Embodiments of the present invention describe a recreational vehicle spindle, including a spindle body having one or more sockets in the spindle body, and an upper attachment mechanism in contact with the spindle body and adapted to attach to a steering component. The spindle also includes a lower attachment mechanism in contact with the spindle body and adapted to attach to a ski or wheel. The one or more sockets are adapted to each receive a ball and stud forming one or more ball joints.

A wheel suspension (1), for a motor vehicle, having a hub carrier (2) for holding a wheel (3), a wheel-guiding link (4) for an articulated connection of the hub carrier (2) to a body (6), and a steering rod (8) for steering the wheel (3). The hub carrier (2) and the wheel-guiding link (4), for steering the wheel (3), are pivotally connected to each other such that the hub carrier (2) can be swiveled about a steering axis relative to the wheel-guiding link (4). The hub carrier (2) is directly connected to the wheel-guiding link (4), in a first connection area (20), and the hub carrier (2) is indirectly coupled to the wheel-guiding link (4), in a second connecting area (21), via an integral link (5) connected to a chassis element (12).

A machine includes a frame, a suspension system mounted to the frame and including a plurality of struts, and a payload distribution monitoring system supported by the frame. The payload distribution monitoring system includes pressure sensors respectively arranged with the struts, a computer-readable medium bearing a payload distribution monitoring program, a controller, and an interface device. The controller is in operable communication with the pressure sensors to receive their signals and configured to execute the payload distribution monitoring program. The interface device is in operable communication with the controller and configured to display the payload distribution monitoring program's graphical user interface. The payload distribution monitoring program is configured to monitor the strut pressure signals for an unbalanced loading condition that occurs when a relative strut pressure differential, which is computed using the strut pressure signals from the pressure sensors, exceeds a differential limit.

A system for wheel alignment provides an indexable pair of washers in conjunction with a sleeve having non-concentric inner and outer surfaces that allow for adjustments to camber, toe, and thrust. The system can be retrofitted to existing axle systems using a sleeve that fits over the spindle of the axle. Rotation of the sleeve relative to the spindle provides for adjustment to wheel alignment. The indexable washers can be used to determine the precise amount of adjustment and fix the position of the sleeve once adjusted. The system can be implemented regardless of the circumferential position (i.e. azimuthal orientation) of a keyway or groove on the axle spindle that is typically used to lock the position of the axle nut.

Various suspension systems for vehicles are described that preferably comprise a multi-link suspension where one or more of the links can move independently of the other links. The multiple independent links are connected to an upright, vertical load reaction that is decoupled from horizontal load reaction, thus delivering a more comfortable ride and reduced feedback to the driver or operator of the vehicle. By eliminating that external feedback using the inventive subject matter discussed herein, vehicles can be safer and easier to control in all circumstances.

The invention provides an axle for wheels of a two-track motor vehicle. The axle has, on each vehicle side, a wheel carrier, a damper strut, a transverse link and a transverse leaf spring which controls the wheel at least partially laterally and/or in the vehicle longitudinal direction. The damper strut has a damper tube and a damper piston which can be moved in the damper tube along a damper longitudinal axis. The damper strut is attached by the damper tube to the wheel carrier. The transverse link is attached by a wheel-carrier-side end region to the wheel carrier. The transverse leaf spring extends substantially in the vehicle transverse direction and has at least one wheel-carrier-side end region. The transverse leaf spring is attached by the wheel-carrier-side end region thereof to the damper strut and is supported on the damper strut.

An active chassis for a two-track vehicle provided with a wheel suspension. A wheel carrier carrying a vehicle wheel is connected via connecting rod to the vehicle structure. The camber behavior of the vehicle wheel is defined by a mechanical camber curve of the vehicle wheels that is predetermined by the rigid kinematics of the connected rods, which defines a mechanical adjustment of the camber angle of the vehicle wheel depending on a spring path of the vehicle structure, and which is controllable with an actuator controller which can be controlled by a chassis control device.

A machine includes a frame, a suspension system mounted to the frame and including a plurality of struts, and a payload distribution monitoring system supported by the frame. The payload distribution monitoring system includes pressure sensors respectively arranged with the struts, a computer-readable medium bearing a payload distribution monitoring program, a controller, and an interface device. The controller is in operable communication with the pressure sensors to receive their signals and configured to execute the payload distribution monitoring program. The interface device is in operable communication with the controller and configured to display the payload distribution monitoring program's graphical user interface. The payload distribution monitoring program is configured to monitor the strut pressure signals for an unbalanced loading condition that occurs when a relative strut pressure differential, which is computed using the strut pressure signals from the pressure sensors, exceeds a differential limit.

Embodiments of the present invention describe a recreational vehicle spindle, including a spindle body having one or more sockets in the spindle body, and an upper attachment mechanism in contact with the spindle body and adapted to attach to a steering component. The spindle also includes a lower attachment mechanism in contact with the spindle body and adapted to attach to a ski or wheel. The one or more sockets are adapted to each receive a ball and stud forming one or more ball joints.

Disclosed is a corner module apparatus for a vehicle. The corner module includes a driving unit that provides drive power to a wheel of the vehicle, a braking unit that interferes with rotation of the wheel to generate braking power, and a suspension unit connected to the driving unit. The suspension unit absorbs shock transferred from a road surface. The corner module also includes a steering unit connected to the suspension unit and rotated about a steering axis inclined with respect to the wheel. The steering unit adjusts a steering angle of the wheel.