A shiftable shaft connector that has a sliding sleeve that can be displaced axially between an engaged position and a disengaged position, a shifting gear (6) with a shifting contour (11) that is connected in an axially fixed manner to the sliding sleeve and can rotate in relation thereto, at least one support element corresponding to the shifting contour (11), and an actuator for rotating the shifting gear (6), in which the shifting contour (11) has a release stop (14) assigned to the disengaged position, and an engagement selection stop (15) and an engagement stop (16) assigned to the engaged position, a method for shifting such a shaft connector, wherein the shifting gear (6) is rotated in a releasing direction in order to displace the sliding sleeve into the disengaged position, until the at least one support element reaches the release stop (14) of the shifting contour (11), and is rotated in an engagement direction in order to displace the sliding sleeve into the engaged position of the shifting gear (6), until the at least one support element reaches the engagement selection stop (15) of the shifting contour (11), and a vehicle transmission that has a drive shaft and an output shaft, wherein the vehicle transmission has a shaft connector of the type described above, that acts between the drive shaft and the output shaft.

A power transmission apparatus includes a first meshing engagement mechanism that selectively couples a first rotational section and a second rotational section; and a second meshing engagement mechanism that selectively couples a third rotational section and a fourth rotational section. The first meshing engagement mechanism includes a first movable member provided with third meshing teeth that mesh with first meshing teeth provided on one of the first and the second rotational sections. The second meshing engagement mechanism includes a second movable member provided with fourth meshing teeth that mesh with second meshing teeth provided on one of the third and the fourth rotational sections. At least a portion of a first movable region of the third meshing teeth and at least a portion of a second movable region of the fourth meshing teeth overlap with each other in a radial direction with respect to a rotational axis.

A drivetrain assembly having a shift mechanism. The shift mechanism may include a shift rail, a first shift assembly, a second shift assembly, and a sector cam. The shift rail may be fixedly disposed on a housing. The sector cam may control movement of the first shift assembly and the second shift assembly.

A multi-speed transmission includes a shaft member, an idler gear connected to the shaft member, an intermediate lever having a first movement and a second movement, the intermediate lever selectively engaging with the shaft member during the first movement and remaining engaged with the shaft member during the second movement, and a synchronizer assembly that is selectively engaged by the intermediate lever during the first movement of the intermediate lever, the synchronizer assembly remaining engaged during an initial stage of the second movement of the intermediate lever and becoming unengaged during a final stage of the second movement of the intermediate lever, the idler gear being fully engaged to achieve a reverse gear ratio during the final stage of the second movement of the intermediate lever.

In a vehicle drive transmission device, a transmission includes an intermesh first engagement device, a frictional second engagement device, a first drive device configured to drive the first engagement device, and a second drive device configured to drive the second engagement device. The first drive device includes a first shift drum, a first cam mechanism configured to convert rotational motion of the first shift drum into linear motion, and a first transmission mechanism configured to perform the linear motion. The second drive device includes a second shift drum, a second cam mechanism configured to convert rotational motion of the second shift drum into linear motion, and a second transmission mechanism configured to perform the linear motion. The first shift drum and the second shift drum are connected so as to rotate integrally with each other via a drive shaft. A drum drive source is provided to drive the drive shaft.

A vehicle powertrain hydraulic system (10) includes a clutch (12), a piston (62) disposed in a cylinder (60) to drive a shift selector (14), a pump (82) in fluid communication with a fluid supply (86) to pressurize fluid, and first and second fluid pressure lines (91, 92) from the pump to first and second sides of the piston. A third fluid pressure line (93) may extend to the clutch from the cylinder in a location between the first and second sides of the piston, such that the piston also may be a valve to control fluid flow to the clutch. The pump may be reversible and coupled to an electric motor (80), and a centrifugal regulator (84) may be coupled to the motor and in fluid communication with the first and second pump pressure lines to regulate fluid pressure therein. A related operational method is also disclosed.

An apparatus for axially adjusting a shifting element includes a shifting shaft, which can be rotated about an axis, an actuating body, which is connected to the shifting shaft for conjoint rotation and in an axially movable manner and which has at least two slotted guide sections designed as grooves on a peripheral surface, and a linear actuator, which is associated with the actuating body and has an actuatable actuator pin, which can engage in the slotted guide sections in order to axially move the actuating body. Each slotted guide section has an incoupling region for the actuator pin, an opposite outcoupling region for the actuator pin, and an adjusting region, which lies therebetween in the peripheral direction and is bent in a curved shape, for axially moving the actuating body. The incoupling region and the outcoupling region of the slotted guide sections that are adjacent in the peripheral direction are arranged at the same axial position.

A forkless synchronizer arrangement selectively couples one or more gears to a drive shaft that is rotatable about a rotation axis. A shift collar, rotated by the drive shaft, is configured to disengage from a first of the gears when in a first neutral axial position and to engage the first gear when in a first engaged axial position to transmit rotational input from the drive shaft to the first gear. A rail is arranged in parallel with the rotation axis. A rail arm has an end fixedly coupled to the rail and another end coupled to the shift collar to permit relative rotation and to transmit axial shifting movement to the rail in response to axial movement of the shift collar between the first engaged and neutral axial positions. A sensor proximate the rail senses an axial position of the rail.

A motor vehicle has an electric drive machine for driving the motor vehicle and a coupling mechanism which can be switched at least between a coupling position, in which the electric drive machine is coupled to a drive wheel so as to transmit torque, and a decoupling position in which the electric drive machine is decoupled from the drive wheel. A parking lock device has at least one parking lock element that can be moved between a parking lock position, in which the at least one parking lock element at least indirectly blocks a rotation of the drive wheel, and an unlocking position in which the at least one parking lock element releases the rotation of the drive wheel. An actuation device with an actuator is designed to actuate a clutch of the coupling mechanism, which clutch has at least one switching element and is used to switch between the coupling position and the decoupling position, and is designed to move the at least one parking lock element between the parking lock position and the unlocking position. The switching element has a retaining region preventing the parking lock element from moving into the parking lock position as long as the lock has not been adjusted to the coupling position.

A vehicle transfer includes an input shaft, an output shaft, an output member, a clutch, a motor, a screw mechanism, a transmitting mechanism, a fork shaft, an amplifying link mechanism, a high-low switching mechanism, and a fork. The fork shaft is configured to move in an axial direction of the fork shaft. The amplifying link mechanism is connected to the nut member and the fork shaft. The amplifying link mechanism is configured to amplify an amount of movement of the nut member in the direction of the common axis and transmit the amplified amount of movement to the fork shaft. The fork is connected to the fork shaft. The fork is configured to transmit moving force of the fork shaft to the high-low switching mechanism such that the high-low switching mechanism switches between the high-speed gear and the low-speed gear.