A spindle sleeve and washer for adjusting the camber, toe, or thrust angle of a vehicle wheel to a desired predetermined angle which allows for use of existing hub and spindle assembly without permanent modification to the vehicle.

A vehicle including a frame having an axle and a support apparatus coupled thereto. The support apparatus is configured to support a load coupled to the axle and permit the load to translate along an x-axis, a y-axis, and a z-axis.

The Lateral Trailer Suspension Support Device system is a suspension support that locks the axles of a trailer into the frame of the trailer, similar to a track bar on a truck. It is a lateral trailer suspension support device for reducing lateral loading of a trailer body having a wheeled axle comprising a frame rail connectively attached to said trailer body, a rigid member having a frame connection end having a first flexible joint connectively attached to said frame rail and an axle connection end having a second flexible joint connectively attached to said wheeled axle. It prevents and decreases lateral loading on all types of trailers. It can be used on single, tandem, and triple axle trailers.

Driven lift axles and associated systems and components are provided for use on heavy duty trucks, trailers, and/or other vehicles. Driven lift axle systems may include one or more motors mounted to the lift axle to provide torque to drive one or more wheels of the lift axle. Various mounting configurations of such motors are possible, such as arranging a motor on the axle to provide torque at a conventional driveshaft input by interfacing with a differential drive gear, positioning a motor at each of the wheel ends of the axle to provide torque directly to the wheels, etc. Each wheel can be driven by a separate motor, allowing for independent control of the torque applied to each wheel. Lift axles described herein can be suitable for use with various motors capable of applying torque to the axle and/or wheels, such as electric motors, hydraulic motors, internal combustion engines, etc.

Driven lift axles and associated systems and components are provided for use on heavy duty trucks, trailers, and/or other vehicles. Driven lift axle systems may include one or more motors mounted to the lift axle to provide torque to drive one or more wheels of the lift axle. Various mounting configurations of such motors are possible, such as arranging a motor on the axle to provide torque at a conventional driveshaft input by interfacing with a differential drive gear, positioning a motor at each of the wheel ends of the axle to provide torque directly to the wheels, etc. Each wheel can be driven by a separate motor, allowing for independent control of the torque applied to each wheel. Lift axles described herein can be suitable for use with various motors capable of applying torque to the axle and/or wheels, such as electric motors, hydraulic motors, internal combustion engines, etc.

This disclosure is directed to suspension assemblies for vehicles. More specifically, this disclosure is directed to secondary springs for suspension assemblies of vehicles. In some embodiments, a secondary spring can comprise a base, a tip, and one or more extension members positioned between the base and the tip that are configured to be removably coupled to the base and/or the tip to adjust a length of the secondary spring. In some embodiments a user can adjust the length of the secondary spring, so that the secondary spring is compatible with a given coil spring of the suspension assembly, by increasing or decreasing the number of extension members included in the secondary spring and/or by replacing one or more of the extension members with longer or shorter extension members.

A system for monitoring payload of a vehicle includes at least one wireless transmitter comprising a piezo-resistive pressure sensor, a transceiver and a battery unit, encapsulated in an insulating casing, the at least one wireless transmitter being configured to be attached to an axle beam of the vehicle and to emit a wireless signal in response to a mechanical strain of the axle beam, a wireless receiver configured to receive the wireless signal from the at least one wireless transmitter.

A vehicle rigid axle with an axle beam, at the ends of which axle journals or wheel carriers, respectively, are arranged, and with at least two trailing arms rigidly attached to the axle beam and with at least one air spring bellows assigned to the respective trailing arm. At least one component of an electric drive is placed in the hollow body, the drive shaft of which passes through the axle journal. To form at least one axle journal connection section extending between the two trailing arms, a trailing arm connected thereto and a receptacle for at least one component of an electric drive, two shell elements are formed from sheet metal and connected to one another, in particular welded, to form a hollow body surrounding the receiving space. At least one component of the electric drive is mounted in the receiving space.

A vehicle rigid axle with an axle beam, at the ends of which axle journals or wheel carriers, respectively, are arranged, and with at least two trailing arms rigidly attached to the axle beam and with at least one air spring bellows assigned to the respective trailing arm. At least one component of an electric drive is placed in the hollow body, the drive shaft of which passes through the axle journal. To form at least one axle journal connection section extending between the two trailing arms, a trailing arm connected thereto and a receptacle for at least one component of an electric drive, two shell elements are formed from sheet metal and connected to one another, in particular welded, to form a hollow body surrounding the receiving space. At least one component of the electric drive is mounted in the receiving space.

A vehicle component such as an axle spindle or suspension beam (3) is connected to a tubular vehicle axle (1) by fitting a connector sleeve (2) onto the axle and subjecting the assembly to a crimping operation in which plural depressions (206,2018) are formed by indentation in the connector sleeve and the axle wall at the connection region (11,12) to fix the connector sleeve on the tubular axle. In the described proposals a solid lubricant (4) such as molybdenum disulphide is applied at the connection region between the connector sleeve (2) and axle (1), before crimping. The further vehicle component (3) is then connected to the connector sleeve (2) by welding.