current in a respective busbar link of the network; and a processor coupled to the outputs of the sensors and configured to: receive data from the sensor outputs; process the data to determine a current in each of a set of busbar links that are connected at a node of the network; and compare the currents in the busbar links of the set to determine an overall current at the node.

2. A sensor arrangement as claimed in claim 1, wherein each sensor of the array of sensors comprises a magnetic field sensor for sensing a magnetic field adjacent a busbar link when the magnetic field sensor is fitted to a busbar, the magnetic field being a result of current through the busbar link, and wherein the data from the sensor outputs comprises magnetic field data.

3. A sensor arrangement as claimed in claim 1, wherein the array of sensors comprises any of: Hall probes; magneto-resistive sensors; magneto-electric sensors; and/or optically pumped magnetometers; fluxgates; printed fluxgates; and/or MEMS fluxgates.

4. A sensor arrangement as claimed in claim 2, wherein each magnetic field sensor has a sensitivity greater than 1 μT Hz.sup.−1/2.

5. A sensor arrangement as claimed in claim 2, wherein each magnetic field sensor comprises a drive coil and a sense coil, outputs from each of the drive coils and the sense coils are arranged to send coil signal data from the drive coil and sense coil to inputs of multiplexers, and the multiplexers are arranged to send multiplexer signals to inputs of the processor.

6. A sensor arrangement as claimed in claim 1, wherein the array of sensors is arranged on a substrate for attachment to a busbar or wherein the array of sensors is arranged to be integrated into a busbar arrangement.

7. A sensor arrangement as claimed in claim 1, wherein the processor is configured to process the data to determine a current in each busbar link of a plurality of sets of busbar links and compare the currents in the busbar links of each set of busbar links to determine overall currents at a plurality of nodes.

8. A sensor arrangement as claimed in claim 7, wherein the processor is configured to determine a condition of each cell of a plurality of cells of a battery module based on the electrical current values at the plurality of nodes when the sensor is fitted to a busbar and battery module such that each of the plurality of cells is electrically connected to a respective node of the network.

9. A sensor arrangement as claimed in claim 8, wherein the condition of the cells being determined by the processor is one or more of: a state of health (SoH) of the cell; a state of charge (SoC) of the cell; a presence of one or more defects leaking charge internally between terminals of the cell; a temperature and/or predicted temperature change of the cell; and a determination of overheating of the cell.

10. A sensor arrangement as claimed in claim 1, wherein sensors of the array of sensors are held in a spaced relationship with respect to each other in the array and positioned so that each sensor of the array of sensors aligns with a busbar link of a network of busbar links when the sensor arrangement is fitted to a busbar of a battery module.

11. A sensor arrangement as claimed in claim 1, wherein the processor is configured to determine an amplitude and direction of current flowing through each of the busbar links, and is configured to determine an overall current at the node of the network based on the amplitude and direction of the currents.

12. A busbar configuration for a battery module comprising: the sensor arrangement of claim 1; and a plurality of busbar links arranged in a network for connection to respective cells of a battery module at a plurality of nodes of the network, wherein each sensor of the array of sensors is provided adjacent to each of the busbar links, each sensor of the array of sensors is provided in series with each of the busbar links, and/or each sensor of the sensor arrangement is integrated into each of the busbar links.

13. The busbar configuration of claim 12, wherein the plurality of busbar links comprises a plurality of switches, wherein each switch of the plurality of switches is associated with a respective busbar link to switch on/off a current flow through the busbar link.

14. The busbar configuration of claim 13, wherein switches of the plurality of switches are bi-directional switches.

15. The busbar configuration of claim 13, wherein between each of the plurality of nodes of the network, one of the switches is connected in series with one of the sensors of the array of sensors.

16. The busbar configuration of claim 15, wherein some or all of the connections between the plurality of nodes of the network, the plurality of switches and/or the array of sensors of the sensor arrangement are formed using conductive adhesive, conductive film or pressure connectors.

17. The busbar configuration of claim 13, wherein operation of the plurality of switches can be coordinated to isolate a cell within a battery module.

18. The busbar configuration of claim 13, wherein operation of the plurality of switches can be coordinated to connect groups of cells in series and/or parallel within a battery module.

19. A battery module comprising: an array of cells, the cells being electrically connected by a busbar configuration as claimed in claim 12, wherein a network of busbar links extends between adjacent cells, wherein a sensor is mounted on each busbar link between adjacent cells, a sensor is provided in series with each of the busbar links and/or a sensor is integrated into each of the busbar links, and wherein the processor is configured to monitor electrical current flowing in each cell.

20. The battery module of claim 19, wherein each node of the plurality of nodes is connected to a cell of the battery module.

21. The battery module of claim 20, wherein each node of the plurality of nodes is connected to a respective cell of the array of cells via a conductive adhesive, conductive film or pressure connectors.

22. The battery module of claim 19, wherein the array of cells are lithium-ion cells.

23. The battery module as claimed in claim 19, wherein the array of cells of the battery module comprises an array of 6 by 4 cells

24. A battery pack comprising one or more battery modules as claimed in claim 19, wherein the one or more battery modules are electrically coupled to form the battery pack and the battery pack comprises one or more battery management systems for controlling an output from a set of terminals of the battery pack.

25. A battery pack as claimed in claim 24, comprising the busbar arrangement of claim 12, wherein the battery pack is arranged to send data to the battery management system and the battery management system controls the switches based on this data, wherein the data comprises any one or a combination of: the data from the sensor outputs; the current in each of a set of busbar links that are connected at a node of the network; an overall current at each node; a condition of each of a plurality of cells; and/or an optimum voltage and/or current from the battery pack.

26. A method of assessing a condition of a weld and/or connection between cells of a battery module using a sensor arrangement as claimed in claim 1, wherein neighbouring cells of the battery module are connected to one another via busbar links, the method comprising: processing data received from the sensor outputs to assess currents in the busbar links between neighbouring cells; comparing the currents flowing through individual cells, the nodes and/or the busbar links; and identifying a faulty weld and/or connection based on detecting a level of current that is indicative of a defect.

27. A method of optimising the output from or load on cells of a battery module, the battery module comprising a busbar configuration as claimed in claim 13, the method comprising: operating the switches of the busbar arrangement to isolate one or more cells, connect groups of cells in series, and/or connect groups of cells in parallel within the battery module.

Description

FIGURES

[0071] Certain example embodiments will now be described by way of example only and with reference to the accompanying drawings, in which:

[0072] FIG. 1 shows a perspective view of a battery module;

[0073] FIG. 2 shows a plan view of a battery module with a sensor arrangement;

[0074] FIG. 3 shows a plan view of a battery module with a sensor arrangement and switches;

[0075] FIG. 4 shows a top plan view of the top of a battery module and a top plan view of the bottom of a battery module similar to that shown in FIG. 3;

[0076] FIGS. 5 to 9 show one switching arrangement of battery module shown in FIG. 4;

[0077] FIGS. 10 to 14 show another switching arrangement of the battery module shown in FIG. 4;

[0078] FIG. 15 shows an exploded view of a magnetometer on a substrate;

[0079] FIG. 16 shows a schematic of a multiplexed array of magnetometers such as that shown in FIG. 15;

[0080] FIG. 17 shows a perspective view of an example battery pack;

[0081] FIG. 18 shows a plan view of a busbar arrangement with integrated sensors; and

[0082] FIG. 19 shows a plan view of another busbar arrangement with integrated sensors.

DETAILED DESCRIPTION

[0083] FIG. 1 shows a prior art battery module (1-1) comprising sixteen cylindrical cells (1-2) in a 4×4 configuration arrangement. The cells are connected via a busbar at the top of the module (1-3) and also via a busbar (1-4) at the base of the module, the busbars comprising a series of busbar links (1-5) between adjacent cells. In the example, the cells are mounted so that the negative terminal of each cell is located at the top of the module, so that the cells are in a parallel arrangement. In an alternative arrangement, the negative terminal of each cell may be located at the base of the module.

[0084] FIG. 2 shows a plan view of a 4×4 battery module (2-1) similar to that described above. In this first embodiment, a magnetometer (2-2) is mounted on each busbar link (2-3) between adjacent cells (2-4), at the top of the module. The busbar links are represented by dashed lines beneath the magnetometers. Each magnetometer reading can be used to calculate (non-invasively) the current in the busbar link.

[0085] While the magnetometers (2-2) are shown mounted on an outwardly facing surface of the busbar links (2-3) with respect to the battery module (2-1) as that is more convenient for fabrication, they could also be mounted on an inwardly facing surface of the busbar links (2-3) or a combination of inwardly and outwardly facing surfaces.

[0086] The current flowing in each cell can be calculated by taking the summation of the current flow from each busbar link into the terminal of the cell. Using this method, faulty cells (with either too much or too little current flowing) can be easily identified.

[0087] In this embodiment it is possible to measure the current in each cell within the module and the module can be controlled as a single unit.

[0088] In a second embodiment, it is possible to isolate dangerous or faulty cells individually within the module. The second embodiment is shown in FIG. 3. A 4×4 module (3-1) is shown with magnetometers (3-2) mounted on the busbar links (3-3) between individual cells (3-4), at the top of the module. In addition, a switch (3-5) is mounted on each busbar link between cells. The magnetometers are illustrated with dashed lines for clarity. As in the first embodiment, the current flowing in each cell is calculated by taking the summation of the current flow from each busbar link into the terminal of the cell. The switches can be opened around each cell to allow the isolation of faulty cells.

[0089] A third embodiment uses the techniques previously described in the first two embodiments, with the additional feature of the ability to reconfigure the individual cells in the module to balance the load within the module. This allows the cells within a single module to be configured in two or more series blocks to set the module voltage and load across the cells. A first example of this embodiment is shown in FIG. 4. In this 4×8 module (4-1), cells are mounted so that the positive terminal of one section of cells and the negative terminals of another section of cells are in contact with the upper busbar. The 4×8 array on the left side of FIG. 4 (4-2) shows a view of the top of the module (as viewed from above, e.g. from the exemplary line A-A shown in FIG. 1). The 4×8 array on the right side of FIG. 4 (4-3) shows a view of the bottom of the module (also as viewed from above, e.g. from the exemplary line B-B shown in FIG. 1). The left array (4-2) shows 16 cells on the left with positive terminals in contact with the top busbar via busbar links (4-4) and 16 cells on the right with negative terminals in contact with the top busbar via busbar links (4-5).

[0090] Magnetometers (not shown) and switches are mounted on the busbar links between adjacent cells, at the top of the module (4-2) as well as on the busbar links at the bottom of the module (4-3). The switches can be used to configure the module, so that the cells are connected in parallel or in series. Where busbar links between cells are shown, switches are closed and if no connection is shown between adjacent cells, switches are open. Hence, at the bottom of the array (4-3), all switches are closed. At the top of the array (4-2), switches are open between the bank of 16 cells connected in parallel on the right (those with positive terminals at the top) and the bank of 16 cells connected in parallel on the left (those with negative terminals at the top). All other switches are closed. The external connectors (4-6, 4-7) to the module (4-1) are shown. Current flows through the module via the external connectors (4-6), through the positive terminals of the first group of cells connected in parallel at the top of the array (4-2), to the negative terminals of those cells at the bottom of the array (4-3). Current then passes through the closed switches (4-8) connected in series, then through the second group of cells which are connected in parallel, to the top of the array (4-2) to “exit” the module via external connectors (4-7).

[0091] By adjusting the switching arrangement as shown in the next two examples, the voltage of the module can be controlled. If the cells are connected in parallel, the voltage of the module will equal the voltage of the cells. However, if the cells are connected in series, the voltage of the module will be a multiple of the voltage of individual cells.

[0092] A second example of the third embodiment is given in FIG. 5. The orientation of the cells is as before (shown in FIG. 4), however, in this example, the switching arrangement has been altered so that there are several groups of cells acting together in parallel at each stage. As before, closed switches are represented by a solid line connecting adjacent cells. If no connection between adjacent cells is shown, that switch is in the open position.

[0093] FIG. 6 shows the first stage. The module (6-1) is again split into two views: the top of the module, as viewed from above (6-2) and the bottom of the module, also as viewed from above (6-3). The top of the module (6-2) has as its “input” external connectors (6-4). Current flows through the first group of cells in parallel (shaded grey) and this passes in series to the second group of cells at the bottom of the module via two busbar links (6-5).

[0094] FIG. 7 shows the second group of cells in parallel (shaded grey), through which current flows via four busbar links (7-1) connected in series, to the third group of cells in parallel shown in FIG. 8. Current flows through the third group of cells (shaded grey) via two busbar links (8-1) connected in series, to the final group of cells in parallel. FIG. 9 shows the final group of cells (shaded grey) through which current flows out of the module via external connectors (9-1).

[0095] In this second example, 8 cells act together in each group at each stage i.e. there are evenly balanced cells across the module. In the third example, given below, of this (third) embodiment, there are unevenly balanced cells across the module.

[0096] A third example of the third embodiment is given in FIG. 10. The orientation of the cells is the same as that shown in the previous examples (FIG. 4 and FIGS. 5-9), however, a different switching arrangement is shown. As in the previous example (FIGS. 5-9), groups of cells act together in parallel at each stage to direct the current flow within the module.

[0097] FIG. 11 shows the first stage. The module (11-1) is again split into two views: the top of the module, as viewed from above (11-2) and the bottom of the module, also as viewed from above (11-3). The top of the module (11-2) has as its “input” external connectors (11-4). Current flows through the first group of cells in parallel (shaded grey) and this passes in series to the second group of cells at the bottom of the module via three busbar links (11-5).

[0098] FIG. 12 shows the second group of cells in parallel (shaded grey) through which current flows via three busbar links (12-1) connected in series, to the third group of cells in parallel shown in FIG. 13. Current flows through the third group of cells (shaded grey) via two busbar links (13-1) connected in series to the final group of cells in parallel. FIG. 14 shows the final group of cells (shaded grey) through which current flows out of the module via external connectors (14-1).

[0099] In this third example, it can be seen from FIGS. 11-14, that 9 cells act together at the first stage, 8 at the second stage, 7 at the third stage and 8 at the final stage i.e. there are unevenly balanced cells across the module. Hence, it can be seen that for the same arrangement of cells in a module, it is possible, by adjusting the switching configuration, to alter the balance of the output from/load on individual cells groups connected in parallel, within the module.

[0100] FIG. 15 shows an example of a fluxgate 15-1 that may be formed by printing on a substrate 15-2. The fluxgate comprises an upper conductive layer 15-3 and a lower conductor layer 15-4, each of the conductive layers comprising conductive wire portions arranged on a surface of a respective insulative layer 15-5, 15-6. The fluxgate further comprises a magnetic core 15-7 sandwiched between the upper and lower conductive layers, wherein ends of the conductive wire portions from the upper conductive layer are joined to ends of the conductive wire portions from the lower conductive layer to form coil structures, and wherein the lower conductive layer of the fluxgate is mounted to a substrate.

[0101] FIG. 16 shows an example array 16-1 of multiplexed fluxgates 16-2 similar to that shown in FIG. 15. Drive coil negative 16-3, drive coil positive 16-4, sense coil negative 16-5 and sense coil positive 16-6 connections can also be seen. The multiplexers 16-7 send outputs to a processor 16-8.

[0102] FIG. 17 shows an example battery pack 17-1 comprising two battery modules 17-2, each battery module comprising an array of cells 17-3. Busbar configurations 17-4 and battery management systems 17-5 are connected to each battery module. Sensor arrangements 17-6 are fitted to the exterior of the busbar arrangements. A third sensor arrangement 17-7 is also fitted between the battery modules.

[0103] Commercially available power electronics and current/magnetic field sensors such as those previously described can be directly embedded in a busbar arrangement, as shown in FIG. 18.

[0104] FIG. 18 shows a plan view of such a busbar arrangement with current sensors 18-3 in the form of Hall sensors and bidirectional switches 18-4 integrated into the busbar (rather than having separate sensors mounted on a busbar arrangement as described above in relation to FIGS. 2 and 3).

[0105] The busbar arrangement of FIG. 18 comprises a PCB 18-2 with electrical connection points 18-1 that correspond to the cell terminals of a 4×4 cell module to which the busbar arrangement can be connected. The cells (not shown) are attached to the underside of the PCB 18-2 using a conductive adhesive. The current sensors 18-3 and bidirectional power switches 18-4 are mounted between each electrical connection point 18-1. The busbar arrangement can be used to replace a conventional busbar arrangement by simply fitting the PCB 18-2 to a cell module via the connection points 18-1.

[0106] Alternatively, the cells of a cell module can be connected via integrated busbar links as shown in FIG. 19. Electrical connection points 19-1 correspond to the cell terminals of each cell (16 cell terminals are shown in FIG. 19). Conductive adhesive is used at each connection point 19-1 to connect the cell to the integrated busbar links which comprise a current sensor 19-2 and a bidirectional power switch 19-3, both mounted on a PCB 19-4 and connected in series. Alternatively, a current sensor and bidirectional power switch can be connected to the cell terminals via wires in free space.

[0107] The integrated current sensors 18-3, 19-2 in the above described arrangements of FIGS. 18 and 19 are connected in series with the bi-directional power switches 18-4, 19-3.

[0108] The bi-directional power switches 18-4, 19-3 are MOSFET configurations in order to produce a low resistance, high power switch.

[0109] It will be appreciated that these arrangements can perform any or all of the functions previously described in relation to separate sensor and busbar arrangements, including the monitoring of current flow and the dynamic reconfiguration of a battery pack by adjusting the switching configuration, to alter the balance of the output from/load on individual cells groups connected in parallel within the module. They can also enable degraded cells to be isolated or reconfigured in order to perform continuous cell balancing to maximise the safe usable energy of the battery.

[0110] As such, these busbar arrangements with integrated current sensors can provide a simpler, more robust and more compact way of realising the advantages of the present invention.

[0111] Any of the sensor arrangements described herein can also be separately be employed to check the quality of cell/busbar connections in a battery pack in order to identify faults in the connections themselves in addition to ensuring that all cells are functioning correctly. This has the potential to identify, non-invasively, a faulty weld in a battery pack.

[0112] To achieve this current/magnetic sensors such as the magnetometers or Hall sensors previously described can be placed between each cell to measure the current flow in the busbar link between neighbouring cells. This allows the current flow in individual cells to be determined as previously discussed; if reduced current flow is detected, bad welds can be identified.