A suspension system for a vehicle may include a steering knuckle operably coupled to a wheel hub, and a plurality of links operably coupling the steering knuckle to a chassis of the vehicle. One of the links may be a trailing blade having a body portion that lies in a plane. The trailing blade may include a first end operably coupled to the steering knuckle and a second end operably coupled to the chassis. The trailing blade may extend from the first end to the second end such that the plane of the body portion forms an angle of greater than 5 degrees relative to a longitudinal axis of the vehicle.

Multi-link suspension systems for vehicles are described having various linkages or links that connect to distinct points of a wheel mount or knuckle. Each of the linkages are preferably coupled to the wheel mount via a spherical ball joint and mounted such that they can independently move or rotate with respect to the other linkages. A shock assembly is preferably mounted between two of the linkages on a separate link and is rotatably mounted to each of the two linkages.

Multi-link suspension systems for vehicles are described having various linkages or links that connect to distinct points of a wheel mount or knuckle. Each of the linkages are preferably coupled to the wheel mount via a spherical ball joint and mounted such that they can independently move or rotate with respect to the other linkages. A shock assembly is preferably mounted between two of the linkages on a separate link and is rotatably mounted to each of the two linkages.

Independent wheel suspensions for a motor vehicle are described herein. An example independent wheel suspension includes a link to be pivotably coupled to a vehicle body of the motor vehicle via a first flexible pivot bearing and a second flexible pivot bearing. The first and second flexible pivot bearings form a pivoting axis. The link has a wheel attachment point to which a vehicle wheel is to be coupled. The example independent wheel suspension also includes a spring to be disposed between the link and the vehicle body. The spring is configured to produce a force component on the link that is directed outward along a transverse axis of the motor vehicle and that increases during compression.

A car having: a frame; two rear drive wheels; two rear suspensions, which support the two rear wheels; a drivetrain having two axle shafts, which transmit the motion to the rear drive wheels; a rear subframe, which is fixed to the frame in four fixing points through the interposition of elastic isolating elements, directly supports at least part of the drivetrain, and provides a coupling for the rear suspensions. The four fixing points are substantially arranged at the same vertical height. The frame has two “C”-shaped elements, each having its two ends in the area of two fixing points. Two stiffening beams are provided, each arranged longitudinally and screwed to the frame in the area of the ends of a corresponding “C”-shaped element.

A car having: a frame; two rear drive wheels; two rear suspensions, which support the two rear wheels; a drivetrain having two axle shafts, which transmit the motion to the rear drive wheels; a rear subframe, which is fixed to the frame in four fixing points through the interposition of elastic isolating elements, directly supports at least part of the drivetrain, and provides a coupling for the rear suspensions. The four fixing points are substantially arranged at the same vertical height. The frame has two “C”-shaped elements, each having its two ends in the area of two fixing points. Two stiffening beams are provided, each arranged longitudinally and screwed to the frame in the area of the ends of a corresponding “C”-shaped element.

A vehicle comprising: a body; a pair of wheels each rotatable about a respective rolling axis and each wheel having a centre of mass; and a pair of suspension mechanisms, each wheel being attached to the body of the vehicle by a respective suspension mechanism, the suspension mechanism providing the respective wheel with freedom to move relative to the body of the vehicle in steer about a respective steer axis, the steer axis being offset from the centre of mass of the wheel so that when a different amount of torque is applied to each wheel about the rolling axis the difference in torque causes a steering torque on each wheel about the steer axis of the wheel.

A vehicle comprising: a body; a pair of wheels each rotatable about a respective rolling axis and each wheel having a centre of mass; and a pair of suspension mechanisms, each wheel being attached to the body of the vehicle by a respective suspension mechanism, the suspension mechanism providing the respective wheel with freedom to move relative to the body of the vehicle in steer about a respective steer axis, the steer axis being offset from the centre of mass of the wheel so that when a different amount of torque is applied to each wheel about the rolling axis the difference in torque causes a steering torque on each wheel about the steer axis of the wheel.

A vehicle suspension arrangement includes a mounting bracket, a trailing arm, an air spring assembly configured to bias a second end of the trailing arm from a vehicle frame member, an axle assembly couple to the trailing arm, and a trailing arm connection assembly that includes a connector having a first portion received within an aperture of the mounting bracket, and a second portion extending outwardly from the first portion and including an aperture, a bushing member received within a first end of the trailing arm, a pin member received within the bushing member and including a first aperture, and a first mechanical fastener received within the first aperture of the pin member and within the aperture of the second portion of the first connector, thereby pivotably securing the trailing arm to the mounting bracket.

A vehicle suspension having a first load-bearing component assembly and a second load-bearing component assembly. The first and second load bearing component assemblies are adapted to be transversely positioned across from each other on a vehicle chassis. A directionally-dependent heave spring assembly is adapted to be transversely secured to a vehicle chassis, the heave spring assembly is coupled to the first load-bearing component assembly and to the second load-bearing component assembly and exhibits resiliency in opposition to upward vertical movement of both wheel hub assemblies relative to their rest states, and exhibits substantially no resiliency in opposition to downward vertical movement of both wheel assemblies relative to their rest states.