A valve assembly may have an inlet configured to receive pressurized fluid, a first port, a diaphragm comprising a first side and an opposing second side, a first one-way valve disposed so as to allow fluid to flow from the inlet to the first side of the diaphragm, and a second one-way valve disposed so as to allow fluid to flow from the inlet to the first port. The first side of the diaphragm may be in fluid communication with the first port and with atmosphere, and the second side may be in fluid communication with the first one-way valve, the diaphragm sealing the first port from the first one-way valve and from atmosphere, such that when fluid pressure in the first port exceeds the fluid pressure at the first valve, the diaphragm may flex to allow fluid to flow from the first port to atmosphere.

A connection arrangement for a tire inflation system. The connection arrangement includes a rotary union and a hose assembly. A main body of the hose assembly is insertable into and removeable from a receptacle cavity of the rotary union when in a first rotational position. A locking protrusion of the hose assembly is received in the locking opening of the rotary union to secure the main body to the rotary union when in the second rotational position.

The air transmission structure includes a statorhaving an annular outer wall with at least one aperture, an air inlet, and an air passage between the air inlet and the at least one aperture on the annular outer wallbiased against the non-rotating spindle. A housing includes interior annular walls mounted in radially spaced relation with the annular outer wall of the stator to form an annular cavity therebetween, and at least one aperture formed through the interior annular wall, and air outlet, and an air passage between the at least one aperture and air outlet. A seal is inserted within the annular cavity and defines a radial air passage between the apertures defined within the stator annular outer wall and the housing interior annular wall. An annular bearing between the stator and housing is configured to allow the housing to rotate with respect to the stator.

A rotary joint assembly including a rotating portion. The rotating portion includes an annular body and a pair of annular sealing members. Each annular sealing member of the pair of annular sealing members is attached to a side of the annular body. An air passageway is formed in the annular body. The rotary joint assembly also includes a non-rotating portion. The non-rotating portion has a non-rotating portion air passageway formed therein. The non-rotating portion air passageway is in fluid communication with the air passageway formed in the annular body. A pair of annular air seal members are provided between the rotating portion and the non-rotating portion. Each annular air seal member of the pair of annular air seal members contacts a sealing surface of one of the annular seal members to provide a seal around an interface between the air passageway formed in the annular body and the non-rotating portion air passageway.

A rotary feedthrough assembly for a tire inflation system for a vehicle is disclosed. The assembly may have a stationary part comprising a first section of a main fluid line and a first section of a pilot fluid line. A rotatable part may be rotatably mounted on the stationary part and configured to support a pneumatic tire. The rotatable part may have a second section of the main fluid line and a second section of the pilot fluid line. A first annular seal chamber may be radially disposed between the stationary part and the rotatable part. The first annular seal chamber may provide fluid communication between the first section of the main fluid line and the second section of the main fluid line. A second annular seal chamber may be radially disposed between the stationary part and the rotatable part. The second annular seal chamber may provide fluid communication between the first section of the pilot fluid line and the second section of the pilot fluid line.

A rotary union for a tire inflation system includes an axle housing and a wheel axle rotatably mounted in the axle housing. The wheel axle has a flange for attachment of a wheel rim. The wheel axle is received by a passage socket that is connected for conjoint rotation to the wheel axle and supported by a radial bearing relative to a bearing seat within the axle housing. A compressed air duct is disposed inside a cylindrical wall of the passage socket such that the compressed air duct is connected at one end to a pressure connector mounted on the axle housing and at the other end to a tire connector mounted on the passage socket. The passage socket is sealed rotationally movably with respect to an adjacent inner side of the axle housing such that an enclosed chamber is formed between the pressure connector and the compressed air duct.

An on-board centralized system for regulating pressure of tyres of a vehicle includes a pressurized air source, two pneumatic rotary joints each associated to a driving wheel of the vehicle, and a circuit that sets in communication the pressurized air source with each rotary joint. An output member of a constant-velocity joint and a wheel spindle have an internal duct for air passage, connected to the respective rotary joint and to a plenum of the respective driving wheel. Each non-driving wheel has its wheel spindle traversed by an axial bore for air passage, connected to the circuit via a pneumatic rotary joint and a plenum of the non-driving wheel, which is connected to the inner chamber of the tyre. Each driving or non-driving wheel has its plenum connected to the inner chamber via two parallel lines, for deflating and inflating, respectively, the tyre interposed in which are respective one-way valves.

An actuator for a tire inflation system, the actuator having a first component that has a first fluid passage and a second component having a second fluid passage and a sealing surface for sealing engagement with a rotatable component of a wheel assembly. The second component is movable relative to the first component between a first position, in which the first fluid passage is isolated from the second fluid passage and the sealing surface is spaced from the rotatable component, and a second position, in which the first fluid passage is in fluid communication with the second fluid passage and the sealing surface is in sealing engagement with a rotatable component.

The present disclosure relates to a wheel valve arrangement (1) for a tire pressure control system of a vehicle, which wheel valve arrangement (1) comprises a pneumatically switchable wheel valve (2) and a shuttle valve (3) operating on the pressure balance principle as a vent valve, the control input (6) of which is to be connected to a tire connection channel (7) leading to a tire interior, and the input (4) of which is to be connected as control input to an air supply line. Said wheel valve arrangement (1) is characterized by the fact that the pneumatically controllable wheel valve (2) is connected into the tire connection channel (7) for closing and opening a fluid path between the shuttle valve (3) and a wheel connection (9) belonging to the wheel valve arrangement (1), which wheel valve (2) has a valve body (17) which can be moved by a piston rod (19) which, by means of a least one spring element (24), acts against the valve seat (13) assigned thereto in the closed position and which can be moved by the piston rod (19) into an open position moved away from the valve seat (13), and has a control piston (22) guided in a control cylinder (21) and connected to the piston rod (19), which control cylinder (21) is to be connected or is connected by the control chamber (28) of the control cylinder delimited by the drive side of the control piston (22) via the control line (29) to the supply line (5) on the input side of the shuttle valve (3), wherein the control piston (22) is designed in order that the valve body (17) can be moved away from the valve seat (13) of the valve body by means of the target tire filling pressure present in the air supply line (5) in order to open the wheel valve (2). The present disclosure further relates to a tire pressure control system for a vehicle having such a wheel valve arrangement.

A tire pressure management system includes at least an axle, a hubcap supported by the axle and having an interior and an exterior, and a rotary union mounted to the hubcap. The rotary union includes at least rotary union housing providing a central bore, a fluid conduit having upstream and downstream ends, and a bearing in contact engagement with the fluid conduit via an inner race of the bearing, and in sliding engagement with a bearing sleeve via an outer race of the bearing. The bearing sleeve in pressing contact with the central bore; and a seal, is disposed between the bearing and the downstream end of the fluid conduit.