The invention relates to a method for rolling an electrically driven vehicle into a parking lock device from a position in which a pawl is prevented from locking a parking lock gear. Furthermore, the invention relates to the use of the method for rolling an electrically driven vehicle into a parking lock device.
DE 10 2015 217 975 A1 relates to a method for designing a parking lock of a dual-clutch transmission of a vehicle. The dual-clutch transmission comprises a parking lock. In order to design the parking lock of a dual clutch transmission of a vehicle, a torque request is issued when a road inclination is detected and a powershift clutch of the dual clutch transmission is closed when a gear is engaged in the partial transmission to which the powershift clutch is assigned. The powershift clutch to be engaged and the required torque are selected in such a way that the torque counteracts the torque applied to the transmission on the output side via the drive gears when the parking lock is engaged, which is supported by the locking pawl, and serves as a relief torque.
DE 10 2011 079 618 A1 relates to a parking lock that has a parking lock gear with toothing and a locking pawl. The locking pawl can be moved relative to the parking lock gear in such a way that it blocks or releases the parking lock gear. The parking lock gear can be moved by a drive that operates independently of the adjustment mechanism. Before or during engagement or disengagement of the parking lock by means of the drive, the parking lock gear is repositioned relative to the locking pawl, wherein the parking lock gear is subjected to torque. This reduces the insertion or removal forces to be applied by the adjustment mechanism.
DE 10 2009 030 084 B4 relates to a method for releasing a parking lock of a motor vehicle. The parking lock is first activated by means of a control variable to release the parking lock. This involves setting a drive torque that counteracts a downhill drive torque as a function of a control variable. A downhill drive torque is determined using a characteristic measured variable as a function of the control variable, which acts on the locked wheels by means of the parking lock. A drive torque that counteracts the downhill torque is set depending on the measured variable. The drive torque is set against the approach direction if the approach direction and the downhill drive direction are in the same direction, wherein the downhill drive torque exceeds the drive torque during release and/or during stopping or, alternatively, the drive torque is set in the approach direction if this and the downhill drive direction are in opposite directions to each other.
Today, parking locks are used in most automatic transmissions to prevent the vehicle from rolling away unintentionally. Parking locks are also installed in the transmission downstream of the electric motor in electrically driven vehicles. If a vehicle equipped with a parking lock is parked on a slope or downhill section, the following situation may arise:
The driver brakes the vehicle to a standstill using the brake system and then activates the parking lock. The parking lock actuator then actuates the pawl via a mechanism to insert it into a gap in the parking lock gear. It can happen that the tooth of the pawl hits the tooth of the parking lock gear and locking is impossible. In this case, a spring is biased in such a way that it presses the pawl onto the parking lock gear. When the driver releases the brakes, the vehicle starts to roll forwards or backwards, depending on whether it is on a downhill or uphill section of the route. The rolling of the vehicle turns the drive gears, the transmission and thus also the parking lock gear coupled to it. The pressed pawl engages in the next gap of the parking lock gear due to the effect of the spring biasing. However, this causes the vehicle to stop abruptly, resulting in vibrations and torques that put mechanical stress on the components in the drivetrain, but can also lead to a reduction in noise and comfort for the driver. In order to make this abrupt stop more gentle, DE 10 2017 118 517 A1 and US 2018/0043895 A1 propose slowly reducing the applied brake pressure and thus slowly rolling the vehicle into the parking lock.
According to the invention, a method is proposed for rolling an electrically driven vehicle into a parking lock device from a position in which a pawl is prevented from locking a parking lock gear, wherein the following method steps are carried out:
In the manner described above, a gentle rolling of the vehicle can be achieved without the need for additional sensor technology if the electrically driven vehicle is parked on an incline or downhill section and a tooth-on-tooth position is present on the parking lock device. The brake pressure or the gradient of the brake pressure reduction is not used, and no additional sensors or other additional parts are required. Finally, there is the advantageous possibility of cost-effective and simple realisation.
In a further development of the method proposed according to the invention, a direction of rotation of the electric motor for sweeping the angle of rotation determined according to c) is determined in the control unit of the electrically driven vehicle from the information as to whether the electric motor has delivered a torque before reaching the standstill position of the electrically driven vehicle, or whether the electric motor was rotated or dragged by the vehicle movement before reaching the standstill position of the electrically driven vehicle in recuperation mode.
Using existing components, both the angle of rotation to reach the nearest tooth spaces and the direction of rotation in which the electric motor is to be moved can be determined without the need for additional hardware components.
In an advantageous further development of the method proposed according to the invention, the rotary movement of the pawl about an axis of rotation is brought about by a translatory movement of an actuating mechanism. This makes it possible to realise short actuating paths in an advantageous way, so that the actuator of the parking lock device can be designed accordingly.
In a further advantageous embodiment of the method proposed according to the invention, the biasing of the biasing spring according to a) is transferred to a translationally movable slider of the actuating mechanism of the parking lock device, so that the latter is set against an actuating surface having a wedge-shaped contact surface.
In a further advantageous embodiment of the method proposed according to the invention, the position of the parking lock gear according to b) is detected by means of a position sensing system designed as a resolver. This is an advantageous way of ensuring reliable signal acquisition.
In a further advantageous embodiment of the method proposed according to the invention, the pawl is held in a position set against the outer toothing of the parking lock gear while method steps a) through d) are being carried out. This ensures that as soon as the information in the control unit regarding the angle of rotation and the direction of rotation of the electric motor is determined, the parking lock can be locked immediately in the next available tooth space of the outer toothing of the parking lock gear without any further delays in the signal chain.
In a further, advantageous embodiment of the method proposed according to the invention, the pawl is locked there by the slider of the actuating mechanism after engaging in the nearest tooth space of the outer toothing according to c), so that the vehicle remains reliably secured in its parked position.
In the method proposed according to the invention, the pawl is unlocked, i.e. released again, by a translatory movement of the slider once the parking lock device has been activated again after the controlled rolling movement has been carried out.
Furthermore, the invention relates to the use of the method for rolling an electrically driven vehicle into a parking lock device from a position in which a pawl is prevented from locking the parking lock gear.
In contrast to the known methods, in which the brake pressure can be used to execute a rolling movement and is slowly reduced during the rolling process, the method proposed according to the invention does not require the use of brake pressure. With electrically driven vehicles, the driver can only bring the vehicle to a standstill using one-pedal operation, as the electrically driven vehicle is braked by the drag torque applied by the electric motor if the accelerator pedal is not depressed, i.e. it is not absolutely necessary to apply the brake to decelerate. If the situation arises in this driving position and in this driving mode, i.e. one-pedal operation, that the electrically driven vehicle comes to a standstill on an uphill or downhill gradient and there is a tooth-to-tooth position on the parking lock, the method proposed in accordance with the invention can be used to achieve a gentle rolling of the vehicle. This is achieved without additional sensors by using components already known for detecting the position of the parking lock gear, for example in the form of a resolver. This allows a reliable rotational position of the parking lock gear to be determined on the one hand, and on the other hand, the direction of rotation of the electric motor is used to determine whether the electric motor supplied a torque before the vehicle came to a standstill or whether a torque was applied to it by the vehicle movement in towing mode. From the position sensing and the known geometry of the outer toothing of the parking lock gear, the nearest tooth space in the outer toothing of the parking lock gear can be determined without the use of additional hardware.
Based on the now known angle of rotation of the rotor shaft, on the circumference of which the parking lock gear is fastened in a rotationally fixed manner, and the known direction of rotation of the electric motor, it is now possible to achieve controlled rolling of the electrically driven vehicle into the parking lock.
A further advantage of the method proposed according to the invention is that the method can also be retrofitted to vehicles that have already been delivered as an update with regard to the software and can therefore also improve the driving comfort of vehicles that have already been delivered.
Embodiments of the invention are explained in greater detail with reference to the drawings and the following description.
Here:
In the following description of the embodiments of the invention, identical or similar elements are denoted by identical reference numbers, wherein a repeated description of these elements is omitted in individual cases. The figures illustrate the subject-matter of the invention merely schematically.
As can also be seen from the representation according to
Furthermore, a parking lock device 44 is associated with the transmission 16 as shown in
The illustration in
The transition from the state in the position according to
The position detecting 36 is connected to the control unit 40 via the signal connection 38. The control unit 40 can be used to control the entire electric drivetrain 12, but a separate control unit 40 can also be used for this purpose.
The rotor shaft 34 of the electric motor 14 transmits the torque of the electric motor 14 to the transmission 16. This is where the torque conversion takes place via the gearwheels 42. The torque is transmitted to the drive gears 22 and 24 via the axle differential 26 via the drive shafts 18, 20. The parking lock device 44 is located in the transmission 16.
The parking lock gear 46 of the parking lock device 44 is, for example, connected to the rotor shaft 34 or the rotor 32 of the electric motor 14 in such a way that a rotary movement, which is detected by the position detecting 36 in the form of a resolver, also leads to a corresponding rotation of the parking lock gear 46. This means that the position of the parking lock gear 46, which can be accommodated in a rotationally fixed manner in the rotor shaft 34 or in an intermediate shaft, can be clearly assigned to a signal of the position detecting 36. This makes it possible to determine the exact position of the parking lock gear 46 from the position detection signal 36.
If the electrically driven vehicle 10 now comes to a standstill on an uphill or downhill gradient and the parking lock device 44 is actuated by the driver, the control unit 40 controls the parking lock actuator 52 of the parking lock device 44, which in turn actuates the pawl 48 via the actuation mechanism 50. In the case of the tooth-on-tooth position shown in
The control unit 40 calculates the angle of rotation by which the electric motor 14 in the electric drivetrain 12 must rotate the rotor 32 or the rotor shaft 34 so that the nearest tooth space 60 of the outer toothing 56 of the parking lock gear 46 can engage with the pawl 48 or its pawl tooth 64.
The direction of rotation for the electric motor 14 is known in the control unit 40 by the fact that when the vehicle is parked on an incline, the electric motor 14 has delivered a torque before coming to a standstill. When passing a downhill section before the vehicle is parked, a drag torque was applied to the electric motor 14 by the vehicle movement.
Since the control unit 40 now knows the direction of rotation of the electric motor 14 and the angle of rotation for reaching the nearest tooth space 60, this position can now be approached in a precisely controlled manner, which corresponds to the state of
During this process, it is not necessary for the driver of the electrically driven vehicle 10 to press the brake pedal. However, if the driver has applied the brake pedal out of habit and then released it again, the brake application or brake release is transmitted to the control unit 40, for example via a CAN bus in the electrically driven vehicle 10.
If the electrically driven vehicle 10 begins to move and a rotary movement is transmitted via the drive gears 22, 24, the drive shafts 18 and 20 to the transmission 16 and thus to the electric motor 14, this rotary movement is detected by the position detecting 36. The control of the further movement, i.e. the rolling of the electrically driven vehicle 10 into the parking lock device 44 via a corresponding control of the electric motor 14 in the electric drivetrain 12 can be carried out as described above.
The invention is not limited to the exemplary embodiments described herein and the aspects highlighted therein. Rather, a variety of modifications, which are within the scope of activities of the person skilled in the art, is possible within the range specified by the claims.
Number | Date | Country | Kind |
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10 2021 205 592.3 | Jun 2021 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2022/061039 | 4/26/2022 | WO |