A stabilizer adhesive bearing for a vehicle stabilizer may comprise an annular sleeve having a resilient inner contour for coaxial arrangement on the vehicle stabilizer. The resilient inner contour of the annular sleeve may comprise on a side facing the vehicle stabilizer a three-dimensionally structured surface with an adhesive receiving volume. The three-dimensionally structured surface has a maximum roughness depth (R.sub.max) greater than 45 m and a core roughness depth (R.sub.K) of at least 65% relative to the maximum roughness depth (R.sub.max) of the three-dimensionally structured surface. The maximum roughness depth (R.sub.max) is a total of the reduced tip height (R.sub.pk) and the reduced groove depth (R.sub.vk). Further, the reduced tip height (R.sub.pk), the reduced groove depth (R.sub.vk), and the core roughness depth (R.sub.K) may be determined in accordance with EN ISO 13565-2: December 1997.

A bracket for a vehicle stabilizer is provided and includes an elastomer element for receiving a stabilizer spring, a first and a second bracket element. The first and the second bracket elements are connectable in such a way that the elastomer element is fixed between the first and the second bracket elements. A connection means for connecting the first and the second bracket elements is formed on the first and second bracket elements, the connection means has at least one connection pin and a connection recess. In a connection state of the first bracket element and of the second bracket element, the connection pin is inserted into the connection recess, and in the connection state the connection pin is frictionally fixed in the connection recess and/or the connection pin is riveted in the connection recess in a positive manner and/or the connection pin is cohesively fixed in the connection recess.

A torsion spring arrangement for a wheel suspension of a motor vehicle, including two torsion bars arranged coaxially one inside another and also a spring element, which is arranged axially-parallel to the two coaxial torsion bars and can be mounted on the motor vehicle body via a bearing position, wherein the radial outer hollow-cylindrical torsion bar can be mounted on the motor vehicle body side and is connected in a rotationally-fixed manner to an output lever fastenable on a wheel guiding element and the radial inner torsion bar is connected in a rotationally-fixed manner to the outer torsion bar and is connected in a rotationally-fixed manner via a coupling to the spring element.

A torsion spring assembly for a wheel suspension of a motor vehicle, including two torsion bars arranged coaxially one inside another and also a spring element, which is arranged axially-parallel to the two coaxial torsion bars, and can be mounted on the motor vehicle body via a bearing position, wherein the radial outer hollow-cylindrical torsion bar can be mounted on the motor vehicle body side and is connected in a rotationally-fixed manner to an output lever fastenable on a wheel guiding element and the radial inner torsion bar is connected in a rotationally-fixed manner to the outer torsion bar and is connected in a rotationally-fixed manner via a coupling to the spring element.

The present invention relates to all terrain vehicles having at least a pair of laterally spaced apart seating surfaces. More particularly, the present invention relates to trail compliant side-by-side all terrain vehicles.

Methods and systems are provided for a fuel tank and suspension system. In one example, a system may include arranged a dampener between the fuel tank and the suspension system. The dampener may be configured to couple to the fuel tank or suspension system such that a threshold distance between a spud of the fuel tank and a stability bar of the suspension system may be maintained.

An overload suspension system configured for operative engagement to a vehicle having a first leaf spring and second leaf spring to provide auxiliary support to the vehicle when overloaded. A first control arm attached to a first torsion bar has a distal end positioned a separation distance from the first leaf spring. A second control arm attached to the second control arm has a distal end positioned substantially the same separation distance from the second leaf spring. The suspension system operates as an auxiliary suspension only when added weight to the vehicle deflects both leaf springs to contact a respective one of the control arms, thereby preserving the ride and suspension characteristics of the vehicle when the added weight is not present.

A suspension strut assembly comprises a suspension strut 10 formed by a strut housing 10a having first and second ends and an outer surface, and a strut rod 10b which is telescopically engaged in the first end of the strut housing 10a. A thread 11a is formed on a sleeve 11 which is slideably engaged on the outside of the strut housing 10a. An anti-roll bar collar 13 is screwingly engaged on the outer surface of the strut housing 10a. The collar 13 has a plate 13a extending outwardly thereof for engaging with an anti-roll bar. An annular spring seat 14 is also screwingly engaged on the outer surface of the strut housing 10b between the collar 13 and the first end of the strut housing 10a. The collar 13 and spring seat 14 are each windable along the housing 10a to vary their longitudinal positions on the housing 10a.

Provided is a vehicular holding device that, in an ON state, holds a vehicle component in a state where displacement of the vehicle component in an axial direction is restrained, and that, in an OFF state, holds the vehicle component in a state where displacement of the vehicle component in the axial direction is possible. The vehicular holding device includes at least one engagement part, a cam mechanism, and an axial direction restraining part. The at least one engagement part is at a position where the engagement part engages with an engaged part in the ON state, and is at a position where the engagement part is separated from the engaged part in the OFF state. The cam mechanism displaces the at least one engagement part from the OFF-state position to the ON-state position. The axial direction restraining part receives axial-direction force acting on the at least one engagement part.

A vehicle is disclosed. The vehicle may include a hydraulic system. The vehicle may include a sway bar. The sway bar may be positioned rearward of a hydraulic pump of the hydraulic system. A console having a first hydraulic input may be provided in an operator area of the vehicle.