A gear lever for a motor-vehicle gearbox includes an elongated body, an actuating member arranged on the elongated body and a transmission member arranged within an inner passage of the elongated body. The transmission member is operatively connected to the actuation member and is configured to transmit movement of the actuation member to a controlled member.

An anti-theft apparatus of a shift lever for a vehicle includes: a shift lever case having a shift lever which is connected with a shift cable and a mounting portion fixing a socket of the shift cable; and a mounting bracket which is detachably connected to the mounting portion to cover the mounting portion when the mounting bracket is mounted to the mounting portion, wherein the mounting bracket includes: a first end portion having a penetration hole through which the shift cable passes when the mounting bracket is mounted to the mounting portion; and a second end portion having an insert groove into which a part of the socket is inserted and in which fixing pins wrap the shift cable to limit a lateral movement of the shift cable.

An anti-theft apparatus of a shift lever for a vehicle includes: a shift lever case having a shift lever which is connected with a shift cable and a mounting portion fixing a socket of the shift cable; and a mounting bracket which is detachably connected to the mounting portion to cover the mounting portion when the mounting bracket is mounted to the mounting portion, wherein the mounting bracket includes: a first end portion having a penetration hole through which the shift cable passes when the mounting bracket is mounted to the mounting portion; and a second end portion having an insert groove into which a part of the socket is inserted and in which fixing pins wrap the shift cable to limit a lateral movement of the shift cable.

A controller is integrated into a vehicle with the controller coupled to a fob detector and also coupled to a vehicle disabler. Examples of vehicle disablers include a brake transmission shift interlock (BTSI), a transmission shift interlock (TSI) and an air brake or electric parking brake of the vehicle. The fob detector can be provided along with the controller and separate from a mechanical key ignition of the vehicle, or can be a fob detector associated with a keyless ignition of the vehicle. A mobile fob is used as part of the system, carried on the person of an authorized driver of the vehicle. This fob can be provided separately from the vehicle, along with the controller, or can be a fob associated with a keyless entry of the vehicle. The controller causes the vehicle disabler to not be disengaged unless presence of the fob is detected by the fob detector.

A controller is integrated into a vehicle with the controller coupled to a fob detector and also coupled to a vehicle disabler. Examples of vehicle disablers include a brake transmission shift interlock (BTSI), a transmission shift interlock (TSI) and an air brake or electric parking brake of the vehicle. The fob detector can be provided along with the controller and separate from a mechanical key ignition of the vehicle, or can be a fob detector associated with a keyless ignition of the vehicle. A mobile fob is used as part of the system, carried on the person of an authorized driver of the vehicle. This fob can be provided separately from the vehicle, along with the controller, or can be a fob associated with a keyless entry of the vehicle. The controller causes the vehicle disabler to not be disengaged unless presence of the fob is detected by the fob detector.

A brake transmission shift interlock (BTSI) solenoid includes a solenoid housing having an inner surface defining a lock pin cavity. The solenoid also includes a lock pin positioned within the lock pin cavity, the lock pin moveable between a first position and a second position. The solenoid further includes a bumper protruding into the lock pin cavity and stationary relative to the lock pin, the bumper defining the first position of the lock pin.

A brake transmission shift interlock (BTSI) assembly is provided. The BTSI assembly may include an armature assembly and a flux collector. The armature assembly may include an armature component, a shaft, and a pin. The armature component may include a central through-hole defining a central axis and include a first end defining a first angle surface. The shaft may be disposed within the central through-hole and the pin mounted to the shaft. The flux collector may be mounted to the shaft and includes a second end defining a second angle surface. The armature component and the flux collector may be arranged with one another such that a first plane defined by the first angle surface is substantially parallel to a second plane defined by the second angle surface.

A brake transmission shift interlock (BTSI) assembly is provided. The BTSI assembly may include an armature assembly and a flux collector. The armature assembly may include an armature component, a shaft, and a pin. The armature component may include a central through-hole defining a central axis and include a first end defining a first angle surface. The shaft may be disposed within the central through-hole and the pin mounted to the shaft. The flux collector may be mounted to the shaft and includes a second end defining a second angle surface. The armature component and the flux collector may be arranged with one another such that a first plane defined by the first angle surface is substantially parallel to a second plane defined by the second angle surface.

A method is provided for alternately triggering driving states of a utility vehicle. The method includes providing a control element and a transmission selectively engageable in a forward driving state (F) for forward travel of the utility vehicle, a reverse driving state (R) for reverse travel, and a standstill driving state (S) for a stationary output of the transmission without disconnection of the drivetrain in the utility vehicle. The method further includes operating the transmission in a current driving state, operably selecting a target driving state while operating in the current driving state, and controllably triggering the transmission to the standstill driving state before shifting the transmission to the target driving state.

A method is provided for alternately triggering driving states of a utility vehicle. The method includes providing a control element and a transmission selectively engageable in a forward driving state (F) for forward travel of the utility vehicle, a reverse driving state (R) for reverse travel, and a standstill driving state (S) for a stationary output of the transmission without disconnection of the drivetrain in the utility vehicle. The method further includes operating the transmission in a current driving state, operably selecting a target driving state while operating in the current driving state, and controllably triggering the transmission to the standstill driving state before shifting the transmission to the target driving state.