An electronic shift system for an automated manual transmission includes a shift lever moveable between at least a neutral position and a first gear position, a clutch pedal, a biasing member connected to the shift lever that biases the shift lever to the neutral position, and a grip system configured to selectively immobilize the shift lever in the first gear position when the clutch pedal is released. An electrical circuit communicates a position of the shift lever to a control module. The control module commands the automated manual transmission to achieve the gear ratio (forward or reverse) corresponding to the first gear position when the shift lever is in the first gear position.

A reset device for a gearshift lever for a gear step of a transmission in a motor vehicle comprises an electric drive device for controlling an operating element, in order to move the gearshift lever into a predetermined position, a position sensor for determining a position of the operating element, and an electric activation device for activating the drive device, depending on the position of the operating element. The position sensor comprises a first coil thereby, which is attached to the activation device, and a magnetic flux element is mechanically coupled to the operating element. The drive device is disposed in relation to the activation device, such that the flux element influences the inductivity of the first coil, depending on a position of the operating element.

A selector includes a lever guide, an operating lever, and a stopper. The lever guide has first and second movable-path slits therein. The first movable-path slit extends from a first position to a second position along a first direction. The second movable-path slit extends along a second direction different from the first direction as to intersect the first movable-path slit at an intersection position. The second movable-path includes a third position. The operating lever is movable in along the first and second movable-path slits. The operating lever is configured to move to the first position through the first and second movable-path slits. The stopper slides and contacts the operating lever when the operating lever moves from the third position to the first position. The stopper slides and contacts the operating lever when the operating lever moves from the first position to the third position. The stopper opens and closes an opening-and-closing target path out of the first movable-path slit between the second position and the intersection position in conjunction with a movement of the operating lever.

When a shift lever is moved to a shift position corresponding to a first gear position etc., the shift lever is urged by its own weight to a neutral position, which is disadvantageous for the shift lever in terms of gear slip-out after shifting. However, a counter mass is moved to a position reached by turning a second predetermined angle, larger than a first predetermined angle corresponding to the neutral position, downward with respect to a vertical line passing through a center of turn of the counter mass. Meanwhile, the shift lever is urged by the weight of the counter mass in the direction away from the neutral position, so that gear slip-out after shifting can be prevented.

The present disclosure relates to a shift device for a control system for a vehicle. The shift device may include at least one optical fiber for conducting a light signal, where the light signal has an input characteristic when entering the shift device, and where the light signal has an output characteristic when exiting the shift device. The shift device may further include a control element, where the control element can be moved between a home position, a first actuation position, and a second actuation position by an actuation force. The control element may have an adjustment device for adjusting the characteristic of the light signal, where the adjustment device is configured to set the output characteristic of the light signal to a first value when the control element is in the home position.

A vehicular shift apparatus includes an operation member configured to be put in five shift positions including a home position, a drive position, a reverse position, a drive-side neutral position, and a reverse-side neutral position. Nine sensing elements are provided to sense a magnet moved by movement of the operation member. The home position is allocated with three sensing elements, and each of the remaining four shift positions is allocated with two sensing elements, wherein two of the sensing elements allocate to the home position are shared by other two of the shift positions. The five shift positions and four intermediate positions between respective two adjacent shift positions are determined, based on combination of outputs of the nine sensing elements.

A shift lever is movable from a home position in a left or rear direction. A reverse mode selection position is set in a route extending in the left direction from the home position. A drive mode selection position is set in a route extending in the rear direction from the home position.

In a shift device, when a switch is operated, a moving portion, a first lock plate, a second lock plate and a third lock plate are moved toward a vehicle front side, and placement of the first lock plate, the second lock plate and the third lock plate at a return path is cancelled. Therefore, if the switch is operated when a lever is placed at other than a “P” position, due to a guide pin being moved along the return path toward an upper side by urging force of a return spring, the guide pin is returned to a vehicle front side end of a first lateral path, and the lever is returned to the “P” position. Due thereto, the lever can easily return to the “P” position from other than the “P” position.

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.

The invention pertains to a force transmitting device (100) for a transmission (200), particularly of a motorcycle, with a shift assist system, featuring a shift input shaft (30) with a shift lever connection (20) for receiving a shifting motion of a shift lever (300) and a transmission connection (40) for transmitting the shifting motion to a gear shifting gate (110) of the transmission (100), wherein the shift input shaft (30) features an energy accumulator (32) for the intermediate storage of at least part of the shifting force such that the relative motion between the shift lever connection (20) and the transmission connection (40) can be realized by changing the shifting force stored in the energy accumulator (32), and wherein the shift input shaft (30) features a sensor device (60) for detecting the relative motion between the shift lever connection (20) and the transmission connection (40).