A system is used with a pneumatic tire mounted on a wheel rim to keep a tire cavity of the pneumatic tire from becoming underinflated from a set pressure. The first system includes a plurality of pumps attached circumferentially to the wheel rim, each pump having a piston for inflating the tire cavity and a weight for moving the piston, and a stop mechanism for each pump, the stop mechanism including a stop piston, a stop cylinder, a first spring, and a second spring, when air pressure in the tire cavity reaches the set pressure, the set pressure overcomes a force of the first spring against the stop piston and moves the stop piston into a stopping engagement with the weight, when air pressure in the tire cavity is below the set pressure, the second spring overcomes the force of the first spring and moves the stop piston away from the weight.

A system for tire inflation including a drive mechanism defining a rotational axis, including an eccentric mass that offsets a center of mass of the drive mechanism from the rotational axis along a radial vector; a pump arranged radially distal the rotational axis of the drive mechanism, including a chamber defining a chamber lumen, and a reciprocating element arranged at least partially within the chamber lumen and translatable along a pump axis; a drive coupler coupled between the drive mechanism at a first position and the reciprocating element at a second position fixed to the reciprocating element; a torque regulation mechanism; and a controller, communicatively coupled to the torque regulation mechanism; wherein the system is operable between at least a first mode and a second mode by the torque regulation mechanism in cooperation with the controller.

A system for tire inflation including a drive mechanism defining a rotational axis, including an eccentric mass that offsets a center of mass of the drive mechanism from the rotational axis along a radial vector; a pump arranged radially distal the rotational axis of the drive mechanism, including a chamber defining a chamber lumen, and a reciprocating element arranged at least partially within the chamber lumen and translatable along a pump axis; a drive coupler coupled between the drive mechanism at a first position and the reciprocating element at a second position fixed to the reciprocating element; a torque regulation mechanism; and a controller, communicatively coupled to the torque regulation mechanism; wherein the system is operable between at least a first mode and a second mode by the torque regulation mechanism in cooperation with the controller.

An air maintenance system for use with a pneumatic tire is described. The air maintenance system includes a pumping mechanism that is preferably mounted on the interior surface of a wheel rim to keep the pneumatic tire from becoming underinflated. The pumping mechanism includes at least one dual chamber pump, preferably at least two dual chamber pumps configured in series. More preferably, the dual chamber pumps are driven by an external mass that moves as the tire rotates. The tire's rotational energy operates the pump to ensure the tire cavity is maintained at the desired pressure level. An optional control valve shuts off airflow to the pumping mechanism when the tire cavity pressure is at the desired level.

An air maintenance tire assembly includes a tire having a tire cavity bounded by first and second sidewalls extending to a tire tread region and air pumping means for generating pressurized air for maintaining air pressure within the tire cavity at a preset pressure level. The air pumping means includes an upper mounting plate fixed to a vehicle rim, a lower mounting plate fixed to the rim and diametrically opposed to the upper mounting plate, a dynamic mass pivotally attached to the upper mounting plate at a first end of the dynamic mass, and a pump fixed to the lower mounting plate and pivotally attached to a second end of the dynamic mass.

Disclosed herein are systems, methods, and computer-readable storage media for gravity-driven pumps, gravity-driven power generators that power electric pumps, as well as various supporting concepts, mechanisms, and approaches. As a tire rotates around an axle, the pull of gravity varies for a given point on the tire. While gravity is always pulling down, the force relative to a fixed point on the tire changes. Gravity-driven pumps exploit these changes in gravitational force to do work. Automatic, gravity-driven pumps can be used to inflate tires to offset the natural gas leakage of modern tires, and can maintain tire pressure and inflation within a desired or optimal range. As different conditions are met, pump parameters are determined which can adjust the pumps. Such conditions include driving patterns, load, and temperature, and resulting adjustments include turning on and off pumps, varying stroke length, and varying the number of strokes required.

Systems and methods for accommodating gravity based devices within wheel rims. An exemplary method includes identifying a number of the gravity based devices to be contained within the wheel, identifying a type of each of the gravity based devices to be contained within the wheel, identifying, based on the type and the number of the gravity based devices, a location where each of the gravity based devices are to be installed within the wheel (i.e., the air hole locations), and generating holes in the rim, where the number of the holes equals the number of the gravity based devices, and where for each air hole location in the air hole locations a single hole in the holes is generated.

A system is used with a pneumatic tire mounted on a wheel rim to keep a tire cavity of the pneumatic tire from becoming underinflated from a set pressure. The first system includes a plurality of pumps attached circumferentially to the wheel rim, each pump having a piston for inflating the tire cavity and a weight for moving the piston, and a stop mechanism for each pump, the stop mechanism including a stop piston, a stop cylinder, a first spring, and a second spring, when air pressure in the tire cavity reaches the set pressure, the set pressure overcomes a force of the first spring against the stop piston and moves the stop piston into a stopping engagement with the weight, when air pressure in the tire cavity is below the set pressure, the second spring overcomes the force of the first spring and moves the stop piston away from the weight.

An air maintenance system for use with a pneumatic tire is described. The air maintenance system includes a pumping mechanism that is preferably mounted on the interior surface of a wheel rim to keep the pneumatic tire from becoming underinflated. The pumping mechanism includes at least one dual chamber pump, preferably at least two dual chamber pumps configured in series. More preferably, the dual chamber pumps are driven by an external mass that moves as the tire rotates. The tire's rotational energy operates the pump to ensure the tire cavity is maintained at the desired pressure level. An optional control valve shuts off airflow to the pumping mechanism when the tire cavity pressure is at the desired level.

The present invention relates generally to an air maintenance system for use with a tire and, more specifically, to an air maintenance pumping assembly