A chassis component (1) for a wheel suspension having at least two pivot points (3, 4), at least one connecting structure (7) which interconnects the pivot points (3, 4) with one another, and at least one sensor (9). The at least one sensor (9) is embodied as a piezoresistive thin film (19) arranged on a section of a surface (8) of the connecting structure (7). A thin film interconnects contact points (15, 16), of at least two conductive sections (13, 14) which are integrated in the connecting structure (7), to one another.

A load sensor system including one or more of a vehicle suspension including a pair of beams outwardly extending from a vehicle axle, a pair of air suspension assemblies correspondingly coupled between the pair of beams and a vehicle frame, where each of the air suspension assemblies includes a load sensor capable of generating a load signal, a load sensor computer communicatively coupled to the load sensor having a load sensor program including a load calculator, and a central computer communicatively coupled to the load sensor computer having a central program executable to receive the load calculated by the load sensor computer.

An additional spring for a shock absorber of a motor vehicle and a damper bearing for a shock absorber of a motor vehicle. In this case, the additional spring includes a first spring body which has a central hole for guiding through a piston rod of the shock absorber. The first spring body is formed spherical on an end face. The damper bearing according to the invention comprises a cylindrical receptacle space in which the first spring body of the additional spring is retained at least in certain regions, and is distinguished in that the receptacle space has a spherically formed base surface formed corresponding to the end face of the first spring body.

An ultrasound transducer with at least one piezoelectric oscillator, a damping compound and at least one electrically conductive conducting element that is in contact with the piezoelectric oscillator. The damping compound in an ultrasound transducer encloses at least the at least one conducting element, and the composite structure of the at least one conducting element and of the damping compound is designed such that the composite structure is in contact over an area with the piezoelectric oscillator, and forms a support on the side of the ultrasound transducer that faces away from the piezoelectric oscillator on which the ultrasound transducer can be supported.

A vibration device includes a vibration element that has a plurality of terminals, a base that has a plurality of electrical connection terminals, and a board that has a wiring portion which electrically connects the plurality of electrical connection terminal and the plurality of terminals to each other, and that supports the vibration element with respect to the base. The board has a base fixing portion fixed to the base, a vibration element mounting portion on which the vibration element is mounted, and at least one beam portion which couples the base fixing portion and the vibration element mounting portion to each other. At least the one beam portion has a first portion which extends in a first direction and a second portion which extends in a second direction intersecting the first direction.

A piezo-electric air spring, comprising an air spring and a piezo-electric sensor for generating electrical charges to determine the weight of a semi-trailer.

An elastic support for on-board suspension systems of a motor-vehicle includes at least one body formed of polymeric elastomeric material supplemented with carbon-based nanofillers. An outer surface is provided with one or more piezo-resistive areas where a polymeric material supplemented with carbon-based nanofillers has been made locally piezo-resistive by laser irradiation so as to define one or more electric deformation sensors configured to detect the load applied on the elastic support.

A chassis component (1) for a wheel suspension having at least two pivot points (3, 4), at least one connecting structure (7) which interconnects the pivot points (3, 4) with one another, and at least one sensor (9). The at least one sensor (9) is embodied as a piezoresistive thin film (19) arranged on a section of a surface (8) of the connecting structure (7). A thin film interconnects contact points (15, 16), of at least two conductive sections (13, 14) which are integrated in the connecting structure (7), to one another.

A vehicle suspension system having a twist beam axle including a crossbeam and two trailing arms connected thereto. The rear ends of each trailing arm, in the motor vehicle longitudinal direction, having with a wheel mount for fastening a motor vehicle wheel. The front ends of each trailing arm connected via a bearing to the motor vehicle body. Each bearing associated with a MEMS designed as an actuator wherein movements of the bearings and therefore the twist beam axle about the vertical motor vehicle axis can be caused or unfavorable movements of the twist beam axle can be counteracted.

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.