Self-Inflating Pumping Mechanism

Abstract

A compression device for a self-inflating tire is provided that includes a first surface made from a flexible memory material, where the first surface is mechanically connected to a pumping chamber, where the first surface includes a first arm, a second arm and a fulcrum along an X-Y plane, where the fulcrum is disposed between the first arm and the second arm, an arc-shape length along a Y-Z plane that is configured to conform to an inner surface of a tire, a first state, where when in the first state, the first surface conforms to an unloaded, pressurized inner surface of the tire, and a second state, where when in the second state, the first surface collapses radially outward about the fulcrum by the first arm and the second arm, where air is drawn in from the atmosphere and pushed through the pumping chamber into the tire.

Claims

1. A compression device for a self-inflating tire, comprising a first surface made from a flexible memory material, wherein said first surface is mechanically connected to a pumping chamber, wherein said first surface comprises: a. a first arm, a second arm and a fulcrum along an X-Y plane, wherein said fulcrum is disposed between said first arm and said second arm; b. an arc-shape length along a Y-Z plane that is configured to conform to an inner surface of a tire; c. a first state, wherein when in said first state, said first surface conforms to an unloaded, pressurized inner surface of said tire; and d. a second state, wherein when in said second state, said first surface collapses radially outward about said fulcrum by said first arm and said second arm, wherein the change between said first state and said second state results in air being drawn in from the atmosphere and pushed through said pumping chamber.

2. The compression device according to claim 1, wherein a second surface is disposed on said first surface, wherein said second surface comprises an elastic material having a curved cross section in an X-Y plane and an arc-shape length along a Y-Z plane.

3. The compression device according to claim 1, wherein said pumping chamber comprises a pneumatically sealed pumping chamber.

4. The compression device according to claim 1, wherein said pumping chamber is configured to house a pneumatically sealed lumen.

5. The compression device according to claim 1, wherein said arc-shape length spans an entire circumference of said inner tire surface, or spans a segment of said circumference of said inner tire surface.

6. The compression device according to claim 1, wherein said fulcrum comprises a hinge.

7. The compression device according to claim 1, wherein said fulcrum comprises a reduced-thickness of said flexible memory material relative to a thickness said second arm and said first arm.

8. The compression device according to claim 1, wherein said second surface and said first surface are anisotropic having greater rigidity in said X-Y plane compared to said Y-Z plane.

9. The compression device according to claim 1, wherein said compression device is irremovably attached to an inner tube.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0013] FIGS. 1A-1B show a compression device for a self-inflating tire, according to one embodiment of the invention.

[0014] FIGS. 1C-1D show a compression device spanning a partial tire circumference and a complete tire circumference, respectively, according to embodiments of the invention.

[0015] FIG. 1E shows a compression device implemented to a tire and inner tube, according to embodiments of the invention.

[0016] FIG. 2 shows a mechanical model of the compression device depicted as a 4-bar mechanism, according to one embodiment of the invention.

[0017] FIG. 3 shows the compression device with the compression cavity forming a shell and a sealing element therein, according to one embodiment of the invention.

[0018] FIG. 4 shows the compression device with the compression cavity forms a shell and a separate lumen inserted therein, according to one embodiment of the invention.

[0019] FIG. 5 shows the compression device having a separate second surface and pumping chamber integrated into the inner tube extrusion, according to one embodiment of the invention.

[0020] FIGS. 6A-6B show the compression device implemented in a tire with an inner tube and without an inner tube, respectively, according to embodiments of the invention.

DETAILED DESCRIPTION

[0021] The invention is a self-inflating pumping or compression mechanism for use on bicycles and other similarly wheeled applications. In one embodiment, the compression mechanism rests on the inside surface of the tire. As the tire rolls and deforms under the wheel's load, the pumping mechanism collapses and pushes air into the tire. When the tire returns to its original shape, the pumping mechanism returns to its original shape drawing in air from the atmosphere. The pumping mechanism runs circumferentially around the inside of the tire. The invention employs rigid lower surface having lever arms that are split along the lower surface length allowing the lever arms to move easily about a fulcrum while retaining excellent ride quality.

[0022] A self-inflating tire system draws in air from the atmosphere and pushes it into the tire while the tire is in motion. A series of one or more check valves ensure the air moves only one way through the system. In one embodiment, a compression device is provided that is disposed in the tire, where the compression device operates on a lumen, or has a lumen structure as part of the device, that is pneumatically in contact with the atmosphere.

[0023] According to one embodiment, FIGS. 1A-1B show the compression device for a self-inflating tire that includes a second surface made of an elastic material having a curved cross section in an X-Y plane and an arc-shape length along a Y-Z plane, where the length along the Y-Z plane is configured to conform to an inner surface of a tire. The device further has a first surface made of a flexible memory material that is disposed on the second surface, where the first surface includes a cross section in the X-Y plane having a second arm, a first arm and a fulcrum, where the fulcrum is disposed between the second arm and the first arm. According to the invention, FIGS. 1C-1D show the device having an arc-shape length along the Y-Z plane that is configured to conform to the inner surface of the tire, where shown is the compression device spanning a partial tire circumference and an entire circumference, respectively. As shown in FIG. 1A, the invention has a second state where a cross section of the second surface and first surface includes a pumping chamber disposed there between, and FIG. 1B shows the device having a first state where the second surface and first surface collapses the pumping chamber according to movement by the second arm and the first arm about the fulcrum, where collapsing the pumping chamber forms a pumping element for the self-inflating tire.

[0024] In one embodiment, FIG. 2 shows a mechanical model of the compression device depicted as a 4-bar mechanism. As shown, the hinges incorporated into the compression device to enable the compression device to move more freely. In further embodiments, the compression device incorporates living hinges of the same material or of different materials from the second and first arms. The placement of a hinge at the fulcrum is critical to the efficiency and functioning of the compression device. The hinges at points at the center and ends of the second surface are less important due to the small angle changes in these locations.

[0025] One key aspects of the compression device is the rigidity of the first surface, resulting in excellent ride quality. One would normally expect a rigid material to support the load directly and not flex, since the second and first arms are curved in the X-Y plane and project in an arc along the Y-Z plane. However this is not the case. The second arm and first arm of the first surface create an excellent riding profile without any high spots or ridges. When a load is applied to the wheel the second and first arms bend easily out of the way and allow the force to be concentrated on compressing the pumping chamber as shown in FIGS. 1A-1B and FIGS. 6A-6B.

[0026] As the second and first arms move from the unloaded position to the loaded position, the chamber collapses, thereby pushing air through a sealed chamber, or through a lumen disposed in the pumping chamber, in the direction of rotation. A series of one or more one-way valves ensure the air moves through the self-inflating tire system in one direction. The mechanism is in the unloaded position, herein know as the second state, when the tire is pressurized and not deformed by a load placed on the tire. The mechanism is in the loaded position, herein known as the first state, when the tire is de-pressurized and deformed by a load placed on the tire. The loaded tire flattens and becomes wider in the area of the tire in contact with the riding surface, as shown in FIGS. 1A-1B and FIGS. 6A-6B. It is this shape change that the invention enables pumping of the air. In the unloaded, second state position, the round shape of the tire supports the second and first arms of the compression device. The geometry and material properties of the second and first surfaces support the pumping chamber so it does not collapse in the pressurized environment of the tire. In the loaded, first state position, the second and first arms flatten by rotating about the fulcrum and the included angle of the second and first arms increases 20-60 degrees when viewed from the cross-sectional view of FIG. 1A. In one embodiment, the compression device has been engineered to close when the internal angle opens 20 degrees. Utilizing smaller angle changes allows the compression device to operate when less tire deformation is present. Tires deform less under higher pressure and when supporting less load. The angle change closes the pumping chamber as the second and first arms press on the second surface. Because the second and first lever arms are significantly wider than the second surface, there is considerable force multiplication. This allows the compression device to generate higher pressure than the pressure found in the tire. Increasing the width ratio between the second and first arms and the second surface increases the force multiplication. Another beneficial aspect of the invention is that the pumping chamber collapses horizontally in the same way as the tire. This is beneficial in that the pressure inside the tire works in conjunction with the lever arms to pump the air.

[0027] In further embodiments, the compression device is placed on the outer surface of an inner tube having an integrated pumping chamber, as shown in FIG. 5, or the compression device and pumping chamber are placed outside the inner tube as shown in FIG. 6A. The invention may be used in a tire with an inner tube, as shown in FIG. 6A, or without an inner tube, as shown in FIG. 6B. The lever arms are held in position by the air pressure inside the inner tube, as shown in FIG. 6A, or the inside surface of the inner tube as shown in FIG. 5. In the embodiment shown in FIG. 6A, the compression device is positioned outside the inner tube and is held in position by the outside of the inner tube and the inside surface of the tire. In the case where no inner tube is used, as shown in FIG. 6B, the compression device is held in place by the pressure inside the tire. The bottom surface of the second and first arms conforms to the pressurized, un-loaded shape of the inside of the tire. The invention may also include a low-friction material on the surface of the second and first arms that touches the tire. A low-friction material may also be used on the inside of the tire to further minimize friction between these surfaces.

[0028] In another embodiment, the compression device completely encircles the tire, as shown in FIG. 1D, or can partially encircle the tire, as shown in FIG. 1C, for example the length of the compression device along the Y-Z plane can be as short as 10 mm. Each embodiment must weigh a number of variables such as weight, balance, pumping volume, max pumping pressure, lifespan and cost to optimize for the intended application.

[0029] The mechanical force of the second and first arms increases by increasing the stiffness. This can be done through material choice or increasing the thickness and width of the lever arm in the X-Y plane. The greater the stiffness of the lever arm the more force can be generated. However as the lever arm also has a component in the Y-Z plane, the system must balance the benefit of the system in all three dimensions.

[0030] The second surface structure is dictated by the following three requirements. Second, its primary purpose is to resist the pressure in the tire at maximum pressure and not collapse. First, during the compression cycle it must not fail due to tension. And third, it must successfully meet life test and reliability requirements. The upper second surface does not have the same stiffness requirements as the first surface.

[0031] In one embodiment the second surface and pumping chamber are integrated into the inner tube extrusion, as shown in FIG. 5. In this embodiment, the material located above the pumping chamber must successfully perform the three above mentioned functions of the second surface plus it must resist stretching to generate high enough pressures required by the pumping chamber.

[0032] The invention has further benefits in that it also reduces flat tires due to puncture. In the embodiment shown in FIG. 1D, where the pumping mechanism goes completely around the major circumference of the tire, there is significant puncture-resistance improvement, where the puncture-resistance is provided by the first surface material. This is important due to the difficulty in differentiating between a flat tire from slow diffusion of air and a flat tire from a sharp object puncture. FIG. 1E shows a compression device implemented to a tire and inner tube, according to embodiments of the invention.

[0033] The compression device can be made of rigid or semi-rigid materials, where the mechanical efficiency of the invention is enhanced by the second and first arms having increased rigidity. First surface materials include rubbers and plastics including ABS, Nylon, Delrin, PEEK, Natural rubber, NBR, TPE, fiberglass, Kevlar, aramid, carbon fiber, elastomers, thermoplastic polyester elastomers, Hytrel, Zytel, polymers, copolymers, resins and any other commercially available materials.

[0034] Further embodiments include separating the pumping function from the sealing function in the system, as shown in FIG. 4. Here, the pumping chamber forms a shell and a separate lumen of sealing element is used in the shell, as shown in FIG. 4 and FIG. 3, respectively. The sealing element may be extruded, injection molded or produced by any other method. The sealing element can be optimized for durometer, geometry, wear, manufacturability and any other consideration.

[0035] FIG. 4 shows an embodiment with a separate lumen incorporated inside the pumping chamber. This further concentrates the closing force on an even smaller area and could have application where even higher pressures are required. The tubing may be made out of a variety of materials including, PVC, Tygon, Silicone, synthetic rubber, natural rubber, elastomers or any other type of material. In an exemplary prototype embodiment, the tubing used was natural rubber tubing with 1.5 mm inside diameter and 3.0 mm outside diameter. The area inside the pumping chamber, but outside the external tubing may be at 0 bar, 1 bar or even the pressure inside the inner tube. The first surface was constructed from 2.2 mm thick PVC bar stock that was heat formed to match the inner profile of a 38 mm700 mm tire. The curved arc of the first surface measures 28 mm in the X-Y plane. The arc length in the Y-Z plane measures 1 m. The second surface was constructed of 1.0 mm thick PVC bar stock in a similar manner. The curved arc of the second surface measures approximately 10 mm in the X-Y plane. The two surfaces were joined at the hinge joints using nylon fabric and a cyanoacrylate adhesive.

[0036] In a further embodiment, the pumping chamber is the entire space between the second and first surfaces or only some of the space between the second and first surfaces. For example the pumping chamber may have spaces to either side of it that are captured in the area between the second and first surfaces. This permits the cross section area of the pumping chamber to be reduced and serves as another embodiment for increasing the maximum generated pressure of the system.

[0037] Another prototype similar in cross section to FIG. 1 is designed for operation in a tire 38 mm wide by 700 mm diameter. In this embodiment the arc length of the first surface is 30 mm wide in the X-Y plane. The first surfaces reaches its maximum thickness of 1 mm just before the fulcrum and tapers to 0.1 mm as the first surfaces extends outward in the X-Y plane. Both sides of the first surface are symmetrical and are joined in the center with a living hinge. The second surface is co-extruded with the first surface. The second surface is 10 mm wide in the X-Y plane and 0.5 mm thick. In its unloaded state, the second and first surfaces form a chamber 1 mm high by 9 mm wide. The prototype requires the internal angle of the first surface to open 20 degrees for the chamber to close. The prototype extends 0.5 m in the Y-Z plane.

[0038] The present invention has now been described in accordance with several exemplary embodiments, which are intended to be illustrative in all aspects, rather than restrictive. Thus, the present invention is capable of many variations in detailed implementation, which may be derived from the description contained herein by a person of ordinary skill in the art. All such variations are considered to be within the scope and spirit of the present invention as defined by the following claims and their legal equivalents.