A vehicle suspension system includes left and right control arm assemblies each having a wheel mount structure, an upper control arm, and a lower control arm. Each control arm includes a first end configured to be pivotably connected to a frame structure of a vehicle and a second end rotatably connected to the wheel mount structure. The vehicle suspension system also includes a transverse leaf spring having an elongated body extending between the control arm assemblies, outer mounting brackets respectively connecting left and right ends of the elongated body to the left and right control arm assemblies, and one or more inner mounting brackets located between the outer mounting brackets. The transverse leaf spring is contoured such that a contoured portion of the elongated body deviates in a downward direction in order to extend below an electric drive system disposed within an internal space between rails of the frame structure.

An off-road vehicle has two front wheels and two rear wheels, the rear wheels being connected to a spool gear driven by a motor. The vehicle also has a left front brake, a right front brake and a single rear brake. Speeds of left and right front wheels are respectively monitored by left and right front speed sensors. A single sensor monitors a common speed of left and right rear wheels. Two user actuated braking input devices, for example a hand lever and a foot lever, may be used independently or concurrently to provide a braking command. An anti-lock braking system may use speed measurements from the various speed sensors to control selective application of pressure on the left front brake, the right front brake and the rear brake.

A suspension assembly for a vehicle may include a wheel support structure operably coupling a wheel to the suspension assembly, a bolt-in spring seat bracket operably coupled to the wheel support structure, and a spring supported by the bolt-in spring seat bracket and disposed between a chassis of the vehicle and the bolt-in spring bracket. The bolt-in spring seat bracket may be adjustable to change a ride height of the vehicle.

An independent suspension system includes two suspension oil cylinders, respectively arranged between wheels at two sides and a frame: and a steering mechanism, configured to be driven by a steering booster oil cylinder to drive the wheels at two sides to turn. The independent system also includes two swing links arranged corresponding to the wheels at two sides, an end at one side of each of the swing links is hinged to a wheel hub of the wheel at the corresponding side via a spherical hinge, and an end at another side of each of the swing links is hinged to a fixing member fixed below a main speed reducer via two spherical hinges respectively along a fore-and-aft direction. A crane having the independent suspension system is further provided.

A suspension device for an in-wheel motor driven wheel is provided. An upper suspension arm is pivotally supported on the vehicle body for supporting the wheel in a vehicle upper position higher than an axle. A link member pivotally connects the wheel to the upper suspension arm and has an absorber connecting portion connected to a lower end of the shock absorber. The shock absorber connecting portion is disposed in the vehicle bottom position lower than an upper end portion of the in-wheel motor unit. The shock absorber is disposed between the vehicle body and the in-wheel motor unit and inclined so as to be closer to the vehicle body toward the lower end.

A pivot bearing for independent wheel suspension of a steerable front wheel of a vehicle having at least one upper bearing with a connection to a spring strut for attachment to the body. To improve the safety of the passenger cell in the event of a frontal collision, the connection has a separating device that brings about separation of the attachment of the pivot bearing to the spring strut and to the body of the vehicle at the upper bearing in the event of a frontal impact.

A suspension coil spring, when assembled to a suspension device, in which a spring reaction axis (AR) is positioned coincident with or sufficiently close to a load input axis (AA), and the design and manufacture of coil springs are facilitated. Namely, a suspension coil spring (10) in a free state is formed so that a coil axis (AC) is bent in V-shape at bend point (PB) and the distance from the end turn center (CU) of the upper seating surface (38) to an imaginary coil axis (AI) is an upper inclination amount (V.sub.U), and the distance from the end turn center (CL) to the imaginary coil axis (AI) is a lower inclination amount (V.sub.L). When the suspension coil spring (10) is interposed between spring seats (22, 24) in the suspension device and compressed along a strut axis, the spring reaction AR axis of the suspension coil spring (10) is inclined and offset with respect to the imaginary coil axis (AL) according to the inclination amounts (V.sub.U, V.sub.L).

A shock absorber assembly includes a pressure tube having an upper end and a lower end and defining an interior, a rod guide disposed adjacent the upper end, a first compression valve assembly adjacent the lower end, a rod operatively coupled to the pressure tube having a first end and a second end, an extender coupled to the second end of the rod, a piston assembly coupled to the extender between the rod guide and the first compression valve assembly with the piston assembly disposed within the interior and slideably coupled to the pressure tube, with the piston assembly dividing the interior into an upper and a lower working chamber, a second compression valve assembly coupled to the extender between the piston assembly and the first compression valve assembly, and a cup disposed within the lower working chamber and defining a bore shaped to receive the second compression valve assembly.

The invention relates to a strut rod made of composite material for a suspension of a front axle of a vehicle, including: an upper part coupled to a rod and piston assembly connected to a vehicle body; and a U-shaped lower part including two brackets for fixing a knuckle arm of the vehicle. This strut rod includes means for detecting a crack. This detection means includes at least one additional edge positioned so as to project from an outer surface of the U-shaped lower part of the strut rod in a region where a crack possibly occurs in the case of an accidental shock on a wheel of the vehicle.

The control arm assembly includes a control arm body and a socket assembly for connecting the control arm body with a vehicle frame. The socket assembly includes a housing with an inner bore which extends along a vertical axis between opposite open ends. A stud extends past the open ends and has an axially extending through passage. The stud has a pair of end portions on opposite sides of a ball portion that has a curved outer surface which is in sliding contact with a bearing surface for allowing the control arm body to pivot relative to the stud and the vehicle frame. The through passage is eccentrically located in a radial direction on the stud for translating the control arm body relative to the vehicle frame in response to rotation of the stud relative to the housing to adjust a camber angle of the wheel assembly.