A height-adjusting axle assembly separate from and connectable to a trailer frame. A first pair of wheels is connected to a first cross-beam by a first pair of torsion axles such that rotation of the first cross-beam causes rotation of the first pair of torsion axles. A second pair of wheels is connected to a second cross-beam by a second pair of torsion axles such that rotation of the second cross-beam causes rotation of the second pair of torsion axles. An interconnecting bar is pivotally connected to the first cross-beam and the second cross-beam. A first frame rail and a second frame rail are connectable to the trailer frame. The first cross-beam and the second cross-beam are supported by and extend between the first frame rail and the second frame rail.

A drive unit for a commercial vehicle includes at least one electric motor; and means for levelling the axle driven by the at least one electric motor.

A forecarriage (8) of a rolling motor vehicle (4), comprising a forecarriage frame (16), at least a pair of front wheels (10), each wheel (10) being connected to a rolling kinematic mechanism (20), which enables the front wheels (10) to roll in a synchronous and specular manner, by means of a respective axle journal (60), and a roll block system (100) comprising a rod extensible in length (110) which directly connects one of the two front wheels (10) at the respective axle journal (60) to said forecarriage frame (16) by means of hinging means (71, 72, 73) at both its ends, and means (120) to reversibly block the lying position of said rod extensible in length (110) on a rolling plane with respect to said axle journal (60) and to said forecarriage frame (16), so as to block the rolling movements allowed by said rolling kinematic mechanism (20).

An automotive suspension for a sports car comprising a lower oscillating arm and a shock absorber having a relative end connected with a first intermediate part of the lower oscillating arm by means of a connecting rod having a first end hinged with said end of the shock absorber and a relative second end, opposite to the first end, hinged with said first intermediate part, locking means for locking said connecting rod in a stable position ranging between two extreme positions wherein said first end of the connecting rod is in a position close to or distal relative to the frame of the car.

A rotating latch assembly includes a lift housing extending between a first opened end and a second opened end and defining a chamber extending therebetween. A support tube is slidably disposed in the chamber and extends between a first end and a second end. The lift housing is movable along the support tube between an extended position and a lowered position in response to a movement provided by an actuator wherein the extended position is the lift housing being adjacent to the first end and the lowered position is the lowered position being adjacent to the second end. A retaining member is disposed between the lift housing and the support tube and attached to the support tube and the lift housing for maintaining the lift housing in the extended position as the lift housing moving from the lowered position to the extended position.

According to an aspect of the disclosed embodiments, an apparatus for a vehicle includes a locking plate configured to be coupled to a first shaft of a suspension rod. A housing is configured to be coupled to a second shaft of the suspension rod that moves relative to the first shaft. The housing extends along a first longitudinal axis. A pin is configured to rotate about a second longitudinal axis. A locking mechanism is configured to lock the pin in starting position.

A bogie for a forestry vehicle is disclosed that includes a bogie body, which has a first wheel hub for arrangement of a first wheel and a second wheel hub for arrangement of a second wheel. The bogie includes a swing arm pivotably hinged at a first end portion on the bogie body, and at a second end portion has a wheel hub for arrangement of a center wheel between the first wheel and the second wheel. The bogie further includes a spring and/or damper element, which at one end portion is hinged on the bogie body and at the other end portion is hinged on the second end portion of the swing arm and by means of which the swing arm is capable of being applied with force. A vehicle, in particular a forestry vehicle, is also disclosed having at least one bogie axle with such a bogie.

A height-adjusting axle assembly separate from and connectable to a trailer frame. A first pair of wheels is connected to a first cross-beam by a first pair of torsion axles such that rotation of the first cross-beam causes rotation of the first pair of torsion axles. A second pair of wheels is connected to a second cross-beam by a second pair of torsion axles such that rotation of the second cross-beam causes rotation of the second pair of torsion axles. A interconnecting bar is pivotally connected to the first cross-beam and the second cross-beam. A first frame rail and A second frame rail are connectable to the trailer frame. The first cross-beam and the second cross-beam are supported by and extend between the first frame rail and the second frame rail.

A vehicle steering system includes: actuators, respectively provided for wheels, for changing toe angles of the wheels; lock devices, respectively provided for the wheels, for restricting changes in the toe angles of the wheels; and a control device for controlling the actuators and the lock devices. For each lock device, the control device at a time performs an individual unlocking operation of unlocking the lock device, and a lock relaxation operation of relaxing a locked state of the lock device.

A motion control system that can detect a change in a an operating characteristic and send a stabilizing command to an actuator system based on the change is described. A motion control component in the system includes a first component with an electropermanent magnet having a coil, differing first and second permanent magnet materials, and differing first and second states. The motion control component includes a second component configured to magnetically interact with the first component to define a damping characteristic that affects motion between the first component and the second component and a controller configured to supply a current pulse to the electropermanent magnet to switch the electropermanent magnet between the first and second states. The electropermanent magnet retains the respective first or second state after cessation of the current pulse.