ELASTOMERIC TIRE FOR A TRACKED VEHICLE

Abstract

A road wheel for a tracked vehicle is provided with a circular mounting flange having a dished wall extending radially outwards and circumferentially therefrom, a peripheral rim having a first edge and a second edge with the rim connected to an outer edge of the dished wall at an intermediate region of the rim, and a first lip extending from the first edge. Another road wheel for a tracked vehicle is provided with a mounting flange, a peripheral rim, at least one inner dished wall, at least one outer dished wall offset from the inner dished wall along the flange, and at least two connector walls with each connector wall extending between the inner dished wall, outer dished wall, and the peripheral rim.

Description

BACKGROUND

1. Technical Field

The invention relates to non-pneumatic tires for use with tracked vehicles.

2. Background Art

Tracked vehicles have applications in military use, heavy commercial use, and others where the vehicle may be travelling over uneven terrain, carrying a heavy load, or the like. The vehicles have a track which interfaces with the ground to support or propel the vehicle. Wheels are located within the track to drive or support it. Some of the wheels are connected to the drivetrain of the vehicle. A tire is placed over the rim of the wheels to interface with the track to improve ride quality characteristics. The tires are typically made from a natural or synthetic rubber and are solid, or non-pneumatic.

Typical failure modes of these rubber tires are blow-out and heat checking from high operating temperatures, cutting and chunking from sharp debris, and bonding failure at the rubber-wheel interface. Failure of the elastomer rubber tire on the road wheel may account for more than ninety-five percent of all road wheel failures. For temperature failures, the primary source of heat generation is hysteretic heating from the rubber, with vehicle speed and ambient temperatures as strong contributors. The higher the operating speed of the vehicle, the greater the number of hysteretic cycles the elastomer goes through, and consequently the higher the operating temperature. The thickness of the elastomer has a major affect on the hysteretic heating. Typically a thicker tire and a lower modulus generate greater hysteretic heating, but provide better damping for reduced vehicle vibrations. As a result the compound is blended for a compromise in these design features.

For cutting and chunking, sharp pointed debris material indents the elastomer. Once the elastomer tensile forces at the tip of the debris exceed the tensile strength of the elastomer, a crack initiates and then begins to propagate. Two usual methods to prevent crack initiation include using a higher modulus elastomer or a thicker tire. Unfortunately, the tensile strength of elastomer decreases drastically with higher operating temperatures over 175 F or 200 F. The higher temperatures promote crack initiation by weakening the tire.

Currently, tire improvements are being sought through use of higher temperature formulations, polyurethane or poly urea, or optimized width and thickness of the rubber.

The cutting and chunking characteristics may be improved with polyurethane, but drawbacks include a lower operating temperature threshold, a harder ride with increased vibrations, additional cost, and greater susceptibility to contaminants and humidity during adhesion molding.

SUMMARY

In one embodiment, a tire assembly for a tracked vehicle has an inner tire layer forming a first tube sized to substantially cover an outer surface of a rim of a wheel, and an outer tire layer forming a second tube with a larger diameter than the first tube, the outer tire layer adapted to contact a track of a vehicle. At least one carcass layer is interposed between the inner and outer tire layers to provide tensile and impact strength to prevent crack propagation from reaching the inner tire layer of the tire assembly, thereby prolonging the useful life of the tire assembly and reducing the frequency of replacement of the tire assembly. The inner and outer tire layers encapsulate the carcass layer to protect it from an environment of use.

In another embodiment a wheel assembly for a tracked vehicle has a wheel with a circular mounting flange with a wall extending radially outwards and circumferentially therefrom, and a peripheral rim connected to an outer edge of the wall. The peripheral rim has an outer surface. The wheel assembly also has a tire with an inner layer sized to substantially cover the outer surface of the peripheral rim, at least one intermediate fabric carcass layer bonded to an outer surface of the inner layer, and an outer layer bonded to an outer surface of the at least one carcass layer. The outer layer is adapted to contact a track of a vehicle. The at least one intermediate carcass layer provides tensile and impact strength to prevent crack propagation from reaching the inner layer of the tire, thereby prolonging the useful life of the tire and reducing the frequency of replacement of the tire.

Yet another embodiment provides a method of forming a tire assembly for a wheel of a tracked vehicle. An inner tire layer is provided as a first tube about a rim of a wheel. The inner tire layer is sized to substantially cover an outer surface of the rim. An outer tire layer is positioned about the inner tire layer as a second tube with a larger diameter than the first tube. The outer tire layer is adapted to contact a track of a vehicle. At least one carcass layer is interposed between the inner and outer tire layers. The carcass layer provides tensile and impact strength to prevent crack propagation from reaching the inner tire layer of the tire assembly, thereby prolonging the useful life of the tire assembly and reducing the frequency of replacement of the tire assembly. The inner and outer tire layers encapsulate the carcass layer to protect it from an environment of use.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view of an embodiment of a tracked vehicle;

FIG. 2 is a perspective view of a pair of wheels and a section of track of the vehicle of FIG. 1;

FIG. 3 is a perspective section view of a tire and wheel according to another embodiment;

FIG. 4 is a top section view of the tire and wheel of FIG. 3;

FIG. 5 is a perspective section view of the tire and wheel of FIG. 3;

FIG. 6 is a partial section view of a tire according to yet another embodiment;

FIG. 7 is a schematic view of a tire and debris according to another embodiment;

FIG. 8 is a section schematic view of a tire according to yet another embodiment;

FIG. 9 is a section schematic view of a tire according to another embodiment;

FIG. 10 is a partial view of a tire assembly according to an embodiment;

FIG. 11 is a schematic view of a tire assembly according to another embodiment; and

FIG. 12 is a schematic view of a tire assembly according to yet another embodiment.

DETAILED DESCRIPTION

As required, detailed embodiments of the present invention are disclosed herein; however, it is to be understood that the disclosed embodiments are merely exemplary of the invention that may be embodied in various and alternative forms. The figures are not necessarily to scale; some features may be exaggerated or minimized to show details of particular components. Therefore, specific structural and functional details disclosed herein are not to be interpreted as limiting, but merely as a representative basis for the claims and/or as a representative basis for teaching one skilled in the art to variously employ the present invention.

FIG. 1 illustrates a tracked vehicle 20. The tracked vehicle 20 may be an armored tank as shown, and may also be any military, commercial, or other tracked vehicle as is known in the art. The vehicle 20 has a track 22 to interact with an underlying surface 24. The underlying surface may be a road, or uneven terrain such as dirt, rock, or the like. The track 22 is continuous and is supported by wheels 26. The wheels 26 may include drive wheels 28 at the front or rear of the vehicle 20 to transfer power to the track 22, and road wheels 30 to support the vehicle 20 on the track 22.

FIG. 2 illustrates a pair of wheels 26 interacting with a track section 22 of the tracked vehicle 20. The pair of wheels 26 has a first wheel 32, or outer wheel, and a second wheel 34, or inner wheel, connected to one another along the mounting flange 36 of each wheel 26. A gap 38 is formed between the wheels 32, 34, which interacts with a guide 40 on the track 22 to retain and align the pair of wheels 26 with the track 22. The interface between the guide 40 and one of the wheels 32, 34 transmits a lateral vehicle load to the track 22 during side slope operations and vehicle cornering, and maintains track alignment. Each wheel 26 also has a wear ring 44 on the inner surface of each wheel 26 adjacent to the gap 38. The wear rings 44 interface with the guide 40 and protect the surface of the wheels 26, which may extend the lifetime of the wheels 26.

Each wheel 32, 34 has a tire 42, or an elastomeric pad, located circumferentially around each wheel 32, 34. The tires 42 act as an interface between the wheels 32, 34 and the track 22.

FIGS. 3-5 illustrate an embodiment of a wheel assembly 46 with a wheel 48 and a tire 50. The wheel 48 has a circular mounting flange 52 which allows for attachment to an adjacent wheel to form a pair of wheels to interact with a track. A wall 54 extends from the mounting flange 52 radially outwards and circumferentially. A rim 56 is connected to the outer edge of the wall 54. The rim 56 has an outer surface 58. The wheel 48 may be fabricated from steel, aluminum, magnesium, alloys, and other metals or materials as is known in the art. The wheel 48 may be forged or cast. Other shapes and cross sections for the wheel 48 are also contemplated as are known in the art.

A tire 50 is positioned around the outer surface 58 or the rim 56 or the wheel 48. The tire 50 may be a non-pneumatic structure that substantially covers the outer surface 58 of the rim 56. The use of the phrase “non-pneumatic” with respect to the tire 50 does not preclude having air or another gas or fluid within the tire 50 structure. For example, an air bladder, a honeycomb layer containing a gas, or the like are contemplated for the tire 50. The tire 50 has an inner layer 60 positioned adjacent to the rim 56. An intermediate layer 62 is positioned on the outer surface of the inner layer 60. An outer layer 64 is positioned on the outer surface of the intermediate layer 62 and designed to be in contact with the track of the vehicle. The inner and outer layers 60, 64 are made from natural rubber, synthetic rubber, or another material with similar properties. In one embodiment, the inner tire layer 60 has a stiffer compliance than the outer tire layer 64. The intermediate layer 62 has at least one fabric carcass layer. The carcass layer 62 provides tensile and impact strength to the tire 50 and prevents crack propagation through the tire 50, as shown in FIG. 6. The carcass layer 62 also has natural abrasion and tear resistance which is beneficial as the tire 50 wears. By preventing crack propagation from the outer layer 64 through the tire 50, a crack cannot reach the inner layer 60 of the tire 50, the useful life of the tire 50 is prolonged, and the frequency of replacement of the tire 50 is reduced. The inner and outer layers 60, 64 may encapsulate the carcass layer 62 to protect it from the environment of use when the vehicle is in the field.

Referring back to FIGS. 3-5, the fabric carcass layer 62 may be made from polyester, nylon, steel, aramid, para-aramid, or other fibers as are known in the art. The fabric in the carcass layer 62 may be single ply or multiple ply. In one embodiment, the fabric in the carcass layer 62 is unidirectional and may be aligned with the direction of rotation of the wheel 46, orthogonal to the direction of rotation of the wheel 46, or positioned otherwise. In another embodiment, the fabric in the carcass layer 62 has a weave pattern with a first set of fibers in the weave positioned in a first fiber direction and a second set of fibers in the weave positioned in a second fiber direction. The first set of fibers may be made from the same material or a different material as the second set of fibers. The first fiber direction may be orthogonal to the second fiber direction, or alternatively, may be arranged at any angle relative to the other. For example, as shown in FIG. 7, the first fiber direction is generally aligned with a rotational direction of the wheel with the second fiber direction generally orthogonal to the first fiber direction. Alternatively, the first fiber direction is offset from a rotational direction of the wheel with the second fiber direction generally orthogonal to the first fiber direction.

Referring back to FIGS. 3-5, the inner layer 60, intermediate layer 62, and the outer layer 64 may be bonded together during the manufacturing process for the tire 50 by using an adhesive or through another process as is known in the art.

In one embodiment the tire 50 is bonded to the wheel 48 using an adhesive. In another embodiment, the tire 50 is undersized relative to the rim 56 of the wheel 48, which retains the tire 50. Alternatively, one or two axial rings 66 (in phantom) are positioned on the outer surface 58 of the rim 56 and on either side of the tire 50 to mechanically retain the tire 50 on the wheel 48. In another embodiment, the outer surface 58 of the rim 56 is machined to have a specified roughness or a machined pattern to mechanically retain the tire 50 on the wheel 48.

FIG. 8 illustrates another embodiment of a tire 70 for use with a wheel 26. The tire has an inner layer 72 and an outer layer 74. The inner and outer layers may be different thicknesses to provide varying damping and wear characteristics. The intermediate layer 76 has multiple fabric carcass layers. The intermediate layer as shown has a pair of outer fabric layers 78, a central fabric layer 80, and additional elastomer layers 82 separating them. The elastomer layer 82 may be a natural or synthetic rubber or a polymer material. The pair of outer fabric layers 78 and the central fabric layer may contain the same or different weave patterns or fiber material.

FIG. 9 illustrates an embodiment of a tire 84 for use with a wheel 26. The tire has an inner layer 86 and an outer layer 88. The intermediate layer 90 has multiple fabric carcass layers. The intermediate layer 90 as shown has a pair of fabric layers 92 and an additional elastomer layer 94 separating them. The elastomer layer 94 may be a natural or synthetic rubber or a polymer material. The pair of fabric layers 92 may contain the same or different weave patterns or fiber material.

Referring back to FIG. 2, the tire 42 may be manufactured in several ways including: a molded continuous loop belt or splicing a belt that is prepared to length. A tire 100 with a spliced belt connection is shown in FIG. 10. For a spliced belt tire 100, a vulcanized step splice may be used with a series of steps prepared on the two tire ends 102, 104. These ends 102, 104 overlap the functional layers within the tire 100. The splice then undergoes a vulcanizing process for curing. When prepared properly, a vulcanized step splice can have similar load and bend ratings as the continuous portion of the tire 100.

The spliced belt tire may be attached to the wheel 32 using compression molding as shown in FIG. 11. The tire 100 has an inner layer 106 and an outer layer 108 which may be made from an uncured rubber. The intermediate layer 110 includes a fabric carcass layer. The layers of the tire 100 are placed within the compression mold 112. The outer piece 114 of the compression mold 112 is an outer die. The inner piece 116 of the compression mold 112 is either an inner die to fabricate a tire 100 alone, or the wheel 32 for direct compression molding of the tire 100 to the wheel 32. The outer piece 114 compresses the tire 100 against the inner piece 116 and heats it to form and cure the circular tire 100. Final curing of the tire in the compression mold 112 may also eliminate the joint as a potential weak spot. Compression molding the tire 100 directly onto the wheel 26 provides a strong bond between the inner layer 106 the rim of the wheel 32.

Referring back to FIG. 3, in other embodiments, the tire 50 may be attached and retained to the wheel 46 using a tensile force in the tire 50 to maintain a friction fit between the tire 50 and the wheel 46 or a structural adhesive may be used to bond the tire 50 to the wheel 46. In addition to the friction fit or the use of adhesive, the tire 50 may be mechanically retained on the wheel 46, and not molded directly to the wheel 46. This allows for replacement of the tire 50 in the field instead of returning them for reconditioning. An axial ring 66, or retention ring, retains and supports the tire 50 on one or both ends of the rim 56 to prevent the tire 50 from “walking off” the rim 56. In this configuration, the one of the two rings 66 is fixed while the other one of the rings 66 may be removed for assembly and disassembly of the tire 50.

The use of an adhesive bond or a friction fit with the tire 50 allows a tire 50 to be replaced in the field without the need for a remote refurbishment process to replace the tire 50.

For a friction fit tire 50, the tire 50 is undersized relative to the wheel 46 circumference. When the tire 50 is pressed over the wheel 46 a tensile force is developed in the tire 50, which creates a static contact pressure between the wheel 46 and tire 50. Depending on the initial preload based on the tire 50 sizing, the contact pressure can be relatively high, creating a significant friction force to resist tire slippage and shear off of the wheel 46. In one embodiment, the tire pretension is combined with an adhesive for a stronger bond. One method of assembling the tire 50 to the wheel 46 is depicted in FIG. 12, showing a press operation. The tire 50 is placed over a mandrel 120, which is adjacent to the wheel 48. A force is applied to the tire 50 causing it to slide on the mandrel and onto the wheel 48. Disassembly the tire 50 from the wheel 48 may include cutting the tire 50 and peeling it from the wheel 48. The wheel 48 rim may need to be cleaned if an adhesive is used before assembling a replacement tire 50 to the wheel 48.

The wheel 46 may additionally have a surface finish applied to the outer surface 58 of the rim 56, which may include scoring, blasting, machined grooves or ridges, or alternate wheel rim 56 geometry such as a convex or a concave profile to aid in retention of the tire 50.

While embodiments of the invention have been illustrated and described, it is not intended that these embodiments illustrate and describe all possible forms of the invention. Rather, the words used in the specification are words of description rather than limitation, and it is understood that various changes may be made without departing from the spirit and scope of the invention. Additionally, features of various implementing embodiments may be combined to form further embodiments of the invention.

Claims

1. A tire assembly for a tracked vehicle comprising: an inner tire layer forming a first tube sized to substantially cover an outer surface of a rim of a wheel;an outer tire layer forming a second tube with a larger diameter than the first tube, the outer tire layer adapted to contact a track of a vehicle; andat least one carcass layer interposed between the inner and outer tire layers, the carcass layer providing tensile and impact strength to prevent crack propagation from reaching the inner tire layer of the tire assembly thereby prolonging the useful life of the tire assembly and reducing the frequency of replacement of the tire assembly;wherein the inner and outer tire layers encapsulate the carcass layer to protect it from an environment of use.

2. The tire assembly of claim 1 wherein the at least one carcass layer is constructed from a fabric.

3. The tire assembly of claim 2 wherein a fiber in the fabric includes at least one of polyester, nylon, steel, aramid, and para-aramid.

4. The tire assembly of claim 2 wherein the fabric is single ply.

5. The tire assembly of claim 2 wherein the fabric is multiple ply.

6. The tire assembly of claim 1 wherein the at least one carcass layer has a weave having a first fiber direction and a second fiber direction generally orthogonal to the first fiber direction.

7. The tire assembly of claim 6 wherein the first fiber direction is generally aligned with a rotational direction of the wheel.

8. The tire assembly of claim 6 wherein the first fiber direction is offset from a rotational direction of the wheel.

9. The tire assembly of claim 1 wherein the at least one carcass layer further comprises a first carcass layer and second carcass layer; and the tire further comprises an intermediate tire layer between the first and second carcass layers.

10. The tire assembly of claim 1 wherein the inner tire layer has a stiffer compliance than the outer tire layer.

11. The tire assembly of claim 1 wherein the outer tire layer includes one of a natural rubber and a synthetic rubber.

12. The tire assembly of claim 1 wherein the inner tire layer includes one of a natural rubber and a synthetic rubber.

13. A wheel assembly for a tracked vehicle comprising: a wheel having a circular mounting flange with a wall extending radially outwards and circumferentially therefrom, and a peripheral rim connected to an outer edge of the wall, the peripheral rim having an outer surface; anda tire having: an inner layer sized to substantially cover the outer surface of the peripheral rim,at least one intermediate fabric carcass layer bonded to an outer surface of the inner layer, andan outer layer bonded to an outer surface of the at least one carcass layer, the outer layer adapted to contact a track of a vehicle;wherein the at least one intermediate carcass layer provides tensile and impact strength to prevent crack propagation from reaching the inner layer of the tire thereby prolonging the useful life of the tire and reducing the frequency of replacement of the tire.

14. The wheel assembly of claim 13 wherein the tire is a molded continuous loop belt.

15. The wheel assembly of claim 13 wherein the tire is a formed from a spliced belt.

16. The wheel assembly of claim 13 wherein the tire is undersized relative to the peripheral rim of the wheel.

17. The wheel assembly of claim 13 further comprising an adhesive between the outer surface of the peripheral rim and the inner layer of the tire to bond the tire to the wheel.

18. The wheel assembly of claim 13 further comprising at least one axial ring mounted to the outer surface of the peripheral rim of the wheel for mechanical retention of the tire to the wheel.

19. The wheel assembly of claim 13 wherein the outer surface of the peripheral rim is machined to mechanically retain the tire to the wheel.

20. A method of forming a tire assembly for a wheel of a tracked vehicle comprising: providing an inner tire layer as a first tube about a rim of a wheel, the inner tire layer sized to substantially cover an outer surface of the rim;positioning an outer tire layer about the inner tire layer as a second tube with a larger diameter than the first tube, the outer tire layer adapted to contact a track of a vehicle; andinterposing at least one carcass layer between the inner and outer tire layers, the carcass layer providing tensile and impact strength to prevent crack propagation from reaching the inner tire layer of the tire assembly thereby prolonging the useful life of the tire assembly and reducing the frequency of replacement of the tire assembly;wherein the inner and outer tire layers encapsulate the carcass layer to protect it from an environment of use.