A connecting member and method of forming the connecting member in an air maintenance tire is provided. The method includes providing a tire having a sidewall formed with an annular groove. The groove receives an annular air tube having a first end with a first fitting and a second end with a second fitting. A recess is formed in the tire sidewall along the annular groove at a location where the first end of the annular air tube is adjacent the second end of the annular air tube. A mold formed with a cavity is provided and the fittings are removably secured in the cavity. The mold is positioned on a surface of the tire sidewall and an elastomer or a polymer is introduced into the mold cavity. The mold is heated to form the connecting member on the tire sidewall.

The inflation system includes a pump and a dehumidifier fluidly connected between the pump and a reservoir, such as a tire.

A mounting member for an air maintenance tire is provided. The tire includes a sidewall that is formed with a groove for receiving an air tube and a recess for receiving at least one pneumatic connector that is in fluid communication with the air tube. The mounting member includes a plurality of layers, in which the layers are in stacked alignment with one another. The plurality of layers includes at least an axially outward layer and an axially inward layer. The mounting member is received in the recess and secured to the tire sidewall, thereby securing the position of the at least one pneumatic connector. A method of forming a mounting member for an air maintenance tire is also provided.

A self-inflation device for maintaining pressure in a tire includes a piston compartment, a piston, and an intake opening for fluidically connecting the piston compartment to ambient atmosphere. A valve controls airflow between the piston compartment and the inner space of the tire. Airflow between the piston compartment and the inner space is allowed when the valve is opened and prevented when the valve is closed. The piston is movable within the piston compartment between an air intake position, in which the intake opening fluidically connects the piston compartment and the ambient atmosphere, and a compression position, in which the piston fluidically seals the piston compartment from the intake opening, thereby creating a compression chamber. The piston opens and closes the valve, and cycles between the air intake and the compression positions, through application of centrifugal force onto the self-inflation device by rotation of the tire.

The inflation system includes a pump and a dehumidifier fluidly connected between the pump and a reservoir, such as a tire.

A pumping mechanism in accordance with the present invention is used with a pneumatic tire mounted on a wheel to keep the pneumatic tire from becoming underinflated. The pumping mechanism includes a frame having a first chamber and a pump chamber, a strike plate positioned in the first chamber and being connected to a plunger plate, said plunger plate having a nose for engagement with a diaphragm mounted in the pump chamber; said pump chamber being in fluid communication with a pump inlet and a pump outlet; wherein actuation of the strike plate in the first chamber causes engagement of the nose with the diaphragm. Preferably the strike plate is actuated by a permanent magnet mounted on a stationary part, or the strike plate is actuated by an electrically driven magnet.

A tire inflation system and method for a tire supported by a wheel, the tire inflation system including a pump system including a pump cavity configured to fluidly connect to the tire, an actuating element configured to actuate relative the pump cavity, a drive mechanism rotatably coupled to the wheel, the drive mechanism including a motion transformer and an eccentric mass, a valve fluidly connecting the pump cavity to a fluid reservoir; and a control system configured to operate the valve.

An air maintenance tire system is provided. The tire includes a pair of sidewalls, in which each one of the sidewalls extends from a respective bead area to a crown of the tire. The air maintenance tire includes an annular groove formed in a selected one of the tire sidewalls. The groove is formed with an open end at an outer surface of the tire sidewall and a closed end opposite the open end. The open end is formed with an outward radial taper and the groove is formed with at least one increased diameter feature. An air tube of a peristaltic pump assembly is received in the groove.

A system is used with a pneumatic tire mounted on a wheel rim to keep the pneumatic tire from becoming underinflated. The first system includes a plurality of pumps attached circumferentially to the wheel rim, each pump having pump parameters, and a control valve for controlling inlet air into a tire cavity of the pneumatic tire. The control valve has valve parameters. The system predicts system performance under various configurations and conditions through use of the pump parameters and the valve parameters.

A wheel for an air maintenance tire system is provided. The air maintenance tire system includes at least one pump and a regulator. The wheel includes a body that is formed with an axially-extending wall, a pair of flanges, and a pair of bead mounting areas. Each bead mounting area is disposed axially inwardly proximate a respective one of the flanges. The axially-extending wall is formed with an AMT mounting channel. The AMT mounting channel extends circumferentially about the wheel approximately mid-way between the flanges and is defined by a first adjacent wall, a second adjacent wall, and a base. Mounting surfaces are formed in or adjacent the AMT mounting channel, so that the at least one pump is mounted in the AMT mounting channel radially inwardly of the bead mounting areas.