The present invention relates to a method for operating a motor vehicle. A request for coupling a power take-off is detected. It is checked (12) whether relevant boundary conditions for coupling the power take-off are fulfilled. If the boundary conditions are fulfilled, a system pressure for actuating the power take-off clutch is built up (16). It is checked (18) whether sufficient system pressure to actuate the power take-off clutch has been built up. When sufficient system pressure has been built up, a confirmation signal is produced (20). In reaction to the confirmation signal, a driving transmission control unit is modified (34) in order to actuate the at least one shifting element of the driving transmission with a higher actuation pressure than with an unmodified driving transmission control unit.

A method of operating a motor vehicle. A request for coupling a power take-off is detected. It is checked (12) whether relevant boundary conditions for coupling the power take-off are fulfilled. If the boundary conditions are fulfilled, a system pressure for actuating the power take-off clutch is built up (16). It is checked (18) whether sufficient system pressure to actuate the power take-off clutch has been built up. When sufficient system pressure has sufficiently been built up, a confirmation signal is produced (20). In reaction to the confirmation signal, a driving transmission control unit is modified (34) in order to actuate the at least one shifting element of the driving transmission with a higher actuation pressure than with an unmodified driving transmission control unit.

A coupling assembly has a second coupling member mounted for rotation and a first coupling member having a speed sensor to sense a speed of rotation of the second coupling member. The coupling assembly further has a forward and a reverse locking element movable between (i) a coupling position in which the locking elements engage the second coupling member to thereby prevent rotation of the second coupling member in opposite first and second directions and (ii) a non-coupling position. Upon the speed of rotation of the second coupling member decreasing to be lower than a hill-hold speed threshold, the reverse locking element is moved to the coupling position while the forward locking element is maintained in the non-coupling position. Irrespective of a Park command, the locking elements are maintained in the non-coupling position while the speed of rotation of the second coupling member is greater than a park speed threshold.

The present disclosure relates to an electric brake system for an electric vehicle, which is more economical by simplifying a configuration of an electric vehicle that includes a main service brake and an electromagnetic brake, the electric brake system including an inductor, in a spherical shape, formed so that a drive axle penetrates through a center portion of the inductor; a plurality of springs inserted into holes defined in the inductor; an armature, in a disk shape, provided to contact the spring; and a friction disk mounted on a side of a motor, where a braking force is generated by operating the friction disk toward the armature.

A coupling assembly has a second coupling member mounted for rotation and a first coupling member having a speed sensor to sense a speed of rotation of the second coupling member. The coupling assembly further has a forward and a reverse locking element movable between (i) a coupling position in which the locking elements engage the second coupling member to thereby prevent rotation of the second coupling member in opposite first and second directions and (ii) a non-coupling position. Upon the speed of rotation of the second coupling member decreasing to be lower than a hill-hold speed threshold, the reverse locking element is moved to the coupling position while the forward locking element is maintained in the non-coupling position. Irrespective of a Park command, the locking elements are maintained in the non-coupling position while the speed of rotation of the second coupling member is greater than a park speed threshold.

The present disclosure relates to an electric brake system for an electric vehicle, which is more economical by simplifying a configuration of an electric vehicle that includes a main service brake and an electromagnetic brake, the electric brake system including an inductor, in a spherical shape, formed so that a drive axle penetrates through a center portion of the inductor; a plurality of springs inserted into holes defined in the inductor; an armature, in a disk shape, provided to contact the spring; and a friction disk mounted on a side of a motor, where a braking force is generated by operating the friction disk toward the armature.

A method for operating a vehicle drive-train having a continuously power-branched transmission with secondary coupling. In the open operating condition of reversing clutches of a reversing gear unit, torque applied in the area of a drive output can be supported by a range group in the area of a variator. In the event of a command to interrupt the power flow between a drive engine and the drive output, it is checked whether the vehicle is on an inclined surface and if the result of that inquiry is positive, the power flow between the drive engine and the transmission is interrupted at the latest when the rotational speed of the drive output is reduced to zero by opening the reversing clutches, while the active connection between the drive output and the variator is maintained by way of the range group.

Backstopping Brake System (BBS) is a part with two original and Accessory natures that can be installed on all manual transmission cars which their engine power is transmitted into forward wheels. By installing the system on vehicle forward wheels axle (plus (P)), when plus rotates around its axle in a reverse motion of engine, it locks the plus (P) and prevents unnecessary reverse motion of vehicle. This system can be activated or inactivated from cabin inside wirelessly through control remote system (2-3) or by wire. In the case of necessary reverse motion, this system is inactivated by pulling back its pawl. For safety, when vehicle has a severe shock, this system will be separated from joint point of vehicle body.

A method for preventing overheating of a clutch for a vehicle may include determining, by a controller, whether a state of the vehicle satisfies a hill hold condition; acquiring, by the controller, a temperature of a clutch between an engine and a transmission when the hill hold condition is satisfied; applying, by the controller, a first torque having a predetermined square wave shape to the clutch when the temperature of the clutch reaches a first temperature; and applying, by the controller, a second torque having a predetermined sine wave shape to the clutch when the temperature of the clutch reaches a second temperature higher than the first temperature.

A method for operating a vehicle drive-train having a continuously power-branched transmission with secondary coupling. In the open operating condition of reversing clutches of a reversing gear unit, torque applied in the area of a drive output can be supported by a range group in the area of a variator. In the event of a command to interrupt the power flow between a drive engine and the drive output, it is checked whether the vehicle is on an inclined surface and if the result of that inquiry is positive, the power flow between the drive engine and the transmission is interrupted at the latest when the rotational speed of the drive output is reduced to zero by opening the reversing clutches, while the active connection between the drive output and the variator is maintained by way of the range group.