A method for monitoring an air pressure in at least one tire of a motor vehicle, wherein at least one air pressure in the tire is detected by at least one measuring electronics unit present in the tire and data is transmitted by the measuring electronics unit to a control unit. Depending on the data, the control unit activates components of the motor vehicle to generate optical and/or acoustic signals. The control unit is switched into an after-running mode for a defined period of time when an ignition of the motor vehicle is shut off, in which mode the control unit can continue to receive data from the measuring electronics unit and may activate components of the motor vehicle to generate optical and/or acoustic signals.

A valve stem system includes a valve stem that is fluidly coupled to a tire thereby facilitating the valve stem to selectively inflate and deflate the tire. A sensing unit is coupled to the valve stem and the sensing unit is visible on the valve stem. The sensing unit is in fluid communication with the valve stem to sense air pressure within the tire thereby facilitating the sensing unit to display the air pressure within the tire.

A vehicle wheel illumination assembly includes a light source located on the body of a vehicle near the wheel well and oriented to direct light onto a wheel assembly having a tire. A tire pressure indicator detects tire pressure of the tire. The light source illuminates the wheel assembly with a desired color to indicate a tire pressure status based on the detected tire pressure. A photoluminescent material is located on the wheel assembly and configured to luminesce in response to excitation by the light assembly.

The invention comprises a tire pressure monitoring system. One system comprises a tire pressure monitor that signals to a user with audio alarm and visual alarm. Another component is the use of a tire air pressure balancing device with a safety trigger to ensure that dual tire systems share air but that stop sharing air in the case of rapid air pressure drop as in cases of tire blow out.

A wireless sensor for a wheel end assembly of a heavy-duty vehicle is provided. The wheel end assembly includes a wheel hub and a hub cap mounted on the wheel hub. The sensor includes mounting means disposed in the hub cap. Sensing means are mounted on the mounting means to sense at least one condition of the vehicle. A processor is mounted on the mounting means and is electrically connected to the sensing means to process data from the sensing means. Communication means are mounted on the mounting means and are electrically connected to the processor to communicate the processed data to a user. An electrical energy storage device is mounted on the mounting means and is electrically connected to the sensing means, the processor and the communication means, enabling the sensor to be independent from the vehicle power supply. The sensor also accommodates components of a tire inflation system.

An integrated tire inflation valve comprises an inlet configured to receive air from an air tank, a pressure protection assembly configured to control air flow into the tire inflation system when an air pressure reaches a pre-set pressure level, a valve assembly in fluid communication with the pressure protection assembly, a pressure regulator configured to be adjusted to a desired pressure to thereby allow air through the pressure regulator at a desired level, a flow switch configured to selectively allow air therethrough, and an outlet configured to provide air from the flow switch to one or more tires of a vehicle. The inlet, pressure protection assembly, valve assembly, pressure regulator, flow switch, and outlet are all positioned within a single housing.

A vehicle warning includes a tire pressure monitoring device disposed in each tire of the vehicle. Each tire pressure monitoring device obtains information regarding pressure within the associated tire and communicated the tire pressure information in a wireless manner. A receiver receives the communicated tire pressure information from each tire pressure monitoring device. A processor circuit, associated with the receiver, determines if the communicated tire pressure information from at least one of the tire pressure monitoring devices is significantly less than a tire pressure determined to be safe for vehicle operation and, if so, to generate a warning signal. A body control module, upon receiving the warning signal, automatically activates the hazard lights without driver input.

A tire pressure monitoring system includes tire pressure sensors installed within vehicle tires, a receiver, an alerting device, an electronic input/output device and an electronic controller. The receiver receives tire pressure signals from the tire pressure sensors, The electronic input/output device provides manual input of instruction and data. The electronic controller is configured to monitor tire pressure and in response to tire pressure in each of vehicle tires achieving a change from a first preset tire pressure to a second preset tire pressure the alerting device is operated to alert a person changing the tire pressure that the change has been achieved. The first preset tire pressure corresponds to paved road driving conditions and the second preset tire pressure corresponds to off-road driving conditions.

A computer-implemented method for calculating a tire wear rate of a vehicle, the method comprising obtaining technical data of at least one tire of a vehicle obtaining technical data of the vehicle, obtaining data of at least one in-operational measurement of at least one property of at least one tire of the vehicle; and calculating a tire wear rate based at least in part on the obtained technical data of the at least one tire of the vehicle, the obtained technical data of the vehicle and the obtained data of the at least one in-operational measurement of at least one property of the at least one tire of the vehicle according to a self-tuning mathematical tire wear model.

An assistance method for adjusting the pressure of a tire mounted on a wheel of a motor vehicle having an electronic module adapted to transmit, to an on-board central unit in the vehicle, signals including data representing the pressure of the associated tire, this assistance method includes, in the first place, during an action of adjusting the pressure of a tire, determining, after receiving a number n of initial measurement signals, where n2, the gradient or slope Cd of the straight line representing the variation of the measured value Pm(t) of the pressure as a function of time. Next, on receiving each subsequent measurement signal, the remaining time required to obtain the setpoint pressure Pc is deduced from the ratio |Pc-Pm(t)|/Cd, and, on the expiry of this remaining time, initiating a procedure for managing the cessation of the pressure adjustment, and signaling the end of the adjustment.