A vehicle fluid spring system is adapted to absorb road shock imparted onto at least one road wheel of a vehicle. The vehicle fluid spring system includes a fluid spring and a variable volume unit. The fluid spring includes a fluid chamber adapted to change in volume. The variable volume unit including a rigid piston cylinder, a piston, a fluid cavity, and an actuator. The piston is adapted to reciprocate within, and is in sliding contact with, the rigid piston cylinder. The fluid cavity is defined by the piston cylinder and the piston. The actuator is adapted to drive the piston changing a volume of the fluid cavity. The fluid cavity is in fluid communication with the fluid chamber.

A vehicle powertrain proactive damping system includes a plurality of proactive damping structures mounted on a powertrain structure with each proactive damping structure includes a magneto rheological elastomer (MRE). An electromagnet is associated with each proactive damping structure. A control unit includes a processor circuit. A sensor obtains vibration data regarding the powertrain structure. A LIDAR sensor is mounted on the vehicle and is electrically connected with the control unit. The LIDAR sensor provides data to the control unit indicative of upcoming road surface conditions to be experienced by the vehicle. Based on data from at the sensor and the LIDAR sensor, the processor circuit is constructed and arranged to control voltage to the electromagnets to selectively adjust a rigidity of the associated proactive damping structure so as to control vibrational effects on the powertrain structure.

A vehicle suspension comprises a hub carrier on which a wheel hub is suitable for being mounted, a suspension arm having an outer end connected to the hub carrier by a ball joint and an inner end suitable for being attached to a suspended structure of the vehicle, and a shock absorber. At least one load responsive device is arranged on the suspension arm, the load responsive device comprising a sensor able to generate an output signal in response to a load applied to the suspension arm, wherein a control unit is configured to receive the output signal generated by the sensor and to adjust the stiffness of the shock absorber through a valve adapted to vary passage cross-sections of the fluid contained in the shock absorber.

A powered weight distribution system is provided for a vehicle having a platform on which a load is supported. The powered weight distribution system includes a shiftable axle assembly. The shiftable axle assembly includes a drivable axle and a frame supporting the drivable axle. The frame is configured to be supported on the platform. The frame is switchable between a locked configuration in which the frame is fixed relative to the platform and an unlocked configuration in which the frame is shiftable relative to the platform. The shiftable axle assembly further includes a powering element configured to rotatably drive the drivable axle, such that the frame and the drivable axle shift relative to the platform when the frame is in the unlocked configuration and the drivable axle is rotated by the powering element.

A damper valve with an adjustable effective stiffness of a shim. The damper valve includes a piston. The piston has a fluid path formed therethrough. A shim is disposed proximate the fluid path formed through the piston. A stiffness adjustment feature is coupled to the shim, and the shim is disposed between the piston and the stiffness adjustment feature. The stiffness adjustment feature is configured to adjust the effective stiffness of the shim without affecting a preload applied to the shim.

A vehicle suspension comprises a hub carrier on which a wheel hub is suitable for being mounted, a suspension arm having an outer end connected to the hub carrier by a ball joint and an inner end suitable for being attached to a suspended structure of the vehicle, and a shock absorber. At least one load responsive device is arranged on the suspension arm, the load responsive device comprising a sensor able to generate an output signal in response to a load applied to the suspension arm, wherein a control unit is configured to receive the output signal generated by the sensor and to adjust the stiffness of the shock absorber through a valve adapted to vary passage cross-sections of the fluid contained in the shock absorber.

A damper valve with an adjustable effective stiffness of a shim. The damper valve includes a piston. The piston has a fluid path formed therethrough. A shim is disposed proximate the fluid path formed through the piston. A stiffness adjustment feature is coupled to the shim, and the shim is disposed between the piston and the stiffness adjustment feature. The stiffness adjustment feature is configured to adjust the effective stiffness of the shim without affecting a preload applied to the shim.

Embodiments of the present invention provide a method and system for enacting various driving profiles based on identifying the age and gender of the user. Initially, identifying information is acquired from a user of a vehicle. An identification program determines whether the driver is known, by comparing the identifying information to a set of stored identifying information. If the driver of the vehicle is known, as the identifying information from the user is similar to stored identifying information, then a specific driver profile associated with the specific driver is activated. If the driver is not known, as the identifying information from the user of the vehicle is not similar to the stored identifying information, then the age and gender of the user of the vehicle is determined. Based on the determined age and gender of the driver of the vehicle, various vehicle setting ranges are enacted.

A damper valve with an adjustable effective stiffness of a shim. The damper valve includes a piston. The piston has a fluid path formed therethrough. A shim is disposed proximate the fluid path formed through the piston. A stiffness adjustment feature is coupled to the shim, and the shim is disposed between the piston and the stiffness adjustment feature. The stiffness adjustment feature is configured to adjust the effective stiffness of the shim without affecting a preload applied to the shim.

Embodiments of the present invention provide a method and system for enacting various driving profiles based on identifying the age and gender of the user. Initially, identifying information is acquired from a user of a vehicle. An identification program determines whether the driver is known, by comparing the identifying information to a set of stored identifying information. If the driver of the vehicle is known, as the identifying information from the user is similar to stored identifying information, then a specific driver profile associated with the specific driver is activated. If the driver is not known, as the identifying information from the user of the vehicle is not similar to the stored identifying information, then the age and gender of the user of the vehicle is determined. Based on the determined age and gender of the driver of the vehicle, various vehicle setting ranges are enacted.