Axle load detection system for a commercial vehicle includes a force transmission element and a sensor unit, wherein the sensor unit includes at least one sensor, wherein the force transmission element includes a first assembly area and a second assembly area, wherein the first assembly area is fixed or can be fixed indirectly and/or directly to a vehicle frame of a vehicle of a commercial vehicle, wherein an air spring and/or a control arm is arranged and/or configured to be arranged on the second assembly area, wherein the sensor unit is configured to determine and/or detect a force transmitted via the force transmission element between the first assembly area and the second assembly area in a supporting direction.

An axle/suspension system for a heavy-duty vehicle including a wheel and a sensor. The sensor is operatively connected to an air spring mounted on the axle/suspension system and is capable of detecting a condition of a road or the heavy-duty vehicle. The air spring has a stiffness capable of being altered in response to the sensor and to reduce resonant load variation on the wheel.

A vehicle air spring suspension system includes multiple air springs. Each air spring has at least one volume. A valve is fluidly arranged between at least two volumes of the at least one volume of the air springs. The valve is movable between open and closed positions in response to an input. The at least two volumes are fluidly coupled with the valve in the open position. The at least two volumes are fluidly decoupled with the valve in the closed position. At least one vehicle sensor is configured to detect a vehicle attitude condition. A controller is in communication with the valve and the at least one vehicle sensor. The controller is configured to provide the input and selectively adjust the air springs to change the vehicle attitude by raising and/or lowering at least one vehicle wheel relative to a vehicle chassis in response to the input.

An air spring suspension system includes a first air spring that has a first volume with a first pressure that is configured to provide a first spring stiffness to a first suspension assembly. A second air spring has a housing with a second volume with a second pressure that is configured to provide a second spring stiffness to a second suspension assembly. The second air spring includes a piston that is arranged in the second volume. One of the housing and the piston includes a first mounting structure that is configured to connect to a vehicle chassis. Another of the housing and the piston includes a second mounting structure that is configured to connect to the second suspension assembly. The second air spring also includes a fluid connection on the housing. The second air spring further includes a crosslink valve that is disposed in the housing and movable between open and closed positions. The crosslink valve is configured to selectively fluidly connect the second volume to the fluid connection. A crosslink line is fluidly connected to the first volume of the first air spring and the fluid connection on the second air spring. A controller is in communication with the crosslink valve. The controller is configured to command the crosslink valve between the open and closed positions in response to an input.

An air spring for a motor vehicle having a rolling bellows filled with gas under pressure, one end of the rolling bellows is connected to a load receiver and the other end is fastened to a roll-off piston. The load receiver and the roll-off piston are moveable relative to one another depending on a force impinging on the load receiver toward the roll-off piston. A sensor device is arranged inside the rolling bellows by which a distance between the load receiver and the roll-off piston is detected. A pressure piece extending in direction of the roll-off piston is arranged at the load receiver and a sensor body is movably drivable along a sensor track of the sensor device by an end region of the pressure piece facing the roll-off piston. The sensor device generates an electric signal corresponding to the position of the sensor body on the sensor track.

An air management system for a vehicle having a first pneumatic circuit and a second pneumatic circuit, in which the first and second pneumatic circuits are pneumatically connected in a neutral position via a cross-flow mechanism. The first pneumatic circuit is configured to independently adjust air pressure of a first side of the vehicle. The second pneumatic circuit is configured to independently adjust air pressure of a second side of the vehicle. The system is configured to establish pneumatic communication between the first and second pneumatic circuits when the air management system is not independently adjusting the adjust air pressure of the first side of the vehicle and the air pressure of the second side of the vehicle in the cross-flow mode.

A shock absorber assembly for cycling includes a shock absorber (2a, 2b) for connecting two subassemblies that are movable relative to each other, and a distance sensor (15) that is fixedly disposed in the interior of, or on, the shock absorber or on one of the two subassemblies. The distance sensor senses, detects or determines measurement values that represent a momentary spacing between the two subassemblies, which spacing varies during cycling. The distance sensor (15) may be a time-of-flight sensor that uses light in the ultraviolet, visible or infrared wavelength range. A bicycle (1), such as a mountain bike or a racing bike, may include such a shock absorber assembly mounted thereon.

A jounce bumper can be dimensioned for securement along an end member of a gas spring assembly adjacent a sensing device. The jounce bumper can include a bumper body with a sensing passage extending their through such that the sensing device can communicate through the sensing passage. A gas spring assembly including a sensing device and such a jounce bumper as well as a suspension system including one or more of such gas spring assemblies are also included.

Technology is provided for a pneumatic anti-roll system for use on a vehicle suspension. The pneumatic anti-roll system includes left and right side air springs connectable between a chassis of the vehicle and an axle of the vehicle suspension. Left and right side height control valves are mounted to the chassis and left and right side linkages connect between the left and right side height control valves and corresponding left and right end portions of the axle. Left and right side control air lines connect between the left and right side height control valves and corresponding left and right side air springs, respectively.

A vehicle suspension arrangement includes mounting brackets configured to couple to a vehicle frame assembly, trailing arms coupled to the mounting brackets, a first axle member coupled to the trailing arms, an air spring arrangement coupled to the vehicle frame assembly and one of the trailing arms, and an air spring arrangement, wherein the first end, the second end and the air spring arrangement cooperate to define an interior space, a second axle member spaced from the first axle member, a sensor arrangement position within the interior space and configured to sense an operational parameter of the air spring arrangement, and a control arrangement operably coupled to the sensor arrangement and configured to receive information from the first sensor arrangement, wherein the control arrangement is configured to control at least one operational characteristic of the second axle member based upon the information received from the sensor arrangement.