An all-wheel-drive vehicle includes a primary axle operably coupled to an engine and a secondary axle having an input operably coupled to the engine a first halfshaft, a second halfshaft, a first clutch selectively connecting the first halfshaft to the input, and a second clutch selectively connecting the second halfshaft to the input. A transmission has an input coupled to the engine and output coupled to the primary drive axle. A driveshaft couples a power-transfer unit and the input, and a third clutch selectively couples the output to the driveshaft. A controller is programmed to, during a power-limiting routine, command a torque to the engine based on closed-loop feedback control such that the torque decreases when a calculated slip of a selected one of the first and second clutches is greater than a target slip of the selected clutch and increases when the calculated slip is less than the target slip.

An all-wheel-drive vehicle includes a primary axle operably coupled to an engine and a secondary axle having an input operably coupled to the engine a first halfshaft, a second halfshaft, a first clutch selectively connecting the first halfshaft to the input, and a second clutch selectively connecting the second halfshaft to the input. A transmission has an input coupled to the engine and output coupled to the primary drive axle. A driveshaft couples a power-transfer unit and the input, and a third clutch selectively couples the output to the driveshaft. A controller is programmed to, during a power-limiting routine, command a torque to the engine based on closed-loop feedback control such that the torque decreases when a calculated slip of a selected one of the first and second clutches is greater than a target slip of the selected clutch and increases when the calculated slip is less than the target slip.

A vehicle drive device includes: an electric motor; a multi-plate clutch including a plurality of clutch plates; a pressing mechanism configured to press the multi-plate clutch; an output rotary member to which a drive force of the electric motor is transferred through the multi-plate clutch; and a control device configured to control the electric motor and the pressing mechanism. The control device is configured to control the pressing mechanism using information on the result of test operation performed while the vehicle is stationary.

A vehicle includes a first axle, a second axle, a driveshaft, a first clutch, a second clutch, a third clutch, and a controller. The second axle has first and second half shafts. The second axle has first and second wheels. The driveshaft is disposed between the first and second axles and is coupled to the second axle. The first clutch is configured to selectively couple the driveshaft to the first axle. The second clutch is configured to selectively couple the first wheel to the first half shaft. The third clutch is configured to selectively couple the second wheel to the second half shaft. The controller is programmed to control the clutches to connect the second axle to the first axle via the driveshaft.

A vehicle includes a first axle, a second axle, a driveshaft, a first clutch, a second clutch, a third clutch, and a controller. The second axle has first and second half shafts. The second axle has first and second wheels. The driveshaft is disposed between the first and second axles and is coupled to the second axle. The first clutch is configured to selectively couple the driveshaft to the first axle. The second clutch is configured to selectively couple the first wheel to the first half shaft. The third clutch is configured to selectively couple the second wheel to the second half shaft. The controller is programmed to control the clutches to connect the second axle to the first axle via the driveshaft.

Methods and systems for a vehicle transmission are provided. In one example, a vehicle transmission system is provided that includes a first planetary gear set rotationally coupled to a second planetary gear set, a first electrical machine rotationally coupled to a sun gear in the first planetary gear set, and a second electrical machine rotationally coupled to a sun gear in the second planetary gear set. The transmission system also includes an inter-axle differential including a third planetary gear set rotationally coupled to a first axle and a second axle and selectively rotationally coupled to the first planetary gear set and the second planetary gear set, wherein the inter-axle differential is configured to selectively enable and disable speed differentiation between the first and the second axles.

A four-wheel drive vehicle includes right and left main drive wheels and right and left auxiliary drive wheels, and a drive force transmission system configured to constantly transmit a drive force of a drive source to the right and left main drive wheels and to transmit the drive force to the right and left auxiliary drive wheels depending on a vehicle state. The drive force transmission system includes a differential device, a propeller shaft, a drive force transmission device configured to adjust the drive force that is transmitted from the propeller shaft to the right and left auxiliary drive wheels, and an electronic control unit configured to control the drive force transmission device.

A four-wheel drive vehicle includes right and left main drive wheels and right and left auxiliary drive wheels, and a drive force transmission system configured to constantly transmit a drive force of a drive source to the right and left main drive wheels and to transmit the drive force to the right and left auxiliary drive wheels depending on a vehicle state. The drive force transmission system includes a differential device, a propeller shaft, a drive force transmission device configured to adjust the drive force that is transmitted from the propeller shaft to the right and left auxiliary drive wheels, and an electronic control unit configured to control the drive force transmission device.

This disclosure details exemplary electrical architectural layouts for distributing high voltage power within electrified vehicles. An exemplary battery pack associated with an electrical architectural layout of an electrified vehicle may include an enclosure assembly that houses one or more battery arrays. The battery arrays may be efficiently arranged relative to one another inside the enclosure assembly to establish an open channel within the enclosure assembly. A high voltage wiring harness may be routed through an interior of the battery pack within the open channel. The exemplary electrical architectural layouts of this disclosure may be employed within all-wheel drive, rear-wheel drive, or front-wheel drive electrified vehicles.

This disclosure details exemplary electrical architectural layouts for distributing high voltage power within electrified vehicles. An exemplary battery pack associated with an electrical architectural layout of an electrified vehicle may include an enclosure assembly that houses one or more battery arrays. The battery arrays may be efficiently arranged relative to one another inside the enclosure assembly to establish an open channel within the enclosure assembly. A high voltage wiring harness may be routed through an interior of the battery pack within the open channel. The exemplary electrical architectural layouts of this disclosure may be employed within all-wheel drive, rear-wheel drive, or front-wheel drive electrified vehicles.