In a shift device, when a lock lever is disposed at a restriction position or an intermediate position, a detent groove of a lever is abutted by the lock lever, and pivoting of the lever from a D position toward an S position, and pivoting of the lever from the S position toward the D position, is restricted. However, when the lever is disposed at the D position or the S position, by moving the lock lever to a permitted position, the detent groove does not abut the lock lever and so pivoting of the lever from the D position toward the S position and pivoting of the lever from the S position toward the D position is permitted. Thus, pivoting of the lever from the D position toward the S position and pivoting of the lever from the S position toward the D position can be restricted and permitted.

In a shift device, when a lock lever is disposed at a restriction position or an intermediate position, a detent groove of a lever is abutted by the lock lever, and pivoting of the lever from a D position toward an S position, and pivoting of the lever from the S position toward the D position, is restricted. However, when the lever is disposed at the D position or the S position, by moving the lock lever to a permitted position, the detent groove does not abut the lock lever and so pivoting of the lever from the D position toward the S position and pivoting of the lever from the S position toward the D position is permitted. Thus, pivoting of the lever from the D position toward the S position and pivoting of the lever from the S position toward the D position can be restricted and permitted.

A shifter assembly for a vehicle includes: a body; a shift lock; and a shift lock lever that is supported by the body such that the shift lock lever is movable between a first position and a second position to cause corresponding movement of the shift lock between a locked position, in which the vehicle is immovable, and an unlocked position, in which the vehicle is movable. The shift lock lever includes a first end portion, and an opposite second end portion that is configured for contact with the shift lock. The second end portion is generally L-shaped in configuration, and defines an interior region that is configured to receive the shift lock to inhibit (if not entirely prevent) contact between the shift lock and other components of the vehicle to reduce any likelihood of inadvertent disengagement of the shift lock and unintended movement of the vehicle.

A shifter assembly for a vehicle includes: a body; a shift lock; and a shift lock lever that is supported by the body such that the shift lock lever is movable between a first position and a second position to cause corresponding movement of the shift lock between a locked position, in which the vehicle is immovable, and an unlocked position, in which the vehicle is movable. The shift lock lever includes a first end portion, and an opposite second end portion that is configured for contact with the shift lock. The second end portion is generally L-shaped in configuration, and defines an interior region that is configured to receive the shift lock to inhibit (if not entirely prevent) contact between the shift lock and other components of the vehicle to reduce any likelihood of inadvertent disengagement of the shift lock and unintended movement of the vehicle.

A transmission lever device for an automobile includes: a base: a lever rotatably mounted on the base, wherein the lever is configured to select one of sequentially disposed gear positions including park (P), reverse (R), neutral (N), drive (D), and low (L) by a linear movement and to be movable from P to L and from L to P; and a blocker mounted on the base and configured to restrict and wide movement of the lever from P to L.

A transmission lever device for an automobile includes: a base: a lever rotatably mounted on the base, wherein the lever is configured to select one of sequentially disposed gear positions including park (P), reverse (R), neutral (N), drive (D), and low (L) by a linear movement and to be movable from P to L and from L to P; and a blocker mounted on the base and configured to restrict and wide movement of the lever from P to L.

Methods and systems for seamlessly transitioning a load between two different actuators each having a different transmission ratio are described herein. A multiple drive, variable transmission ratio (MD-VTR) system includes two drive actuators, each having different reduction ratios, a locking mechanism, and a differential transmission subsystem. In one aspect, a MD-VTR system includes a locking mechanism disposed between a drive actuator and an input port of the differential. The locking mechanism couples the input port of the differential to a stationary reference frame element in a locked state. In an unlocked state, the locking mechanism couples the drive actuator to the input port of the differential. In some embodiments, the locking mechanism includes an actuator to actively transition between the locked and unlocked states. In some other embodiments, the locking mechanism transitions between the locked and unlocked states based on torque applied by the drive actuator.

Methods and systems for seamlessly transitioning a load between two different actuators each having a different transmission ratio are described herein. A multiple drive, variable transmission ratio (MD-VTR) system includes two drive actuators, each having different reduction ratios, a locking mechanism, and a differential transmission subsystem. In one aspect, a MD-VTR system includes a locking mechanism disposed between a drive actuator and an input port of the differential. The locking mechanism couples the input port of the differential to a stationary reference frame element in a locked state. In an unlocked state, the locking mechanism couples the drive actuator to the input port of the differential. In some embodiments, the locking mechanism includes an actuator to actively transition between the locked and unlocked states. In some other embodiments, the locking mechanism transitions between the locked and unlocked states based on torque applied by the drive actuator.

An automotive transmission capable of preventing a lever from unintentionally rotating from one position to another position is provided. The automotive transmission includes a lever assembly including a lever which rotates between a plurality of positions about a rotational axis thereof to select one of a plurality of gear stages; a plurality of locking parts rotating integrally with the lever and disposed at different locations in a direction of the rotational axis of the lever to be spaced apart by a predetermined distance in a direction of rotation of the lever and thus to block the rotation of the lever in at least one direction about the rotational axis of the lever; and a moving part moving in the direction of the rotational axis of the lever to allow one side thereof to be placed on at least one of paths of rotation of the plurality of locking parts.

An automotive transmission capable of preventing a lever from unintentionally rotating from one position to another position is provided. The automotive transmission includes a lever assembly including a lever which rotates between a plurality of positions about a rotational axis thereof to select one of a plurality of gear stages; a plurality of locking parts rotating integrally with the lever and disposed at different locations in a direction of the rotational axis of the lever to be spaced apart by a predetermined distance in a direction of rotation of the lever and thus to block the rotation of the lever in at least one direction about the rotational axis of the lever; and a moving part moving in the direction of the rotational axis of the lever to allow one side thereof to be placed on at least one of paths of rotation of the plurality of locking parts.