A wheel carrier for a motor vehicle, with a base element carrying a wheel bearing, at least one bearing point for a detachable connection to a link provided with a link connection region, as well as at least one bearing point for a detachable connection to a link connection region provided at a link. The first link connection region and the second connection region are designed as separate components and the first link connection region and the second connection region are detachably connected by a fastener to the base element.

A suspension device for a non-steered driving wheel including a wheel carrier having an in-wheel motor incorporated therein for driving the driving wheel, and a suspension arm pivotally supported on a vehicle body and connected to the wheel carrier by a connecting structure. The connecting structure includes a plate member fixed to the wheel carrier by fastening and a pair of elastic bushing devices attached to the plate member. The suspension arm has an open cross sectional portions for receiving portions of the plate member and the elastic bushing devices, and the elastic bushing devices are fixed to the open cross sectional portions at both ends.

A vehicle suspension having a frame attachment portion attached to a saddle, first and second bolster springs mounted to spring mounts on an outboard side of the saddle and mounted on walls of a spring mount on an outboard side of an equalizing beam, and third and fourth bolster springs mounted to walls of a spring mount on an inboard side of the saddle and mounted to spring mounts on an inboard side of the equalizing beam, wherein upwardly extending flanges on the bottom of the first and second bolster springs are mounted to each other using a common fastener, and wherein upwardly extending flanges on the bottom of the third and fourth bolster springs are mounted to each other with a common fastener.

The present invention concerns an axle unit comprising a stub axle and an axle tube, wherein the stub axle has a longitudinal channel which extends inside the stub axle substantially along a stub axis, wherein the stub axle has a transverse channel which extends inside the stub axle substantially transversely to the stub axis and opens to the environment at the outer face of the stub axle, wherein the longitudinal channel and the transverse channel are connected together, wherein the stub axle has a stub joining region to which the hollow-bodied axle tube can be secured.

A vehicle suspension having a frame attachment portion attached to a saddle, first and second bolster springs mounted to spring mounts on an outboard side of the saddle and mounted on walls of a spring mount on an outboard side of an equalizing beam, and third and fourth bolster springs mounted to walls of a spring mount on an inboard side of the saddle and mounted to spring mounts on an inboard side of the equalizing beam, wherein upwardly extending flanges on the bottom of the first and second bolster sprints are mounted to each other using a common fastener, and wherein upwardly extending flanges on the bottom of the third and fourth bolster springs are mounted to each other with a common fastener.

A suspension device for a non-steered driving wheel in which an in-wheel motor for driving the driving wheel is incorporated in a wheel carrier and which includes suspension arm pivotally supported on a vehicle body at one end and connected at the other end to the wheel carrier via at least two elastic bushing devices. A principal elastic axis which is determined by the at least two elastic bushing devices and extends vertically passes through a grounding area of the driving wheel.

A suspension device for a non-steered driving wheel including a wheel carrier having an in-wheel motor incorporated therein for driving the driving wheel, and a suspension arm pivotally supported on a vehicle body and connected to the wheel carrier by a connecting structure. The connecting structure includes a plate member fixed to the wheel carrier by fastening and a pair of elastic bushing devices attached to the plate member. The suspension arm has an open cross sectional portions for receiving portions of the plate member and the elastic bushing devices, and the elastic bushing devices are fixed to the open cross sectional portions at both ends.

A vehicle axle suspension having a leaf spring unit suspending a rigid axle on a structural component or portion of the vehicle. The leaf spring unit arranged on the vehicle to extend parallel with a longitudinal axis of the vehicle. A first bearing unit, secured to the structure, and pivotably connects, at a first pivot axis, to a first end portion of the leaf spring unit. A second bearing unit is secured to the structure. A connection arm pivotably connects at one end, at a second pivot axis, to the second bearing unit. The other end of the connection arm pivotably connects, at a third pivot axis, to a second end portion of the leaf spring unit. The second bearing unit including at least one resilient spring element engaging the connection arm wherein the connection arm is supported on the resilient spring element from a pivoting about the second pivot axis a predetermined extent.

A clamp group for a vehicle leaf spring suspension is disclosed. The clamp group secures a longitudinally disposed, leaf spring at separate and distinct locations, between which the leaf spring is undamped and spaced away from the top and bottom pads of the clamp group. Shear stress is reduced and the spring remains active throughout its length.

A suspension for a vehicle includes a pair of opposing upper and lower control arms that longitudinally locate an axle along the frame. The upper and lower control arms include first ends pivotably mounted to the ends of the axle at upper pivotable axle joints and a second lower pivotable axle joints, respectively. The upper and lower control arms include second ends that are pivotably mounted to frame hanger brackets at upper and lower pivotable hanger joints, respectively. The frame hanger bracket are laterally interposed between an upper and lower hanger joint so that an upper pivotable hanger joint is on one side of each frame hanger and a lower pivotable hanger joint is on an opposite side of the each frame hanger.