A vehicle including a chassis, a lift axle coupled to the chassis and including a tractive element, a lift actuator coupled to the lift axle, a location sensor configured to provide location data indicating a location of the vehicle, and a controller operatively coupled to the lift actuator and the location sensor and configured to control the lift actuator to reposition the lift axle based on the location data.

The invention relates to a method of estimating the load on a motor vehicle (10). The motor vehicle (10) having a wheel (12) comprising a tread (20) for rolling over a surface being driven on (14) and a first air chamber (32) in which there is a gas which by means of its gas pressure (G) counteracts de-formation of the tread (20) when the wheel (12) is rolling. The method lets gas into the first air chamber 32 over a predetermined period and estimates the load based on the change in pressure in the chamber. The object under-lying the invention is to provide a means of estimating the load on a vehicle. For this purpose the wheel (12) may have a second air chamber (38) coupled to the first air chamber (32) by a valve device (44), the first air chamber (32) extending between the tread (20) and the second air chamber (38) and the gas may flow from the second air chamber (38) into the first air chamber (32).

A tire inflation system for a work vehicle includes a controller with a memory and a processor, where the controller is configured to perform an iterative process until a stopping condition is reached. The iterative process includes receiving a tire pressure sensor signal indicative of a tire pressure a one tire, receiving a draft load sensor signal indicative of a draft load on the work vehicle, determining a draft load difference between the draft load and a maximum draft load, and outputting a target tire pressure output signal indicative of instructions to adjust the tire pressure of the tire in response to determining that the draft load difference is greater than or equal to a first threshold value. The stopping condition includes determining that the draft load difference is less than the first threshold value, determining that a variation in the draft load between iterations is less than a second threshold value, determining that a maximum runtime is reached, and determining that a maximum number of iterations is reached.

A central tire inflation system that is operably coupled to a vehicle wherein the system is operable to monitor and control the tire air pressure of the vehicle. The central tire inflation system includes a wheel assembly that includes a housing having an annular central portion with opposing arm members extending outward therefrom. The annular central portion includes an interior volume having a valve and a bearing/cap assembly. A controller is further provided wherein the controller includes a central processing unit. A valve is disposed within the controller and is operably coupled to three ports wherein a first port provides a fluid connection to the wheel assembly. The central tire inflation system further includes a control panel having a graphical display operable to provide a user interface for operation of the central tire inflation system. A plurality of operational modes are provide for selection by a user.

A multi-chambered wheel assembly may include a wheel rim and a tire mounted on the wheel rim. The tire and the wheel rim may define an interior chamber. A divider wall may be disposed in the interior chamber. The divider wall may define a fill chamber and a gas cavity. A gas valve may be communicated with the gas cavity. The gas valve may be configured to allow pressurized gas to be introduced into the gas cavity. A fill valve may be communicated with the fill chamber. The fill valve may be configured to allow fill material to be introduced into the fill chamber.

A rapid inflation system is provided for the tires of a machine such as an agricultural machine which must periodically move between field conditions and road conditions. The system can relatively rapidly inflate the tires from a lower field ready state to a higher pressure road ready state by the use of a high pressure reservoir chamber defined within the tire.

A method and system for collision avoidance that goes beyond automatic steering and braking. A trained artificial intelligence (AI)/machine learning (ML) system is used to detect an impending impact event that exceeds a predetermined severity threshold based on received sensor and vehicle operational data. Upon detecting such an impending impact event, vehicle systems are deployed to avoid or lessen the severity of the impending impact event. These vehicle systems include automatic steering and braking, and automatic tire flattening and vehicle anchor deployment which are intended to stop or slow the vehicle before impact.

A tire assembly includes a tire for mounting on a vehicle, an elastic body disposed on an inner side of the tire, and a power generation body disposed between an inner surface of the tire and the elastic body. The power generation body includes a first member and a second member. The first member has a first insulating film forming a first surface. The second member has a second insulating film forming a second surface that faces the first surface and contacts the first surface. The elastic body biases the power generation body toward the inner surface of the tire.

Environmentally friendly electrical vehicles are presented. The electrical vehicles include electrical low speed vehicles (LSVs) that may use sensed location data to obtain one or more operational profiles. The operational profiles may govern the behavior of the LSV in a specific environment, area, or zone to ensure the LSV reduces its impact on the local terrain. The LSV may leverage locally sensed data to form a local context in which the LSV is operating. The LSV's vehicular controller may refine the operational parameters of the operational profile to ensure smooth operation based on local conditions from the local context.

A system (40) for transmitting control pressures and/or working pressures from a wheel-hub pressure medium supply (20, 21, 22), in particular from a wheel-hub pressure medium rotary union (21), to a vehicle rim (2) mounted on the wheel hub (1). The system (40) has a receiving part (41), which has a central region (55) with a central opening (44) and at least one extension region (43) projecting radially from the central region (55), at least in some regions. The receiving part (41) can be connected to the wheel hub (1) by means of the at least one radially projecting extension region (43), in a detachable way, and the control pressures and/or working pressures can be transmitted from the wheel-hub pressure medium supply (20, 21, 22) to the opening (44).