BR102014027254B1 - TIRE PUMP AND AIR PRESERVATION ASSEMBLY - Google Patents

Abstract

PNEUMATIC AIR RELEASE AND PRESERVATION VALVE ASSEMBLY. An air-preserving tire and pump assembly that includes a tire having a tire cavity, first and second sidewalls extending, respectively, from the first and second tire bead regions, along with a tread region tire, a substantially elongated annular air passage enclosed within a sidewall curvature region, with the air passage functionally closing and opening, segment by segment, as the sidewall curvature region passes adjacent to a tire tread design impression for pumping air along the air passage, an air inlet orifice assembly for, and communicating the air flow with, the air passage with the orifice assembly air inlet being functional for channeling inlet air from the outside of the tire into the air passage, the air inlet orifice assembly including an inlet control valve and an outlet pin structure positioned at 180 ° opposite the valve (...).

Description

TECHNICAL FIELD

[001] In general terms, the present invention relates to air preservation in tires and, more specifically, to a release valve assembly.

BASICS OF THE INVENTION

[002] Normal air diffusion reduces tire pressure over time. Therefore, the normal state of tires comprises a deflated condition. Consequently, drivers must continually pay attention to maintaining tire pressures or they will experience increased expenses, reduced tire life, and/or poorer braking performance and vehicle handling. Tire Pressure Monitoring Systems have proposed alerting drivers when tire pressure becomes significantly low. Such systems, however, remain dependent on how much the driver acts in prevention when alerted to inflate the tire to the recommended pressure. It is desirable, therefore, to incorporate a feature aimed at preserving air inside a tire that will maintain the correct pressure inside the tire without the need for intervention on the part of the driver to compensate for any reduction in tire pressure over the course of the tire. of time.

SUMMARY OF THE INVENTION

[003] A tire air preservation and pump assembly includes a tire having a cavity, first and second sidewalls extending from the first and second bead regions, respectively, adjacent to the tread region of the tire, a substantially elongated annular air passage, enclosed within a region of curvature of the side walls, with the air passage operating the closing and opening, segment by segment, as the region of curvature of the side walls passes adjacent to a print of the tread design of the tire pumping air along the passage, a coupled air inlet orifice assembly, and communicating the air flow with the air passage, with the air inlet orifice assembly being operated adjacent to the air channel inlet coming from the outside of the tire toward the air passage, the air inlet orifice assembly including an inlet control valve and an outlet pin structure positioned at 180° opposite the air inlet control valve. entry into the air passage for air displacement within the tire cavity, the inlet control valve including two inlet metering valves to ensure air flow only internally, and not externally, at the inlet control valve, in the air passage, in a corresponding single inlet pin structure, and in the tire cavity, and a pressure release valve for releasing a volume equal to the last volume segment of the air passage plus the volume of the pin structure about to leave.

[004] According to another aspect of the set, the inlet gauging valves consist of spherical gauging valves.

[005] According to yet another aspect of the assembly, the outlet pin structure includes two outlet metering valves to ensure only air flow into, and not outside, the tire cavity.

[006] According to yet another aspect of the set, the outlet gauging valves consist of spherical gauging valves.

[007] According to yet another aspect of the assembly, a first constrictive point is defined by a portion of the air passage adjacent to the tread pattern impression so that the first constrictive point rotates in a clockwise direction around the tire. .

[008] According to yet another aspect of the assembly, the two 180° portions of the air passage both pump air into the tire cavity as the first constrictive point rotates in a clockwise direction.

[009] According to yet another aspect of the assembly, a second constrictive point is defined by a portion of the air passage adjacent to the impression of the tread design so that the second constrictive point rotates in a counterclockwise direction around of the tire.

[010] According to yet another aspect of the assembly, the two 180° portions of the air passage both pump air into the tire cavity as the second constrictive point rotates in a clockwise direction.

[011] A method for pumping air into a tire cavity of a tire includes the steps of: operating the closing and opening of an annular air passage inside a sidewall of the tire, segment by segment, as per a region of curvature of the sidewall pass adjacent to a tread design impression for pumping along the air passage, coupling an air inlet orifice assembly, and communicating the air flow with, the air passage along a air inlet passage junction, channeling inlet air from the outside of the tire through the air inlet hole assembly into the air passage so that a constrictive point of the air passage moves around the air passage. along the air passage; and release a volume equal to the last volume segment of the air passage plus a volume of the outlet pin structure through the pressure release valve.

[012] According to yet another aspect of the method, the method further includes the step of rotating the constriction point to the one o'clock position just to the right of an output pin structure so that movement of the constriction point away from the output pin structure.

[013] According to yet another aspect of the method, the method further includes the step of rotating the constricting point to a four o'clock position relative to the output pin structure so that the movement of the constricting point moves beyond the output pin structure, thus forcing air into the tire cavity.

[014] According to yet another aspect of the method, the method further includes the step of rotating the constricting point to a seven o'clock position relative to the output pin structure so that the movement of the constricting point moves towards output pin structure.

[015] According to yet another aspect of the method, the method further includes the step of rotating the constricting point to a nine o'clock position relative to the output pin structure so that the movement of the constricting point is toward the structure outlet pin so that air continues to be forced to flow through the air passage from the nine o'clock position into the outlet pin structure and into the tire cavity and simultaneously with the vacuum in the air passage path positions by forcing the path portions to be filled with air through the inlet control valve.

[016] According to yet another aspect of the method, the method further includes the step of rotating the constricting point to an eleven o'clock position relative to the output pin structure so that the movement of the constricting point is directed towards outlet pin structure as air continues to be forced to flow through the eleven o'clock position air passage to the outlet pin structure and into the tire cavity, and simultaneously the vacuum continues to fill the outlet pin structure with air. portions of travel through the inlet control valve.

[017] According to yet another aspect of the method, all previous steps were carried out when the constricting point rotates in both the clockwise and counterclockwise directions.

Definitions

[018] Tire “stretch” implies the ratio of its section elevation (SH) to its section width (SW) multiplied by 100 percent expressed as a percentage.

[019] “Asymmetrical tread” means a tread that presents a tread pattern without symmetry around the central plane or the EP equatorial plane of the tire.

[020] “Axial” and “axially” represent lines or directions that are parallel to the axis of rotation of the tire.

[021] “Spherical gauging valve” consists of a gauging valve where the closing member, the movable part blocking the air flow, comprises a spherical ball. In some spherical metering valves, the ball is spring loaded to help keep it closed, requiring a specified magnitude of upstream pressure near the ball to overcome valve spring bias toward valve opening. The inner surface of the main valve spring seats can be conically tapered to drive the ball into the seat and form a positive seal when stopping reverse flow.

[022] “Filament mode nylon fabric” consisting of a narrow strip of material positioned around the outside of a tire bead to provide protection to the cord plies against wear and tear by the rim and distribution of flexibility above the rim .

[023] "Measuring valve" comprising two-hole valves having two openings in the body, one for air and the other for the exit of this air.

[024] "Circumferential" comprising lines or directions extending along the perimeter of the tread surface perpendicular to the axial direction.

[025] "Fracture pressure" consisting of a minimum upstream pressure at which the valve can operate. Typically, a gauging valve is designed and can be specified based on a specific fracture pressure.

[026] "Downstream" comprising a direction away from the energy source, that is, the direction away from the air flow source. In the context of a valve, "downstream" refers to a side of the valve from which air flows out of the valve when an "upstream" airflow into the valve exerts sufficient fracturing pressure to open the valve .

[027] "Central Equatorial Plane (CP)" meaning the perpendicular plane along the axis of rotation of the tire and passing through the center of the tread.

[028] "Tread Design Impression" meaning a spot or area of contact of the tire tread with a flat surface at zero speed and under normal load and pressure.

[029] "Groove" representing an elongated empty area in a sidewall that may extend circumferentially or laterally around the tread in a straight, curved, or zigzag manner. Grooves extending circumferentially or laterally sometimes have portions in common. The "groove width" is equal to the surface area occupied by a groove or portion of a groove, the width thereof is actually divided by the length of such groove or portion of a groove; thus, the width of the groove comprises the average of its width and its length. Grooves can vary in depth across a tire. The depth of a groove may vary around the circumference of the tread, or the depth of a groove may vary around the circumference of the tread, or the depth of one groove may be constant by varying from the depth of another groove on the tire. If such narrow or wide grooves have substantially reduced depths compared to grooves having wide circumferences that are interconnected, they are interpreted as forming "bars" tending to preserve a streak-shaped character near the band region. running involved.

[030] "Internal Side" comprising the side of the tire closest to the vehicle when the tire is to be installed on a wheel and the wheel is mounted on the vehicle.

[031] "Lateral" comprising an axial direction.

[032] "Side edges" comprising a tangential line along the spot or impression of the tread pattern of the axially outermost tread contact as measured under normal load and tire inflation, with the lines appearing parallel to the equatorial central plane .

[033] "Net contact area" comprising the total area of ground in contact with the tread elements between the side edges around the entire circumference of the tread divided by the gross area of the entire tread between the side edges.

[034] "Non-directional tread" representing a tread that does not present a preferred direction of forward travel and does not need to be positioned on a vehicle in a specific wheel position or positions to ensure that the tread pattern be aligned with the preferred direction of travel. Conversely, a directional tread pattern presents a preferred direction of travel necessitating specific wheel positioning.

[035] "Outer side" comprising the side of the tire furthest from the vehicle when the tire is installed on a wheel and the wheel is installed on the vehicle.

[036] "Peristaltic" comprising functioning through wave-like contractions that propel retained matter, such as air, along tubular passages.

[037] "Radially" and "radially" comprising directions radially towards or away from the axis of rotation of the tire.

[038] "Rake" comprising a rubber strip extending circumferentially on the tread that is defined by at least one circumferential groove and either a second groove of the type or a lateral edge, with the strip being lateral without divisions through very deep grooves.

[039] "Sip" comprising small slits molded into the tire's tread elements that subdivide the tread surface and improve traction, the sips generally appearing narrow in width and close together in the tread design impression in opposition to the grooves that remain open in the tread pattern print of the tire.

[040] "Tread element" or "traction element" comprising a lane or a block element defined by the shape of adjacent grooves.

[041] "Tread Arch Width" comprising the length of the tread arch measured according to the lateral edges of the tread.

[042] "Upstream" comprising a direction towards the energy source of the air flow, that is, the direction from which the air flows or where it is coming from. In the context of a valve, "upstream" refers to a side of the valve where air flows when an "upstream" airflow into the valve exerts sufficient fracturing pressure to open the valve.

BRIEF DESCRIPTION OF THE DRAWINGS

[043] The present invention will be described by way of example and with reference to the accompanying drawings, where:

[044] FIG. 1 consists of an isometric view of the tire, rim and tubing with an example of a peristaltic pump and inlet valve for use with the present invention.

[045] FIG. 2A consists of a side view of the tire and example of the peristaltic pump assembly of FIG. 1 with the tire rotating counterclockwise and creating an impression of the tread pattern against a surface of the ground.

[046] FIG. 2B consists of a side view of the tire and example of the peristaltic pump assembly of FIG. 1 with the tire rotating clockwise against a ground surface.

[047] FIG. 3A consists of a schematic diagram of the cross-section of the inlet port of the example peristaltic pump of FIG. 1 showing a two-port control valve in the closed position.

[048] FIG. B consists of a schematic cross-sectional diagram of the peristaltic pump inlet port of FIG. 1 showing a two-hole control valve in the open position functioning to fill the tire with rotation of the tire in a counterclockwise direction.

[049] FIG. 3C consists of a schematic diagram of the cross-section of the inlet port of the example peristaltic pump of FIG. 1 with the two-way valve featuring two-hole inlet control that fills the tire as the tire rotates in a clockwise direction.

[050] FIG. 4A consists of a schematic diagram of the cross-section of the inlet port of the example peristaltic pump of FIG. 1 showing a bi-directional five-port inlet control valve alternatively configured in the closed position.

[051] FIG. 4B consists of a schematic diagram of the cross-section of the inlet port of the example peristaltic pump of FIG. 1 featuring an alternatively configured bi-directional five-hole inlet control valve shown in the open position operating to fill the tire with the tire rotating in a counterclockwise direction.

[052] FIG. 4C consists of a schematic diagram of the cross-section of the inlet port of the example peristaltic pump of FIG. 1 with the two-way valve featuring an alternatively configured five-hole inlet control that fills the tire by having the tire rotate in one hourly tire rotation.

[053] FIG. 5A consists of a schematic diagram of the cross-section of the inlet port of an alternative exemplary peristaltic pump filling a tire with the tire in a counterclockwise rotation where the valve has been incorporated therein in a five-hole regulator.

[054] FIG. 5B consists of a schematic diagram of the cross-section of the entrance portal of FIG. 5A of alternative example peristaltic pump bi-directional valve filling a tire acting on a clockwise rotation and featuring the five-hole regulator.

[055] FIG. 5C consists of a schematic diagram of the cross-section of the entrance portal of FIG. Fig. 5B of the alternative example peristaltic pump bi-directional valve with the tire rotating clockwise and the valve in a side passage mode.

[056] FIG. 5D consists of a schematic diagram of the cross-section of the entrance portal of FIG. 5B of alternative example peristaltic pump bi-directional valve with counterclockwise rotation of the tire in a side passage mode.

[057] FIG. 6 consists of a schematic diagram of an exemplary peristaltic pump and inlet valve assembly for use with the present invention.

[058] FIG. 7 comprises a schematic diagram of the operating positions of the example peristaltic pump and inlet valve assembly of FIG. 6 under a first operational condition.

[059] FIG. 8 consists of a schematic diagram of operating positions of the example peristaltic pump and inlet valve assembly of FIG. 6 under a first operational condition.

[060] FIG. 9 consists of a schematic representation of a release valve assembly in accordance with the present invention.

[061] FIG. 10 consists of a schematic representation of another release valve assembly in accordance with the present invention.

[062] FIG. 11 consists of a schematic representation of yet another release valve assembly in accordance with the present invention.

[063] FIG. 12 consists of a schematic representation of yet another release valve assembly in accordance with the present invention.

DETAILED DESCRIPTION OF EXAMPLES OF THE PRESENT INVENTION

[064] Referring to Figures 1, 2A and 2B, a pump and tire assembly may include a pair of sidewalls 12 extending into a tread 14 and enclosing a tire air cavity 26 defined by a liner liner. internal 25. A peristaltic pump assembly 16 may be attached to one or both side walls 12, generally a region of high curvature of the side walls. The peristaltic pump assembly 16 may include an annular air passage 20 either: 1) in the form of an independent tube formed separately from the tire and installed with the tire in a post-manufacturing procedure; or 2) an air passage formed as an integral void within the sidewalls 12 during tire manufacturing. The air passage 20 may be enclosed by the sidewall 12 and may extend along an annular path around a region of the sidewall that experiences high flexion or curvature as the tire rotates under load. In the case of a free-standing tube shape, the tube may be formed from a flexible, resilient material, such as plastic, rubber, and/or polymeric compounds capable of withstanding repeated cyclic deformation, with the tube deforming into a flattened condition subject to to a load and, upon removal of such load, returning to an original condition that is generally circular in cross-section. If the air passage is integrally formed within the sidewall, the air passage likewise withstands repetitive cyclic deformation and recovers as the tire rotates under load and passes a volume of air sufficient for the purpose described in this document. The general operation of an air tube in a peristaltic pump is described in U.S. Patent No. 8113254 incorporated herein by reference.

[065] Opposite ends 22, 24 of the air passage 20 may terminate near an inlet hole assembly 28. The inlet hole assembly 28 may be affixed to rotate with the tire as it rotates against a tire surface. terrain 132. Rotation of the tire creates an impression of tread pattern 134 against the surface of the terrain 132, which in turn introduces compressive force 138 into the tire. The compression force 138 in turn can be applied to the component 140 in the air passage 20, causing segment by segment to collapse in the passage as the tire rotates under load. Segment-to-segment collapse of the air passage 20 may occur if the tire rotates in a counterclockwise direction 136 in FIG. 2A or in a clockwise direction 133 in FIG. 2B. The peristaltic pump assembly 16 is therefore bi-directional or reversible when operating to pump air into the tire cavity 256 in both a forward and reverse direction of air flow continuously through a 360 degree rotation.

[066] As the tire rotates in both the front and rear directions 136, 133 in Figures 2A or 2B, respectively, the air passage 20 can be flattened, segment by segment, whether the passage is in the form of a tube embedded in a separate sidewall or as a fully formed void. The flattening 137 in sequence, segment by segment, of the air passage 20 may move in a direction 142 opposite to the direction of tire rotation in Figures 2A and/or 2B. The sequential flattening 137 of the passage 20, segment by segment, can evacuate the air from the flattened segments to be pumped in the direction 142 towards the inlet port assembly 28 where the air is directed to the tire cavity 26. The pressure of air within the tire cavity 26 can be preserved at a desired threshold pressure. The air admitted through the inlet port assembly 28 into the air passage 20 may supply air pumped into the tire cavity 26 or be recirculated out of the pump assembly 16 if it is not necessary to maintain the tire pressure together. to a desired level.

[067] The inlet port assembly 28 may include a regulator valve assembly 30 and a filtered air inlet port 32. A two-port bi-directional inlet control assembly 28 is shown in Figures 3A through 3C . FIG. 3A represents an input control in a closed position; FIG. 3B represents the inlet control in an open position with the airflow moving counterclockwise and the tire rotating clockwise; and FIG. 3C represents the inlet control in an open position with the airflow moving clockwise and the tire rotating counterclockwise. It can be appreciated that the system is bi-directional, with the air flow within the air passage 320 in one and/or two more directions as the tire rotates under load, with the direction of air flow within the air passage 320 ar 20 determined by a forward or reverse direction of tire rotation. Pumping along the air passage 20 can occur in any direction, alternatively, through a full 360 degree rotation of the tire under load.

[068] A filtered air inlet hole 32 can be positioned along the outer surface of a tire sidewall 12 and external air can be admitted into the inlet hole through a cell filter 32 housed inside a cylindrical compartment 36. FIG. 3A shows the assembly 28 in a closed condition where air coming from the outside of the tire is prevented from passing through the inlet hole 32 (for example, a condition occurring when the pressure inside the tire cavity 26 is at or above of a PREG regulated threshold pressure). An air conduit 56 may extend from the filter housing 36 to the regulator valve assembly 30 and may convey incoming air to the valve assembly. From the regulator valve assembly 30, an outlet conduit 54 may convey air flow to a connecting conduit 40 that conveys air into oppositely directed valves 62, 64 positioned adjacent and on opposite sides of an air junction. 38. According to the usage given in this report, “inlet junction” may refer to a location in the air passage 20 leading the inlet air from the assembly 28 to the upstream sides of the supply interruption valves. Alternative examples of system 16 are shown in Figures 3A through 3C, 4A through 4C, and 5A through 5D.

[069] The regulator valve assembly 30 may have a valve housing 42 and a valve piston 44 residing within a cylinder or housing chamber 46. A biasing mechanism, such as a spring 48, may exert a force bias (see arrow 72 in Figures 3b, 3C) in piston 44, biasing the piston downward within cylinder 46 in an “open” or “tire fill” location as indicated in Figures 3B and 3C. When the pressure inside the tire cavity 26 is at or greater than the PREG set pressure level, the pressure will overcome the biasing force of the spring 48 and the force of the piston 44 (see arrow 50) in an upward direction. inside cylinder 46 in the “closed” or “unfilled” location of Figure 3A. The piston 44 may include an air conduit 52 extending transversely along the piston 44. In the “closed” position of FIG. 3A, the conduit 52 is poorly aligned with respect to the air conduits 54, 56 and air cannot flow along the piston 44 to the conduits 54, 56, and from there to the inlet junction 38. Consequently, in position “closed”, air flow is prevented from reaching the inlet junction 38 and reaching the upstream sides of the valves 62, 64. Air flow into the passage 20 can be obstructed with the valve assembly 30 in the closed position of the FIG. 3A.

[070] FIG. 3B shows valve assembly 30 moving to an “open” position. The tire can rotate in a clockwise direction, causing air to be pumped along passage 20 in a counterclockwise direction. A configuration of four one-way valves 62, 64, 66, 68 can be located as shown in FIG. 3B. The two in-line valves 62, 64 can be positioned along the conduit 40 on the opposite side of the inlet junction 38. The two in-line valves 62, 64 can open in opposite directions along the conduit 40 and conduct the air flow in such respective directions towards the two in-line valves 62, 64 with the air passage 20. From the junction of the conduit 40 and the air passage 20, the radially extending opening conduit passages 58, 60 may extend for the tire cavity 26. Two unidirectional valves may be positioned along the conduits 58, 60, respectively. The valves 66, 68 may be oriented to open in a direction towards the tire cavity 26 allowing air to flow through the valves 66, 68 along the conduits 58, 60 into the tire cavity.

[071] The unidirectional valves 62, 64, 66, 68 may comprise, for example, diaphragm or spherical gauging valves. Valves 62, 64, 66, 68 can be oriented to open in the direction shown when pressure along an upstream side of valve 62, 64, 66 or 68 overcomes a bias spring and forces the ball past its seat. The piston 44 may move downward (as seen in the Figures) under the action of the biasing force exerted by the actuator spring 48. When the air pressure PREG within the tire cavity 26 drops below a desired pressure limit , movement of the piston 44 can align the air duct 52 through the piston 44 with the ducts 54, 56 thereby enabling air to enter the inlet filter orifice 32 and flow through the piston duct 52 to the control junction inlet 38 and for connection to conduit 40. The tire, rotating clockwise against the ground surface 132 (see FIG. 2B), can collapse the air passage 20, segment by segment, as opposed to printing 134 tire tread pattern generated. The collapsed segments can create a vacuum which, in turn, can be refilled, segment by segment, by a flow of air into the air passage 20 in a counterclockwise direction 142, drawn through the inlet orifice assembly. 28.

[072] The incoming air flow in a counterclockwise direction opens the unidirectional valve 64, allowing air to flow into passage 20 and circulate in a counterclockwise direction. When the air flow reaches the junction of the conduit 40 and the radial outlet conduit 60, the air cannot flow through the closed valve 62 and must therefore flow to the outlet valve 68. The air flow forces the valve to close. outlet 68 is open and continues to flow air into tire cavity 26, as indicated by arrow 70 (FIG. 3B). When the air pressure within the tire cavity 26 reaches the desired pre-set level, the tire pressure against the piston 44 can force the piston into the closed position of FIG. 3A and the airflow near the tire cavity can be discontinued (according to the description above).

[073] This operation of the peristaltic pump assembly 16 can also function similarly in the reverse tire rotation direction, as will be understood from FIG. 3C. In Figures 2A and 3C, with the tire rotating in a counterclockwise direction, air can be pumped in a clockwise direction 142. FIG. 3 shows the inlet port assembly 28 and the regulator valve assembly 30 in such condition. If the pressure inside the tire cavity 28 is below the pre-set PREG, the piston 44 is biased by the spring 48 in the open position. The piston duct 52 can align with the ducts 54, 56 and the air flow can be directed to the junction 40. Rotation of the tire in a counterclockwise direction can cause the air to flow in a clockwise direction 74 according to the segments evacuees from passage 20 are filled in again. The air flow in the clockwise direction opens the unidirectional valve 62 and allows air to circulate from the conduit 40 to the passage 20. The pressurized air can circulate in the passage 20 and enter the conduit 58 where it is directed against the valve. outlet 66, thereby flowing through outlet valve 66 into tire cavity 26, as indicated by arrow 70 of FIG. 3C. As given in FIG. 3C, when the air flow reaches the junction of the conduit 40 and the radial outlet conduit 58, the air cannot flow through the closed valve 64 and can flow into the outlet valve 66. The air flow that forces the valve to open outlet 66 can continue into the tire cavity 26, as indicated by arrow 70. When the air pressure inside the tire cavity 26 reaches the preset level established by PREG, the tire pressure against the piston gasket 44 can force the piston into the closed position of FIG. 3A and airflow to the tire cavity can be discontinued as explained above.

[074] Figures 4A, 4B and 4C present an alternative example embodiment where the regulator valve assembly 78 may comprise a five-hole inlet control configuration. In FIG. 4A, the valve assembly is in the closed position where air is not introduced into the tire cavity 26. FIG. 4B shows the valve assembly in the open position with the rotational direction of the tire in a clockwise direction and the air flow in a counterclockwise direction. FIG. 4C presents the valve in the open position during the rotational direction of the tire in a counterclockwise direction and the airflow in a clockwise direction. In the valve assembly shown in Figures 4A, 4B and 4C, air may be admitted into the system through the inlet port assembly 76 to the regulator valve assembly 78. The inlet port assembly 76 may include an inlet port. filter body 80 and a filter body 82 housed within a filter housing 84. Air passing through the filter body 82 may be directed via the inlet duct 86 to a transverse piston duct 88. The junction 90 created by the intersection of the inlet conduit 86 and the piston conduit 88 can also be located inside the piston 92.

[075] The piston 92 can be biased by the spring 94 in an open condition represented by Figures 4B and 4C with the air pressure inside the tire cavity 26 being less than a pre-set PREG pressure level. If the air pressure inside the tire cavity 26 is at or above the PREG level, the air pressure in the cavity can overcome the bias spring 94 and move the piston 92 upwards inside the cylinder 98 in the closed position of the tire. FIG. 4A. In the closed position, no air is pumped into tire cavity 26.

[076] The transverse conduit 88 of the piston 92 may align with the connecting conduits 100, 102 in the open valve conditions of Figures 4B and 4C and may misalign with the connecting conduits 100, 102 when the valve is closed as shown in FIG. 4A. Four one-way valves 106, 108, 110, 112 may be positioned to form the in-line valves 108, 110 and the outlet valves 106, 112. The in-line valves 108, 110 may open in opposite directions away from the junction 90 and the valves outlet valves 112, 106 can open radially inwards towards the tire cavity 26. The outlet valves 106, 112 can be housed, respectively, within the outlet conduits 103, 101, which couple with the passage 20. conduits 103, 101 may intersect and connect, respectively, with the connecting conduits 102, 100, and proceed radially inwardly beyond the outlet valves 112, 106 to the outlet ends 22, 24 adjacent to the tire cavity 26.

[077] The operation of the five-hole valve configuration of Figures 4A, 4B and 4C can operate in an analogous manner as explained above with reference to the two-hole valve of Figures 3A, 3B and 3C. Figures 2B, 4B show the regulator valve open with the tire rotating clockwise and leading to a counterclockwise flow of air into the passage 20. Air admitted through the inlet valve assembly 76 can be directed to the junction 90 on the piston 92 through the conduit 86. Near the junction 90, the air flow does not pass through the closed valve 108 and thus can open the valve 110. The air flow can circulate in the direction 114 inside the passage 20 entering the conduit 101. The air flow near the junction of the conduit 102 and the connecting conduit 100 cannot pass through the closed valve 108 and can be directed to the open valve 106, providing conditions for the pumped air flow enter tire cavity 26.

[078] Figures 2A and 4C show the operation of the regulator valve with the tire rotating in a counterclockwise direction 136 to pump the air flow into the passage 20 in a clockwise filling direction 118. The air flow 118 in passage 20 may be directed to tire cavity 26 as shown. Valve operation in this tire rotation direction and in the opposite air flow direction in Figures 2A and 4C can proceed as described above. When the air pressure within the tire cavity 26 reaches the desired preset level for PREG, the pressure against the piston 92 can force the piston into the closed position (misaligned conduit) of FIG. 3A and the air flow into the tire cavity can be discontinued. A pressure within the tire cavity 26 below the PREG preset desired threshold level may cause the piston 92 to move in the open position of Figures 4B and 4C and the air flow in the passage 20 in the indicated direction as established by the direction tire rotation. Air pumping can proceed through 360° rotation of the tire and, as shown, can occur regardless of whether the tire (and vehicle) is traveling in the forward or reverse direction.

[079] Figures 5A, 5B, 5C and 5D show another example of a regulator valve assembly 78 modified by the inclusion of a side passage valve 120. The side passage valve 120 may consist of a pressure controlled valve connected to side passage opening the gauge valves 106, 112 when the pressure inside the tire cavity 26 exceeds a PSET or PREG value. The side passage valve 120 can ensure that air cannot be introduced into the tire cavity 26 when the air pressure inside the cavity is at or greater than the PSET or PREG threshold pressure.

[080] The side passage valve 120 can direct air in any direction when the pressure inside the tire cavity 26 is equal to or greater than the PSET or PREG value, giving air a side passage to the outlet valves 106 , 112 and preventing the introduction of excessive air into the tire cavity. The side passage valve 120 can connect to the conduit 120 by passing through the piston 92 and connecting the conduits 101, 103 at opposite ends.

[081] FIG. 5A features a five-hole side passage regulator with the pressure in the cavity below the PSET or PREG boundaries, the tire rotating in a clockwise direction, and filling with air rotating around passage 20 in a counterclockwise direction. In the side passage regulator of Figures 5A, 5B, 5C and 5D, the piston 92 may not move between an open operation, aligned with respect to the conduits 100, 102 and a misaligned closed orientation, remaining aligned in all filling modes ( e.g. fixed).

[082] With reference to FIG. 5A, the pressure in the cavity is below the PSET or PREG thresholds, causing the side passage valve 120 to close. With the side passage valve 120 closed, operation of the regulator and air passage 20 proceeds in the manner discussed previously with reference to FIG. 4B. Figures 5A and 4B both depict a clockwise rotation of the tire, airflow into the tire cavity 26 (arrow 124) through the filter inlet hole 80, and a counterclockwise airflow into the passageway 20 ( arrow 126).

[083] In FIG. 5B, for a counterclockwise rotation of the tire and a clockwise filling direction, the side passage valve 120 continues to remain closed as long as the pressure in the cavity remains below the PSET or PREG limit. Air flow (arrow 128) along the side passage duct is blocked by the closed side passage valve 120. The airflow and filling direction in FIG. 5B are processed in the manner explained above with reference to the same analogous operating conditions as in FIG. 4B. The air circulating in FIG. 5B in the clockwise direction acts to open the outlet valve 112 and passes air in the direction 130 into the tire cavity 26.

[084] In FIG. 5C, with the pressure in the cavity being equal to or greater than PSET or PREG, air can flow in a clockwise direction bypassing the outlet valves 106, 112 and passing instead through the open side passage valve 120. The outlet valves 106, 112 remain closed and in none of them the circulated air (arrow 126) will pass through the outlet 106, 112 and enter the tire cavity 26. FIG. 5D shows operation of the side passage regulator during counterclockwise rotation of the tire and a counterclockwise airflow path through air passage 20. As shown in FIG. 5C, the pressure in the tire cavity in FIG. 5D is greater than the boundary PSET or PREG and the side passage valve 126 is open and directing airflow counterclockwise (direction arrow 126) through the side passage duct, rather than through the outlet valves 106, 112. Air flow within the tire cavity 26 is prevented from occurring. The side passage regulator of Figures 5A, 5B, 5C and 5D ensures that under no circumstances will air be forced into the tire cavity 26 when the pressure inside the cavity is equal to or greater than the PSET or PREG threshold. settled down.

[085] From the foregoing discussion, it should be appreciated that the peristaltic pump and regulator system provide a mechanism for preserving the air pressure within the tire cavity 26 at a desired PSET or PREG pressure level, without the presence of a pressure greater than the desired pressure level. The pump assembly 16 may include the elongated annular air passage 20 enclosed within a curved region of the tire. The air passage 20 can functionally close and open segment by segment as the tire curvature region passes adjacent to a tire tread pattern impression for pumping air along the air passage. The pump assembly 16 may further include the air inlet port assembly 28 positioned to channel air from the outside into the air passage 20 near an inlet junction (38 or 90). The pair of in-line valves 62, 64 (or 108, 110) can direct the incoming air in opposite directions into the air passage 20. The pair of outlet valves 66, 68 (or 106, 112) can be positioned adjacent to a downstream side of a respective in-line valve with the outlet valves directing a bi-directional flow from the downstream side of a respective in-line valve through and toward the tire cavity 26.

[086] The inlet port assembly 28 may further extend the control conduit between an air inlet/inlet airflow portal and an upstream side of the inlet valves. The piston 44 may operate under the influence of the valve spring 48 by stopping the incoming air through the control junction 38 near the upstream side of the inlet valves when the air pressure within the tire cavity 26 is above the level threshold air pressure PSET or PREG. The inlet and outlet valves can open selectively with bi-directional air flow within the air passage 20 dictated by the direction in which the tire rotates.

[087] Another example of inlet control valve 601 can be used with an example of peristaltic pump assembly 600 similar to the exemplified assemblies 16 described previously. Such assembly 600 can be bi-directional and can simultaneously make use of pumping extension in a complete 360° of the air passage 20 (and not just 180° in one opportunity, for example). Example assembly 600 (FIGS. 6-8) may include inlet control valve 601 and an outlet pin structure 612 oppositely positioned 180° to the inlet control valve in air passage 20 for air movement. inside the tire cavity 26. The inlet control valve 601 may include two inlet metering valves 621, 622 to ensure that air flow is only into, and not out of, the inlet control valve. of the air passage 20, a corresponding single inlet pin structure 611, and the tire cavity 26. The inlet metering valves 621, 622 may consist of spherical metering valves, as shown in FIG. 6. The outlet pin structure 612 may include two outlet metering valves 631, 632 to ensure only air flow into, and not out of, the tire cavity 26. The outlet metering valves 631, 632 may comprise of spherical gauging valves, as shown in FIG. 6.

[088] FIG. 7 schematically shows the operation of the example set 600 for a clockwise rotation of the tire tread pattern print 134 at the beginning of a pumping cycle (e.g., a tire rotation). The first view shows a constriction point 705 (e.g., the sidewalls 12 located adjacent to the tire tread pattern print 134) at a one o'clock position just to the right of the output pin structure 612 moving beyond the output pin structure.

[089] As the constriction point 705 rotates to the four o'clock position of the second view, air is forced to flow through the air passage 20 from the four o'clock position to the output pin structure 612 and into the tire cavity 26. The inlet metering valve 622 and the outlet metering valve 632 respectively block the flow of air to the inlet control valve 601 and to a portion of the path 628 of the air passage 20.

[090] As the constriction point 705 rotates to a seven o'clock position from the third view, air continues to be forced to flow through the air passage 20 from the seven o'clock position to the exit pin structure 612 and to within the tire cavity 26. The vacuum in the travel portions 628, 629 can now receive air from the inlet control valve 601.

[091] As the constricting point 705 rotates to the nine o'clock position of the fourth view, the remainder of the air continues to be forced to flow through the air passage 20 from the nine o'clock position to the exit pin structure 612 and into the tire cavity 26. Simultaneously, the vacuum in the path portions 628, 629 may proceed with filling the path portions with air through the inlet control valve 601.

[092] Once the constricting point 705 rotates to the eleven o'clock position of the fifth view, the remainder of the air continues to be forced to flow through the air passage 20 from the eleven o'clock position to the pin structure. exit 612 and into the tire cavity 26. Simultaneously, the vacuum in the travel portions 628, 629 may continue to be filled with air through the inlet control valve 601. This ends with a pumping cycle in this clockwise direction of rotation. Once the constricting point 705 rotates back to the one o'clock position of the first display, a new pumping cycle begins against a full volume of air at 360° along the filled path portions 628, 629 of the air passage 20 .

[093] FIG. 8 schematically shows the operation of the example set 600 for a counterclockwise rotation of the tire tread pattern print 134 at the beginning of a pumping cycle (e.g., a tire rotation). The first view shows a constriction point 805 (e.g., sidewalls 12 located adjacent to the tire tread pattern print 134) at an eleven o'clock position just to the left of the output pin structure 612 moving beyond of the output pin structure.

[094] Once the constricting point 805 rotates to the nine o'clock position of the second view, air is forced through the air passage 20 from the nine o'clock position to the output pin structure 612 and into the tire cavity 26. The inlet metering valve 622 and the outlet metering valve 612 respectively block the air flow in the inlet control valve 601 and in a portion of the path 628 of the air passage 20.

[095] As the constriction point 805 rotates to the five o'clock position of the third view, air continues to be forced to flow through the air passage 20 from the five o'clock position to the exit pin structure 612 and to the interior of the tire cavity 26. The vacuum present in the travel portions 628, 629 can now receive air from the inlet control valve 601.

[096] Once the constricting point 805 rotates to the nine o'clock position of the fourth view, the remaining air continues to be forced to flow through the air passage 20 from the nine o'clock position to the exit pin structure 612 and into the tire cavity 26. Simultaneously, the vacuum in the travel portions 628, 629 may continue to fill the travel portions with air through the inlet control valve 601.

[097] Once the constricting point 805 rotates to the one o'clock position of the fifth view, the remaining air continues to be forced to flow through the air passage 20 from the one o'clock position to the exit pin structure 612 and into the tire cavity 26. Simultaneously, the vacuum in the path portions 628, 629 may continue to fill the path portions with air through the inlet control valve 601. This ends with a pumping cycle in this direction. counterclockwise rotation. As the constricting point 805 rotates back to the eleven o'clock position of the first display, a new pumping cycle can begin against a 360° full air volume in the now fully filled path portions 628, 629 of the air passage. air 20.

[098] An assembly 900 according to the present invention can manage the release even before the super-pressurized air can reach the tire cavity 26 (FIG. 9). Thus the release volume may be equal to the last segment volume 910 plus a pin volume 920, and not entirely the volume of the tire cavity. The pressure at pin 920 may never exceed the predetermined release pressure (PREL) and the pressure in tire cavity 26 may never exceed PREL. If the pressure in the tire cavity is below PREL, pressurized air can be sent to the tire cavity 26 from the last segment 910. A release valve 930 installed externally to the tire can together eliminate the regulator by reducing the amount of punctures/modifications made to the tire. FIG. 10 shows a 2x180° pumping configuration with assembly 900. FIG. 11 shows a 2x180° pumping configuration containing assembly 900. FIG. 12 shows a 360° pumping configuration containing assembly 900. The fracture pressure of a control valve on the inside of the tire and/or the PREL release pressure can be adjusted to the desired performance (PSET = PREL - PCRACK).

[099] Variations in the present invention are possible in view of the description thereof provided in this report. While certain examples and representative details have been presented for purposes of illustrating the invention in question, it should be evident to those skilled in the art that various changes and modifications can be made without deviating from the scope of the invention in question. Therefore, it should be understood that changes may be made to the particular examples described which may fall fully within the intended scope of the present invention defined in accordance with the appended table of claims.

Claims (8)

1. Tire air preservation and pump assembly, comprising: a tire having a tire cavity (26), first and second sidewalls (12) extending, respectively, from the first and second bead regions adjacent to a tire tread region (14); an elongated annular air passage (20) enclosed within a curved region of the side walls (12), the air passage (20) functioning for closing and opening, segment by segment, according to the region of curvature of the side walls ( 12) passes adjacent to a tire tread design impression to pump air along the air passage (20); an air inlet orifice assembly coupled to, and in air flow communication with, the air passage (20), with the air inlet orifice assembly being operative with the channel inlet air coming from the outside of the tire for the air passage (20), the air inlet orifice assembly including an inlet control valve (601) in the air passage (20) for moving air into the tire cavity (26), and an outlet pin structure (612, 900) preferably positioned 180° opposite the inlet control valve (601) for moving air from the air passage (20) into the tire cavity (26). ; CHARACTERIZED in that the inlet control valve (601) includes two inlet metering valves (621, 622) to ensure air flow only into, and not out of, the inlet control valve (601), the air passage (20), a corresponding single inlet pin structure (611), and the tire cavity (26); and a pressure release valve (930) connected to the outlet pin structure (612, 900) for releasing a volume equal to a last segment volume of the air passage (20) plus a volume of the outlet pin structure (612, 900) exit (612, 900). 2. Tire air preservation and pump assembly, according to claim 1, CHARACTERIZED by the fact that the inlet metering valves (621, 622) are spherical metering valves. 3. Tire air preservation and pump assembly according to claim 1 or 2, CHARACTERIZED by the fact that the output pin structure (612) includes two output gauging valves (631, 632) to ensure the air flow only inside, and not outside, the tire cavity (26). 4. Tire air preservation and pump assembly, according to any one of claims 1 to 3, CHARACTERIZED by the fact that the outlet metering valves (631, 632) are spherical metering valves. 5. Tire air preservation and pump assembly according to any one of claims 1 to 4, CHARACTERIZED by the fact that a first constrictive point (705, 805) is defined by a portion of the air passage adjacent to the impression tire tread design so that the first constriction point (705, 805) rotates in a clockwise direction around the tire. 6. Tire air preservation and pump assembly according to claim 5, CHARACTERIZED by the fact that two 180° portions of the air passage (20) both pump air into the tire cavity (26) as per the first constricting point (705, 805) rotate clockwise. 7. Tire air preservation and pump assembly according to claim 5 or 6, CHARACTERIZED by the fact that a second constrictive point (705, 805) is defined by a portion of the air passage (20) adjacent to the tire tread pattern impression so that the second constriction point (705, 805) rotates in a counterclockwise direction around the tire. 8. Tire air preservation and pump assembly according to claim 7, CHARACTERIZED by the fact that the two 180° portions of the air passage (20) both pump air into the tire cavity (26) as the second constricting point (705, 805) rotate clockwise.