WO2016005107A1 - Method for controlling an output voltage of a battery system, and battery system configured for carrying out the method - Google Patents

Abstract

The present invention relates to a method for controlling an output voltage of a battery system (1), having a plurality of battery cells (2), which are electrically connected in such a way that in each case, battery cells (2) of the battery system (1) are switched into the battery system (1) in accordance with a first switching state, and are electrically bridged in accordance with a second switching state. In order to adjust an actual output voltage (3) of the battery system (1) to a target output voltage, at least one switch-on probability (5) is generated, and the battery cells (1) with the at least one generated switch-on probability (5) are switched into the battery system (1). In addition, a switch-over probability (15) is generated, and the battery cells (2) with the at least one generated switch-over probability (15) change the respective switching state. The present invention further relates to a battery system (1) designed for carrying out the method according to the invention, comprising a plurality of electrically connected battery cells (2), a plurality of drive circuits (10), and a control unit (16), wherein in each case, the battery cells (2) can be switched into the battery system (1), or can be electrically bridged, by means of the drive circuits (10).

Description

 Description title

 Method for regulating an output voltage of a battery system and for carrying out the method trained battery system

The invention relates to a method for controlling an output voltage of a battery system having a plurality of battery cells, which are electrically connected such that battery cells of the battery system are respectively connected to the battery system according to a first switching state and are electrically bridged according to a second switching state, wherein for adapting an actual - Output voltage of the battery system to a desired output voltage at least one switch-on probability is generated and the battery cells are connected to the battery system with the at least one generated switch-on probability.

Furthermore, the invention relates to a battery system comprising a plurality of electrically interconnected battery cells, a plurality of drive circuits and a control unit for controlling an output voltage of the battery system provided by the battery cells, wherein the battery cells each one of the drive circuits is assigned and the battery cells each by means of the drive circuits Battery system can be switched on or can be electrically bypassed.

State of the art

To meet requirements of battery systems in terms of their capacity and / or performance, it is known to electrically interconnect battery cells. In particular, it is known to connect a plurality of battery cells electrically in series to a battery string and this In turn, connect battery strings to each other electrically in parallel. In order to provide a required output voltage through the battery system, it is also known to connect such battery strings and / or individual battery cells of a battery system to the battery system, so that these battery cells provide a voltage contribution to the output voltage. Likewise, in order to provide a required output voltage, it is known to electrically bridge battery cells of the battery system in order to disconnect the battery cells from the battery system in such a way that they do not contribute any voltage to the output voltage of the battery system.

The problem here is in particular that the individual battery cells with respect to their capacity and their internal resistance have deviations, especially for manufacturing reasons, so that the battery cells usually have divergent states of charge.

From the documents KR 2003-92464, KR 2007-66293 and US 2005/053092 battery systems are known which comprise a plurality of battery cells, wherein for adapting an actual output voltage of the battery system to a predetermined desired output voltage of the battery system, the individual battery cells at random - Be switched off and thus either make a contribution to the output voltage of the battery system or not.

Furthermore, it is known in the prior art to generate a switch-on probability, wherein the battery cells are switched to the battery system with this switch-on probability. For example, if a battery system is designed to provide a maximum output voltage of 400 volts, with all the battery cells interconnected to provide the output voltage, and a target output voltage of 300 volts is required, a turn-on probability of 75 percent is set to maintain the predetermined target voltage. To reach output voltage.

This switch-on probability is advantageously via a central communication bus of the battery system, the battery cells or corresponding drive circuits of the battery cells communicates. In particular, it is known that each battery cell itself determines a battery cell associated quality factor, which may depend for example on the battery cell voltage of this battery cell, the battery cell temperature and / or the state of charge of the battery cell (SOC, SOC: State of charge).

Taking into account the quality factor of the battery cell and the predetermined switch-on probability then battery cells are connected to the battery system. In this case, the target output voltage is set on average. One

Disadvantage of this method is that the case may occur that the battery cells are switched so that a large deviation of the actual output voltage from the target output voltage occurs. This would then be corrected by the regulation in that the switch-on probability is adjusted accordingly. However, this can lead to undesirable outliers of the actual output voltage. If, in order to avoid this problem, the switch-on probability would not be redefined, disadvantageously an autonomous cell balancing would no longer be realized.

Against this background, it is an object of the present invention to improve the regulation of the output voltage of a battery system. In particular, an improved adaptation of an actual output voltage of a battery system to a desired output voltage is to be achieved. It should advantageously be avoided strong deviations of the actual output voltage from the desired output voltage. An autonomous cell balancing should advantageously continue to be possible.

Disclosure of the invention

To achieve the object, a method for controlling an output voltage of a battery system having a plurality of battery cells, which are electrically connected such that battery cells of the battery system are respectively connected to the battery system according to a first switching state and are electrically bridged according to a second switching state, proposed, for adapting an actual output voltage of the battery system to a desired output voltage at least one switch-on probability is generated and the battery cells are connected to the at least one generated switch-on probability the battery system, and wherein for adapting the actual output voltage of the

Battery system to the target output voltage in addition a switching probability is generated and change the battery cells with the generated switching probability the respective switching state. The switch-on probability is advantageously the one

Probability that an electrically bridged battery cell should be connected to the battery system. The switch-on probability preferably has a value between 0 and 1. The switchover probability is advantageously the probability that a battery cell changes its switching state at all, ie in particular changes from the first switching state to the second switching state or changes from the second switching state to the first switching state. It is possible in principle that the switching probability can also assume a value between 0 and 1.

A battery cell of the battery system is advantageously always either connected to the battery system or electrically bridged, the battery cell by a change in the interconnection, in particular by controlling switching elements, from one switching state in the other

Switching state can change, so for example, from the switching state "electrically bridged" can switch to the switching state "the battery system" switched. If a battery cell of the battery system is connected to the battery system, this battery cell advantageously provides a voltage contribution to the output voltage of the battery system. When charging the battery system, battery cells connected to the battery system are also advantageously recharged. If a battery cell of the battery system is electrically bridged, this battery cell advantageously provides no voltage contribution to the output voltage of the battery system. When charging the battery system electrically bridged battery cells are also advantageously not recharged.

By generating a switching probability in addition to the switch-on probability and the central transmission of this switching probability and the switch-on probability to the battery cells of a battery system, deviations between the actual

Output voltage and the target output voltage advantageously reduced.

For this purpose, provision is made, in particular, for the switching probability to be at low deviations between the actual output voltage and the setpoint

Output voltage has small values, so that virtually the readiness of a battery cell to change their switching state is lower and strong deviations from the desired value when specifying a new switch-on thus advantageously be avoided. Small deviations between the actual output voltage and the desired output voltage are in particular deviations of less than seven percent.

Furthermore, it is provided in particular that the switching probability has large values for large deviations between the actual output voltage and the setpoint output voltage, so that, as it were, the readiness of a

Battery cell whose switching state to change is greater and thus advantageously a faster and better adaptation of the actual output voltage to the target output voltage with specification of a new switch-on probability can thus be achieved. Large deviations between the actual output voltage and the desired output voltage are in particular deviations of more than twenty percent.

Advantageously, the change in the switching state still depends on the quality factor determined by the respective battery cell, the determination of the quality factor in particular being known from the prior art he follows. The quality factor may in particular depend on the state of charge of the battery cell and / or the battery cell temperature of the battery cell and / or the battery cell voltage of the battery cell. By the specification of switch-on probability and

Switching probability in consideration of the respective quality factor of the respective battery cell is advantageously an autonomous cell balancing allows, advantageously while avoiding the occurrence of large deviations between the actual output voltage and target output voltage.

In particular, it is provided that the at least one switch-on probability and / or the at least one switchover probability are generated as a function of the difference between the setpoint output voltage and the actual output voltage, preferably as a function of the difference between the setpoint output voltage and the actual output voltage.

According to a further preferred embodiment of the method according to the invention, the switching probability is generated as a function of the amount of the difference between the desired output voltage and the actual output voltage. This means that it is irrelevant in this embodiment for the size of the switching probability to be generated, whether the actual output voltage is greater or less than the desired output voltage. Particularly preferably, the switching probability becomes proportional to the

Amount of the difference between the setpoint output voltage and the actual output voltage generated. In particular, it is provided that the magnitude of the generated switchover probability increases linearly in relation to an increase in the amount of the difference between the desired output voltage and the actual output voltage.

Advantageously, the switching probability is greater than zero. This means that a switching probability other than 0 is always generated, so that a switchover of the battery cells between the first switching state and the second switching state is basically always possible, albeit where appropriate, the probability of such switching is low. Thus, an autonomous cell balancing, in particular taking into account the quality factor of the respective battery cell, is advantageously also possible.

In a generation of the switching probability based on a switching probability function, in particular a linear switching probability function, the

Switching probability function advantageously a predetermined offset when the actual output voltage matches the setpoint output voltage. In particular, this offset can have a value between 0.001 and 0.01. The switching probability is then advantageously always at least as large as the predetermined offset.

As a further particularly advantageous embodiment of the method according to the invention it is provided that the switching probability and / or an increase in the switching probability is limited when the amount of the difference between the desired output voltage and the actual output voltage exceeds a predefined value. Advantageously, the value is predefined as an absolute value, for example as a value of 20 volts or more, and / or as a relative value, for example as a deviation of more than 15%. If this predefined value is exceeded, it is provided as an embodiment variant that the generated switching probability is limited to a maximum value, in particular a value between 0.6 and 0.9. As a further embodiment variant, it is provided that the switchover probability, when the predefined value is exceeded, continues to increase with further increasing magnitude values of the difference between the setpoint output voltage and the actual output voltage, but less strongly than in the case of magnitude values that are smaller than the predefined value ,

Although various well-known controller types, such as controllers with D components, can be used to generate the switch-on probability and / or the switchover probability. However, it is preferably provided that the at least one switch-on probability by means of an I-controller or a PI controller is generated. The switching probability is preferably generated by means of a P controller.

According to a further advantageous embodiment variant of the method according to the invention it is provided that the connection of the

Battery cells can be done to the battery system for each battery cell with either positive polarity or negative polarity, to adapt the actual output voltage to the desired output voltage, a positive switch-on probability is generated and the battery cells with the generated positive switch-on probability are connected to the battery system with positive polarity and / or a negative switch-on probability is generated and the battery cells with the generated negative switch-on probability are connected to the battery system with negative polarity. In particular, it is provided that the battery cells are connected in a full bridge configuration to a battery string of the battery system.

The positive switch-on probability is advantageously the probability that a bridged battery cell with positive polarity should be connected to the battery system.

The negative switch-on probability is advantageously the probability that a bridged cell with negative polarity should be connected to the battery system.

The positive switch-on probability preferably has a positive sign, the negative switch-on probability preferably a negative sign. To achieve the object mentioned above is further a

Battery system comprising a plurality of electrically interconnected battery cells, a plurality of drive circuits and a control unit for controlling an output voltage provided by the battery cells of the battery system proposed, wherein the battery cells each one of the drive circuits is assigned and the Battery cells can be connected to the battery system respectively by means of the driving circuits or can be electrically bridged, wherein the battery system is advantageously designed to carry out a method according to the invention.

In particular, it is provided that the battery system is a battery system designed to provide the electrical energy required for the operation of a hybrid, plug-in hybrid or electric vehicle. The battery cells are advantageously secondary battery cells, that is, rechargeable battery cells, preferably lithium-ion cells.

In particular, it is provided that the battery system has at least one battery string, wherein a battery string advantageously each comprises a plurality of battery cells. Preferably, the battery system has a plurality of battery strings, wherein the battery strings are advantageously connected in parallel electrically.

According to a particularly advantageous embodiment of the battery system according to the invention it is provided that the battery system comprises at least one battery string, wherein the battery cells are each connected in a half-bridge configuration to a battery string of the battery system.

Another particularly advantageous embodiment of the battery system according to the invention provides that the battery system comprises at least one battery string, wherein the battery cells are each connected in a full bridge configuration to a battery string of the battery system. Due to the full bridge configuration, a battery cell of the battery system is advantageously electrically connected in each case such that the battery cell can be connected to the battery system with positive polarity of the battery system by means of the associated switching elements can be connected to the battery system with negative polarity and can be electrically bridged, the Battery cells advantageously - except for the switching torque as such - is in one of these switching states. According to a further particularly advantageous embodiment of the battery system according to the invention, it is provided that the drive circuit assigned to a battery cell comprises at least one switching element, at least one driver, at least one microcontroller circuit and at least one interface. The microcontroller circuit is advantageously designed to receive the at least one switch-on probability and the switching probability via the at least one interface. Advantageously, the microcontroller circuit is furthermore designed to generate a drive signal based on the at least one switch-on probability and the switchover probability. This drive signal is advantageously transmitted to the at least one driver. The driver is advantageously designed to switch the at least one switching element as a function of the generated drive signal. In particular, it is provided that the switching element is a transistor, preferably a MOSFET (MOSFET: metal oxide semiconductor field-effect transistor). In particular, it is further provided that the battery system comprises a bus system, preferably a CAN bus (CAN: Controller Area Network), via which in each case the at least one switch-on probability and the switching probability is transmitted to the battery cells, preferably centrally transmitted.

Advantageously, the battery system comprises a battery management system. The battery management system preferably comprises the control unit. In particular, it is provided that a control unit of the battery management system, preferably the Battery Control Unit (BCU) is designed to generate the at least one switch-on probability and / or the switching probability. The control unit in particular the actual output voltage and the target output voltage are supplied. Depending on the difference between the desired output voltage and the actual output voltage, the at least one of a switch-on probability function is advantageously used

Input probability and / or from a

Switch Probability function generates the switchover probability. The at least one switch-on probability and the Switching probability are advantageously the manipulated variables of the control of the output voltage.

Further advantageous details, features and design details of the invention are explained in more detail in connection with the exemplary embodiments illustrated in the figures. Showing:

1 shows a simplified schematic representation of an embodiment of a battery system according to the invention;

FIG. 2 shows a simplified schematic representation of a further exemplary embodiment of a battery system according to the invention; FIG.

3 shows a schematic representation of an exemplary embodiment for generating a switch-on probability and a switch-over probability;

4 shows a schematic illustration of a further exemplary embodiment for generating a switch-on probability and a switch-over probability; and

5 shows a schematic representation of an exemplary embodiment for generating a switching probability as a function of the amount of the difference between the nominal output voltage and the actual output voltage

The battery system 1 shown in FIG. 1 comprises a plurality of electrically interconnected battery cells 2, wherein, for better clarity, only one battery cell 2 with a drive circuit 10 assigned to the battery cell 2 is shown. This arrangement of battery cell 2 with drive circuit 10 is repeated several times, as symbolized by the punctures in the battery system 1.

The battery cells 2 are in the embodiment shown in Fig. 1 in a half-bridge configuration 7 via the battery string 6 the battery system 1 switchable or electrically bridged. This depends on the switch position of the switching elements 14. The switching elements 14 are driven by the respective battery cell 2 associated drive circuit 10. The switching element 14 can be realized in particular by transistors. In this case, the drive circuit 10 assigned in each case to a battery cell 2 comprises an interface 11, a microcontroller circuit 12 and a driver 13.

The battery system 1 further comprises a control unit 16, wherein advantageously the battery control unit of the battery system 1 is designed as a control unit. In this case, the control unit 16 is supplied with the actual output voltage 3 of the battery system 1 as an input variable. The control unit 16 is designed to generate a switch-on probability 5 and a switchover probability 15 as a function of the actual output voltage 3 and the predetermined desired output voltage. The switch-on probability 5 and the switch-over probability 15 are transmitted to the drive circuit 10 via a communication bus of the battery system 1.

The switch-on probability and the switching probability are transmitted to the microcontroller circuit 12 via the interface 11. Advantageously, the microcontroller circuit 12 is designed to determine a quality factor associated with the battery cell 2. In particular, battery cell parameters flow into the determination of this quality factor, in particular the battery cell voltage, the battery cell temperature and the state of charge of the battery cell. A good battery cell state leads to a high quality factor, a poor battery cell state to a low quality factor. The microcontroller circuit 12 is further configured to determine, based on the received switch-on probability 5, the received switching probability 15 and the quality factor associated with the battery cell 2, whether the switching state of the battery cell 2 is changed, ie the battery cell 2 is to be connected to the battery system 1 or is electrically bridged shall be. If the quality factor is high, this favors Connecting the battery cell 2 to the battery system 1. If the quality factor is low, this favors a bridging of the battery cell 2. The microcontroller circuit 12 sends a corresponding switching signal to the driver 13 for bridging the battery cell 2 or for connecting the battery cell 2 to the battery system 1 , which then the

Switching elements 14 switches accordingly.

The switching probability 15 is advantageously proportional to the amount of deviation between the actual and desired value of the battery output voltage. Thus, in case the desired target

Output voltage is reached, the switching probability is reduced to a minimum, so that only a few battery cells ever switch. As a result, it is advantageously prevented that a new switch-on likelihood specification leads to a state in which the deviation of the actual output voltage 3 from the setpoint output voltage becomes extremely high.

FIG. 2 shows an advantageous embodiment variant of the battery system 1 shown in FIG. 1 and explained in connection with FIG. 1. The battery cells 2 of the battery system 1 are in contrast to that shown in FIG

Embodiment over a full bridge configuration 8 connected to the battery string 6. Due to the full-bridge configuration 8, the battery cells 2 can advantageously be connected to the battery system 1 either with negative polarity or with positive polarity. Here, battery cells 2 with negative polarity advantageously by the battery cells

2 are loaded with positive polarity, whereby advantageously an autonomous cell balancing is further improved feasible. In addition, the battery cells 2 can be electrically bridged. The control unit 16 is advantageously designed to generate a switch-on probability 5 and a switch-over probability 15 which corresponds to that of a respective one

Battery cell 2 associated drive circuit 10 are transmitted.

According to an advantageous embodiment, not shown, it can be provided that a number of battery cells of a battery system in a half-bridge configuration to a battery string of the battery system is connected and a further number of battery cells of this battery system is connected in a full-bridge configuration to a battery string of this battery system. Fig. 3 shows a schematic representation of an advantageous

Embodiment for a realization of the control unit 16. By means of a summing unit 17, the difference between the setpoint output voltage 4 and the actual output voltage 3 is formed. Based on the difference between the desired output voltage 4 and the actual output voltage 3, the switch-on probability 5 is generated by means of a first regulator 18, preferably by means of an I or Pl controller. The switching probability 15 is generated by means of a second regulator 19, preferably a proportional regulator, from the difference of the desired output voltage 4 and the actual output voltage 3.

According to an advantageous embodiment variant shown in FIG. 4, it is provided that the amount of the difference between the nominal output voltage 4 and the actual output voltage 3 is initially formed by means of an absolute value image 20 in order to generate the switching probability 15. The switching probability 15 is then generated by means of the second regulator 19 in proportion to the amount of the difference between the desired output voltage 4 and the actual output voltage 3.

FIG. 5 shows a particularly advantageous characteristic curve as a switching probability function Ρυ _Μ (| Δ υ |) for generating the

Switching probability as a function of the amount | Δ U | the difference between the target output voltage and the actual output voltage shown. On the x-axis 21 of the illustrated coordinate system is the amount | Δ U | the difference between the desired output voltage and the actual output voltage applied. The respective value for the switching probability PUM is plotted correspondingly on the y-axis 22 of the illustrated coordinate system. For values of | Δ U | that lie in the interval [0, | Δ u, the advantageous characteristic shown in FIG. 5 is linear. In this case, the characteristic curve has an offset 23, which, in particular with only a slight deviation of the actual output voltage from the desired output voltage, that is, at | Δ U | ~ 0, ensures that a certain switching probability PUM persists, so that in particular "weak" battery cells, thus in particular battery cells with a low quality factor, can nevertheless switch off and thus an active cell balancing is still possible PUM thereby has the value PUM min, wherein PUM min can in particular have a value between 0.001 and 0.01, but in particular also larger values for PUM min are conceivable.

Moreover, the characteristic shown in FIG. 5 is such that the switching probability PUM is limited to a value PuM max when the value | Δ U | the difference between the desired output voltage and the actual output voltage has a predefined value | Δ U | _G exceeds. The switching probability PUM then advantageously increases even as the amount | ΔU | increases not further. PuM max can in particular have a value between 0.6 and 0.9.

According to a further embodiment variant, not shown in FIG. 5, it is provided that the characteristic PUM (| ΔU |) continues to rise even for values greater than ΔU | G, but advantageously significantly less than in the interval [0, | Δ u , The dependence of the switching probability PUM on | Δ U | greater | Δ U | _G is advantageously low.

The exemplary embodiments illustrated in the figures and explained in connection therewith serve to explain the invention and are not restrictive of it.

Claims

claims

1. A method for controlling an output voltage of a battery system (1) having a plurality of battery cells (2), which are electrically connected such that battery cells (2) of the battery system (1) in each case according to a first switching state the battery system (1) are switched on and are electrically bypassed according to a second switching state, wherein for adapting an actual output voltage (3) of the battery system (1) to a desired output voltage (4) at least one switch-on probability (5) is generated and the battery cells (1) with the at least one generated Switch-on probability (5) the battery system (1) are switched on, characterized in that for adapting the actual output voltage (3) of the battery system (1) to the desired output voltage (4) additionally a switching probability (15) is generated and the battery cells ( 1) change the respective switching state with the generated switchover probability (15).

2. The method according to claim 1, characterized in that the at least one switch-on probability (5) and / or the switchover probability (15) in dependence on the difference between the desired output voltage (4) and the actual output voltage (3) are generated.

3. The method according to any one of the preceding claims, characterized in that the switching probability (15) is generated as a function of the amount of the difference between the desired output voltage (4) and the actual output voltage (3).

4. The method according to any one of the preceding claims, characterized in that the switching probability (15) proportional to the amount of the difference between the desired output voltage (4) and the actual output voltage (3) is generated.

Method according to one of the preceding claims, characterized in that the switching probability (15) is greater than zero.

Method according to one of the preceding claims, characterized in that the switching probability (15) and / or an increase in the switching probability (15) is limited when the amount of the difference between the desired output voltage (4) and the actual output voltage (3) exceeds a predefined value.

Method according to one of the preceding claims, characterized in that the at least one switch-on probability (5) is generated by means of an I-controller or a PI controller and / or the switch-over probability (15) is generated by means of a P-controller.

A battery system (1) comprising a plurality of electrically interconnected battery cells (2), a plurality of drive circuits (10) and a control unit (16) for controlling an output voltage of the battery system (1) provided by the battery cells (2), wherein the battery cells (2 ) is assigned in each case one of the drive circuits (10) and the battery cells (2) each by means of the drive circuits (10) the battery system (1) can be switched on or can be electrically bypassed, characterized in that the battery system (1) is formed, a Method according to one of Claims 1 to 7.

Battery system (1) according to claim 8, characterized in that the battery system (1) comprises at least one battery string (6), wherein the battery cells (2) each in a half-bridge configuration (7) to a battery string (6) of the battery system (1 ) are connected.

10. Battery system (1) according to claim 8 or claim 9, characterized in that the battery system (1) comprises at least one battery string (6), wherein the battery cells (2) each in a full-bridge configuration (8) to a battery string (6 ) of the battery system (1) are connected.

11. Battery system (1) according to one of claims 8 to 10, characterized in that the one battery cell (2) assigned drive circuit (10) at least one switching element (14), at least one driver (13), at least one microcontroller circuit (12) and at least one interface (11), wherein the microcontroller circuit (12) is adapted, via the at least one interface (11) to receive the at least one switch-on probability and the switching probability and generate based thereon a drive signal, and wherein the driver (13) is formed is to switch in dependence on the generated drive signal, the at least one switching element (14).