A kinetic energy shock absorber is shown and described. The kinetic energy shock absorber is comprised of a sleeve that has a first closed end and a second opened end. A piston is sized to fit within the sleeve and has at least one dosed end. The closed end of the sleeve has a protrusion attached to the closed end, wherein the protrusion has an aperture located therethrough. The dosed end of the piston has a protrusion, wherein the protrusion has an aperture therein. The piston will create electric energy when it enters the sleeve via an electric generation device. The kinetic energy shock absorber is a device that may be attached to an existing vehicle shock. The kinetic, energy shock absorber may also be used as a replacement shock for a motor vehicle.

Disclosed herein a suspension system includes a damper in which a piston valve is movably provided in a chamber inside a cylinder; and an actuator coupled to a side portion of the cylinder to communicate with the chamber inside the cylinder; wherein the actuator comprises a rotating body in which a rotational drive shaft coupled to a center thereof, the rotating body configured to be rotated by working fluid transmitted from the chamber during a stroke of the piston valve; a centrifugal valve coupled to the rotational drive shaft in front of the rotating body, the centrifugal valve rotating together with the rotating body and varying an area of a flow path hole through which the working fluid passes according to a rotational speed of the rotating body; and a generator combined motor in which the rotational drive shaft is rotatably arranged at a rear of the rotating body, the generator combined motor configured to charge by generating electric energy through the rotation of the rotational drive shaft.

An electromechanical vehicle height adjustment unit comprises an upper spring pad operative to support an upper end of a vehicle spring, a top mount that is displaceable relative to the upper spring pad, and a displacement mechanism coupled to the upper spring pad and the top mount and operative to displace the top mount relative to the upper spring pad in a height direction. The displacement mechanism comprises a rotary-to-linear motion conversion mechanism and an electric motor.

An electromechanical vehicle height adjustment unit comprises a control arm, a lower spring pad operative to support a lower end of a vehicle spring, and a displacement mechanism supported on the control arm. At least a portion of the displacement mechanism is integrated into the control arm. The displacement mechanism is coupled to the lower spring pad and is operative to displace the lower spring pad relative to the control arm. The displacement mechanism comprises a rotary-to-linear motion conversion mechanism and an electric motor.

A regenerative shock absorber that include a housing and a piston that moves at least partially through the housing when the shock is compressed or extended from a rest position. When the piston moves, hydraulic fluid is pressurized and drives a hydraulic motor. The hydraulic motor, in turn, drives an electric generator that produced electric energy. The electric energy may be provided to a vehicle, among other things. The regenerative shock absorber may also provide ride performance that comparable to or exceeds that of conventional shock absorbers.

A shock absorber including a shock absorber body substantially filled with a hydraulic fluid. The shock absorber includes a piston disposed within the shock absorber body that includes a piston head movable within the shock absorber to apply a pressure change in the hydraulic fluid. The shock absorber includes a piezoelectric material disposed within the shock absorber and in fluid communication with the hydraulic fluid. The piezoelectric material is configured to generate an electrical charge in response to the pressure change in the hydraulic fluid. The piezoelectric material is electrically connected to at least one battery configured to receive the electrical charge generated by the piezoelectric material.

The invention relates to a damper unit (10) for a chassis (100) of a vehicle with levelling, comprising a hydraulic cylinder (1) having a container tube (2) which is filled with a damper fluid and in which a piston (3) is movably mounted and separates an upper container space (21) from a lower container space (22). The piston (3) comprises a first valve (41) through which the damper fluid flows when the piston (3) moves in a first direction A. The damper unit (10) further comprises an accumulator (5) and a check valve (6), wherein the accumulator (5) is connected to the container tube (2) via the check valve (6) in such a manner that, when the piston (3) moves in at least one direction, damper fluid is pumped through the check valve (6) into the accumulator (5).

A regenerative shock absorber that include a housing and a piston that moves at least partially through the housing when the shock is compressed or extended from a rest position. When the piston moves, hydraulic fluid is pressurized and drives a hydraulic motor. The hydraulic motor, in turn, drives an electric generator that produced electric energy. The electric energy may be provided to a vehicle, among other things. The regenerative shock absorber may also provide ride performance that comparable to or exceeds that of conventional shock absorbers.

A suspension including a spring interposed between the body (B) of the vehicle and the wheel (W); a regenerative hydraulic shock-absorbing unit comprising a hydraulic shock-absorber arranged parallel to the spring, a motor and pump unit with a volumetric hydraulic machine and an electric machine coupled to the hydraulic machine), and an electronic control unit arranged to control the torque of the electric machine. A hydraulic actuator is arranged in series with the spring. A reservoir and a hydraulic circuit are connected to each other, the hydraulic shock-absorber, the hydraulic machine the hydraulic actuator and the reservoir. The hydraulic circuit includes a valve assembly for controlling the flow of a working fluid between the hydraulic shock-absorber, the hydraulic machine, the hydraulic actuator and the reservoir.

An actuator system for a vehicle suspension system including: an actuator having a piston and a first fluid chamber separated from a second fluid chamber by the piston; a hydraulic pump having a first port, a first hydraulic circuit operable to connect the first port to the first chamber, the first hydraulic circuit including a first valve, the first valve being a damper valve operable to variably restrict flow of hydraulic fluid out of the first chamber; a first hydraulic accumulator connected to a first gallery of the first hydraulic circuit between the first port and the first valve; a second hydraulic accumulator connected to a second port of the pump via a second gallery; and a second valve, the second valve being a variable pressure relief valve operable to variably restrict flow of hydraulic fluid from the first gallery to the second gallery.