A shifting device (1) for the powertrain of a motor vehicle, including a control shaft (10) for adjusting a control element (9), the control shaft (10) has a first sub-section (15) which can be driven by an actuator (36) and a second sub-section (16) which is designed to adjust the control element (9). The first sub-section (15) is rotatably mounted relative to the second sub-section (16). A spring element (11), via which a torque of the first sub-section (15) can be transmitted to the second sub-section (16), is provided between the two sub-sections (15, 16).

A driving system includes an electric motor, a transmission apparatus, a differential apparatus and a brake. The differential apparatus includes an input portion coupled to an output portion of the transmission apparatus, a pair of output portions, and a differential device that allows differential rotation of the pair of output portions. A brake is provided in a drive path from an output portion of the electric motor to the input portion of the differential apparatus. The differential apparatus includes a clutch member movable between a first position in which a differential rotation of the differential device is allowed and a second position in which the differential rotation of the differential device is stopped, a clutch actuator that moves the clutch member to the first position, and a holding portion that holds the clutch member to the second position when the clutch actuator is in a non-operating state.

A transmission configured to change a speed of rotation transmitted from a rotary electric machine side includes a first gear and a second gear disposed on a first axis, and a third gear, a fourth gear, and an output gear disposed on second axis parallel to first axis. The first gear and the third gear mesh with each other, and second gear and the fourth gear mesh with each other. A differential gear mechanism includes a differential input gear disposed on a third axis parallel to the first axis and the second axis and meshing with the output gear. The first gear and the second gear are disposed on a first axial side with respect to a rotor of the rotary electric machine. The parking gear is disposed on the second axis on a second axial side with respect to the third gear, the fourth gear, and the output gear.

In the lid opening and closing device, the rotating body at the initial position rotates to one side in the rotation direction, so that the lock member is disengaged from the first link. Further, the first link and the rotating body are provided with a differential connecting mechanism, and the differential connecting mechanism connects the rotating body and the first link to operate the link mechanism at the retracted position after the lock member is disengaged from the first link, when the rotating body is rotating. As a result, the differential connecting mechanism imparts a time difference between the two operations of the rotating body. Therefore, the lock member and the link mechanism can be operated by rotationally driving the rotating body by a single actuator.

An assembly for the selective coupling of two coaxially arranged shafts, comprising a first shaft and a second shaft arranged coaxially, a selector unit for selectively coupling the first shaft to the second shaft and including an electric motor, a selector fork, and a sliding sleeve connected to the selector fork to allow an adjusting action. The first shaft has a first external tooth system, at least in some section or sections, and the second shaft has a second external tooth system, at least in some section or sections. The first external tooth system is in engagement with an internal tooth system of the sliding sleeve and the second external tooth system can be brought into engagement with the internal tooth system of the sliding sleeve. A first tooth system formed on an output shaft of the electric motor is in engagement with a second tooth system of a gear segment, wherein the gear segment is arranged in a fixed manner on the selector fork. The first tooth system and the second tooth system are each designed as a spur gear tooth system.

A transfer (13) that changes a distribution ratio of torque to be transmitted to a wheel using an electric motor (43), is controlled by a TF-ECU (18). The TF-ECU (18) includes a driver circuit (200) that drives the electric motor (43), a current sensor (53) that detects an actual current of the electric motor (43), and a microcomputer (100) that calculates a target current (I*) corresponding to a desired distribution ratio of torque and performs current feedback control for calculating an operation amount (D) of the electric motor (43) so as to adjust an actual current (Ia) to the target current (I*), and then outputs to the driver circuit (200) a drive signal corresponding to the operation amount (D).

An assembly for a vehicle comprising a mechanism for adjusting the angular position of a vehicle pedal includes a motor for generating and transmitting rotary motion to a rotating member, a first pedal assembly having a first support frame with a first slotted hole, rotatably supported on a first fulcrum and supporting a first pedal, a first motion conversion mechanism, having a first rotating member rotatable about a first rotation axis and a first translating member, receiving and converting rotational motion into translational motion, and a first pin, for joint translation with the first translating member and sliding inside the first slotted hole. Sliding of the first pin draws the first support frame in rotation about the first fulcrum between a first and a second angular position. The mechanism includes a second pedal assembly. The first rotating member is connected to the motor to receive rotary motion. A second rotating member of a second motion conversion mechanism is connected in rotation to the first rotating member through a flexible transmission.

An electric powertrain includes a first electric motor that has an uninterrupted connection with a drive shaft of a vehicle. The electric powertrain further includes a second electric motor that has an interruptible connection with the drive shaft. In one form, this interruptible connection includes a clutch. The electric powertrain further includes a first gear train in the form of a first planetary gear and a second gear train in the form of a second planetary gear. The clutch in one variation includes a positive clutch in the form of a dog clutch. The dog clutch has a clutch suspension configured to deflect a clutch collar when gearing is misaligned during shifting.

A structural component made of a plastics material for a skin of a body of a motor vehicle has a separating line that separates the structural component into an inner region and an outer region. The inner region has three-dimensional regions having reduced material thickness for defined pivotability with a reduced force requirement. The design means that a significantly lower force requirement is needed for opening or closing the inner region.

A transfer (13) that changes a distribution ratio of torque to be transmitted to a wheel using an electric motor (43), is controlled by a TF-ECU (18). The TF-ECU (18) includes a driver circuit (200) that drives the electric motor (43), a current sensor (53) that detects an actual current of the electric motor (43), and a microcomputer (100) that calculates a target current (I*) corresponding to a desired distribution ratio of torque and performs current feedback control for calculating an operation amount (D) of the electric motor (43) so as to adjust an actual current (Ia) to the target current (I*), and then outputs to the driver circuit (200) a drive signal corresponding to the operation amount (D).