DE102020121612A1 - Method for determining a state of charge of a battery, battery and vehicle - Google Patents

Abstract

The invention relates to a method for determining a state of charge (SOC) of a battery (1) and a battery (1) and a vehicle with such a battery (1). The battery (1) advantageously has a plurality of first battery cells (3A) with a charging/discharging voltage of 3 volts to 3.5 volts. The battery (1) also has at least one second battery cell (3B), the second battery cell (3B) having a charge voltage/discharge voltage with an increased possible change in voltage, for example 3 volts to 5 volts. A monitoring unit (5) records the voltage (U) at the second battery cell (3B) and uses the voltage (U) at the second battery cell (3B) to determine the state of charge (SOC) of the battery (1). Due to the increased width of a possible change in the voltage (U), in particular the charging voltage/discharging voltage, the state of charge (SOC) of the battery (1) can be determined more precisely.

Description

The invention relates to a method for determining a state of charge of a battery. The invention also relates to a battery and a vehicle with such a battery.

Determining the state of charge of a battery, in particular a lithium-ion battery, is often only possible imprecisely. In addition, to determine the state of charge, it may be necessary to fully charge or discharge the battery. In addition, the respective battery cells of the battery have a different charge. A state of charge is also referred to as the State of Charge (SOC).

As a result, regular full charging events are disadvantageously necessary in order to enable the state of charge to be determined precisely.

EP 3 309 568 B1 discloses an example of a relatively complex way of simulating the state of charge with the help of a simulation.

DE 10 2010 050 980 discloses a method for determining the state of charge of a battery for different ages of the battery.

Disadvantageously, the solutions of the current state of the art for determining the state of charge of a battery are expensive.

It is therefore the object of the invention to provide a method and a battery with the aid of which a state of charge can be recognized in an improved manner.

The object is achieved with the aid of a method according to claim 1. The object is also achieved with the aid of a battery according to claim 5. Finally, the task is solved by a vehicle with such a battery.

Advantageous configurations and further developments are the subject matter of the dependent claims.

In the method for determining a state of charge of a battery, the battery comprises a plurality of first battery cells and at least one second battery cell, the at least one second battery cell having a higher voltage and/or a wider possible change in voltage than the respective first battery cell, wherein a The voltage and/or the change in the voltage of the at least one second battery cell is determined and the state of charge of the battery is determined based on the voltage, in particular the change in voltage as a function of time and/or as a function of the state of charge of the at least second battery cell .

The first battery cells are advantageously connected in series, so that the voltages of the respective battery cells add up. The second battery cell is advantageously connected in series with the respective first battery cells. The second battery cell is particularly advantageously positioned at at least one end of the series connection of first battery cells.

The voltage can be the charging voltage of the battery or the discharging voltage of the battery depending on whether the battery is being charged or discharged.

The discharge voltage is advantageously the voltage which is present at the battery or at the respective battery cell in the loaded state between its poles. The charging voltage is advantageously the voltage which is present at the poles of the battery or the battery cell during the charging process.

The first battery cell in each case can be a battery cell of a first type or of a first design, and the second battery cell in each case can be a battery cell of a second type or of a second design. Advantageously, the first and second battery cells each have different cell chemistry characteristics.

A possible change in the voltage at the battery or the battery cell can also be referred to as a voltage swing. In the unloaded case, the voltage usually reduces as the state of charge decreases. As the state of charge increases, the voltage usually increases. This relationship generally applies in the loaded and unloaded case, in which there is an infinitely high resistance between the poles of the battery or the battery cell.

The battery cells are advantageously connected in series and thus form a module, with the module providing the voltage as the sum of the voltages of the battery cells. A battery can include one or more such modules.

The state of charge is also referred to as the state-of-charge (SOC) and usually indicates to what extent the battery is charged. The state of charge is advantageously specified as a percentage, with a fully discharged battery having a state of charge of 0% and a fully charged battery having a state of charge of 100%.

As a rule, battery cells of one type each have a defined range for a voltage, in particular the charging voltage, with the range of the voltage generally depending on the chemical composition of the respective battery cell.

The respective first battery cell and the respective second battery cell advantageously have a similar capacity. Advantageously, the capacities of the respective first and second battery cells deviate from one another by a maximum of 10%. The second battery cell particularly advantageously has a higher capacity than the first battery cell.

The second battery cell is advantageously designed in such a way that its capacity does not fall above the capacity of the respective first battery cell over a long period of operation. The at least equally high capacity of the second battery cell in comparison to the respective first battery cell advantageously prevents the second battery cell from forming a capacity-limiting factor.

A change in the voltage and/or the current of the respective battery cell can be understood to mean a rise or fall over time.

Alternatively, a possible change in the voltage can be understood to mean the difference in the voltage of the battery or the respective battery cell at a state of charge of 0% and a state of charge of 100% (advantageously in the respective unloaded state). Alternatively, the possible change in voltage between states of charge of 20% and 80% can be defined.

The invention is based on the finding that the determination of the state of charge is imprecise in the case of a weak change in the (charging) voltage or the (charging) current during the charging process for a first battery cell. When using a second battery cell with a higher possible change in voltage or a higher possible change in current, the state of charge can be determined more precisely with the aid of the second battery cell. However, second battery cells usually have a more complex structure and are therefore more complex and/or expensive to manufacture than first battery cells.

The invention circumvents this disadvantage in that the battery comprises only a second battery cell or a small number of second battery cells. The state of charge is preferably determined on the basis of the respective second battery cell, while a larger number of the first battery cells are used to store a large part of the electrical energy. Alternatively or additionally, the second battery cell can be used to check a determination of the state of charge of the respective first battery cells.

By using first and second battery cells in the arrangement described above, an accurate and low-error determination of the state of charge can be determined even with a slight increase in technical complexity through the use of predominantly first battery cells (of a simple type).

In an advantageous embodiment of the invention, the voltage of the at least one second battery cell is determined at a first point in time and a second point in time, the state of charge of the battery being determined on the basis of the voltages, the change in voltage and/or the current.

The points in time are preferably arranged during a charging process or during a discharging process of the battery. In order to have the greatest possible effect, the time points can be spaced 10 to 30 minutes apart. For example, the first point in time is arranged 5 to 60 seconds after the start of the respective charging process or the respective discharging process. Also by way of example, the second point in time is arranged 5 to 60 seconds before the end of the respective charging process or the respective discharging process.

If the duration of the charging process is not known, the points in time can be arranged at intervals of 1 minute to 60 minutes.

The voltage and/or the current are each detected using a corresponding detection means, it being possible for the respective detection means to be integrated in the battery management system.

The change in the voltage or the current is advantageously determined by regularly determining the voltage and/or the current of the respective battery cell, in particular the respective second battery cell.

The detection of the respective voltage can advantageously be combined with a detection of the current (charging voltage and/or discharging current). Such a detection takes place particularly advantageously at regular time intervals, for example once per millisecond. Alternatively, the voltage and/or the current can be detected every 1 to 10 seconds.

By detecting the respective voltage, in particular at the second battery cell, the state of charge can be determined particularly precisely.

In a further advantageous embodiment of the invention, a monitoring unit serves to determine the respective state of charge of the respective second battery cell and optionally of the respective first battery cell.

The monitoring unit is particularly advantageously used to determine the respective charge states of the first and second battery cells together.

The monitoring unit is advantageously designed as an ASIC module. The monitoring unit preferably comprises detection means for current and/or voltage, in particular for the (discharge) charge current and/or for the (discharge) charge voltage. Furthermore, the monitoring means can include a computing unit in order to determine the state of charge from the detected values of the voltage and/or the current, in particular the (discharging) current and/or the (discharging) charging voltage.

In addition, the monitoring unit can be integrated into a battery management system. As a rule, a battery management system includes appropriate detection means and optionally the computing unit.

By integrating the monitoring unit into a module or into an already existing battery management system, the invention can be integrated into an existing battery in a simplified manner.

In a further advantageous embodiment of the invention, the current at the second battery cell is detected, with the state of charge of the battery being detected using current integration.

The current that runs through the second charging cell is advantageously recorded as a function of time and/or integrated over time. Such a process is also referred to as Coulomb counting.

With the aid of the configuration described above, the state of charge can be corrected for errors.

Alternatively or additionally, the voltage during charging and/or discharging of the respective battery cell can be recorded as a function of time. Since detecting a voltage is generally more accurate than determining a current, knowing the charging curve/discharging curve, for example the charging voltage as a function of time or as a function of the state of charge, can be used to easily determine the state of charge.

The states of charge, which are determined by detecting the current or by detecting the voltage, are compared to one another in a particularly advantageous manner and are used in each case to correct the state of charge determined in the other way.

In summary, a state of charge of the battery can be precisely detected with the aid of the method by detecting the current and/or the voltage at the at least one second battery cell. A plurality of first battery cells with a small change in voltage are advantageously combined with at least one second battery cell, the second battery cell having an increased change in the charging voltage or the discharging voltage as a function of the state of charge. By determining the voltage, in particular with a constant current, at successive points in time at the respective second battery cell, the state of charge of the battery can be determined particularly precisely. Since second battery cells are often more complex to produce and therefore often more expensive than first battery cells, the state of charge can be determined very precisely on a battery that is easy to produce. An existing battery can advantageously be upgraded by replacing at least one battery cell.

The battery has at least one first battery cell and at least one second battery cell, with the battery being assigned a monitoring unit, with at least the respective first battery cells and optionally the second battery cell being connected in series, with the monitoring unit being designed to determine the current of the at least second battery cell is, wherein the second battery cell has a higher change in voltage as a function of time or the state of charge compared to the respective first battery cell.

The battery advantageously includes a second battery cell, the second battery cell being connected in series with a plurality of first battery cells.

The first battery cells and the second battery cell(s) advantageously have a similar capacity. The second battery cell with a low state of charge advantageously has a lower charge voltage/discharge voltage than the respective first battery cell and/or a higher charge voltage/discharge voltage than the respective first battery cell.

In order to make defective or aged battery cells, in particular the second battery cell, replaceable, the battery can have connection options. The second battery cell can thus be removed from the series connection in a particularly advantageous manner if there is a detachable connection between the second battery cell and the respective (connection) adjacent battery cells.

In a further advantageous embodiment of the invention, the monitoring unit is integrated in a battery management system and/or designed as an ASIC module.

A battery management system (BMS) is advantageously assigned to the battery. The state of charge of the battery is preferably determined only by detecting the current and/or the voltage of the at least one second battery cell.

The integration of the monitoring unit in an ASIC component makes it possible to determine the state of charge in a particularly simple manner, since such an ASIC component is small and can therefore be easily integrated into a battery.

In a further advantageous embodiment of the invention, the respective first battery cell is a lithium iron phosphate battery cell.

Such a battery cell is characterized by simple production and the associated easy availability. Because the battery consists predominantly of first battery cells, such a battery can be provided particularly inexpensively.

In a further advantageous embodiment of the invention, the respective second battery cell is a lithium-nickel-manganese-cobalt battery cell.

Such a second battery cell is characterized by a high bandwidth of the charging voltage or discharging voltage as a function of the state of charge. In comparison to the first battery cell, whose charge voltage or output voltage fluctuates between 3.2 volts and 3.3 volts, a second battery cell of the aforementioned type can fluctuate between 3.6 volts and 4.2 volts. Due to the relatively large difference in the charging voltage/discharging voltage, a second battery cell can be used to determine the state of charge of the battery cell particularly precisely—and thus determine a particularly precise state of charge of the battery.

In a further advantageous embodiment of the invention, the respective first battery cell has an output voltage or charging voltage of 3 volts to 3.5 volts, with the respective second battery cell having an output voltage or charging voltage of 3 volts to 5 volts.

The aforementioned voltage values of the first and/or second battery cell are advantageously determined in the unloaded state.

Of course, other types of battery cells with the appropriate properties for the battery can also be used, insofar as at least one of the battery cells has an increased range of charging voltage or discharging voltage.

In a further advantageous embodiment of the invention, the second battery cell is directly connected to a first battery cell on only one side.

In the above embodiment of the invention, the first and second battery cells can be connected in series and at least one second battery cell forms the beginning and/or end of the series.

In a further advantageous embodiment of the invention, the output voltage of the battery in the unloaded state is between 10 and 60 volts or a high-voltage battery with an output voltage of 400 volts to 1000 volts.

As a rule, a high-voltage battery is used to drive a vehicle, while a battery with an output voltage of 10 volts to 60 volts is used to operate other components of the vehicle. A battery with an output voltage of 10 to 60 volts is preferably used to supply the monitoring unit or the battery management system with energy. Due to the above embodiment of the invention, the battery can be used particularly well for electrically operated vehicles.

In a further advantageous embodiment of the invention, the battery is designed as a multi-voltage battery, in particular as a dual-voltage battery.

A multi-voltage battery is characterized in that a plurality of charging voltages or discharging voltages can be provided by an alternating possibility of series connection and parallel connection of the battery cells or the modules. In this case, at least one second battery cell is assigned to at least some of the modules or some of the first battery cells. The state of charge of the battery is advantageously determined using the respective second battery cells.

A dual-voltage battery can advantageously have output voltages of 12 volts and 48 volts.

Due to the design of the battery as a multi-voltage battery, in particular as a dual-voltage battery, the invention can be used with particular advantage in modern motor vehicles.

The vehicle according to the invention advantageously has a battery as described above. Such a vehicle can be a motor vehicle or a rail vehicle. It can particularly advantageously be an at least partially electrically operated vehicle.

The invention is described and explained in more detail below with reference to figures. The features shown in the figures can be combined to form new configurations of the invention without restricting the scope of the invention.

• 1 eine beispielhafte Batterie sowie
• 2 eine beispielhafte Ladekurve.

It shows:

• 1 an exemplary battery as well
• 2 an example charging curve.

1 12 shows an exemplary battery 1. The battery 1 has first battery cells 3A, the first battery cells 3A being connected in series. The first battery cells 3A can be so-called LFP cells, where LFP stands for lithium iron phosphate. A second battery cell 3B is arranged at the end of the series connection. The second battery cell 3B is preferably an NMC cell, where NMC stands for lithium nickel manganese cobalt.

A monitoring unit 5 is used to detect the voltage U, in particular the charging voltage and/or the discharging voltage, at the respective cell 3A, 3B.

The battery cells 3A, 3B are connected in series and are supplied with electric current I during a charging process in such a way that the same current I is provided by the battery cells 3A, 3B in the series connection. The voltage U, in particular the charging voltage and/or the discharging voltage, can preferably also be detected at the respective battery cell 3A, 3B. The voltage U and/or the current I is preferably detected both between the poles of the battery 1 (+, -) and at the respective battery cell 3A, 3B using the detection means which are assigned to the monitoring unit 5 . The monitoring unit 5 can be part of a battery management system.

2 shows exemplary charging curves. Shown is a first charge curve of the first battery cell 3A and above that a second charge curve of the second battery cell 3B. The charge curve of the second battery cell 3B has a steeper rise. The voltage U, in particular the charging voltage or the discharging voltage, increases more over time t or with the state of charge SOC than the voltage at the respective first battery cell 3A.

At a first point in time t1, the battery 1 or the respective battery cell 3A, 3B is in a low state of charge SOC. For example, the battery is initially 20% charged. At a second point in time t2, the battery 1 or the respective battery cell has a high state of charge SOC. For example, the battery is 80% charged at the second point in time t2. According to the example shown, the voltage U is shown in an unloaded state.

This behavior can be found in reverse form during the discharging process of the respective battery cell 3A, 3B.

In summary, the invention relates to a method for determining a state of charge SOC of a battery 1 and a battery 1 and a vehicle with such a battery 1. The battery 1 advantageously has a plurality of first battery cells 3A with a charging/discharging voltage of 3 volts to 3.5 volts . The battery 1 also has at least one second battery cell 3B, the second battery cell 3B having a charge voltage/discharge voltage with an increased possible change in voltage, for example 3 volts to 5 volts. A monitoring unit 5 detects the voltage U at the second battery cell 3B and uses the voltage U at the second battery cell 3B to determine the state of charge SOC of the battery 1. The increased width of a possible change in the voltage U, in particular the charging voltage/discharging voltage, more accurate determination of the state of charge SOC of the battery 1 done.

QUOTES INCLUDED IN DESCRIPTION

This list of documents cited by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent Literature Cited

• EP 3309568 B1 [0004]
• DE 102010050980 [0005]

Claims (13)

Method for determining a state of charge (SOC) of a battery (1), the battery (1) comprising a plurality of first battery cells (3A) and at least one second battery cell (3B), the at least one second battery cell (3B) having a higher voltage (U) and/or a wider possible change in the voltage (U) than the respective first battery cell (3A), with a determination of the voltage (U) and/or the determination of the change in the voltage (U) of the at least one second battery cell (3B) and based on the voltage (U), in particular the change in voltage (U) as a function of time (t) and/or as a function of the state of charge (SOC) of the at least second battery cell (3B), the state of charge (SOC) of the battery (1) is determined. procedure after claim 1 , The voltage (U) of the at least one second battery cell (3B) at a first time (t1) and a second time (t2) is determined, based on the voltage (U), the current (I), the change in voltage (U) and/or the change in the current (I) determines the state of charge (SOC) of the battery (1). Method according to one of the preceding claims, wherein a monitoring unit (5) is used to determine the respective state of charge (SOC) of the respective second battery cell (3B) and optionally of the respective first battery cell (3A). Method according to one of the preceding claims, in which the current (I) through the second battery cell (3B) is detected and the state of charge (SOC) of the battery (1) is determined on the basis of current integration. Battery (1), having at least one first battery cell (3A) and at least one second battery cell (3B), wherein a monitoring unit (5) is assigned to the battery (1), wherein at least the respective first battery cells (3A) and optionally the second battery cell (3B) are connected in series, the monitoring unit (5) being designed to determine the current (I) and/or the voltage (U) of the at least second battery cell (3B), the second battery cell (3B) having a higher possible change the voltage (U) as a function of time (t) or the state of charge (SOC) compared to the respective first battery cell (3A). battery (1) after claim 5 , wherein the monitoring unit (5) is integrated in a battery management system (BMS) and/or is designed as an ASIC module. Battery (1) according to one of Claims 5 or 6 , wherein the respective first battery cell (3A) is a lithium iron phosphate battery cell. Battery (1) according to one of Claims 5 until 7 , wherein the respective second battery cell (3B) is a lithium-nickel-manganese-cobalt battery cell. Battery (1) according to one of Claims 5 until 8th , wherein the respective first battery cell (3A) has a voltage (U) of 3 volts to 3.5 volts and / or wherein the respective second battery cell (3B) has a voltage (U) of 3 volts to 5 volts. Battery (1) according to one of Claims 5 until 9 , wherein the second battery cell (3B) is directly connected to a first battery cell (3A) on only one side. Battery (1) according to one of Claims 5 until 10 , wherein the voltage (U) of the battery (1) in the unloaded state is between 10 and 60 volts and/or between 400 volts and 1000 volts. Battery (1) according to one of Claims 5 until 11 , wherein the battery (1) is designed as a multi-voltage battery, in particular as a dual-voltage battery. Vehicle, comprising a battery (1) according to one of Claims 5 until 12 .

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