EP4399381A1 - Motor vehicle and use of a traction battery - Google Patents

Abstract

The invention relates to a motor vehicle, in particular electric motor vehicle or hybrid motor vehicle, which is equipped with at least one electromotively actuable motor vehicle lock (4), and with at least one on-board battery (7) and with an emergency battery (2) for application of an electromotive drive (8) of the motor vehicle lock (4) during normal operation and during emergency operation. According to the invention, a traction battery (2) provided for driving the motor vehicle acts as the emergency battery (2) during emergency operation.

Description

Description

Motor vehicle and use of a traction battery

The invention relates to a motor vehicle, in particular an electric or hybrid motor vehicle, with at least one motor vehicle lock that can be actuated by an electric motor, and with at least one on-board battery and an emergency battery for charging an electric motor drive of the motor vehicle lock in normal operation and in emergency operation.

Motor vehicle locks that can be actuated by an electric motor are generally constructed in such a way that an obligatory locking mechanism consisting of a rotary latch and a pawl can be opened using the electric motor. For this purpose, the pawl is lifted from its engagement with the rotary latch, with the result that a locking bolt previously caught by the rotary latch is released as a result. The associated motor vehicle door can be opened. In principle, the electric motor drive for the motor vehicle lock can also be used and work in such a way that the previously mentioned locking mechanism is unlocked with its help and can then be opened mechanically, for example.

Either way, normal operation of such a motor vehicle and the associated motor vehicle lock requires that the electric motor drive is supplied with sufficient electrical energy using the on-board battery in order to be able to open the locking mechanism by electric motor in the example described or at least to ensure unlocking. If an accident or a crash occurs in such a motor vehicle, the system switches to what is known as emergency operation. The same applies if the on-board battery has failed. In emergency operation, instead of the on-board battery, the additional emergency battery provided acts on the electromotive drive of the motor vehicle lock. In this way, the motor vehicle lock in question can also be opened by an electric motor in emergency operation with the aid of the emergency battery, or can at least be unlocked. This is necessary in order to enable rescue personnel arriving at the motor vehicle after such an accident or crash to open the motor vehicle door and thus to allow access to vehicle passengers who may need to be cared for inside the motor vehicle.

In the prior art according to KR 10-2015-0015 051 A, the procedure is such that in normal operation an electric lock there is supplied with the required electrical energy using the on-board battery. In addition, an additional external emergency energy source is implemented, which can be connected via a USB port, for example.

The generic prior art according to DE 695 09 316 T2 relates to an arrangement consisting of a motor vehicle door and an associated electric door lock. The electric door lock is opened by actuating an actuating element, which is supplied by the vehicle battery or the on-board battery. In the event of a malfunction in the power supply of said on-board battery, the electric door lock can be opened by the power supply provided by a backup battery. For this purpose, the reserve battery is arranged in the associated motor vehicle door to which the electric door lock belongs. This has basically worked.

However, the supplementary realization of a reserve battery or emergency battery inside the motor vehicle door or also inside a lock housing of the motor vehicle lock leads in practice not only to increased costs but also to an increased weight of the motor vehicle door in question or also of the motor vehicle lock. castle or both. This is disadvantageous in that the motor vehicle door is opened by a user must be and this is consequently associated with increased operating forces.

In addition, the faultless functioning of the emergency battery must be guaranteed over the entire service life of the motor vehicle in question. This generally requires a regular replacement of the emergency battery every few years. In addition, the emergency battery usually has to be charged externally or internally using the on-board battery. Nevertheless, malfunctions in the event of a crash cannot be ruled out with absolute certainty. This is where the invention comes in.

The invention is based on the technical problem of further developing such a motor vehicle and in particular an electric or hybrid motor vehicle in such a way that a problem-free door opening following a crash or failure of the on-board battery is functionally reliable over long time scales and with less effort compared to the prior art becomes.

To solve this technical problem, the invention proposes in a generic motor vehicle and in particular an electric or hybrid motor vehicle that a traction battery provided for driving the motor vehicle functions as an emergency battery in emergency operation.

The invention thus makes use of a special emergency battery which, in emergency operation, ensures the actuation of the motor vehicle lock which can be actuated by an electric motor. In fact, the emergency battery in question is the traction battery intended to drive the vehicle. The invention is based on the finding that electric or hybrid motor vehicles typically have, in addition to the on-board battery that is still implemented and provided unchanged, a traction battery that (exclusively) ensures the drive of the motor vehicle in electric mode. For this purpose, the motor vehicle in question has at least one electric motor, which using is driven by the traction battery, in order to then in turn move the motor vehicle either purely electrically or to support the drive using, for example, an internal combustion engine.

The traction battery is implemented and provided independently of the on-board battery and is therefore usually not charged via an additionally provided generator (alternator), but rather by recuperators or at a charging station of an electrical charging infrastructure.

For this reason, the supply voltage delivered by such a traction battery for the electric motor of the additional drive is generally designed to be much higher than the vehicle electrical system voltage provided by the on-board battery. In fact, such traction batteries usually work with high voltage, which can be up to several 100 V, whereas the vehicle electrical system voltage typically has values of 12 V to a maximum of 48 V, if only to avoid any health hazards for users.

For this reason, the driving battery, which typically works with high voltage, is usually designed to be completely separate, both mechanically and electrically, from the on-board battery and also the on-board network and the body of the motor vehicle. The mechanical separation of the traction battery is typically provided by a cage enclosing the traction battery or some other type of housing inside the body of the motor vehicle, if only to prevent damage to the traction battery even in the event of a crash.

For this reason, the traction battery is usually placed in an underbody and away from crumple zones of the associated motor vehicle. Supply lines, which connect the traction battery in question to the at least one electric motor for driving the vehicle, ensure the electrical insulation Motor vehicle and on the other hand connect to a charging socket. The supply lines expressly do not use the body of the motor vehicle, as is regularly the case for the ground line or the negative pole of the vehicle electrical system voltage and the vehicle battery. Rather, the supply lines for the two poles of the traction battery, which usually works with DC voltage, are explicitly electrically insulated from the body. In any case, the traction battery is both mechanically and electrically separated from the on-board battery and thus the on-board voltage.

In this way, even in the event of a crash or an accident or if the on-board battery has other malfunctions, i.e. in emergency operation, it can be assumed that the traction battery will continue to function and consequently as an emergency battery for driving the electric motor drive inside the vehicle -Castle can be used. The motor vehicle lock in question can be any conceivable motor vehicle lock that is present in or on the body. This includes not only motor vehicle door locks, motor vehicle tailgate locks or motor vehicle bonnet locks, but also locks on, for example, tank flaps, loading flaps or inside the motor vehicle in connection with, for example, a glove compartment or other storage compartments. In any case, all motor vehicle locks that can be actuated by an electric motor can be reliably opened according to the invention, even in emergency operation, because in emergency operation the traction battery provided for driving the motor vehicle acts as an emergency battery, which is also functional if the on-board battery fails and consequently in emergency operation. This is where the main advantages can be seen.

The subject matter of the invention is consequently also the use of a traction battery of an electric or hybrid motor vehicle as an emergency battery for acting on an electromotive drive of a motor vehicle lock.

The use of the traction battery in the context mentioned is considered independent claim formulated.

According to a further advantageous embodiment, the traction battery is electrically connected to the relevant motor vehicle lock with the interposition of a switching device. In this context, the switching device is inactive during normal operation and only works in emergency operation. This means that in normal operation the switching device ensures that the traction battery is electrically isolated from the motor vehicle lock. Only when emergency operation occurs and is observed does the switchover device work and ensure that the motor vehicle lock in question can be electrically supplied with the help of the traction battery.

For this purpose, the switching device is generally designed as a switching device that can be actuated during an opening process of the motor vehicle lock, or has such a switching device. In other words, in the simplest case, the switching device can be the switching device that can be actuated or is actuated when the motor vehicle lock is opened. Such a switching device may be embodied as a simple switch, which is assigned to an outside door handle, for example, and is acted upon when the outside door handle is actuated to open the motor vehicle door and thus the associated motor vehicle lock. In principle, the switching device can of course also be designed independently of the outside door handle. In principle, it is possible and conceivable for the switching device to be acted upon manually, such as actuation of the switching device using a remote control.

As a rule, however, the switching device is assigned to the outside door handle and is acted upon as soon as the outside door handle is actuated. The overall design is such that during normal operation the actuation of the switching device to open the motor vehicle lock ensures that the motor vehicle lock is charged by the on-board battery with the necessary electrical energy is supplied. In emergency operation, the switching device, which is designed as a switching device in the example, ensures that the motor vehicle lock is supplied with electricity using the traction battery, which acts as an emergency battery.

In most cases, however, the switching device is part of the switching device. Here, the invention is based on the additional finding that the switching device is acted upon with the aid of a control unit in order to change from normal operation to emergency operation. For this purpose, the control unit can, for example, evaluate the signal from a sensor. The sensor can be a crash sensor. Alternatively or additionally, however, the sensor can also be used to evaluate the vehicle electrical system voltage. If the vehicle electrical system voltage falls below a predetermined value, for example 10 V or 8 V, the control unit switches from normal operation to emergency operation depending on the signal from the relevant sensor. The same applies when the crash sensor transmits a corresponding signal to the control unit.

Today's modern motor vehicles are obligated to have such a crash sensor, which is designed as an acceleration sensor and reports decelerations above a certain threshold to the control unit, which then activates appropriate safety devices such as airbags, belt tensioners, etc. According to the invention, the signal from the relevant crash sensor is also used and converted by the control unit in order to be able to switch from normal operation to emergency operation.

In addition, the switching device advantageously has a conversion unit that has a voltage-dependent resistor. This voltage-dependent resistor is usually an electronic resistor such as a varistor. The voltage-dependent resistor as part of the switchover device ensures that the power provided by the traction battery in emergency mode is available (High) voltage and also the available current can each be reduced to such an extent that the electromotive drive in the motor vehicle lock can be controlled and, in particular, is not destroyed in the process. In addition, the voltage-dependent resistor provides protection against overvoltage when the motor vehicle lock is acted upon by the electromotive drive. Of course, other devices such as voltage and current converters can also be used here, which ensure that the electrical energy provided by the traction battery can be used precisely to control the electric motor drive of the motor vehicle lock in emergency operation.

In this context, the further possibility according to the invention should also be seen that the switching device is also used to connect a timing control within which the electromotive drive of the motor vehicle lock is controlled in order to prevent any overheating. In the simplest case, instead of the voltage-dependent resistor in connection with the switching device, you can also simply work with a mechanical relay, which ensures the desired conversion of the electrical energy provided by the traction battery to control the electric motor drive of the motor vehicle lock.

According to a further advantageous embodiment, the switching device can be arranged largely inside a motor vehicle lock housing. In this case, the motor vehicle lock is upgraded, so to speak, according to the invention by the switching device, which as a rule only has to be connected to the switching device provided externally when it is installed in the

Motor vehicle must be connected. In principle, however, the switching device can also be integrated into the motor vehicle lock housing, so that in such a case the switching device can be accommodated completely inside the motor vehicle lock housing. As a result, a particularly compact and inexpensive variant is made available because under other things, a separate housing for the switching device is not required, but rather the already existing motor vehicle lock housing is used to enclose the switching device.

As a result, a motor vehicle and the use of a traction battery of such a motor vehicle are described, the traction battery being used or functioning as an emergency battery for charging the electromotive drive of a motor vehicle lock belonging to the motor vehicle door. This procedure makes it possible to dispense with an additional backup battery in the relevant motor vehicle lock. In addition, such backup batteries usually have to be provided on every motor vehicle lock, whereas according to the invention only the drive battery, which is already present, is used as an emergency battery in emergency operation. As a result, a particularly cost-effective and compact structure with weight advantages is implemented.

In addition, the traction battery also makes the electrical energy required for emergency operation of the motor vehicle lock available and can supply it when switching from normal operation to emergency operation, i.e. the on-board battery no longer provides any or insufficient electrical energy. This is where the main advantages can be seen.

The invention is explained in more detail below with reference to a drawing that merely represents an exemplary embodiment; show it:

Fig. 1 shows the motor vehicle according to the invention schematically and

2 shows the circuit implemented at this point for implementing emergency operation.

The figures show a motor vehicle which, according to the exemplary embodiment, is designed as an electric or hybrid motor vehicle. To For this purpose, the motor vehicle first of all has a body 1. Inside the body 1, more precisely in or on its underbody, a traction battery 2 is implemented, which is accommodated in its own housing or cage. The traction battery 2 usually extends in the space between the drive wheels 3 of the motor vehicle. 1 also shows two motor vehicle locks 4 that can be actuated by an electric motor, specifically a motor vehicle lock 4 on a front side door 5 and another motor vehicle lock 4 on a rear side door 6. This of course only applies as an example and is in no way limiting understand.

With the help of the traction battery 2 , one or more additionally provided electric motors can be supplied with electrical energy in order to drive the motor vehicle shown or the drive wheels 3 . If the electric motors alone ensure the drive, it is an electric vehicle. Alternatively, the motor vehicle can also work as a hybrid motor vehicle. In this case, the one or more electric motors, not expressly shown, are implemented in addition to an internal combustion engine and, as an alternative or in addition to the relevant internal combustion engine, ensure the drive of the drive wheels 3.

The motor vehicle shown is equipped with an on-board battery 7 in addition to the traction battery 2 . The on-board battery 7 supplies an on-board network and, among other things, according to the exemplary embodiment, the two illustrated or all motor vehicle locks 4 with the required electrical energy.

In fact, the motor vehicle lock 4 in question is equipped in its interior with an electric motor drive 8, which is only indicated, with the aid of which a locking mechanism 9, 10, which is indicated schematically in FIG. In fact, the electric motor drive 8 works according to the embodiment indirectly or directly onto the pawl 10 and lifts it from its latching engagement with the rotary latch 9 in order to electrically open the motor vehicle lock 4 . As a result of this, a locking bolt which was previously caught by the rotary latch 9 and is not expressly shown and which is fixed to the body is released so that the motor vehicle door 5, 6 in question can then be opened. This is ensured by the on-board battery 7 in normal operation.

For this purpose, the on-board battery 7 works with low direct current in the range from 12 V to approx. 48 V, as has already been described and explained in the introduction. In contrast, the traction battery 2 is mechanically and electrically separate from the on-board battery 7 because the traction battery 2 usually also works with DC voltage, but with a high voltage of several 100 V in the example.

As already explained, in normal operation the on-board battery 7 ensures that the electric motor drive 8 of the relevant motor vehicle lock 4 is charged. According to the invention and in emergency operation, the battery originally used to drive the drive wheels 3 of the motor vehicle acts as an emergency battery for the electric motor drive 8 of the motor vehicle lock provided drive battery 2. For this purpose, the drive battery 2 is electrically connected to the relevant motor vehicle lock 4 with the interposition of a switching device 11, 12. For this purpose, the switching device 11, 12 has a switching device 12 that can be actuated when the motor vehicle lock 4 is opened.

According to the exemplary embodiment, the switching device 12 is provided and arranged on or in the area of an outside door handle 13 . If, in emergency operation, the outside door handle 13 is acted upon to open the motor vehicle lock 4, to which a movement indicated in the direction of the arrow in FIG. 2 corresponds, this results in the switching device 12 being acted upon. In addition to the switching device 12, the switching device 11, 12 in Embodiment still a conversion unit 11 on. With the aid of the conversion unit 11 , the electrical energy made available by the traction battery 2 in emergency operation is adapted to the requirements of the electric motor drive of the motor vehicle lock 4 . For this purpose, the conversion unit 11 and consequently the switching device 11, 12 can be designed with a voltage-dependent resistor, not expressly shown, in the form of an electronic resistor and, for example, a varistor. In principle, however, it is also conceivable for the conversion unit 11 to work with a relay in this context. Voltage-to-current converters as well as timers are also conceivable, on the one hand to adapt the electrical energy provided by the traction battery 2 to the requirements of the electric motor drive 8 of the motor vehicle lock 4 and on the other hand to prevent or reduce any overheating of the electric motor drive 8 via the timer .to ensure that it is switched off in good time in emergency operation.

2 shows that a control unit 14 is additionally provided. The design is such that the switching device 11 , 12 is acted upon with the aid of said control unit 14 to switch from normal operation to emergency operation. For this purpose, the control unit 14 generally evaluates the signal from at least one sensor 15 . The sensor 15 can be one that is used to monitor the vehicle electrical system voltage provided by the vehicle battery 7 . Alternatively or additionally, however, the sensor 15 can also be designed as a crash sensor. The switchover device 11 , 12 can be installed entirely or for the most part inside a motor vehicle lock housing 16 , which is indicated in FIG. 2 by dot-dash lines. As a result, a particularly compact and cost-effective design is made available.

How it works is as follows. In normal operation, ie as long as the on-board battery 7 has a specific value stored in the control unit 14, for example Provides minimum voltage and minimum current available, the electric motor drive 8 of the motor vehicle lock 4 is fed with electrical energy exclusively using the on-board battery 7 . In this case, the switching device 11, 12 is inactive. However, if emergency operation occurs because the evaluation of the signal from sensor 15 by control unit 14 indicates a crash or an insufficient energy supply from on-board battery 7, switching device 11, 12 is switched to emergency operation with the aid of control unit 14 and is active.

The active switching device 11, 12 now ensures (in conjunction with the control unit 14) that the electric motor drive 8 is no longer supplied with the required electrical energy using the on-board battery 7, but rather via the traction battery 2, which acts as an emergency battery in emergency operation . In this context, the conversion unit 11 as part of the switching device 11 , 12 ensures that the electrical power provided by the traction battery 2 is adapted to the electrical power required by the electric motor drive 8 . Also for the fact that the electric motor drive 8 is acted upon in emergency operation and, for example, only for as long as is required following the actuated switching device 12 using the outside door handle 13 until the rotary latch 9 and thus the associated motor vehicle door 5, 6 are safely opened is.

Reference List

body 1

drive battery 2

drive wheels 3

Motor vehicle lock 4 front side door 5 rear side door 6

on-board battery 7 electric motor drive 8

lock 9,10

rotary latch 9

Lock link 10

Switching device 11, 12

conversion unit 11

switching device 12

Outside door handle 13

control unit 14

sensor 15

Motor vehicle lock housing 16

Claims

patent claims 1. Motor vehicle, in particular electric or hybrid motor vehicle, with at least one motor vehicle lock (4) that can be actuated by an electric motor, and with at least one on-board battery (7) and an emergency battery (2) for acting on an electric motor drive (8) of the motor vehicle lock (4 ) in normal operation and in emergency operation, d a d a r c h g e n n n z e i c h n e t that in emergency operation a traction battery (2) provided for driving the motor vehicle functions as an emergency battery (2). 2. Motor vehicle according to claim 1, characterized in that the drive battery (2) with the interposition of a switching device (11, 12) with the relevant motor vehicle lock (4) is electrically connected. 3. Motor vehicle according to claim 2, characterized in that the switching device (11, 12) is designed as an opening process of the motor vehicle lock (4) actuatable switching device (12) or has such. 4. Motor vehicle according to claim 2 or 3, characterized in that the switching device (1 1, 12) is inactive in normal operation and only works in emergency operation. 5. Motor vehicle according to claim 4, characterized in that the switching device (11, 12) is acted upon by a control unit (14) to change from normal operation to emergency operation. 6. Motor vehicle according to claim 5, characterized in that the Control unit (14) evaluates the signal of at least one sensor (15). 7. Motor vehicle according to one of claims 2 to 6, characterized in that the switching device (11, 12) is equipped with a conversion unit (11). 8. Motor vehicle according to claim 7, characterized in that the conversion unit (11) has a voltage-dependent resistor. 9. Motor vehicle according to one of claims 2 to 8, characterized in that the switching device (11, 12) is arranged largely inside a motor vehicle lock housing (16). 10. Use of a traction battery (2) of an electric or hybrid motor vehicle as an emergency battery (2) for acting on an electric motor drive (8) of a motor vehicle lock (4).