This disclosure includes an expansion driver for adjusting expandable implants, the expansion driver including: a first driver having a first gear disposed at a first end thereof; and a second driver having a second gear disposed at a first end of the second driver; and a handle operably connected to the first driver and the second driver, the handle having at least one bevel gear rotatably attached thereto, the at least one bevel gear engaging each of the first gear and the second gear; wherein upon a rotation of the handle a torque is applied to at least one of the first driver or the second driver.

A transmission may include an input shaft, a first output shaft, a second output shaft, a first planetary gearset, and a second planetary gearset connected to the first planetary gearset. The input shaft, the first and second output shafts, and the planetary gearsets may be arranged such that a torque input via the input shaft is converted and distributed in a defined ratio to the two output shafts, and the formation of a combined torque is prevented. At least one element of the first planetary gearset may be connected to at least one element of the second planetary gearset with a shaft for conjoint rotation, and at least one element of the second planetary gearset may be fixed in place on a non-rotating component. A connector may be arranged and configured to passively, and therefore without a control unit and without an actuator, connect the first output shaft and second output shaft.

A differential locking mechanism including a differential mechanism and a locking mechanism. The differential mechanism includes a driven gear, a shell, two half shafts, two half-shaft gears and a planetary gear set, planetary gear shafts. The locking mechanism includes a sleeve, a third gear, a toothed sleeve, a shifting fork and a fixing piece. An end of the first planetary gear shaft, facing outside of the shell, is fixedly provided with the third gear. An end of the shell is fixedly provided with the sleeve; a side of the sleeve close to the shell is sleeved with a fourth gear rotationally connected with the sleeve; one end of the fourth gear is fixedly provided with a fifth gear rotationally connected with the sleeve; a side of the sleeve away from the shell is provided with a longitudinal tooth groove; the toothed sleeve is sleeved on the sleeve.

The present invention relates to a planetary gear device having four or more shafts. The planetary gear device according to the present invention may be expanded by adding another planetary gear device to the planetary gear device in the related art, all shafts of the planetary gear device are exposed to the outside such that a brake may be easily installed, and the shafts may be divided into two groups and separated. The planetary gear device according to the present invention may be used for an apparatus for connecting, braking, and separating an automatic transmission, a plurality of power supplying shafts, and a plurality of power receiving shafts and used to integrate two apparatuses.

A vehicle drive device is provided that can suppress the increase in dimension in the radial direction while ensuring a sufficient speed reduction ratio. Two driving force sources are arranged on a first axis, two output members are arranged on a second axis, two counter gear mechanisms are arranged on a third axis. A planetary gear mechanism is configured to transmit rotation from the two counter gear mechanisms to the output members, and is disposed so as to overlap with both of the two counter gear mechanisms as seen in an axial direction along and axial direction.

A vehicular differential device includes a differential rotation mechanism, and a torque input member that receives drive torque, the drive torque is distributed and transmitted to a first drive shaft and a second drive shaft. The differential rotation mechanism includes an input gear that rotates as a unit with the torque input member, an output gear that rotates as a unit with the first drive shaft, a first gear and a second gear that rotate as a unit, and a carrier that supports the first gear and the second gear, the carrier being configured to rotate as a unit with the second drive shaft. The gear ratio between the input gear and the first gear is different from that between the output gear and the second gear. During differential rotation, the first drive shaft and the second drive shaft are rotated in opposite directions.

Methods and systems are provided for integrating a gearbox into an electric motor. In one example, a system may include enclosing a gearbox containing a planetary gear set and a differential within an envelope of a rotor of the electric motor.

A drive apparatus for an electric-motor four-wheel drive vehicle includes first and second motors, first and second differential mechanisms, and a propeller shaft. The vehicle includes a first wheel pair including first left and right wheels and a second wheel pair including second left and right wheels and positioned on opposite side to the first wheel pair in a front-rear direction. The first and second motors are configured to output first output torque and second output torque, respectively. The first differential mechanism is configured to distribute the first output torque to a first torque-transmitting member coupled to the first left wheel and a third torque-transmitting member coupled to the propeller shaft. The second differential mechanism is configured to distribute the second output torque to the third torque-transmitting member and a second torque-transmitting member coupled to the first right wheel.

A power transmission mechanism including a planetary mechanism, an electronically controlled clutch, and a motor generator. The planetary mechanism is coupled to an input shaft and first and second output shafts. The planetary mechanism includes a differential element rotating the first and second output shafts at different rotation speeds. The planetary mechanism outputs a torque input to the first and second output shafts. The electronically controlled clutch includes first and second clutch plates. The first clutch plate is coupled to a member different from the differential element. The second clutch plate is coupled to the differential element. The electronically controlled clutch allows the differential element to rotate the first and second output shafts at the different rotation speeds when the first and second clutch plates are released. The electronically controlled clutch restricts a rotation speed difference in response to engaging between the first and second clutch plates.

A differential locking mechanism including a differential mechanism and a locking mechanism. The differential mechanism includes a driven gear, a shell, two half shafts, two half-shaft gears and a planetary gear set, planetary gear shafts. The locking mechanism includes a sleeve, a third gear, a toothed sleeve, a shifting fork and a fixing piece. An end of the fast planetary gear shaft, facing outside of the shell, is fixedly provided with the third gear. An end of the shell is fixedly provided with the sleeve; a side of the sleeve close to the hell is sleeved with a fourth gear rotationally connected with the sleeve; one end of the fourth gear is fixedly provided with a fifth gear rotationally connected with the sleeve; a side of the sleeve away from the shell is provided with a longitudinal tooth groove; the toothed sleeve is sleeved on the sleeve.