The disclosure relates to a bearing for a device to be mounted, in particular a support bearing and/or a spring strut head bearing. The bearing comprises a base body. The bearing further comprises a disk which is surrounded by the base body, wherein the disk serves to attach the bearing to the device to be mounted. The bearing further comprises a radial spring arrangement which adjoins a bearing environment via a contact surface.

The disclosure relates to a bearing for a device to be mounted, in particular a support bearing and/or a spring strut head bearing. The bearing comprises a base body. The bearing further comprises a disk which is surrounded by the base body, wherein the disk serves to attach the bearing to the device to be mounted. The bearing further comprises a radial spring arrangement which adjoins a bearing environment via a contact surface.

A spring isolator assembly may include an outer shell with a spring track, an inner wall, and an outer wall for receiving a coil of a spring. The spring track may be disposed between the inner wall and the outer wall. The assembly may also include an insert disposed within the outer shell and includes an angled portion disposed between an inner portion and an outer portion. The insert may include a plurality of holes configured to receive the outer shell. The outer shell may include an inner ring disposed adjacent to the inner wall. The outer shell may include at least one spline configured about the inner diameter of the inner ring. The spring isolator may include at least one spline. The outer shell may include an alignment guide.

A spring isolator for a wheel suspension may include a first side configured to rest on a spring plate of the suspension. The spring isolator may also include a second side, opposite the first side, configured to receive a last coil of a coil spring of the suspension to support the coil spring on the spring plate. The first side may have at least one cavity extending through a thickness of the isolator toward the second side. An elasticity of the isolator between the first and second sides may prevent the last coil from breaking contact with the second side during operation of the suspension.

A spring isolator for a wheel suspension may include a first side configured to rest on a spring plate of the suspension. The spring isolator may also include a second side, opposite the first side, configured to receive a last coil of a coil spring of the suspension to support the coil spring on the spring plate. The first side may have at least one cavity extending through a thickness of the isolator toward the second side. An elasticity of the isolator between the first and second sides may prevent the last coil from breaking contact with the second side during operation of the suspension.

A spring system for a motor vehicle including a spring extending along an extension axis (A) and supported on a spring seat by a resilient spring support. The spring seat including a rigid support structure positioned radially inside the spring. The spring support having a side portion, positioned between the support structure and the spring, and a front portion, connected to the side portion, located axially in front of the spring. The spring exerts a force against the side portion and the side portion exerts a force against the support structure. The spring system provides vibration damping and spring stabilization relative to lateral forces.

A spring system for a motor vehicle including a spring extending along an extension axis (A) and supported on a spring seat by a resilient spring support. The spring seat including a rigid support structure positioned radially inside the spring. The spring support having a side portion, positioned between the support structure and the spring, and a front portion, connected to the side portion, located axially in front of the spring. The spring exerts a force against the side portion and the side portion exerts a force against the support structure. The spring system provides vibration damping and spring stabilization relative to lateral forces.

Suspension for a wheeled vehicle provided with at least one wheel and a frame, having at least one elastic element functionally combinable between the wheel and frame is disclosed. The suspension has at least one hydro-pneumatic spring functionally combined in series with the elastic element so that the equivalent spring modulus (Keq) of the elastic element and hydro-pneumatic spring is variable as a function of the distance between the frame and wheel. The hydro-pneumatic spring is shaped and sized to behave also as an energy dissipator in series to the elastic element.

A spring and damping device for a wheel suspension in motor vehicles includes an upper region, a lower region, and a damping element arranged between the upper region and the lower region. The device further includes a coil spring element and a rubber spring element. The coil spring element and the rubber spring element are arranged one behind the other along a center axis of the damping element such that the coil spring element is positioned to exert a force on the rubber spring element. The device allows a spring rate to be adjusted based either on sensed conditions, or by driver input. The spring rate may be adjustable between discrete settings or continuously variable.

A spring and damping device for a wheel suspension in motor vehicles includes an upper region, a lower region, and a damping element arranged between the upper region and the lower region. The device further includes a coil spring element and a rubber spring element. The coil spring element and the rubber spring element are arranged one behind the other along a center axis of the damping element such that the coil spring element is positioned to exert a force on the rubber spring element. The device allows a spring rate to be adjusted based either on sensed conditions, or by driver input. The spring rate may be adjustable between discrete settings or continuously variable.