Device for electropolishing an energy storage device comprising at least one lithium ion cell, charger, and method for operating the charger

Abstract

A device for electropolishing an energy storage device having at least one lithium-ion cell comprises at least one actuatable first switch which is connected in series to a capacitor and an electrical resistor for current limitation parallel to at least one lithium ion cell, wherein an apparatus for discharging the capacitor is connected in parallel at least to the capacitor (C). The invention further relates to a charger and to a method for operating the charger.

Claims

1. A device for electropolishing an energy storage unit having at least one lithium-ion cell, the device comprising: at least one actuatable first switch that is connected in series with a capacitor and an electrical resistor for current limitation, wherein the at least one actuatable first switch, the capacitor and the electrical resistor are connected in parallel to the at least one lithium-ion cell, an apparatus for discharging the capacitor connected in parallel at least to the capacitor, wherein the apparatus has a controllable electrical energy converter that is designed as a direct current converter, and a control unit that is configured to control the at least one actuatable first switch in order to carry out a pulse discharge for electropolishing the lithium-ion cell in such a way that at least one of lithium nucleation seeds, dendrites, and crystals are broken down by the pulse discharge.

2. The device according to claim 1, wherein the apparatus has an actuatable second switch and a consumer for using the energy stored by the capacitor.

3. The device according to claim 2, wherein the consumer has an electrical resistor for converting the energy stored by the capacitor into heat.

4. The device according to claim 1, wherein the apparatus has at least one freewheeling diode.

5. The device according to claim 4, wherein the apparatus has only the freewheeling diode and the electrical resistor connected in series.

6. The device according to claim 1, wherein the energy converter with its secondary side is connected to at least one lithium-ion cell in order to feed discharge energy of the capacitor back into the lithium-ion cell.

7. The device according to claim 1, wherein the control unit is configured in to control at least one of the at least one actuatable first switch and an electrical energy converter in order to carry out the pulse discharge for electropolishing.

8. A charger for electrically charging an energy store having multiple lithium-ion cells, comprising a device according to claim 1 for at least one of the lithium-ion cells.

9. A method for operating the charger according to claim 8, comprising, during the charging operation of an energy storage unit by means of the charger, carrying out a pulse discharge of at least one lithium-ion cell of the energy store by at least one device that is associated with the energy storage unit, in such a way that at least one of lithium nucleation seeds, dendrites, and crystals are broken down by the pulse discharge.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) Further advantages and preferred features and feature combinations result in particular from the above discussion and from the claims. The invention is explained in greater detail below with reference to the drawings, which show the following:

(2) FIG. 1 shows an energy storage system of a motor vehicle,

(3) FIG. 2 shows an advantageous device for electropolishing lithium-ion cells of the energy store,

(4) FIG. 3 shows a second exemplary embodiment of the advantageous device,

(5) FIGS. 4A and 4B show a third exemplary embodiment of the advantageous device,

(6) FIG. 5 shows a flow chart for explaining an advantageous method for operating the advantageous device, and

(7) FIG. 6 shows an application example of the advantageous device from FIG. 4A.

DETAILED DESCRIPTION OF THE INVENTION

(8) FIG. 1 shows a simplified illustration of an energy storage system 1 of a motor vehicle, not illustrated in greater detail here. The energy storage system 1 has an energy store 2 that includes one or more lithium-ion cells 3 connected in series or in parallel to one another. In addition, the energy storage system 1 has a high-voltage terminal 4_H that is connectable, for example, to the electric drivetrain of the motor vehicle. Furthermore, the energy storage system 1 has a low-voltage terminal 4_N that is used, for example, for supplying energy to a control unit 5 of the energy storage system 1.

(9) The energy store 2 is connected to the high-voltage terminal 4_H via a fuse 6 and a main contactor 7, a precharge circuit 8 being connected in parallel to the main contactor 7. The energy store 2 is connected to the negative pole of the high-voltage terminal 4_H via a further main contactor 9 and a current sensor 10. The control unit 5, which is also used as a battery management system, monitors the energy store 2 and optionally also the fuse 6 as well as the apparatuses 7, 8, 9, and 10.

(10) The charging of the energy store 2 is regulated by a charging current that is specified by the battery management system. To shorten the charging time, the charging current is increased, which may result in lithium nucleation seeds and nanoscale particles forming sponge-like or needle-shaped dendrites.

(11) A device 11 that is integratable into the energy storage system 1 or provided by a charger is presented below in different exemplary embodiments, and is used as needed to remove the in particular needle-shaped dendrites from the lithium-ion cells 3 of the energy store 2. The presented device 11 is thus used for electropolishing in particular an anode of the particular lithium-ion cell 3.

(12) FIG. 2 shows a first exemplary embodiment of the device 11 in a simplified illustration. A resistor R is connected in parallel, and a capacitor C is connected in series, to the energy store 2, with an actuatable switch S situated between the capacitor C and the resistor R. In addition, a balancing circuit 12 having a balancing resistor R.sub.B and a further switch S.sub.B is situated in parallel to the capacitor C.

(13) The circuitry of the particular lithium-ion cell 3 is designed as a function of the properties of the cell, i.e., its capacitance and its electrode surface area or electrode size, which determines the capacitance and resistor values of the cell. Due to the RC element, which is made up of the resistor R and the capacitor C, wherein the resistor R limits the current flow and the capacitor C ensures that no overload occurs when a switch S is defective, the maximum current pulse is limited by the resistor R when a capacitor is discharged, so that the energy store 2 or the particular cell undergoes the desired high discharge pulse, and lithium nucleation seeds are thus broken down, wherein the capacitor C charges over a certain period of time and the discharge current is thus decreased. As soon as the capacitor C is fully charged, the resistance increases infinitely. By closing the switch S.sub.B and opening the switch S, the energy stored in the capacitor may then be converted into heat via the balancing resistor R.sub.B and thus released. The resistor R.sub.B thus represents a consumer 13 that uses energy that is buffered in the capacitor, thus preparing the capacitor C for the next discharge pulse.

(14) FIG. 3 shows a second exemplary embodiment of the device 11. The device 11 according to the second exemplary embodiment differs from the preceding exemplary embodiment in that a freewheeling diode D and the consumer 13 connected in series thereto are connected in parallel to the capacitor C and the resistor R. The consumer 13 in this case is likewise a resistor R.sub.L. The switch S is connected upstream from the capacitor C, the resistor R, and the diode D and the consumer 13. The same as for the balancing resistor R.sub.B and the switch S, the diode D and the consumer 13 represent an apparatus 14 for discharging the capacitor C.

(15) The device 11 having the apparatus 14 according to the second exemplary embodiment has the advantage over the first exemplary embodiment that after the switch S is opened, the energy of the capacitor C is automatically released or removed by the consumer 13.

(16) In principle, the device 11 may be designed in two variants. In the limitation in FIG. 3, the need for active components is less; for this purpose, however, the cell balancing must be discharged via the capacitor C, whereas in the first exemplary embodiment the cell balancing may be carried out independently of the capacitor C.

(17) The device 11 is preferably integrated into a charger 15 that represents an external charger and has its own voltage supply for charging the energy store 2. By use of the device 11, the pulse-like discharging operation of one or more lithium-ion cells of the energy store 2 may be carried out during the charging operation in particular to break down the needle-shaped dendrites.

(18) FIGS. 4A and 4B show further exemplary embodiments of the device 11, which differ from the preceding exemplary embodiments in that the apparatus 14 has a controllable energy converter 16, in the present case in the form of a direct voltage converter. The direct voltage converter 16 is integrated into the charger 15 or into the energy storage system 1 in such a way that the direct voltage converter is connected on the one hand in parallel to the capacitor C, and on the other hand is connected on the output side in particular to the energy store 2 and/or a lithium-ion cell of the energy store 2 in order to return the energy that is released by the capacitor C to the energy store 2 and thus assist with the charging operation. The energy converter 16 thus replaces the consumer 13 and the switch S or the diode D, and allows recovery of at least a major portion of the energy that is used for the electropolishing.

(19) The exemplary embodiments from FIGS. 4A and 4B differ solely in that the arrangement of the resistor R and of the switch S are interchanged. The switches S2 and S1 and the resistors R each have the same dimensions.

(20) FIG. 5 shows one advantageous method for operating the charger 15 or the device 11, with reference to a simple flow chart. The method is advantageously carried out by a regulator and in particular by the control unit 5. The following discussion refers to the exemplary embodiment of FIG. 2. The switch S is opened, thus deactivating the balancing circuit, in the first step S1.

(21) The charging current i during the charging operation is monitored in a second step S2. When this charging current i=0, it is assumed that the previous charge pulse is ended. The pulse switch S is subsequently switched on in a step S3, thus connecting the capacitor C to the lithium-ion cell 3 in order to discharge it.

(22) The resistance value Z formed by the capacitor C for the particular lithium-ion cell 3 is subsequently detected in a step S4 at multiple points in time t.sub.1 through t.sub.x, where t.sub.x represents the point in time at which the capacitor reaches its maximum resistance.

(23) This point in time t.sub.x is compared to the point in time at which the charging current becomes equal to zero in a subsequent step S5. In particular a difference of t.sub.x−t is formed (when i=0) and compared to the value t.sub.x. If the difference is greater than or equal to the point in time t.sub.x, the pulse switch S is once again deactivated or switched off, and the balancing switch S.sub.B is switched on.

(24) A check is subsequently made in a step S6 as to whether the time of the charge pulse corresponds to 5 T, where T=R.sub.B×C. If this is determined, the balancing switch S.sub.B is switched off.

(25) The new charging current i.sub.charge (t) for the next charge pulse is subsequently determined in a step S7 as a function of the instantaneous resistance value, and the charging process is continued.

(26) A discharge pulse is carried out in particular periodically.

(27) Different variants using the advantageous device 11 or the charger 15 are conceivable. Thus far it has been assumed that in each case a device 11 for electropolishing is connected to each lithium-ion cell 3, so that dendrites possibly present may be removed from the individual cells by the pulse discharge. However, it is alternatively conceivable that the device 11 is simultaneously associated with multiple lithium-ion cells 3 in order to jointly discharge them. The multiple lithium-ion cells 3 may form, for example, a module of the energy store 2, wherein the energy store 2 preferably has multiple such modules, each with a device 11. It is also conceivable to associate the device 11 with the energy store 2 as a whole in order to carry out the discharging process or the electropolishing for all lithium-ion cells 3 of the energy store 2 at the same time.

(28) FIG. 6 shows a variant in one exemplary embodiment in which a device 11 is associated in each case with a module made up of multiple lithium-ion cells Z.sub.1 through Z.sub.n, wherein in this case the device 11 is designed according to the exemplary embodiment from FIG. 4a. The current fed back from the energy converter 16 is supplied to the energy store 2, not to the particular module. Alternatively, the fed-back current could also be supplied to the particular module.

(29) Overall, this results in particular in the following variants:

(30) According to one exemplary embodiment, a device 11 according to FIG. 4A is associated with each single cell 3, wherein a secondary side of the energy converter 16 is connected to the positive and negative poles of the single cell, so that the energy is fed directly back to the single cell.

(31) According to another exemplary embodiment, it is provided that the device 11 is associated in each case with one cell, wherein the secondary side of the energy converter 16 is connected to the positive and negative poles of the battery module, which includes multiple of the lithium-ion cells 3 connected in series, so that the energy is fed back to the battery module.

(32) According to another exemplary embodiment, it is provided that the device 11 is associated in each case with one cell 3, wherein the secondary side of the energy converter 16 is connected to the positive pole and the negative pole of the energy store 2 as a whole, wherein the energy store includes a series connection of multiple single cells 3. The energy that can be fed back to each single cell during the electropolishing is thus returned to the overall battery system.

(33) Alternatively, the energy store 2 has multiple battery modules, each with multiple single cells that in particular are connected to one another in series, wherein the energy, as described above, is then fed back to the energy store or to the particular battery module.

(34) According to another exemplary embodiment, it is provided that a device 11 is associated with each battery module, wherein the secondary side of the particular energy converter 16 is connected to the positive pole and the negative pole of the particular battery module, so that the fed-back energy is supplied to the particular battery module.

(35) According to another exemplary embodiment, it is provided that a device 11 is associated with each battery module, wherein the secondary side of the particular energy converter 16 is connected to the positive pole and the negative pole of the energy store 2, so that the energy of the battery modules released during the electropolishing is fed back as a whole into the energy store 2.

(36) According to another exemplary embodiment, it is provided that the device 11 is associated with the entire battery system or the entire energy store 2, wherein the secondary side of the one energy converter 16 is then associated with the positive pole and the negative pole of the energy store 2, so that the energy for electropolishing all cells 3 of the energy store 2 is returned to the battery system or the energy store 2.

(37) FIG. 6 shows the exemplary embodiment in which multiple single cells 3 are combined to form a battery module 17 in each case, wherein multiple of these battery modules 17 are connected in series in the energy store 2. A device 11 that is in particular part of the charger 15 and functions as described above is associated with each battery module 17. In the present case, the devices 11 are designed according to the exemplary embodiment from FIG. 4A. The secondary side of the particular energy converter 16 is connected in each case to the positive pole and the negative pole of the energy store 2, so that the energy released during the electropolishing in the discharging of the capacitor C is fed back as a whole to the energy store 2.

(38) Due to the advantageous design of the devices 11 and the advantageous method, the service life and reliability of the energy store 2 are increased by periodically breaking down the lithium nucleation seeds. In addition, charging of the energy store 2 with an increased charging current and a shortened charging time is made possible. The longer usability of the energy store 2 also results in cost advantages. Energy losses that result in particular when the energy converter 16 is used in the device 11 are minimized during the electropolishing.

(39) The time of the overall discharge pulses advantageously corresponds to 0 to 50%, preferably 0.01% to 25%, particularly preferably 0.05% to 10%, and in particular 0.1% to 5%, of the charging time. The number of discharge pulses is preferably 1 to 5, in particular 2 to 20, particularly preferably 5 to 100, preferably 10 to 1000. The discharge pulse duration is preferably 0.001 s to 30 s, in particular 0.005 s to 10 s, particularly preferably 0.01 s to 5 s, and in particular 0.02 s to 2 s.

LIST OF REFERENCE SYMBOLS

(40) 1 energy storage system 2 energy store 3 lithium-ion cell 4_H high-voltage terminal 4_N low-voltage terminal 5 control unit 6 fuse 7 main contactor/apparatus 8 apparatus 9 apparatus 10 apparatus 11 device 12 balancing circuit 13 consumer 14 apparatus 15 charger 16 energy converter 17 battery module R resistor R.sub.B resistor R.sub.L resistor C capacitor D freewheeling diode S switch S.sub.B switch