EP3895274A1

EP3895274A1 - Method for monitoring and controlling a battery cell unit

Info

Publication number: EP3895274A1
Application number: EP19779834.1A
Authority: EP
Inventors: Johannes Grabowski; Joachim Joos; Carlos Ziebert; Timo Herberholz
Original assignee: Robert Bosch GmbH
Current assignee: Robert Bosch GmbH
Priority date: 2018-12-14
Filing date: 2019-09-26
Publication date: 2021-10-20
Also published as: WO2020119974A1; CN113169571A; DE102018221813A1; US20220077509A1

Abstract

The present invention relates to a method for monitoring and controlling a battery cell unit. The invention also relates to a battery cell unit, a battery system and to a use of the claimed method for monitoring and controlling the battery system.

Description

description

title

Method for monitoring and controlling a battery cell unit

The present invention relates to a method for monitoring and controlling a battery cell unit. Furthermore, the invention relates to a

Battery cell unit, on a battery system and use of the method for monitoring and controlling the battery system.

State of the art

Battery cells, especially secondary cells, change their properties over their lifespan. When used in mobile applications, in particular vehicles, the battery cells may have a shorter lifespan than the vehicle. When using several cells, it can happen that not all cells age at a different rate, but at different speeds. This often means that if a single cell fails, an entire battery system has to be replaced. When monitoring and controlling the battery cells, it would therefore be advantageous if a measurable variable could be used as a parameter that reflects the state of the battery cell particularly accurately.

Disclosure of the invention

The invention relates to a method with the features of claim 1 and a battery cell unit with the features of claim 6, a battery system with the features of claim 8 and a use of the method with the features of claim 9. A method for monitoring and controlling a battery cell unit, which has the following steps, is particularly protected:

At least one battery cell, which has a first pole, which is connected to an input, which can be connected to a first electrical element, and has a second pole, which is connected to an output, which can be connected to a second electrical element, is provided . A switch is also provided which is suitable for connecting the first pole to the input or for disconnecting this connection.

- Another step is to open the first switch to disconnect the input from the first pole.

- In a further step, a measured variable of the battery cell separated from the input is determined. The measured variable determined is evaluated, at least one switching value being determined based on the measured variable. The switching state of the first switch is also adjusted based on the at least one switching value. The above-mentioned serve Steps to control and

Monitor the battery cell unit.

In other words, an energy store in the form of a battery cell, in particular a secondary cell, is provided with a positive and a negative pole. Since the physical processes of the power line are not important in connection with the invention, the terms plus and minus are interchangeable. The input can be connected to a first electrical element, wherein this first electrical element can be, for example, a further battery cell unit, an electrical circuit, a consumer or a connection element, in particular in the form of a plug or a socket. The second electrical element, which can be connected to the output, can also have at least the electrical elements just mentioned.

Instead of a single battery cell, a plurality of battery cells, in particular two battery cells, can also be arranged within a battery cell unit, it being possible for these to be connected both in parallel and in series. In the case of a series connection, only one battery cell is connected to the input and another battery cell to the output, and in the case of a parallel connection, several battery cells are connected to the input and to connected to the exit. The use of several battery cells has the advantage that the voltage or the current can be increased.

Furthermore, a first switch is provided which connects the first pole of the battery cell to the input in the closed state and disconnects this connection in the open state. The connection between the input and the first pole of the battery cell can be made directly via the switch or via one or more cell lines. The switch itself can be designed as a relay, for example, which offers the advantage of galvanic and particularly safe isolation. Alternatively, it can also be provided that the switch is based on semiconductors, as a result of which a high number of switching cycles can be made possible. The switch can also be designed as a MOSFET or IGFET, which can be designed to be particularly small and inexpensive.

By opening the first switch, the at least one battery cell, in particular two or more battery cells, is separated from the input. As a result, the at least one battery cell, in particular two or more

Battery cells, no longer output current to the first electrical element and / or the second electrical element. It is also not possible to charge the battery cell in this state.

The first switch can be opened at specific intervals, which are particularly adapted to the measurement variable to be determined.

The measured variable, which is determined by the battery cell separated from the input, can be any measurable variable, in particular

Temperature, pressure, concentration or by electrical quantities, such as

Voltage, current or impedance. The measured variables can be recorded by measuring means, with corresponding accesses to the

Battery cell unit are provided. To measure electrical quantities, further connections can be provided on the at least one battery cell, in particular on a plurality of battery cells. For example, a means for measuring the impedance can be connected to at least one or, in particular, a plurality of battery cells and measure the impedance at the moment when the first switch opened and the battery cell or battery cells are de-energized. This offers the advantage that the impedance can be determined particularly precisely, which enables a better description of the state of the cell.

When evaluating the measured variable, a switching value based on the

Measured variable determined. The switching value can have a logical value that can serve as a setpoint for a switch. E.g. would correspond to a switch value of 1 a closed switch and a switch value of 0 to an open switch. When evaluating the measured variable, the measured variable can be compared with a target value or target range. This setpoint can be, for example, a generally applicable setpoint, for example a cell voltage, which must not be fallen below. This offers the advantage that switching values of the first switch can be determined regardless of the possible state differences of the battery cells. As an alternative or in addition, it is also possible for the measured variable to be compared with a target value which is individually adapted to the battery cell. For example, it can happen that battery cells are subject to certain fluctuations due to production. Thus, for example, a cell that has a low voltage from the start of production, but has an increased capacity, for example, can receive a correspondingly adjusted setpoint.

An evaluation unit can be provided for evaluation, which

can be designed in particular as a microcontroller. The advantage of microcontrollers is that they are particularly small and inexpensive to implement. Furthermore, it can be provided that the evaluation unit is designed as an FPGA, which is particularly easy to adapt to measurement tasks. Alternatively or in addition to this, the evaluation unit can also be designed as an ASIC, which can be manufactured particularly inexpensively in large quantities.

The determined switching value serves as the setpoint for the first switch. If it is found, for example, that the battery cell has too low a voltage, the first switch can be opened and the battery cell can remain separated from the input and output. However, if the measured value corresponds to a target value or a target range, the battery cell can be connected to the input and output again after the measurement by closing the first switch. It can further be provided that the measuring means and / or the

Evaluation means are firmly connected to the battery cell unit and / or the battery cell so that they can be removed together. This offers the advantage that the battery cell units or battery cells are easy to change.

It can be advantageous that the method additionally has the following steps:

A second switch, which is arranged between the input and the output parallel to the battery cell, can be provided.

- In a further step, the second switch can be closed, whereby the input is short-circuited with the output.

In other words, it can be provided that a further current path is provided in parallel to the at least one battery cell, in particular a plurality of battery cells, which current path can be both interrupted and short-circuited by a second switch. This offers the advantage that the at least one battery cell, in particular several battery cells, can be bridged. In particular, if the battery cell unit is connected to further battery cell units via the input and / or output, the battery cells of a battery cell unit can be bridged by closing the second switch. The second switch can be closed at the exact moment when the first switch is opened. This offers the advantage that a measured variable can be determined on the separate at least one, in particular several, battery cells, and the input is not electrically separated from the output. As a result, further electrical elements which are connected to the input and / or output can continue to be used during the determination of the measured variable and, if necessary, compensate for the failure of the cell currently being measured. If there are two switches, the switching value can include a setpoint for both switches.

It can further be provided that at least one measurement variable is stored. This has the advantage that a more reliable evaluation of the data is made possible. It can be provided that for storing the measured variable a memory is provided which can be connected in particular to a measuring or evaluation unit. It can also be provided that the memory is part of the measuring and / or evaluation unit. It can also be provided that the memory is arranged on the battery cell unit in such a way that it can be inserted or removed as a common unit in a battery system. This offers the advantage that data about the at least one, in particular several, battery cells can be stored over their entire service life and can be used further with the battery cell itself.

This enables e.g. B. that if the battery cell for a particular

Application, for example as an application in an aircraft, no longer has the required properties, can be expanded and another device can be installed which has lower requirements.

Furthermore, it can be provided that at least one switching value is determined from stored measured variables by an evaluation unit. It can be provided that the data is available in a memory, which can be arranged within the battery cell unit in such a way that it can be exchanged together with the memory. It can be provided that the memory also contains data from other battery cells, which may not be part of the battery

Battery cell unit are included. The setpoint with which the

Measured variable is compared to determine the switching value, adjusted so that the overall functionality of the system remains guaranteed. Signaling means can be provided which signal a recommendation to replace the cell if the setpoint is exceeded or undershot. This offers the advantage that, instead of several battery cells, only those cells that differ from the threshold value adapted to the application and therefore cannot be used any longer are replaced.

It can be provided that the at least one measured variable comprises at least one of the following variables and / or at least one of the following variables is included in the calculation of the switching value:

The voltage of the battery cell, especially as a function of time,

the charging current of the battery cell, in particular as a function of time,

the temperature of the battery cell, in particular as a function of time,

the electrical capacity of the battery cell, in particular as a function of time, - the impedance of the battery cell, especially as a function of time.

It can be provided that the measured variables by at least one

Measurements are determined. It can be single or multiple

Measured variables are ascertained, and individual or several or a combination of several measured variables can be included in the calculation of the switching value to calculate the switching value. Particularly by separating the at least one or in particular a plurality of battery cells from the entrance and exit, a particularly precise determination of the

Measured variables enabled.

Another object of the invention is a battery cell unit,

in particular for a mobile energy supply, comprising at least one battery cell, an input which is connected to the at least one battery cell at a first pole, and an output which is connected to the at least one battery cell at a second pole. Furthermore, the

Battery cell unit has a first switch which is suitable for connecting the input to the at least one battery cell or for separating it from the at least one battery cell. Furthermore, the

Battery cell unit has at least one measuring device which is suitable for determining at least one measured variable and is connected to the battery cell. The battery cell unit also has an evaluation unit which is connected to the at least one measurement device and is suitable for evaluating the at least one measurement variable determined by the at least one measurement device and for calculating at least one switching value which is functionally related to the at least one measurement variable. The

The battery cell unit can be used in particular for a mobile energy supply, for example for an aircraft, motor vehicle, rail vehicle or other mobile consumers.

The battery cell unit has the advantage that the battery cell unit can be switched on and off depending on the measured value determined. If the measured variable is determined and does not reach a target value or target range, the

Battery cell turned off by not turning the first switch back on

is closed. However, if the measured variable reaches the setpoint or setpoint range, the first switch is closed again and the battery cell remains switched on. The first switch can be opened at specific intervals, which are particularly adapted to the measurement variable to be determined. This offers the advantage that the battery cell can be separated as rarely as possible and the performance of the battery cell unit is increased with increased operational reliability.

The input and the output can each be connected to a first and a second electrical element, these electrical elements being, for example, a further battery cell unit, an electrical circuit, a consumer or a connecting element, in particular in the form of a plug or a socket. This offers the advantage that the battery cell unit is in one

Battery system can be integrated.

Instead of a single battery cell, several battery cells can also be connected both in parallel and in series. In the case of a series connection, only one battery cell is connected to the input and a further battery cell to the output, and if necessary, several are connected in a parallel connection

Battery cells connected to the input and to the output. The

Using several battery cells has the advantage that the voltage or the current can be increased.

The first switch connects the first pole of the battery cell to the input in the closed state and disconnects this connection in the open state. The connection between the input and the first pole of the battery cell can be made directly via the switch or via one or more

Cell lines are made. The switch itself can be designed as a relay, which offers the advantage of galvanic and particularly safe isolation. Alternatively, it can also be provided that the switch is open

Semiconductor base is based, which enables a high number of switching cycles. The switch can also be designed as a MOSFET or IGFET, which can be designed to be particularly small and inexpensive.

The measured variable, which is determined by the battery cell separated from the input, can be any measurable variable, in particular Temperature, pressure, concentration or by electrical quantities, such as

Voltage, current or impedance. The measurands are from

Measuring means detected, with corresponding accesses being provided on the battery cell unit. For measuring electrical quantities, further connections can be provided on the at least one battery cell, in particular on a plurality of battery cells. Thus, a means for measuring the impedance can be connected to at least one or, in particular, a plurality of battery cells, and measure the impedance at the moment when the first switch is opened and the battery cell or battery cells are de-energized. This offers the advantage that the impedance can be determined particularly precisely, which enables a better description of the state of the cell.

When evaluating the measured variable, a switching value based on the

Measured variable determined. If several switches are provided, the switching value can also contain a respectively adjusted setpoint for all switches. The switching value can have a logical value that can serve as a setpoint for a switch. E.g. would correspond to a switch value of 1 a closed switch and a switch value of 0 to an open switch. When the measured variable is evaluated by the evaluation unit, the measured variable can be compared with a target value or target range. This setpoint can be, for example, a generally applicable setpoint, for example a cell voltage, which must not be fallen below. This offers the advantage that switching values of the first switch can be determined regardless of the possible state differences of the battery cells. As an alternative or in addition, it is also possible for the measured variable to be compared with a target value which is individually adapted to the battery cell. So it can happen that

Battery cells are subject to certain fluctuations due to production. Thus, a cell that has a low voltage from the start of production, but has an increased capacity, for example, can receive a correspondingly adjusted setpoint.

An evaluation unit is provided for evaluation, which can be designed as a microcontroller. The advantage of microcontrollers is that they are particularly small and inexpensive to implement. Furthermore, it can be provided that the evaluation unit is designed as an FPGA, which is particularly light Measurement tasks is customizable. Alternatively or in addition to this, the evaluation unit can also be designed as an ASIC, which can be large

Can be produced particularly cheaply.

The determined switching value serves as the setpoint for the first switch. If it is found, for example, that the battery cell has too low a voltage, the first switch can be opened and the battery cell can remain separated from the input and output. However, if the measured value corresponds to a target value or a target range, the battery cell can be connected to the input and output again after the measurement by closing the first switch.

It can further be provided that the measuring means and / or the

It can further be provided that a second switch is provided, which is arranged between the input and the output, parallel to the battery cell. In other words, the current can be passed parallel to the battery cell from the input to the output or vice versa during the separation of the battery cell from the circuit by opening the first switch. This offers the advantage that, despite the separation of the at least one, in particular several, battery cells, forwarding from the input to the output or vice versa is ensured.

Another object of the invention is a battery system, comprising a plurality of battery cell units according to claim 6 or 7, which are connected to one another in series and / or in parallel. It can be provided that the at least one measuring device is connected to a plurality of battery cell units and is suitable for determining at least one measured variable. This offers the advantage that measuring means do not have to be provided individually for each battery cell unit, so that costs can be saved. Furthermore, it can be provided that an evaluation unit is connected to a plurality of measuring devices and is suitable for the measured variables determined using the measuring devices evaluate and calculate at least one switching value that is functionally related to the measured variables. This also has the advantage that fewer evaluation units are required than if each measuring device had its own evaluation unit.

Alternatively, however, it can also be provided that the

Battery cell units in the battery system each have their own measuring and evaluation units, so that the battery cell units can be removed or inserted from the battery system without the

Disrupt functionality of the battery system. In particular, it can be provided to increase battery cell units from a battery system

To take requirements and into a battery system with lower

Install requirements if it is determined by the evaluation unit that the increased requirements are no longer met by the battery cell unit.

Another object of the invention is the use of the method for monitoring and controlling the battery system according to claim 8. The following steps can also be provided:

Opening at least one first switch, whereby at least one battery cell is interrupted from the input,

Closing at least one second switch, whereby the input is short-circuited with the output,

Determining a measured variable of at least one battery cell using the at least one measuring device,

Evaluating the measured variable by the evaluation unit, at least one switching value being determined based on the measured variable,

Adapting the switching state of at least one first switch based on the at least one switching value,

Adapting the switching state of at least one second switch based on the at least one switching value,

for monitoring and controlling the battery system. It can be provided that the first switch is opened at defined time intervals in order to carry out a currentless measurement of the battery cell and during the measurement the second switch is closed in order to bridge the battery unit and to ensure the functionality of the battery system.

It can be provided within the system that the measurements are coordinated with one another in such a way that only one or at least a few battery cells are measured at the same time, so that the

Overall functionality of the battery system is guaranteed.

It can also be provided that, based on the currently required requirement on the battery system, particularly suitable battery units are used to provide the power by closing the first switch and by opening the second switch, and rather unsuitable ones

Battery cell units can be excluded from use by opening the first switch and closing the second switch. This can be the case, for example, if particularly high power is to be output from the battery cell units when a vehicle is accelerating, for which some battery cell units may be unsuitable. However, these can still have a large capacity, which can be used, for example, in phases with lower power output requirements.

Furthermore, it can be provided that the deviation from a battery cell unit in comparison with a further battery cell unit is included in the calculation of the switching value by the evaluation unit. In other words, the evaluation unit can compare the status of the individual battery cell units with one another and decide which of the battery cell units is required for the current requirements and is best suited for this purpose.

Accordingly, the switching state of the first two switches of the battery cell units can be adapted such that the battery cells of the battery cell units are either connected to the respective inputs and outputs or else are separated.

Further features and details of the invention result from the

Subclaims, the description and the drawings. Features and details that have been described in connection with the method according to the invention apply, of course, also in connection with the battery cell unit according to the invention, the battery cell system according to the invention and / or the use according to the invention and vice versa, so that with regard to the disclosure of the individual

Aspects of the invention are always mutually referenced.

Further measures improving the invention result from the following description of some exemplary embodiments of the invention, which are shown schematically in the figures. All of the

Claims, the description or the drawings, features and / or advantages, including structural details, spatial

Arrangements and process steps can be essential to the invention both individually and in the various combinations. It should be noted that the figures are only descriptive and are not intended to limit the invention in any way. Show it

Fig. 1 is a schematic view of a battery cell unit in

different switching states,

2 shows a further schematic illustration of the battery cell unit,

3 shows a schematic representation of the battery system,

4 shows a process diagram of a method according to the invention.

In the following figures, the same reference numerals are used for the same technical features of different exemplary embodiments.

1 shows a battery cell unit 100 on the left with an input 103 and an output 104. The input 103 is connected to a battery cell 150 at a first pole of the battery cell 151 via a first switch 111. The current path between input 103 via switch 111 and the

Battery cell 150 for output 104 is referred to below as cell line 106. The current can flow through the battery cell via this cell line 106 150 from input 103 to output 104 or vice versa.

In parallel, a second current path 105 is shown, which likewise connects the input 103 to the output 104 via a second switch 112. In the state shown on the left in FIG. 1, the battery cell 150 is connected to the input 103 and the output 104. In this case, for example, a consumer can be provided between the input 103 and the output 104, which can be operated by the output power of the battery cell 150. As an alternative to this, it is also conceivable that further battery cell units are provided in series or in parallel at input 103 and / or output 104, thereby creating a battery system 1000. In order that the current can flow from the battery cell 150 into the battery system 1000 or to the consumer, any switch 112 that is present must also be opened. This is shown in the left and middle representation in FIG. 1.

When a measured variable of the battery cell 150 is determined, the first switch 111 is opened, and the second switch 112 can be closed. As a result, the battery cell unit 150 is de-energized, which is a more precise determination of the

Measured variable enables. This process is shown on the right side of FIG. 1.

2 shows a further view of the battery cell unit 100, in which measuring means 120 and an evaluation unit 140 with a memory 141 are also shown schematically. The measuring means 120 serve to determine a measured variable of the battery cell 150. The measuring means 120 are with the

Evaluation unit 140 is connected, which evaluates the measured values and determines a switching value based thereon, which determines at least the switching state of the first switch 111 or the switching state of the first and second switches 111, 112. The evaluation unit 140 can use values that are either directly recorded by the measuring means 120 or stored in a memory 141. The evaluation unit 140 can

Adjust the switching state of the first and / or second switch 111, 112 to the target value.

In Fig. 3, a battery system 1000 is shown in which the

Battery cell units 100 are shown connected in series. Of course, the individual battery cell units can also be connected in parallel and / or in series. This offers the advantage that the

Voltage or current can be increased.

FIG. 4 shows a flowchart which shows an example of a

Embodiment of a method according to the invention shows. In a first method step 500, the battery cell units 100, first switches 111, in particular second switches 112, measuring means 120 and an evaluation unit 140 are initially provided. In a next step 510, which can be repeated at defined time intervals, the first switch 111 is opened and the second switch 112 is closed. In the subsequent step 520, the measuring means 120 record at least one measured value. This is evaluated in the subsequent step 530 by the evaluation unit 140, which calculates a switching value for the first switch 111, in particular the second switch 112, based on the at least one measured value. In the next step 540, the switching state of the first switch 111, in particular the second switch 112, is adapted in accordance with the switching value. This means that the battery cell 150 is either reset to its initial state or remains separate from the input 103 and output 104.

The above explanation of the embodiments describes the present invention exclusively in the context of examples.

Of course, if technically meaningful, individual features of the embodiments can be freely combined with one another without departing from the scope of the present invention.

Claims

Expectations

1. A method for monitoring and controlling a battery cell unit (100), comprising the following steps:

• Providing at least one battery cell (150) which has a first pole (151) which is connected to an input (103), which can be connected to a first electrical element and has a second pole (152) which has an output (104) is connected, which can be connected to a second electrical element,

and a first switch (111) which is suitable for connecting the first pole (151) to the input (103) or for disconnecting this connection,

Opening the first switch (111) to disconnect the connection between the input (103) and the first pole (151),

• Determine a measured variable of those separated from the input (103)

at least one battery cell (150),

• Evaluation of the measured variable, with at least one switching value

is determined based on the measured variable,

Adapting the switching state of the first switch (111)

based on the at least one switching value,

for controlling and monitoring the battery cell unit (100).

2. The method according to claim 1,

characterized,

that the method additionally has the following steps:

Providing a second switch (112) between the input (103) and the output (104) parallel to the at least one battery cell (150),

• Closing the second switch (112), whereby the input (103) is short-circuited with the output (104).

3. The method according to claim 1 or 2,

characterized,

that the at least one measurement variable is stored.

4. The method according to claim 3,

characterized,

that an evaluation unit (130) determines at least one switching value from stored measured variables.

5. The method according to any one of claims 1 to 4,

characterized,

that the at least one measured variable comprises at least one of the following variables and / or at least one of the following variables is included in the calculation of the switching value:

Voltage of the battery cell (150), in particular as a function of time,

Charging current of the battery cell (150), in particular as a function of time,

Temperature of the battery cell (150), in particular as a function of time,

Electrical capacity of the battery cell (150), in particular as a function of time,

• Impedance of the battery cell (150), in particular as a function of time.

6. battery cell unit (100), in particular for a mobile energy supply, comprising at least one battery cell (150), an input (103) which is connected to the at least one battery cell (150) at a first pole (151),

and an output (104) connected to at least one battery cell (150) at a second pole (152),

a first switch (111) which is suitable for connecting the input (103) to the at least one battery cell (150) or for separating it from the at least one battery cell (150),

at least one measuring device (120), which is connected to the at least one

Battery cell (150) is connected and is suitable for determining at least one measured variable,

and an evaluation unit (140) which is connected to the at least one measuring device (120) and is suitable for evaluating the at least one measured variable determined by the at least one measuring device (120) and for calculating at least one switching value which is functionally related to the at least one measure is available.

7. battery cell unit (100) according to claim 6,

characterized,

that a second switch (112) is provided, which is arranged between the input (103) and the output (104), parallel to the battery cell (150).

8. battery system (1000), comprising a plurality of battery cell units (100) according to claim 6 or 7, which are connected to one another in series and / or in parallel.

9. Use the procedure to monitor and control the

Battery system (1000) according to claim 8.

10. Using the method according to claim 9,

characterized,

that the deviation from a battery cell unit (100) in comparison with a further battery cell unit (100) is included in the calculation of the switching value by the evaluation unit (140).