An anti-theft device for a vehicle includes an approach prevention cover disposed in a shift lever housing to cover a shift cable connected to a shift lever so as to prevent the shift cable from being detached. Such an anti-theft vehicle makes is possible to easily and efficiently prevent theft of the vehicle by preventing a shift cable operated along with operation of a shift lever from being removed.

An anti-theft device for a vehicle includes an approach prevention cover disposed in a shift lever housing to cover a shift cable connected to a shift lever so as to prevent the shift cable from being detached. Such an anti-theft vehicle makes is possible to easily and efficiently prevent theft of the vehicle by preventing a shift cable operated along with operation of a shift lever from being removed.

A shift device for a vehicle includes a baseplate, a shift lever having a spherical shaft part at a lower end, and a control lever connected to the shift lever. The spherical shaft part of the shift lever is supported by the baseplate and configured to turn relative to the baseplate. A cable coupling part is provided at an upper part of the control lever. A turning shaft part supported by the baseplate is provided at a lower part of the control lever outward of the spherical shaft part of the shift lever in a vehicle width direction, and the turning shaft part is configured to turn relative to the baseplate. The control lever has a branched part between the cable coupling part and the turning shaft parts, and the branched part is located above the spherical shaft part and branched in the vehicle width direction.

A shift mechanism of an outboard motor has an electric actuator having a movable rod, and a guide structure for guiding a linear motion of a sliding body connected to the movable rod. In addition, the shift mechanism includes a link rod connected to the sliding body and bent to extend in a direction different from the direction of the linear motion of the sliding body. Furthermore, the shift mechanism includes a shift shaft part which is connected to the link rod, performs a rotational motion on the basis of a displacement of the link rod, and switches a range of a transmission mechanism provided below on the basis of the rotational motion.

A shift mechanism of an outboard motor has an electric actuator having a movable rod, and a guide structure for guiding a linear motion of a sliding body connected to the movable rod. In addition, the shift mechanism includes a link rod connected to the sliding body and bent to extend in a direction different from the direction of the linear motion of the sliding body. Furthermore, the shift mechanism includes a shift shaft part which is connected to the link rod, performs a rotational motion on the basis of a displacement of the link rod, and switches a range of a transmission mechanism provided below on the basis of the rotational motion.

A differential carrier case with an inserted pipe for high pressure casting may include a mold core into which a first end of a pipe is inserted, a mold core pin fixed to the mold core to fix the mold core and the first end of the pipe, a drive core pin inserted into a second end of the pipe, and a thick portion surrounding an outer portion of the pipe.

A device for detecting the position of a lever includes a member being connected on at least one of its ends to a cable end piece that is fitted sliding into a fixed sheath end piece. The device comprises a magnet fitted inside a pipe that constitutes the cable end piece and a Hall Effect Sensor positioned on one part of the sheath end piece in order to detect the movement between the cable end piece and the sheath end piece, which corresponds to a movement of the lever.

A device for detecting the position of a lever includes a member being connected on at least one of its ends to a cable end piece that is fitted sliding into a fixed sheath end piece. The device comprises a magnet fitted inside a pipe that constitutes the cable end piece and a Hall Effect Sensor positioned on one part of the sheath end piece in order to detect the movement between the cable end piece and the sheath end piece, which corresponds to a movement of the lever.

A gear shifter assembly for a vehicle is described herein. The gear shifter assembly includes a base to be fixed in a vehicle, a shifter yoke mounted to the base by a main pivot shaft, a shift lever mounted to the shifter yoke by a pivotal bearing arranged to allow pivotal movements about a second pivotal axis perpendicular to the first pivotal axis, and an intermediate joint that provides the pivotal bearing of the shift lever. The intermediate joint is attached to the lower end of the shift lever by receiving select pivot pins projecting from the shift lever in recesses of the intermediate joint. The intermediate joint comprises opposite through holes aligned with an aperture in the shift lever for receiving the main pivot shaft. The intermediate joint is made of material having a lower modulus of elasticity than the materials of the shift lever and the shifter yoke.

A gear shifter assembly for a vehicle is described herein. The gear shifter assembly includes a base to be fixed in a vehicle, a shifter yoke mounted to the base by a main pivot shaft, a shift lever mounted to the shifter yoke by a pivotal bearing arranged to allow pivotal movements about a second pivotal axis perpendicular to the first pivotal axis, and an intermediate joint that provides the pivotal bearing of the shift lever. The intermediate joint is attached to the lower end of the shift lever by receiving select pivot pins projecting from the shift lever in recesses of the intermediate joint. The intermediate joint comprises opposite through holes aligned with an aperture in the shift lever for receiving the main pivot shaft. The intermediate joint is made of material having a lower modulus of elasticity than the materials of the shift lever and the shifter yoke.