A valve assembly for a central tire inflation system is provided. The valve assembly includes a first housing having a first port connected to a second port via a cavity. The second port is in fluid communication with a wheel assembly. A biasing member is disposed in the cavity adjacent a first perforation formed in the first housing. A valve member is contacted by the biasing member. The valve member includes a first frustoconical portion having a continuous outer surface connected to a second portion having a continuous outer surface, a first end connected to the second portion and a second end connected to the first frustoconical portion wherein the continuous outer surfaces of the first frustoconical portion and the second portion allow a pressurized fluid to flow between the housing and the outer surfaces of the valve member.

An air valve connecting device includes a housing, a shank slidably engaged in the housing and limited to slide relative to the housing, and prevented from pivoting and rotating relative to the housing, the shank includes one end portion for receiving the pressurized air, a barrel is rotatably engaged with the shank and connected to the housing for detachably securing the inflation valve to the barrel, and a control ferrule is connected to the housing and moved in concert with the housing and the barrel relative to the shank, and the control ferrule is threaded with the shank for forcing and moving the shank toward and to engage with the inflation valve when the control ferrule is rotated relative to the shank.

An air valve connecting device includes a housing, a shank slidably engaged in the housing and limited to slide relative to the housing, and prevented from pivoting and rotating relative to the housing, the shank includes one end portion for receiving the pressurized air, a barrel is rotatably engaged with the shank and connected to the housing for detachably securing the inflation valve to the barrel, and a control ferrule is connected to the housing and moved in concert with the housing and the barrel relative to the shank, and the control ferrule is threaded with the shank for forcing and moving the shank toward and to engage with the inflation valve when the control ferrule is rotated relative to the shank.

Described are valve stems for wheels or other pressure vessels that may be installed from the exterior of a wheel or pressure vessel without access to the interior, pressure retaining areas. The valve stem may include a body with a barrel and taper. A neck may be between the body and a base that includes a flange, a flange landing, and an air aperture. An air channel runs vertically through the valve stem to allow air to pass from one side of the valve stem to another with a valve core or other flow control device. The base of the valve stem may include a groove that allows the valve stem to be installed into a hole by twisting such that the groove may ride along the rim of the hole and guide the valve stem into a fully seated and sealed position.

An air maintenance tire system component protector is provided. An air maintenance tire system includes at least one connecting tube extending between and being in fluid communication with an annular air tube and a valve housing. The protector includes a first end disposed proximate the connection of the at least one connecting tube to the annular tube, and a second end disposed proximate the valve housing. A mid-portion of the protector is disposed between the first and second ends. The protector covers an outboard surface of the at least one connecting tube and the valve housing, and includes means for engaging the at least one connecting tube to secure the position of the tube.

An aspirator assembly for an inflatable device includes an outer housing disposed about an axis, an inner housing disposed about the axis, and a manifold coupled through the outer housing to an annulus located between the inner housing and the outer housing, the manifold providing pressurized gas to said annulus via a plurality of gas ejector nozzles. The annulus may be divided into a plurality of annulus segments by a plurality of vanes protruding radially from the inner housing

A joint contains: a body, at least one locking block, at least one controller, and at least one resilient element. The body has an inlet segment, an outlet segment, and an air channel. The outlet segment has a connection orifice. Each locking block has a tooth and a driving portion. The tooth is controlled to move between a first position and a second position. Between the first position and the second position is defined a reverse driving travel path obliquely extending to the inlet segment. Each locking block also has a coupling shaft. The reverse driving travel path is arcuate, and the driving portion and the coupling shaft are on opposite sides of the tooth. Each resilient element urges the tooth to move to the first position and is pressed so that the tooth moves to the second position along the reverse driving travel path.

A joint contains: a body, at least one locking block, at least one controller, and at least one resilient element. The body has an inlet segment, an outlet segment, and an air channel. The outlet segment has a connection orifice. Each locking block has a tooth and a driving portion. The tooth is controlled to move between a first position and a second position. Between the first position and the second position is defined a reverse driving travel path obliquely extending to the inlet segment. Each locking block also has a coupling shaft. The reverse driving travel path is arcuate, and the driving portion and the coupling shaft are on opposite sides of the tooth. Each resilient element urges the tooth to move to the first position and is pressed so that the tooth moves to the second position along the reverse driving travel path.

Air valve for a pneumatic tire has a threaded shaft between a first end defining an air inlet and an opposite, second end that is located within the bounded space of a tire mounted on a rim. The air passageway through the air valve has at least one outlet at the distal end of the valve that exists the device through a side portion rather than the terminal end of the device. In a preferred embodiment the air passageway is T-shaped so that air flowing into the tire flows in a non-linear path, exiting the air outlets transverse to the air flow through the inlet into the air passageway.

A pneumatic control device is provided designed to work with self-inflating inner tubes and tires, specifically for bicycles or wheelchairs. The device distinguishes a stem assembly and an air control assembly. The device allows users to set a desired pressure and maintains that constant pressure over time, thereby eliminating the need to manually re-fill the tires. The device is compatible with current rims and tires and requires no modification to be installed to existing rims. The device works by regulating the intake of air from the atmosphere into the self-inflating pumping mechanism. Once the desired pressure is reached, the system stops new air from entering the self-inflating mechanism.