A method, apparatus and vehicle for controlling a ride level for a vehicle having at least one first axle having a first air suspension and/or one second axle having a second air suspension, a parking brake and an operating brake, including: reading a ride level variation signal, indicating a ride level variation to be performed; providing a parking break release signal to an interface to a parking brake valve that, responding to the ride level variation signal, releases and engages the parking brake installation, the parking brake release signal being for actuating the parking brake valve for releasing the parking brake installation; and providing a first control signal to an interface to a first valve of the first air suspension and/or a second control signal to an interface to a second valve of the second air suspension while using the ride level variation signal for performing the ride level variation.

A work vehicle state detection system includes: a travel state detector provided in a work vehicle having a rotating machine and detecting a travel state of the work vehicle; a vibration sensor in the rotating machine; a travel state data acquisition unit acquiring travel state data indicating the travel state; a condition satisfaction determination unit determining whether the travel state satisfies a condition; a vibration detection data acquisition unit acquiring vibration detection data indicating a detection value of the vibration sensor when the travel state satisfies the condition; a normal vibration data storage storing normal vibration data indicating a detection value of the vibration sensor when the rotating machine is normal and the travel state satisfies the condition; and an analysis unit that, based on the vibration detection data and the normal vibration data, analyzes a state of the rotating machine when the vibration detection data is acquired.

A suspension assembly for a bicycle is disclosed. The suspension assembly may be configured to use a volume of fluid in a fluid circuit for damping may comprise a volume compensator such as a bladder configured to provide an expandable volume to contain fluid in the fluid circuit and a relief valve configured to open to facilitate the flow of fluid through the relief valve rather than entering the volume compensator. The relief valve may be configured to open at a threshold setting. The volume compensator may comprise an expandable bladder. The threshold setting of the relief valve may be selected to prevent failure of the expandable bladder. The volume compensator and the valve may be contained in the fork assembly. The valve may be configured to open to facilitate the flow of fluid through the valve rather than expanding the volume compensator.

Self-propelled vehicles that adjust the pitch of the vehicle during use are disclosed. The vehicle may include a suspension system position sensor and a control unit that adjusts a suspension element based at least in part on a signal from the suspension system position sensor. In some embodiments, the self-propelled vehicle may include an inclinometer for measuring the pitch of the terrain.

An arm end for a trailing arm, in particular for commercial vehicles, comprising a main body which configures a working volume for an air spring system, the main body having an access region which is designed to provide an access into the working volume, characterized in that a large part of the working volume is configured substantially below the access region.

An air spring for a heavy-duty vehicle axle/suspension system comprising a piston, a bellows, and an intermediate chamber integrally formed with the bellows. The bellows has an upper portion, a top plate, and a bellows chamber and is connected to the piston by a band, a bead-in-groove connection, and/or a bayonet connection. The upper portion is reinforced to prevent the bellows chamber from increasing in volume. The intermediate chamber has an optimally sized top plate and a support structure and extends from the piston into the bellows chamber. The intermediate top plate is formed with means for restricted fluid communication between the bellows chamber and the intermediate chamber. The means for restricted fluid communication is not obstructed when it contacts the bellows top plate during jounce events. The support structure is optimized in relation to the top plate.

A modular wheel and suspension assembly (MWSA) to provide mobility to a load for towing. The MWSA can have a fender housing and a suspension arm and suspension mechanism that is rotated toward a pivot arm with a suspension mount that engages with the suspension mechanism and a wheel. The suspension arm can be rotatably attached to the fender housing. A linear actuator can rotate the suspension arm to raise the fender housing while deploying the wheel from the fender housing. Rotating the suspension arm in the opposite direction causes the fender housing to be lowered over the wheel and the load to be lowered as the wheel retracts into the fender housing. The MWSA can have a rotary tongue system with an operable connection to the suspension arm. Rotating the suspension arm lowers and raises a tongue when the wheel is deployed from or retracted into the fender housing.

A hydraulic drop frame trailer for a tow vehicle, the hydraulic drop frame trailer including a trailer frame having two sides and a hitch, a pair of wheels, a first and second frame bracket, a trailer bed mounted over the trailer frame, a first and second pivoting hydraulic cylinder, a plurality of hydraulic hoses, a first and second pivoting arm, an operating station connected to a power supply, a first and second axle-less wheel mount with independent suspension mechanism mounted to the first and second pivoting arm, and a plurality of safety locks, each securing an arm to the trailer frame for locking each rotating arm to the trailer bed during transport.

A method of on-demand energy delivery to an active suspension system is disclosed. The suspension system includes an actuator body, a hydraulic pump, an electric motor, a plurality of sensors, an energy storage facility, and a controller. The method includes disposing an active suspension system in a vehicle between a wheel mount and a vehicle body, detecting a wheel event requiring control of the active suspension; and sourcing energy from the energy storage facility and delivering it to the electric motor in response to the wheel event.

A system for vehicle load management including a processor and a memory in communication with the processor and including instructions that, when executed by the processor, cause the processor to receive a first indicator signal from a first sensor. The instructions further cause the processor to, based at least in part to the first indicator signal, determine a vehicle load intervention. The instructions further cause the processor to, based, on the vehicle load intervention, transmit one or more adjustment signals to cause one or more vehicle load adjustments to occur, the one or more vehicle load adjustments including at least one of at least one lire being inflated, the at least one tire being deflated, a liftable axle being raised, and the liftable axle being lowered.