A wheel suspension of a vehicle intended to extend in a transversal direction of the vehicle in association with first and second wheels arranged on opposite sides of the vehicle, comprising: a subframe unit provided with a set of attachment points for attachment of the subframe unit to a vehicle body structure, wherein the subframe unit comprises a cross member extending along the subframe unit in a transversal direction of the vehicle when the subframe unit is attached to the vehicle; at least a first link member arranged on each side of the subframe unit, wherein each first link member is arranged to connect a corresponding wheel or wheel supporting element with the subframe unit via a pivoted connection; and a spring arrangement arranged to act onto each of the first link members so as to provide for a spring suspension of the first and second wheels.

A sub-frame arrangement (1) in a vehicle and method thereof wherein the sub-frame arrangement comprises a sub-frame (2), a first body member, and rear attachment means for attaching said sub-frame to the first body member. The sub-frame is a dual part sub-frame comprising a lower sheet section (2b) formed in a single piece wherein said lower sheet section extends the entire length of said sub-frame. The lower sheet section is further formed with two rear portions (21) each extending backwards in the travel direction of said vehicle and the rear portions are adapted to host the rear attachment means.

A sub-frame and method in a sub-frame arrangement in a vehicle wherein said sub-frame arrangement comprises a sub-frame, a body member, and a first and second attachment socket. Each attachment socket is adapted to host a fastening means arranged in a through going apertures of each attachment socket and adapted to fasten said sub-frame to the body member. The fastening means are adapted to fasten a front section of said sub-frame, first and second attachment sockets each comprises a weakened portion arranged at an angle separated from the vehicle deformation direction during a front collision, and the weakened portions are adapted to give way releasing the sub-frame in the event of deformation of the vehicle.

An assembly is provided consisting of a frame element of a motor vehicle and a connecting element used for connecting a part. The connecting element is secured to the frame element by way of a fiber winding.

An actively adjustable wheel suspension for the wheels of an axle of a motor vehicle, wherein each wheel is articulated on the body side of the motor vehicle via a plurality of wheel control elements, includes for each wheel on the axle a rotary actuator which is supported on the body side and includes a torsion bar. The two rotary actuators can be activated for active adjustment via a control unit, with the rotary actuators and the torsion bars of the rotary actuators being oriented in motor vehicle longitudinal direction. The rotary actuators include each at least one strut, which is oriented in motor vehicle transverse direction, for torque support.

A system is disclosed and illustrated for converting vertical movement of a vehicle in motion into electrical energy using at least one example embodiment having a vertically-collapsible frame with a frame bias spring to expand the frame to a normal height under a predetermined weight. The frame mounts between a shortened suspension spring and the vehicle's chassis, so that it is compressed when the vehicle bounces up and down during travel. A shaft to an electrical generator is rotated by at least one, and preferably two, sprag clutch drives responsive to the collapsing and re-expanding of the frame. The generator output is available for storage in a battery to be used by an electric motor or electric accessories. Optional fly weights can be used to keep generator shaft rotation relatively constant during transition between collapsing and re-expanding phases, and vice versa.

A subframe for a rear axle of a motor vehicle includes a transverse structure and a steering device for wheels of the motor vehicle which are fastened to the rear axle. In the installed state of the subframe in the motor vehicle, the transverse structure extends in the transverse direction of the motor vehicle. The transverse structure includes an upper transverse structure element and a lower transverse structure element. The steering device is arranged between the upper transverse structure element and the lower transverse structure element.

A strut assembly including a first cylinder, a second cylinder configured to reciprocally move within the first cylinder, and a damper assembly positioned within the first cylinder. The damper assembly includes a housing having opposing first and second ends, a floating piston in the housing and a damper piston positioned between the floating piston and the first end of the housing. The damper piston divides the housing into first and second chambers, where the first and second chambers include a hydraulic fluid that provides resistance to the movement of the damper piston in the housing. The strut assembly also includes a gas spring in the first and second cylinders, where the gas spring includes a pressurized gas contained within the first and second cylinders.

An insertable drive modal for replacing an existing electric motor and drive configuration in an electric vehicle or for converting an internal combustion vehicle to an electric vehicle with a new motor and drive configuration.

A rear subframe structure is provided with a rear subframe configured such that a front cross member, a rear cross member, a pair of left and right upper side members, and a pair of left and right lower side members are connected; and a vehicle-body mounting portion formed on each of both ends of the front cross member, and on each of rear ends of the upper side members. The rear subframe further includes a vertical-wall-shaped pillar portion held and fixed between a lateral portion of the front cross member in the vehicle width direction and the upper side member, and extending in the vehicle width direction. A lower portion of the pillar portion is connected to the lower side member, an upper-arm support portion is formed on an upper portion of the pillar portion, and a lower-arm support portion is formed on a lower portion of the pillar portion.