A tire condition detecting device includes a case, a detecting section, which is accommodated in the case to detect a condition of a tire, an attachment portion provided in the case, an insertion hole, which is provided in the attachment portion and is configured to allow a snap-in valve to be inserted into the insertion hole, and a case-side fitting portion, which is provided in the attachment portion to be positioned outward of the insertion hole in a direction orthogonal to a central axis of the insertion hole, and is configured to be fitted to a clamp-in valve. The snap-in valve inserted into the insertion hole or the clamp-in valve fitted to the case-side fitting portion is attached to the case with a fixing tool.

A tire pressure monitoring system for a vehicle, for ascertaining tire-specific parameters, includes a valve body, at least one fastening element, and a tire inflation pressure sensor with a housing in which is accommodated a sensor for determining at least one tire-specific parameter and for wirelessly transmitting the at least one tire-specific parameter to a control unit on the vehicle. The housing has a fastening region, and the valve body includes a fastening section. The fastening section of the valve body is detachably engaged with the fastening region of the housing with the aid of a fastening element. The fastening element is made as one piece with the housing of the tire inflation pressure sensor from a thermoplastic plastic.

An in-wheel tire pressure system for use with a rim of a wheel of a vehicle that includes a fluid storage area formed in the rim for holding a quantity of compressible fluid suitable for inflating a tire mounted on the rim, and a micro-compressor mounted on the rim for pressurizing the fluid storage area with the compressible fluid. A wireless electrical charging subsystem may also be included for powering the micro-compressor. The wireless electrical charging system may incorporate a first component associated with the rim and rotatable with the rim, and a second component fixedly mounted to a portion of the vehicle closely adjacent the first component. The system may also include a control for enabling user control over the micro-compressor.

A valve stem structure disposed at a rim of a tire of a vehicle for connecting to an electronic tire pressure monitoring device in the tire is provided. The valve stem structure includes a tube, an air core, and a conducting wire. The tube has a first inlet, a first outlet communicating with an inner space of the tire, and a second outlet. The air core is switchably disposed at the first inlet, and a compressed air is injected into the tire via the first inlet and the first outlet by switching the air core. The conducting wire is disposed in the tube, and an end of the conducting wire extends out of the tube via the second outlet to be electrically connected to the electronic tire pressure monitoring device. A power source charges the electronic tire pressure monitoring device via the conducting wire.

A tire-pressure-monitoring system includes a flexible member including a stem and a bulb, a metal tube disposed coaxially in the stem, an attachment member, and a sensor housing fixed to the attachment member. The bulb includes an outer circumferential surface including a groove. The attachment member is adjacent the outer circumferential surface and includes a rib positioned in the groove.

A custom valve stem is adapted to fit in a conventional valve stem opening in a tire rim. The valve stem has a primary air channel for a conventional Schrader-type valve. The valve stem also has a secondary air channel extending within the valve stem between a base of the valve stem and an outlet through the material of the valve stem to atmosphere outside of the valve stem. The outlet can have a screen as a debris air filter. An optional tire pressure monitoring system TPMS sensor couples to the primary air channel independent of the secondary air channel. The secondary air channel comprises an atmospheric hose coupled to an electric air compressor and rechargeable battery disposed within a pressure cavity of the tire for maintaining tire pressure. A motion activated power generator disposed within the pressure cavity recharges the rechargeable electric storage.

A wheel pressure adjustment assembly includes a valve unit that is fluidly coupled to a vehicle wheel. The valve unit is actuatable in an open condition for passing air therethrough to deflate the vehicle wheel. The valve unit is actuatable in a closed condition for inhibiting air from passing therethrough to retain air pressure in the vehicle wheel at a selected pressure. The valve unit is actuatable into an inflating condition for passing air into the vehicle wheel. A compressor is coupled to the valve unit and the compressor is turned on when the valve unit is actuated into the inflating condition. In this way the compressor inflates the vehicle wheel.

Sensor assemblies and systems comprise a housing configured with an electrical sensor device retained therein to protect the sensor device. The housing may include display indicia relating to some aspect of the sensor assembly. The electrical sensor device include electrical components useful for the purpose of monitoring and transmitting desired data relating to operating parameters/conditions of the dynamic article that the sensor assembly is attached with. The data is transmitted wirelessly from the electrical sensor device. The housing is removably attached with a retaining member that is also attached with the dynamic article or an element connected thereto. A receiver external from the dynamic article receives the data to determine such operating parameter/or conditions, when the dynamic article is a vehicle tire, as outside diameter, tread depth, pressure, radial load, vehicle camber and/or toe alignment variations, and tire/vehicle location, which may be stored.

An assembly comprising a tyre valve (2) and an enclosure (3), wherein the enclosure (3) is adapted to receive a gas pressure monitoring unit, wherein the enclosure (3) comprises a hinge joint, the hinge joint having at least one stationary member connected to the enclosure (3), an axle (6) and a rotatable member (4) arranged to at least partially rotate around the axle (6) and wherein the tyre valve (2) is connected to the rotatable member (5) of the hinge joint. The tyre valve (2) is connected to the rotatable member (4) of the hinge joint by a form-fitting connection which secures the tyre valve (2) against movement in a direction towards the rotatable member (4) and in a direction away from the rotatable member (5).

An air induction system for filtering a compressible fluid to an electromechanical component mounted on a wheel of a vehicle. The system may make use of a first plurality of float valves arranged in series in a non-linear first flowpath path, with at least one of the float valves forming an inlet for intaking the compressible fluid into the first flowpath, and one being in communication with an inlet of the electromechanical component. Each of the float valves may have a buoyant float valve element therein which is responsive to change position when submerged in water, to close off its respective float valve depending on an angular orientation of the wheel, and thus an angular orientation of the float valve.