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.

The subject disclosure relates to a coil module assembly for a bi-directional clutch assembly having at least one active clutch. The coil module assembly includes a housing having an actuator housing portion and a PCB housing portion. An electromagnetic actuator is disposed in the actuator housing portion for effectuating pivotal movement of the active strut from an unlocked position to a locked position in response to an energization of the electromagnetic actuator. An integrated printed circuit board (PCB) is disposed in the PCB housing portion and is in electrical communication with the electromagnetic actuator for selectively energizing the electromagnetic actuator. The housing further includes a thermally decoupled housing portion which is disposed between the actuator housing portion and the PCB housing portion for thermally decoupling, i.e., reducing heat transfer, from the electromagnetic actuator to the PCB during selective energization of the electromagnetic actuator.

An overrunning, non-friction coupling and control assembly, an engageable coupling assembly and locking members for use in the assemblies are provided. A centroid or center of mass of at least one of the locking members is substantially centered on a pivot axis of the locking member so that the locking member is substantially centrifugally neutral or balanced thereby making the locking member easier to pivot between engaged and disengaged positions with respect to the coupling members of its corresponding assembly at high rotational speeds.

A multi-step transmission for a motor vehicle comprises an input shaft, an output shaft, a first transmission stage and a second transmission stage, a clutch which can be transferred into three clutch positions to drivingly connect the input shaft and the output shaft with each other or disconnect them from each other; and an actuating assembly with a setting element that is movable in three setting positions and is connected to a movable clutch part of the clutch, wherein the actuating assembly comprises first and second electromagnetically operable actuators which can be operated independently from one another and which jointly act on the setting element such that the setting element can be transferred by the first and the second actuator into the three setting positions. An electric drive can have such a multi-step transmission.

Two-speed transmission apparatus for electric vehicle comprises a planetary gear mechanism 16, friction brake 28 and friction clutch 26 in coaxial arrangement between input axis 10 and output axis 12, first speed is obtained by fastening the friction brake 28 and one-on-one second speed is obtained by fastening friction clutch 26. The electric actuator 30 to switch first speed and second speed comprises electric motor 32, a torque-thrust converting mechanism 36 and pusher 34. The torque-thrust converting mechanism 36 comprises inside cylindrical screw 40 being rotated by control motor 32 and outside cylindrical nut 42 which is screwed with cylindrical screw 40 and is connected to pusher 34 so as to integrally axis-move. The control motor 32 may include an electromagnetic brake to fasten the friction brake 28 and the friction clutch 26. Thrust of the axial direction may be transmitted by the swing of an arm 316.

A magnetic actuator includes a first element and a second element movable with respect to the first element in a movement direction. The first element includes teeth successively in the movement direction, two coils in slots defined by the teeth, and a permanent magnet. The second element includes teeth successively in the movement direction. The teeth of the first and second elements and the permanent magnet are arranged so that the second element is held by magnetic forces in each of three positions also when there are no currents in the coils. The second element can be moved between the three positions by supplying electric currents to the coils. Thus, the second element is held in any of the three positions also when current supply to the magnetic actuator is unintentionally lost.

An overrunning, non-friction coupling and control assembly, an engageable coupling assembly and locking members for use in the assemblies are provided. A centroid or center of mass of at least one of the locking members is offset from a pivot axis of the locking member so that as the locking member moves from an engaged position, a moment arm of the centroid relative to the pivot axis decreases from a maximum value to substantially zero in a disengaged position to facilitate disengagement of the locking member at high rotational speeds.

The device embodied in the present invention utilizes the lateral rotation produced by a motor, which may be an internal combustion engine or an electrical motor. The lateral rotation is outputted directed unto the main crankshaft of an engine. A main pulley is mounted onto said main shaft and rotates with the same revolution rate as the motor, or at a reduced revolution rate, depending on the diameter of the main pulley and whether additional steps and hears are utilized to reduce or step down the rotary forces.

A multi-step transmission for a motor vehicle comprises an input shaft, an output shaft, a first transmission stage and a second transmission stage, a clutch which can be transferred into three clutch positions to drivingly connect the input shaft and the output shaft with each other or disconnect them from each other; and an actuating assembly with a setting element that is movable in three setting positions and is connected to a movable clutch part of the clutch, wherein the actuating assembly comprises first and second electromagnetically operable actuators which can be operated independently from one another and which jointly act on the setting element such that the setting element can be transferred by the first and the second actuator into the three setting positions. An electric drive can have such a multi-step transmission.

A gearshift for an electric drive includes a housing having a depressed portion with an opening through which a movable component is led. Further, the gearshift for the electric drive includes at least one moving magnet actuator. The at least one moving magnet actuator is configured to move the component and mounted in the depressed portion.