WO2013149763A1 - Battery cell for a vehicle having a device for decoupling and/or bypassing terminals of the battery cell - Google Patents

Abstract

The invention relates to a battery cell (100) having a device for decoupling and/or bypassing terminals (125) of the battery cell (100) for a vehicle, wherein the battery cell (100) has a mechanical safety element (120), wherein the mechanical safety element (120) is designed to sever and/or short-circuit the connections (125) of the battery cell (100), wherein the battery cell (100) has the following feature: a device (150) for triggering the mechanical safety element (120) using an electrical trigger signal (170).

Description

 description

title

 Battery cell for a vehicle with a device for decoupling and / or bridging connections of the battery cell

State of the art

The present invention relates to a battery cell for a vehicle with a device for decoupling and / or bridging connections of the battery cell.

If a battery cell continues to be charged beyond the permitted maximum, it can explode. To prevent this, the terminals of the cell are either disconnected or bypassed. State of the art are passive mechanical see components that z. B. by an overpressure in the cell (irreversible) deformed and thereby triggered. Common names are z. For example, English terms "overcharge protection cireuit" or "current interrupt service" (CID). In the following, the term CID is used as representative of all embodiments of these protective devices according to the prior art.

EP 2 228 849 A1 discloses a rechargeable battery having an electrode unit and a housing for mounting the electrode unit therein, wherein the housing changes depending on the internal pressure. The electrode assembly includes a separator, and first and second electrodes disposed on two opposite sides of the separator.

Disclosure of the invention

Against this background, with the present invention, a battery cell with a device for decoupling and / or bridging of terminals the battery cell for a vehicle, a battery that uses this battery cell and a method for decoupling and / or bridging terminals of a battery cell presented according to the main claims. Advantageous embodiments emerge from the respective subclaims and the following description.

According to one embodiment, the invention relates to a device with mechanical and electrical components which can be installed in a battery cell (for example lithium-ion battery of an electric vehicle) and serves to separate or bridge the connections of the cell internally. An integrated in the battery cell monitoring sensor can provide early signal to the state of the battery cell. A corresponding electrical and / or electronic device can trigger the mechanical security element using the signal of the integrated in the battery cell monitoring sensor. The triggering of the mechanical security element can short-circuit the terminals of the battery cell and at the same time or alternatively, the mechanical security element can decouple the terminals of the battery cell. By short-circuiting the connections, the battery cell can be bridged.

The invention is based on the finding that a mechanical security element such as an "overcharge protection circuit" or a "current interrupt device" can be triggered, for example, by overpressure in the cell or an elevated temperature and thereby irreversibly deformed, but this is only an ultima Should represent ratio. In order to create an intrinsically safe battery cell whose security element does not irreversibly destroy the cell, it may be advantageous to detect an imminent "cell death" or opening a gas membrane early and interrupt a charging process of the battery cell by disconnecting the terminals, for example, and thus on time to prevent "cell death" or opening of the gas membrane.

The present invention provides a battery cell with a device for decoupling and / or bridging connections of the battery cell for a vehicle, wherein the battery cell has a monitoring sensor, wherein the battery cell has a mechanical security element, wherein the mechanical security element is formed to the terminals of the battery cell - to separate and / or short-circuit the device, the device comprising: means for triggering the mechanical security element using an electrical triggering signal.

According to a particular embodiment of the present invention, the battery cell may include a monitoring sensor, wherein the monitoring sensor may be configured to provide at least one measure of a condition of the battery cell, and wherein the means for triggering is configured to apply the mechanical safety feature using an electrical sensor Trigger signal based on the measured variable.

The vehicle may be a motor vehicle, for example a passenger car, a truck or another commercial vehicle. The vehicle may be equipped with a hybrid drive or it may be an electric vehicle. The vehicle may have at least one battery as starter battery or traction battery. Under a battery can be understood an interconnection of multiple battery cells. A battery cell can be understood as meaning a rechargeable storage for electrical energy, such as an accumulator. A battery cell can be understood to mean rechargeable secondary cells, secondary elements or accumulators. The battery cells may be connected in a series connection and / or a parallel connection in the battery. A battery cell can have an energy store with connections, a monitoring sensor and / or a mechanical security element. The monitoring sensor may be referred to as a battery sensor. The monitoring sensor can be integrated in the battery cell. The monitoring sensor can output a monitoring signal which represents, for example, a cell temperature, a cell terminal voltage, an internal cell pressure and / or a cell terminal current intensity. The monitoring signal may be referred to as a measure of the monitoring sensor to a state of the battery cell. A mechanical security element can be understood as a passive mechanical component which can be triggered by a physical condition such as pressure and / or temperature. The mechanical security element can be irreversibly and / or reversibly deformed become. The mechanical security element may be referred to in English as "overcharge protection circuit" or "current interrupt device" (CID). The mechanical security element, when it is tripped, cause a bridging of the terminals of a battery cell and thus the battery cell. Bridging the connections can be referred to as shorting. The mechanical safety element can disconnect the connections of the battery cell from the energy storage of the battery cell. The disconnection of the connections can be effected by a passive system such as a fuse. Under a device for triggering the mechani see safety element can be understood a device that allows electrical actuation of the mechanical security element. In this case, the electrical actuation may be provided parallel to the mechanical function of the mechanical safety element.

An electrical actuation of the mechanical safety element allows the reaction to measured values which are known by the battery cell before a dangerous situation arises which would trigger the mechanical safety element or the passive CID. The device for triggering can trigger when the upper or lower limit values of at least one measured value of a cell, for example the cell temperature, cell terminal voltage, cell pressure or others, the actuators, are exceeded.

The approach presented here extends an existing mechanical security element or CID. The passive safety function of the mechanical safety element can remain. In addition, a possibility is created to electrically trigger the mechanical security element (CID). The electrical triggering can either be done by an external additional connection to the cell or by an incorporated into the cell electrical or electronic system, microsystem, or IC (IC = integrated circuit = integrated circuit). An electrical actuation allows the reaction to measured values that are known by the cell before a dangerous situation arises which would trigger the mechanical safety element or the passive CID. The approach presented here allows the spatial separation between the detection of a critical state using a monitoring sensor and a protective device. The protective device can be designed as a combination of mechanical security element and device for triggering. In this case, the actuators can be triggered only by electrical criteria (U, I,) and / or by physical criteria detected in the vicinity of the cell coil, such as cell temperature and / or internal cell pressure. It is advantageous that the approach presented here prevents a dangerous state of the cell, such as a strong increase in pressure, impending thermal outliers, or "thermal runaway", in which the device for triggering a bridge before the triggering of any passive protection mechanism can bring about.

An embodiment of the invention is also advantageous with a device for monitoring the battery cell exclusively using the battery cell using the monitoring sensor, wherein the device for monitoring is designed to output the electrical triggering signal. This embodiment of the present invention offers the advantage of providing an intrinsically safe battery cell which, in addition to the mechanical security element, has a further electrically acting safety device using a sensor signal. In the present case, an apparatus for monitoring can be understood as meaning an electrical device which processes sensor signals and outputs control and / or data signals in dependence thereon. The device for monitoring can have an interface that can be designed in hardware and / or software. For example, in a hardware implementation, the interfaces may be part of a so-called system ASIC that includes a variety of functions of the monitoring device. However, it is also possible that the interfaces are their own integrated circuits or at least partially consist of discrete components. In a software training, the interfaces may be software modules that are present, for example, on a microcontroller in addition to other software modules.

According to one embodiment of the present invention, the monitoring sensor can be designed as an integrated monitoring sensor and the device for monitoring the battery cell can be an integrated component of the integrated th monitoring sensor. Such an embodiment provides an intrinsically safe battery cell without external components. A monitoring sensor integrated into the battery cell can supply various measured variables, which are partially present only inside the battery cell. Also, for example, the location of the temperature measurement and / or the pressure measurement may be located at a specific location inside the battery cell.

The entire system of the battery cell with integrated sensors, actuators, that means triggering, and electronic unit, that means monitoring, can represent an intrinsically safe system according to ASIL standard. The means for monitoring may be implemented as a microelectronic circuit within an integrated battery sensor.

Further, according to an embodiment of the present invention, the means for monitoring the battery cell may be configured to determine the electrical trigger signal using a plurality of measurements of the monitoring sensor. By using a plurality of measurands, optimum performance and maximum cell safety can be achieved. In this case, linking different measured variables can better describe the state of the cell than a single measured value.

Furthermore, in a further embodiment of the present invention, in the device for monitoring the battery cell, the electrical release signal can be determined using a predefined map. The predefined map can be multidimensional. The predefined map may allow for an assessment of one and / or a plurality of interlinked metrics. The predefined characteristic map can specify upper and / or lower limit values for at least one measured variable and influence an integration state of the battery cell. Using a multi-dimensional characteristic map, different measured values and limit values can be evaluated individually or interactively and simultaneously or alternatively linked in order to control the state of integration of the cell (bridged / not bridged).

It is also favorable if, in one embodiment, the device is designed for triggering, the mechanical security element using a nes triggered by the battery cell externally supplied trigger signal. In this case, the externally supplied trigger signal can be generated by a battery management system, wherein the battery management system can be configured to monitor a plurality of battery cells. This can be advantageous since this can influence the overall performance of a battery, taking into account the state of the individual battery cell. An externally supplied trigger signal may allow targeted cells with a weak "health" within the battery cell string to be bypassed and severed to thereby increase the overall performance of the battery, since it is no longer the weakest battery cell that determines overall performance.

According to an embodiment of the present invention, the mechanical security element can be designed to be reversibly triggered and, simultaneously or alternatively, the mechanical security element can be designed to be triggered irreversibly. Alternatively or additionally, the mechanical security element can also be designed as a bistable security element. A bistable mechanical security element can be understood to mean a security element which remains stable in this second state after a transfer of at least one first state to a second state and / or which is stable in this first state after a transfer of at least one second state to a first state Condition remains. It is also conceivable that the mechanical security element can not only be brought into two states, but also more states, wherein it then after a move into one of these states stable in this

Condition remains until it is returned to another state. If a battery cell continues to be charged beyond the permitted maximum, the battery cell can be severely damaged or even explode. In order to prevent this, the connections of the cell are either disconnected or bridged by means of the mechanical safety element. An irreversible release of the mechanical security element is inexpensive to implement and protects the battery cell safely from an explosion. Likewise, the bridging of a heavily aged or damaged, that is a measurable low-power battery cell, may be useful to increase the overall performance of a battery. Reversible activation of the mechanical safety element may allow the cell to be used again, if this is positive for example the total power of the battery is. The reversible triggering makes it possible to flexibly decouple and reconnect battery cells within a battery.

Furthermore, according to an embodiment of the present invention, the device for triggering can be designed to be reversible, and at the same time or alternatively, the device for triggering can be designed to be irreversible. The device for triggering may be an actuator system that is reversibly or alternatively irreversibly triggered. An irreversibly trained device for triggering can be produced inexpensively. If, in one embodiment, the mechanical security element is designed to be irreversibly deformed, the device for triggering can also be designed. For example, for the irreversible separation and / or bridging of battery cells in a cell assembly, or a battery, an existing passive mechanical protection device can be extended by an airbag squib, thereby creating the possibility of irreversible electrical actuation. In this case, the squib can be attached, for example, close to a normally triggered by a cell overpressure "crackpot" membrane. During ignition, the membrane is then deformed by the resulting pressure wave instead of by a pressure increase triggered by cell chemical processes.

A reversibly designed device for triggering makes it possible to reverse a trip. If the mechanical safety element reacts to an excessive temperature, a reversible actuator system can, for example, consist of a heating coil arranged in such a way that an electric actuator can be used

Trigger signal, the heating coil is heated and thus triggers the mechanical safety element. Bridging a damaged or sensorically measurable low-power cell can be useful to increase the overall performance of the battery. Reversible actuation may allow a cell to be disconnected and switched on after it has been ordered from the remaining cells of a battery. at

Series connection of the cells makes sense, if a bridging of the cells is provided at the same time. As a result, a defective cell can be taken out of series connection, an electric vehicle would continue to remain ready to drive, instead of lying. In the approach presented here, an actuator is described by way of example, with a triggering circuit, an electrical or thermal ignition combined with a mechanical device for closing the battery power line. Exemplary examples of an irreversible actuator are the combinations: squib and flat spring or "cracking frog" membrane or alternatively an electrical fuse and a biased extension spring. Here, the squib is brought to ignition by an electric current, with the important aspect that the ignition temperature of the squib is well above the maximum temperature that may be exposed to the parked vehicle even under extreme climatic conditions - similar to an airbag squib.

Furthermore, according to an embodiment of the present invention, the security element can bridge the connections of an energy store of the battery cell. By bridging the connections of the energy storage of the

Battery cell, a series connection of battery cells can remain functional. The performance of the battery can go down. The bridging of the terminals may also be referred to as a shorting of the terminals.

It is also advantageous if, according to an embodiment of the present invention, the security element separates the energy store of the battery cell from the terminals. By disconnecting the terminals of the energy storage overcharging of the energy storage and thus the battery cell can be prevented. When charging and discharging the battery cells can be treated individually according to their operating state or "state-of-health", thereby the life of battery cells and the entire battery can be significantly increased The interface can be embodied as an analogue and / or digital interface, that is, analog signals and / or digital signals can be transmitted via the interface be formed as a bus interface, wherein data via the interface compliant with a bus protocol can be transmitted. In this case, the interface can be designed to transmit data, to receive data and / or to send and receive data. The interface can be designed for unidirectional communication and / or be designed for bidirectional communication. The interface for communication may allow the status of the individual cells to be reported to the central vehicle control unit and / or communicated to the driver via a warning / warning device. Also, the state of the individual cells in the vehicle diagnosis, for example, as part of a regular maintenance, the diagnostic device can be communicated. In this case, the interface for communication can be designed such that the state of a

Battery cell can be communicated to a battery charger during a charging process, so that the battery charger can control its charging voltage / current accordingly.

Furthermore, the monitoring sensor can be designed to deliver a plurality of measured variables. The monitoring sensor can output a monitoring signal which represents at least two measured variables such as cell temperature, cell terminal voltage, internal cell pressure and / or cell terminal current intensity. This makes it possible to make a triggering decision dependent on the interaction of a plurality of measured variables. Here, the mentioned electrical and / or physical triggering criteria can be linked together. A model (eg ECM) can be used to link various measurements and limits to control the cell's state of integration (bypassed / not bridged).

According to one embodiment, the present invention provides a battery having a plurality of battery cells and a battery control device, the battery cells each having a monitoring sensor and a device for triggering a mechanical safety element, the battery being characterized in that the battery control device is designed to be an electrical Trigger signal for the device for triggering the mechanical security element for the plurality of battery cells. In the present case, a battery control device can be understood as meaning an electrical device which processes sensor signals and outputs control and / or data signals in dependence thereon. The battery control device may have an interface, which may be designed in hardware and / or software. For a hardware ßigen training, the interfaces may for example be part of a so-called system ASICs, which includes a variety of functions of the battery control unit. However, it is also possible for the interfaces to be their own, integrated circuits or to consist at least partly of discrete components. In a software training, the interfaces may be software modules that are present, for example, on a microcontroller in addition to other software modules.

The embodiment as a battery can allow a balance between the battery cells, a so-called "balancing", wherein the balancing can be used to compensate for the cell voltage in a battery, such as a lithium-ion battery, as this is very important in these cells in terms of service life, amount of energy (travel time of an electric vehicle that uses the battery as an energy storage) and ultimately can be performance.The embodiment in a battery, the life of the battery, the quality of the cells and the temperature distribution within the battery can be positively influenced ,

In a battery according to an embodiment of the present invention, a defective cell may be actively taken out of series connection. As a result, an electric vehicle can continue to be ready to drive instead of lying down. Also, weak or damaged cells can be bypassed to increase the overall performance of the battery. The battery comprises an electronic unit for the controlled decoupling and bridging of individual battery cells. The invention according to an embodiment of the invention relates to the combination of sensors (measured values) and actuators (mechanical and electrical components which are installed in a battery cell, for example lithium-ion battery of an electric vehicle, and serve to separate the terminals of the cell internally or to bridge) to ensure optimum performance and safety of a battery. The battery control device is realized, for example, as a microelectronic circuit in the central control unit of a battery and can access the sensors and actuators of all cells of the battery in order to reversibly or irreversibly bypass individual or several cells. According to an embodiment of the invention, the approach presented here makes "cell balancing" unnecessary during the charging process since it can reversibly be bridged when a cell threatens to overcharge itself, in which case only a part or "subset" of a number of cells can be activated such compensation for wear or wear leveling and uniformity

Aging of weak and strong cells to achieve.

According to an embodiment of the invention, the present invention provides a method for decoupling and / or bridging connections of a battery cell for a vehicle, the battery cell having a monitoring sensor, wherein the monitoring sensor is designed to supply at least one measured variable to a state of the battery cell. wherein the battery cell comprises a mechanical security element, wherein the mechanical security element is designed to disconnect and / or short-circuit the terminals of the battery cell, the method comprising the following step:

Triggering the mechanical security element using an electrical trip signal based on the measured value of the monitoring sensor. One aspect of the method presented here is to increase the safety and performance of a battery by actively removing critical cells. An actively triggered bridging of cells with critical temperature / voltage characteristics is of great importance for battery safety. For the battery performance or performance, an actively triggered bridging of strongly aged or otherwise poorly performing cells with poor "state-of-health" is of great importance.The bridging can be achieved by using the mechanical safety element.

The method presented here, or an electronic unit that has devices that implement this method, in particular uses different measured values and characteristic numbers about the cells of a battery for controlling an actuator within a cell, which reversibly or irreversibly the cell in which it is installed , disconnect and / or bridge to produce optimum performance and maximum cell safety. The invention will now be described by way of example with reference to the accompanying drawings. Show it:

Fig. 1 is a schematic representation of a battery cell according to an embodiment of the present invention; and

2 shows a flowchart of an exemplary embodiment of the present invention as a method for decoupling and simultaneously or alternatively for bridging connections of a battery cell for a vehicle.

In the following description of preferred embodiments of the present invention, the same or similar reference numerals are used for the elements shown in the various figures and similarly acting, wherein a repeated description of these elements is omitted.

1 shows a schematic representation of a battery cell 100 according to an embodiment of the present invention. In the battery cell 100, an energy store 1 10 is formed, wherein the energy storage device 1 10 two terminals 1 15 has. The two terminals 1 15 have an opposite polarity. The energy store 1 10 is connected via the two terminals 1 15 with a mechanical security element 120. Two further connections 125 are formed next to the two connections 1 15 on the mechanical security element 120, wherein the two further connections 125 lead out of the battery cell and are designed such that the battery cell 100 can be contacted via the two further connections 125. The mechanical security element 120 is designed to interrupt and / or bridge the connections 1 15 leading out of the energy store 1 10, which pass into the connections 125.

The battery cell 100 further includes a monitor sensor 130, a monitor 140, and a trigger 150. The monitoring sensor 130 is connected to the monitoring device 140. The monitoring sensor is designed to output at least one measured variable 160. The monitoring device 140 is designed to receive at least one measured variable of the monitoring sensor. The means for monitoring is configured to output a trigger signal 170. The device for triggering 150 is configured to receive the trigger signal 170. The battery cell 100 further has an interface 180, which is designed to receive and / or output analog and / or digital signals. In the embodiment shown in Fig. 1, the interface 180 is connected to the means 140 for monitoring. The device 150 for triggering is designed to trigger the mechanical safety element 120 using the trigger signal 170. In one embodiment, the device 150 for triggering is designed to carry out an electrical actuation of the mechanical safety element.

In other words, Fig. 1 thus shows inter alia a device for decoupling and bridging battery cells 100. Existing mechanical safety element 120 (eg CID) is expanded, in particular electrical actuation of CID 120 parallel to the mechanical function is possible or provided.

In particular, the approach presented here extends an existing CID 120. The passive safety function of the CID 120 can be retained. In addition or as a replacement, a possibility is created to trigger the CID electrically. This can be done, for example, by switching on an electrical

Stromes are made by a resistor which heats a bimetallic strip, deflects and in that CID triggers, or disconnects the terminals of the cell and / or short circuits. The electrical triggering may be either through an external additional connection to the cell or through an electrical or electronic system, microsystem or IC built into the cell, such a described system comprising means for monitoring and means for triggering. Depending on whether a reversible or irreversible mechanical deformation is effected, the up. Respectively. Disconnecting or shorting cell connections reversibly or irreversibly. Advantageous is an embodiment in which the CID is bistable, d. H. can be switched by an electrical release between two (or more) latched states.

The approach presented here relates to a device with mechanical and electrical components which can be installed in a battery cell 100 (for example lithium-ion battery of an electric vehicle) and serves to Separate conclusions 125 of the cell 100 internally, or to bridge. In one embodiment of the present invention, in particular, an electrical irreversible actuation of the CID 120 is provided parallel to the mechanical function of the mechanical protection element 120.

2 shows a flow diagram of an embodiment of the present invention as method 200 for decoupling and simultaneously or alternatively for bridging connections of a variant of a battery cell for a vehicle described above. The method 200 includes a step 210 of triggering the mechanical security element using an electrical triggering signal based on the measurand of the monitoring sensor.

The embodiments described and shown in the figures are chosen only by way of example. Different embodiments may be combined together or in relation to individual features. Also, an embodiment can be supplemented by features of another embodiment. Furthermore, method steps according to the invention can be repeated as well as carried out in a sequence other than that described.

If an exemplary embodiment comprises a "and / or" link between a first feature and a second feature, then this is to be read so that the embodiment according to one embodiment, both the first feature and the second feature and according to another embodiment either only first feature or only the second feature.

Claims

claims

1 . Battery cell (100) with a device for decoupling and / or bypassing of terminals (125) of the battery cell (100), wherein the battery cell (100) comprises a mechanical security element (120), wherein the mechanical security element (120) is formed to the Disconnecting and / or shorting terminals (125) of the battery cell (100), the battery cell (100) comprising: means (150) for actuating the mechanical security element (120) using an electrical trip signal (170).

2. Battery cell (100) according to claim 1, wherein the battery cell (100) has a monitoring sensor (130), wherein the monitoring sensor (130) is designed to supply at least one measured variable (160) to a state of the battery cell (100). and wherein the means (150) is configured to trigger the mechanical security element (120) using an electrical triggering signal (170) based on the measurand (160).

Battery cell (100) according to one of the preceding claims, comprising means (140), which are exclusively associated with the battery cell (100), for monitoring the battery cell (100) using the monitoring sensor (130), wherein the device (140) is designed to generate the electrical release signal (170).

Battery cell (100) according to claim 3, wherein the monitoring sensor (130) as an integrated monitoring sensor (130) is formed and the means (140) for monitoring the battery cell (100) is an integral part of the integrated monitoring sensor (130).

A battery cell (100) according to claim 3 or 4, wherein the means (140) for monitoring the battery cell (100) is adapted to determine the electrical trigger signal (170) using a plurality of measurements (160) of the monitoring sensor (130).

The battery cell (100) of claim 5, wherein the means (140) for monitoring the battery cell (100) is configured to determine the electrical trip signal (170) using a predefined map.

Battery cell (100) according to one of the preceding claims, wherein the device (150) is designed to trigger the mechanical security element (120) using a trigger signal (170) supplied externally from the battery cell (100).

Battery cell (100) according to one of the preceding claims, in which the mechanical safety element (120) is designed to be triggered reversibly and / or in which the mechanical safety element (120) is designed to be irreversibly triggered and / or in which the mechanical safety element Security element (120) is designed as a bistable security element (120).

Battery cell (100) according to one of the preceding claims, wherein the means (150) for triggering reversible and / or in which the means (150) for triggering is irreversibly formed.

10. Battery cell (100) according to one of the preceding claims, wherein the security element (120) is designed to bridge the terminals (1 15) of an energy store (1 10) of the battery cell (100).

1 1. Battery cell (100) according to one of the preceding claims, wherein the mechanical security element (120) is designed to separate the energy store (1 10) of the battery cell (100) from the terminals (1 15).

12. Battery cell (100) according to one of the preceding claims, with an interface (180) for communicating with at least one further battery cell (100) and / or a battery management system.

13. Battery cell (100) according to one of the preceding claims, wherein the monitoring sensor (130) is designed to deliver a plurality of measured variables (160).

14. Battery with a plurality of battery cells (100) according to one of claims 1 to 13 and a battery control device, wherein the battery cells (100) each have a monitoring sensor (130) and a device (150) for triggering a mechanical security element (120) characterized in that the battery control device is adapted to output an electrical trip signal (170) to the device (150) for triggering the mechanical security element (120) for one, several or all of the battery cells (100).

15. Method (200) for decoupling and / or bridging connections of a battery cell (100) according to claim 1 for a vehicle, wherein the battery cell (100) has a monitoring sensor (130), wherein the monitoring sensor (130) is designed to at least a measurement variable (160) to provide a state of the battery cell (100), wherein the battery cell (100) comprises a mechanical security element (120), wherein the mechanical security element (120) is designed to, the terminals (125) of the battery cell ( 100) and / or short-circuiting, the method (200) comprising the following step:

Triggering (210) the mechanical security element (120) using an electrical triggering signal (170) based on the measurand (160) of the monitoring sensor (130).