A vehicle includes a first axle, second axle, first clutch, second clutch, and controller. The first and second axles are coupled by a driveshaft. The first and second clutches are configured to isolate the driveshaft from loads transferred through the first and second axles, respectively, when open. The controller is programmed to, in response to a difference between output speeds of the first and second axles exceeding a first threshold, close the second clutch, reduce the difference such that it is below a second threshold, and close the first clutch.

A vehicle comprising a prime mover, first and second groups of wheels, and a driveline configured to connect the prime mover to the wheels. The driveline includes an auxiliary driveline comprising a driveshaft and drive means between the driveshaft and the second group of wheels, the drive means being operable to connect the second group of wheels to the driveshaft when the driveline transitions between first and second modes. The drive means has an input portion, an output and first and second releasable torque transmitting means coupled in series therebetween. The first releasable torque transmitting means is operable to allow slip between the input and output to modulate an amount of torque transmitted therebetween, The second releasable torque transmitting means is operable between a first condition in which an input portion is isolated from an output portion and a second condition in which the input and output portions are directly coupled.

A control apparatus for a four-wheel drive vehicle includes a current detector configured to output a detection signal in accordance with the magnitude of an actual control current, a target current value calculator configured to calculate a target current value that is a target value of the control current, and a current controller configured to control a current output circuit to output the control current having the target current value calculated by the target current value calculator based on a result of detection performed by the current detector. When the four-wheel drive vehicle is in a two-wheel drive mode in which first and second friction clutches are released, the current controller performs zero-point adjustment for adjusting a zero point of the control current to be output from the current output circuit.

In a hydraulic clutch actuation system for controlling in particular a clutch-controlled compensation unit of a drivetrain of a motor vehicle, in which hydraulic clutch actuation system a hydraulic pump is used for generating hydraulic pressure in a hydraulic fluid for the purposes of clutch actuation by means of a hydraulic clutch actuation device, provision is made whereby the hydraulic fluid is supplied as clutch oil to the friction members of the friction clutch which are to be oiled with clutch oil (cooling and/or lubricating oil). In this way, improved and more reliable oiling of the clutch can be made possible even at low vehicle speeds and under heavy clutch load, wherein, despite this, very rapid dry-running of the cutches, and low power losses generated by the clutch oiling, are ensured.

In a control device of a vehicle power transmission device, a first meshing clutch has a drive power source side meshing member coupled to a power transmission member, an auxiliary drive wheel side meshing member coupled to the power transmission member, and an actuator engaging or releasing the drive power source side meshing member and the auxiliary drive wheel side meshing member, and when a rotation speed difference between a rotation speed of the drive power source side meshing member and a rotation speed of the auxiliary drive wheel side meshing member is larger than a predefined value at the time when a first meshing clutch is brought into an engaged state, a clamping pressure on a transmission belt is increased as compared to when a rotation speed difference is equal to or less than a predefined value.

An axle drive mechanism includes a driving toothed wheel, a drive mechanism housing, a differential cage, a differential gear, a first and a second output shaft, and at least one shiftable torque transmission device. The at least one shiftable torque transmission is disposed between the driving toothed wheel and the first output shaft and includes a torque transmission region. The torque transmission region is at least partially disposed between said differential cage bearings in the axial direction.

Some embodiments of the present invention provide a control system configured to control a driveline of a motor vehicle to operate in a selected one of a plurality of configurations, the system comprising at least one sensor for sensing an environment ahead of the vehicle and generating a sensor signal in dependence on the environment, the system being configured to cause the driveline to operate in a configuration selected in dependence at least in part on the sensor signal.

A clutch assembly comprises a first drive part, a second drive part, a clutch which comprises an axially supported first clutch part and an axially movable second clutch part, wherein the second clutch part can be moved into an open position and into a closed position, wherein a clutch profile of the second clutch part 8 and a drive part profile of the second drive part form a form-locking profile connection such that the second clutch part is connected to the second drive part in a rotationally fixed and axially movable way, wherein the drive part profile comprises central flank lines which are each formed between a tip line and a base line of the drive part profile, wherein the drive part profile is designed such that the central flank lines, when rotating around the rotational axis A, define a rotational face which comprises at least one tapered partial portion. Further disclosed is a driveline assembly with such a clutch assembly.

Some embodiments of the present invention provide a control system configured to control a driveline of a motor vehicle to operate in a selected one of a plurality of configurations, the system being configured to receive a signal indicative of a location of the vehicle, the system being configured to cause the driveline to operate in a configuration selected in dependence at least in part on the signal indicative of the location of the vehicle.

A disconnecting axle assembly for a vehicle can include a planetary differential and a clutch. The differential input can be meshingly engaged with an input pinion. The clutch can include first and second friction plates. The first plates can be non-rotatably but axially slidably coupled to a first differential output. The second plates can be interleaved with the first plates and non-rotatably but axially slidably coupled to a first axle half-shaft which can drive a first wheel. A second differential output can be drivingly coupled to a second axle half-shaft which can drive a second wheel. The differential can output a greater amount of torque to the first differential output than the second differential output when the vehicle is traveling in a straight line.