A tire air pressure deflation system comprising an air delivery system having gas communication with at least one vehicle tire, the air delivery system maintaining the desired tire pressure, and an adjustable air control system adapted to control the air pressure maintained in the air delivery system and supply or expel the air from the tire, the air control system having a starting pressure setting, and a finishing pressure setting lower than the starting pressure setting, the finishing pressure setting having an active pressure setting lower than the finishing pressure setting. Upon activation of the tire air pressure deflation system, the tire deflates to the active pressure setting and the air control system deactivates upon reaching the finishing pressure setting.

A high temperature warning system for a vehicle steer axle an air pressure supply, a normally-closed valve in fluid communication with pressure supply, a heat sensitive control capable of opening the normally-closed valve upon a predetermined temperature, the heat sensitive control mounted adjacent to the wheel end assembly in a heat exchange relationship therewith, and a warning system connected to the air pressure supply for actuation upon opening of the normally-closed valve.

A steer axle spindle may have one or more channels formed therein. A rotary union may be mounted to a steer axle wheel end assembly. The rotary union may be sealingly connected to a pressurized fluid source through the channel, and sealingly connected to a vehicle tire.

A computer implemented method of determining a tire pressure is disclosed including the steps of receiving data of a recent stable point comprising both a tire gas pressure and a temperature; receiving data of a desired temperature, at which a current pressure is desired to be determined; and determining the current pressure based on the data of the recent stable point and the desired temperature.

The present invention is a system for controlling the dynamic performance of wheels on an agricultural vehicle. A sensor is mounted on the agricultural vehicle that generates a signal corresponding to the deflection of the tire as the wheel is traveling along a surface. A controller receives the signal corresponding to the deflection of the tire and generates a control signal to an air regulator to either supply additional air to or remove air from the tire. An additional sensor may provide a signal corresponding to a variable load carried by the agricultural vehicle. An accelerometer may also be mounted on the agricultural vehicle and provide to the controller a signal corresponding to acceleration perpendicular to the surface. The controller is further configured to generate control the air regulator as a function of the varying load on the agricultural vehicle and/or based on the signal from the accelerometer.

An agricultural vehicle and method of controlling the same are provided, the vehicle having a motive power unit providing a driving torque to at least one driven wheel and having at least one tire or track frictionally coupled with the periphery of the driven wheel. A vehicle operating parameter is controlled in dependence on the driving torque and a slippage characteristic relating the respective driving torque at which the frictional coupling between driven wheel and tire or track begins to slip for a range of vehicle operating parameter values. The operating parameter is suitably a tire pressure or track tension, and the control may involve reducing driving torque or increasing pressure/tension to prevent slipping.

A vehicle and method for controlling the vehicle changes the transparency of each of a plurality of objects overlapping one another at a point on a three-dimensional map image according to the intensity of detected pressure. The vehicle may include a storage configured to store map information; a display configured to display a three-dimensional map image from a point of view based on the map information; an input device including a pressure input device configured to detect intensity of pressure; and a controller configured to control the display to change transparency of the overlapping objects at the same point on the 3D map image according to the intensity of the detected pressure.

A tire management system includes a control valve and a check valve. A method for managing a tire includes: determining a pressure parameter value, determining an operational parameter for a valve based on the pressure parameter value, and controlling the valve based on the operational parameter.

A system for changing pressure in one or more tires of a self-propelled agricultural machine according to a load differential determined using load sensors on opposing locations of the machine. A load differential may be caused by a disproportionate distribution of forces and/or weight on the machine. Load sensors proximal to the tires may allow determining corresponding loads on the tires and, in turn, the load differential. As a result, tires experiencing greater loads may be inflated, whereas tires experiencing lesser loads may be deflated. In addition, a Human Machine Interface (HMI) may be provided in the operator cab to allow an operator to have further control over tire inflation on the fly while operating the machine.

A fore-aft self-balancing personal transportation device having a single wheel structure with multiple air chambers and air pressure equalization between the air chambers. Embodiments include dual tires on a single rim structure, or a single tire structure with multiple lobes, etc. Air passage between the air chambers may be internal through the rim or external via an air hose or related structure. The air chambers may be tubed or tubeless. Several different embodiments are disclosed.