DE102012000653A1 - Method for controlling potential equalization of battery cells in cell composite, involves raising continuously or stepwise compensation current to predetermined maximum value upon activation of first equalization process - Google Patents

Abstract

A compensating current associated with equalization processes is made to flow through battery cell assigned balancing resistor. The compensation current is raised continuously or stepwise to a predetermined maximum value upon activation of the first equalization process. The compensation current is controlled according to temperature during the second equalization process. An independent claim is included for battery device.

Description

The invention relates to methods for controlling the potential equalization of battery cells in a cell network according to the preamble of patent claim 1 and a battery device according to the preamble of patent claim 7.

Methods for controlling the potential equalization of battery cells are known from the prior art. In particular, lithium ion cells in a battery must always be kept at identical (within a certain margin of tolerance) voltage levels to maximize the extractable energy. The voltage levels of the cells drift over time due to slightly different cell chemistries. In order to ensure this, it is possible in the prior art to discharge cells with a higher voltage level specifically to the lower level of the remaining cells. This can be done by connecting individual resistors in parallel to the cells to be equalized. By means of the resistors connected in parallel, a discharge current over a single cell is established for the duration of the connection.

A disadvantage of such a method is that due to the high load of the balancing resistances, in particular by the large temperature deviation in a short time when activating a compensation process, the life of these is relatively short. The resistors can therefore only be used for a certain number of compensation cycles before they break. Furthermore, at high ambient temperature of the cell electronics no compensation process can be started or must be terminated after a short time, since the power loss of the resistors leads to a further increase in the ambient temperature and the electronics is thereby forced to turn off to prevent damage.

The object of the present invention is therefore to provide a battery cell device and a method for controlling the potential equalization of battery cells in a cell network, in which the balancing resistances are less loaded and a potential equalization of the battery cells in a wider temperature range of the ambient temperature of the cell electronics can be performed.

This object is achieved by a method having the features of patent claim 1, and by a battery device having the features of patent claim 7. Advantageous embodiments of the invention with expedient developments of the invention are specified in the dependent claims.

In the method according to the invention for controlling the potential equalization of battery cells in a cell network, a compensation current flows through at least one first compensation resistor assigned to one of the battery cells during a compensation process. In this case, the compensation current when activating the compensation process is increased continuously or stepwise to a predetermined maximum value and / or the compensation current is controlled temperature-dependent during the compensation process. Thus, when activating the compensation process, the at least one first, a battery cell associated compensation resistance is not charged abruptly, whereby he is not subject to a large temperature in a short time. The temperature increase of the compensation resistor can be slowed down substantially or arbitrarily by the continuous or step by step start-up of the compensation current, which enormously increases the service life of such compensation resistors and reduces their power loss. Due to the temperature-dependent control of the compensation current during the compensation process, it is possible to control the magnitude of the compensation current through the at least one first compensation resistor, and thus its temperature increase and its heat dissipation to the environment. Thus, the power loss of the at least one compensation resistor can be controlled specifically here as well. Thus, overheating of the cell electronics and consequent damage can be avoided. Furthermore, compensation processes can be carried out in a larger temperature range of the ambient temperature of the cell electronics, since the heat release by the compensation resistances can be controlled via the control of the compensation current as a function of the temperature, i. H. For example, at high ambient temperatures, balancing operations can be performed with low equalizing currents and, at low ambient temperatures, equalizing operations with higher equalizing currents.

In an advantageous embodiment of the invention, a period of time is adjustable, which requires the compensation current when activating the compensation process to reach the predetermined maximum value. This allows a smooth start-up of the compensation current, which can be adapted to the load capacity of the respective balancing resistances, which in turn has a positive effect on their service life.

It is also advantageous if the compensation current is controlled by means of a pulse width modulation (PMW) control of the at least one first resistor assigned to one of the battery cells. When activating the compensation process, it is thus possible that the at least one first compensation resistance is not the same to load with the maximum compensation current, but slowly ramp up the compensation current via voltage pulses. The pulse widths of the voltage pulses can be modulated by the PWM. For example, the pulse widths of the voltage pulses at the beginning of activating a balancing operation may be short, whereby only a small compensation current flows across the compensation resistor, and become increasingly longer, until the maximum compensation current is reached. Thus, the temperature of the at least one first compensation resistor is slowly increased, which increases its life.

Furthermore, it is advantageous if, when activating the compensation process, at least one second compensation resistor is connected, wherein the at least one first and the at least one second compensation resistor are assigned to the same battery cell. This distributes the temperature increase when activating the compensation process to at least two compensation resistors, which increases their service life.

In addition, it is preferable, if more than a second compensation resistor is switched on, that the connection of the compensation resistors takes place in succession. This allows a soft start-up of the compensation current without the use of PWM control.

In addition, it is advantageous to implement the connection of at least one second or more compensation resistors by a parallel connection and to use high-resistance resistors. High-impedance resistors are more resilient than low-resistance resistors with the same design. By a parallel connection, however, an arbitrarily high total current of the compensating current can be achieved, wherein the balancing resistors are charged only with a fraction of the total compensation current.

As a further advantage, it has been found that at least one second compensation resistor can be connected or disconnected as a function of the temperature, wherein the at least one first and the at least one second compensation resistor are assigned to the same battery cell. For example, at a high ambient temperature balancing resistances can be switched off, thereby reducing their heat dissipation to the environment. At low ambient temperatures, balancing resistances can be switched on, which increases the total maximum compensation current and speeds up the balancing process. Thus, it is also possible here to control the compensation current as a function of the temperature without PWM control and to allow compensation processes in a larger temperature range of the ambient temperature.

The battery device according to the invention is based on the method according to claim 1. The advantages described for the method according to the invention and its variants also apply to the battery device according to the invention and its exemplary embodiments.

Further advantages, features and details of the invention will become apparent from the claims, the following description of preferred embodiments and from the drawing.

Showing:

1 a representation of the time course of the compensation current of an embodiment of the method according to the invention.

1 shows a representation of the time course of the compensation current 5 , In this embodiment of the method according to the invention, the compensating current increases 5 when activating 1 the compensation process 2 continuously to its maximum value I _max , for example by a pulse width modulation control of the first one of the battery cells associated balance resistance. A gradual increase would also be conceivable, for example, by the successive connection of high-impedance balancing resistors, which are all assigned to the same battery cell, preferably in a parallel circuit. In this case, the time duration t ₀ , the compensating current 5 In order to reach its maximum value I _{max, it} must be adapted to the load capacity of the compensation resistors. Furthermore, the maximum value I _{max of} the compensation current 5 during the balancing process 2 be set temperature dependent. At high ambient temperature, which can be determined by temperature sensors, a low compensation current 5 and vice versa. On the one hand, this can be done by means of a PWM control of the at least one first compensation resistor, or by the connection or disconnection of at least one second compensation resistor, which is preferably connected in parallel with the at least one first compensation resistor.

In other words, the temperature increase per unit of time can be substantially or arbitrarily reduced by a smooth start-up of the compensation current and the balancing resistances are less stressed. This gentle startup can be realized for example by a PWM control of the balancing resistors, wherein the pulse width is to be modulated so that the temperature increase per unit time can be kept correspondingly low. Furthermore, a smooth start-up can also be realized by a parallel connection of high-impedance balancing resistors, which are connected in series, which distributes the temperature increase to a plurality of balancing resistances.

During the compensation process, the compensation current can be arbitrarily controlled by a PWM control of the balancing resistances and is not limited to the maximum current, which, as in the prior art, results from an ohmic resistance. Furthermore, it is also possible to adapt the equalizing current, even without PWM control, by means of a combination of compensating resistors which are appropriately connected. This makes it possible to regulate the heat development of the electronics and to compensate for the potentials of the battery cells even at high ambient temperatures.

Overall, such a method for controlling the potential equalization of battery cells in a cell assembly and a battery device are provided with a cell monitoring device, which significantly increase the life of balancing resistors and allow the temperature-dependent control of the compensation current to perform balancing operations in larger temperature ranges of the ambient temperature and at the same time the cell electronics to protect.

LIST OF REFERENCE NUMBERS

1

Activate

2

settlement process

5

transient

I _max

maximum value

t ₀

time

Claims (7)

Method for controlling the potential equalization of battery cells in a cell network, in which a compensation process ( 1 . 2 ) a balancing current ( 5 ) flows over at least a first one of the battery cells associated balancing resistance, characterized in that the compensating current ( 5 ) when activating ( 1 ) of the compensation process ( 2 ) is raised continuously or stepwise to a predetermined maximum value (I _max ) and / or that the compensating current ( 5 ) during the balancing process ( 2 ) is temperature-dependent controlled. Method according to Claim 1, characterized in that a time duration (t ₀ ) which the compensation current ( 5 ) when activating ( 1 ) of the balancing process is required to achieve the predetermined maximum value (I _max ) is adjustable. Method according to claim 1 or 2, characterized in that the control of the equalizing current ( 5 ) takes place by means of a pulse width modulation control of the at least one first of the battery cells associated balance resistance. Method according to claim 1 or 2, characterized in that upon activation ( 1 ) of the compensation process ( 2 ) at least a second compensation resistor is connected, wherein the at least one first and the at least one second compensation resistor are assigned to the same battery cell. A method according to claim 4, characterized in that when switching on more than a second balancing resistance, the connection of the balancing resistors takes place in succession. Method according to claim 1 or 2, characterized in that during the compensation process ( 2 ) at least one second compensation resistance as a function of the temperature can be switched or switched off, wherein the at least one first and the at least one second compensation resistor of the same battery cell are assigned. Battery device having a cell monitoring arrangement for equipotential bonding of battery cells in a cell assembly of the battery device, comprising - at least two battery cells in a cell network, - at least one battery cell associated with a compensation resistor on the in a balancing process ( 2 ) a balancing current ( 5 ), and - a control device, characterized in that the compensating current ( 5 ) when activating ( 1 ) of the compensation process ( 2 ) can be raised continuously or stepwise by the control device and / or that the compensation current ( 5 ) during the balancing process ( 2 ) is temperature-dependent controllable.

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