The present invention concerns a wheel suspension 5 for a torsion beam axle 1, whereby a wheel mount 8 rotates about a virtual steering axle 18 as a result of a cornering force. According to the invention, it is further provided that a wheel mount bracket 6 with a yielding element 11 is coupled to the end 4 of a longitudinally extending swing arm 3 of the torsion beam axle 1, so that an additional steering in positive toe occurs as a result of a lateral force effect.

An electric vehicle frame strut tower to body structure interface bracket is disclosed. An example electric vehicle disclosed herein includes a frame, a battery pack supported by the frame, a body coupled to the frame, a strut tower coupled to the frame to support the body and absorb road surface impacts on the electric vehicle, and a strut tower interface bracket to couple the strut tower to the body.

A suspension joining structure includes: a lower arm having one end fastened to a vehicle body; an assist knuckle having a strut thereon; a fastening unit configured to connect one end of the lower arm and a lower end of the assist knuckle to each other; a suspension fastened to the assist knuckle and rotating independently of the assist knuckle for steering of a wheel; a steering input part connected to the assiste knuckle, and configured such that a steering force is applied to the suspension upon steering; and a rotation transfer unit arranged between the suspension and the steering input part.

A suspension device (rear suspension (10)) for vehicles is provided which includes a damper (40), a shaft (50) pivotably supporting an end of the damper (40), and a bush (60) including a cylindrical elastic member fitted onto the outer circumference of the shaft (50). The axis (C2) of the bush (60) is disposed along a line of intersection between an imaginary first plane (S1) and an imaginary second plane (S2), or along a line parallel to the line of intersection. The first plane (S1) is orthogonal to the axis (C1) of the damper (40) when a stroke position of a wheel (24) is a first position relative to the vehicle body (80) in the vertical direction of a vehicle body (80). The second plane (S2) is orthogonal to the axis (C1) of the damper (40) when the stroke position of the wheel (24) is a second position.

A shock absorber mounting assembly for an off-road vehicle is provided. The shock absorber mounting assembly may provide A-arm brackets dimensioned and adapted to interconnect body and wheel framing of the off-road vehicle, wherein the lower bracket adjustably engages a lower portion of the shock absorber. The present invention also enables any model year shock absorber to be adapted to operatively associate with the steering system of any off-road vehicle of the same make and model, regardless of model year, through a shock absorber adapter bracket assembly that attaches to the original equipment manufacturer A-arms of the off-road vehicle adding the non-model year shock absorbers. The brackets may be of unitary construction.

A stabilizer clamp for a vehicle stabilizer may include an inner region for receiving a vehicle stabilizer and at least two at least partially opposite end regions for closing the stabilizer clamp. A first of the at least two at least partially opposite end regions may have a connecting element, and a second of the at least two at least partially opposite end regions may have a connecting element receptacle for producing at least a form-fitting connection between the connecting element and the connecting element receptacle. The connecting element may be at least one rivet, and the at least one connecting element receptacle is at least one rivet hole, and the form-fitting connection that is produced is at least a riveted connection.

According to some embodiments of the disclosed subject matter, a ride-on mower can include a main frame, a side member pivotally connected to the main frame, and a transaxle. The transaxle can include a pump portion that has a pump housing fixed on the main frame and a fluid displacement structure located in the pump housing. The transaxle can further include a motor portion including a motor housing and a fluid driven structure located in the motor housing. The motor housing can be separate from the pump housing, and the motor housing can be carried on and movable with the side member. Tubing can interconnect the pump portion and the motor portion.

A tandem axle assembly includes a first slipper spring and a second slipper spring. The two slipper springs are configured or oriented in series with the slipper ends of the two slipper springs oriented toward each other. A keeper for a tandem axle suspension assembly is also disclosed.

A suspension joining structure includes: a lower arm having one end fastened to a vehicle body; an assist knuckle having a strut thereon; a fastening unit configured to connect one end of the lower arm and a lower end of the assist knuckle to each other; a suspension fastened to the assist knuckle and rotating independently of the assist knuckle for steering of a wheel; a steering input part connected to the assist knuckle, and configured such that a steering force is applied to the suspension upon steering; and a rotation transfer unit arranged between the suspension and the steering input part.

An electrically controlled suspension includes a first spring with a first end and a second end, where the first end of the first spring is connectable to a forward frame bracket of a frame of a vehicle and where the second end of the first spring is connectable to a rear frame bracket of the frame of the vehicle via a rear spring support. The suspension includes a second spring with a first end and a second end, where the second end of the second spring is connected to the second end of the first spring. An electrically operated suspension control actuator is provided where the first end of the second spring is connected to the electrically operated suspension control actuator.