The present invention relates to a tire and a tire manufacturing method.
A conventional tire manufacturing method is known in which non-vulcanized bonding rubber is placed in a layer shape on an outer circumference of a fully vulcanized tire frame member, a fully vulcanized tread (what is referred to as a pre-cured tread (PCT)) is disposed thereon, the non-vulcanized bonding rubber layer is then vulcanized using a vulcanizing can or the like, and the tire frame member and the tread are vulcanization bonded through the bonding rubber layer. Such a tire manufacturing method is often employed when retreading tires that have been fully used (for example, Japanese Patent Application Laid-Open (JP-A) No. 2009-269424).
However, in cases in which tires are manufactured using the above tire manufacturing method, slight gaps (gaps of approximately several hundred μm) sometimes occur between the bonding rubber layer and the tire frame member, or between the bonding rubber layer and the PCT, or between both, due to the shape of an outer circumferential face of the tire frame member, or the shape of an inner circumferential face of the PCT. These gaps are ameliorated by increasing the volume of the bonding rubber, namely, by increasing the thickness of the bonding rubber layer; however, the amount of heat generated increases when the volume of the bonding rubber is increased, such that there is a concern of a reduction in the durability of the tire due to thermal degradation.
An object of the present invention is to suppress a reduction in durability, while improving bonding properties between a tire frame member and a tread.
A tire of a first aspect of the present invention includes: a circular tire frame member; a tread that is vulcanization bonded to an outer circumference of the tire frame member via a bonding rubber layer; and a bonding rubber supplementation portion that is provided at the tread, that extends from a tread surface to the bonding rubber layer, and that is formed of an identical rubber material to the bonding rubber layer.
A tire manufacturing method of a second aspect of the present invention includes: arranging non-vulcanized bonding rubber in a layer shape at an outer circumference of a fully vulcanized tire frame member; arranging a fully vulcanized tread, including a bonding rubber supplementation portion that is formed by a non-vulcanized rubber material that is identical to the bonding rubber and that extends from a tread surface to far as a tread back face, at an outer circumference of the bonding rubber; and vulcanizing the bonding rubber and the rubber material.
The tire of the present invention enables a reduction in durability to be suppressed, while improving the bonding properties between the tire frame member and the tread.
Explanation follows regarding an aircraft tire and an aircraft tire manufacturing method of a first exemplary embodiment of the present invention.
As illustrated in
The tire frame member 12 forms a frame section of the tire 10, and is configured by bead portions 12A, side portions 12B, and a crown portion 12C. Although not illustrated in the drawings, conventionally known bead cores, a carcass ply, a belt ply, and the like are placed inside the tire frame member 12.
The tread 16 forms a ground contact section of the tire 10, and plural grooves extending around the tire circumferential direction are formed on the surface thereof. Specifically, as illustrated in
The tread 16 is also provided with circumferential direction grooves 22 extending around the tire circumferential direction at the tire axial direction outsides of the circumferential direction grooves 18, and is formed with rib-shaped intermediate land portions 24 that are each continuous around the tire circumferential direction between the respective circumferential direction grooves 18 and the circumferential direction grooves 22.
The tread 16 is also formed with rib-shaped shoulder land portions 26 that are each continuous around the tire circumferential direction at the tire axial direction outsides of the respective circumferential direction grooves 22.
As illustrated in
As illustrated in
As illustrated in
The cushioning rubber supplementation portions 30 may also be said to be configured by filling the cushioning rubber 31 into through-holes formed in the thickness direction of the tread 16.
As illustrated in
As illustrated in
In the present exemplary embodiment, a size relationship of the volumes of the cushioning rubber supplementation portions 32, 34, 36 is proportionate to a width relationship of the widths W1, W2, W3 of the respective land portions. Note that in the present exemplary embodiment, the width W3 is wider than the width W2. However, the present invention is not limited to this configuration.
In the present exemplary embodiment, the modulus at 100% elongation of the cushioning rubber 15 that forms the cushioning rubber layer 14 (AM), and the modulus at 100% elongation of the rubber that forms an inner circumferential face of the tread 16 (in other words, the rubber that forms the inner circumferential face of the tread 16) (BM) satisfy the relationship in Equation (i) below:
60%≦AM/BM≦140% Equation (i)
Note that when a ratio of the modulus at 100% elongation (AM) with respect to the modulus at 100% elongation (BM) (AM/BM) is less than 60%, or greater than 140%, a difference in rigidity occurs and strain is more liable to concentrate at an interface between the cushioning rubber layer 14 and an inner circumferential portion of the tread 16, such that the interface bonding properties are reduced, causing a reduction in durability. In cases in which the ratio (AM/BM) is less than 60%, there is a concern that strain increases at the cushioning rubber layer 14 itself, and a reduction in durability is more liable due to an increase in the amount of heat generated by the cushioning rubber 15.
It is therefore preferable that the modulus at 100% elongation of the cushioning rubber 15 (AM) and the modulus at 100% elongation of the rubber configuring an outermost layer of the tire frame member 12 (BM) satisfy the relationship in Equation (i). In particular, it is more preferable that the relationship in Equation (i-1) below is satisfied, from the perspective of securing bonding properties at the interface between the cushioning rubber layer 14 and the tread 16.
80%≦AM/BM≦120% Equation (i-1)
Note that in the present exemplary embodiment, the tread 16 is formed of one type of rubber; however, the present invention is not limited to this configuration. For example, configuration may be such that the tread 16 is formed by layering plural types of rubber. In such cases, the rubber that forms an innermost layer of the tread 16 corresponds to the rubber that forms the inner circumferential portion of the tread 16.
Explanation follows regarding a manufacturing method of the tire 10 of the present exemplary embodiment.
First, a non-vulcanized tire frame member 12 is formed by a conventionally known method. As an example, the tire frame member 12 may be formed by respectively wrapping both end portions of a carcass ply (not illustrated in the drawings) around a pair of bead cores, then wrapping a belt ply (not illustrated in the drawings) about an outer circumference of a crown portion of the carcass ply. Note that one or plural of both the carcass ply and the belt ply may be placed, depending on the tire specification. In the above example, explanation regarding various tire configuration members, such as an inner liner, bead filler, and a side rubber, is omitted.
Next, a fully vulcanized tire frame member 12 may be formed by applying pressure or applying heat to the non-vulcanized tire frame member 12, using a vulcanization mold or vulcanization can.
The tire frame member 12 may also be formed by stripping a tread from a tire, when the tread has exceeded a stipulated amount of wear, or after a stipulated duration has elapsed. Note that a tire frame member formed by removing a fully used tread from a tire is referred to as a casing, and a tire in which a new, fully vulcanized tread has been adhered to the casing is referred to as a retreaded tire.
Tread Molding Process
Next, a non-vulcanized tread rubber 17 is applied with pressure or vulcanized to mold a fully vulcanized tread 16. Plural through-holes piercing through in the thickness direction are then formed in the fully vulcanized tread 16, and the through-holes are filled with non-vulcanized cushioning rubber 31 to form non-vulcanized cushioning rubber supplementation portions 30. The fully vulcanized tread 16 is accordingly formed including the cushioning rubber supplementation portions 30, in which the non-vulcanized cushioning rubber 31 are formed so as to extend from the tread surface 16A as far as a tread back face 16B. Note that the fully vulcanized tread 16 may be formed in a belt shape with ends, or in an endless belt shape.
Cushioning Rubber Placement Process
Next, non-vulcanized cushioning rubber 15 is placed in a layer shape around the outer circumferential face of the fully vulcanized tire frame member 12. A non-vulcanized cushioning rubber layer 14 is formed accordingly.
Next, the fully vulcanized tread 16 is placed at the outer circumference of the non-vulcanized cushioning rubber layer 14.
Vulcanization Process
The tread 16 is then housed in a vulcanization can (not illustrated in the drawings) in a state pressed against the fully vulcanized tire frame member 12 with the cushioning rubber layer 14 interposed therebetween, and the non-vulcanized cushioning rubber 15 and the non-vulcanized cushioning rubber 31 are vulcanized. The tire frame member 12 is thereby vulcanization bonded to the tread 16 through the cushioning rubber layer 14, and the tire 10 is complete. During this vulcanization, the cushioning rubber 31 of the non-vulcanized cushioning rubber supplementation portions 30 is able to flow into the non-vulcanized cushioning rubber layer 14, such that, even supposing the volume of the non-vulcanized cushioning rubber 15 is insufficient, this insufficiency can be supplemented by the non-vulcanized cushioning rubber 31. This enables gaps to be suppressed from occurring in the non-vulcanized tire 10 between the cushioning rubber layer 14 and the tire frame member 12, and between the cushioning rubber layer 14 and the tread 16. Note that “fully vulcanized” referred to herein refers to a state in which the degree of vulcanization required of a final product has been reached, whereas a half-vulcanized state refers to a state in which the degree of vulcanization is higher than a non-vulcanized state, but has not reached the degree of vulcanization required of a final product.
Explanation follows regarding operational advantageous effects of the tire 10 of the present exemplary embodiment.
In the tire 10, the cushioning rubber supplementation portions 30 are formed to the tread 16, so as to pierce through the tread 16 and extend from the tread surface 16A as far as the cushioning rubber layer 14. Thus, when the fully vulcanized tire frame member 12 and the fully vulcanized tread 16 are vulcanization bonded through the non-vulcanized cushioning rubber layer 14, the non-vulcanized cushioning rubber 31 can flow into the non-vulcanized cushioning rubber layer 14 as described above, thereby enabling any insufficiency in the non-vulcanized cushioning rubber layer 14 to be supplemented. This enables gaps to be suppressed from occurring between the cushioning rubber layer 14 and the tire frame member 12, and between the cushioning rubber layer 14 and the tread 16, and enables the bonding properties of the tire frame member 12 and the tread 16 to be improved.
In the tire 10, any insufficiency in the non-vulcanized cushioning rubber layer 14 can be supplemented by the cushioning rubber 31 during vulcanization bonding, such that there is no need to increase the thickness of the non-vulcanized cushioning rubber layer 14 and increase the volume of the cushioning rubber 15. This enables a reduction in durability of the tire 10, caused by thermal degradation of the rubber due to an increase in the amount of heat generated, to be suppressed.
Explanation follows regarding an aircraft tire and an aircraft tire manufacturing method of a second exemplary embodiment of the present invention. Note that similar configuration to the first exemplary embodiment is appended with the same reference numerals, and explanation thereof is omitted.
As illustrated in
As illustrated in
Each cushioning rubber supplementation portion 58 is formed to the groove bottom center (the deepest groove portion) of the circumferential direction groove 18, and extends along the extension direction of the circumferential direction groove 18 (the tire circumferential direction in the present exemplary embodiment). Each cushioning rubber supplementation portion 60 is formed to the groove bottom center (the deepest groove portion) of the circumferential direction groove 22, and extends along the extension direction of the circumferential direction groove 22 (the tire circumferential direction in the present exemplary embodiment).
Each cushioning rubber supplementation portion 52 extends along the tire axial direction across the center land portion 20, and both ends thereof are linked to the respective cushioning rubber supplementation portions 58. Each cushioning rubber supplementation portion 54 extends along the tire axial direction across the intermediate land portion 24, with one end linked to the cushioning rubber supplementation portion 58, and the other end linked to the cushioning rubber supplementation portion 60. Each cushioning rubber supplementation portion 56 extends along the tire axial direction across the shoulder land portion 26, with one end linked to the cushioning rubber supplementation portion 60, and the other end linked to the tread end 16E (as a component of the tread end 16E).
As illustrated in
Explanation follows regarding a manufacturing method of the tire 40 of the present exemplary embodiment. Note that explanation of the same processes as the manufacturing method of the tire 10 of the first exemplary embodiment is omitted.
First, plural tile-shaped tread rubber pieces (illustrated by the reference numerals 17A in
Next, the fully vulcanized tread rubber pieces 17A are aligned in the tire circumferential direction and aligned in the tire axial direction, and the tread 16 is molded (assembled). When this is performed, non-vulcanized cushioning rubber 51 is placed between fully vulcanized tread rubber pieces 17A that are adjacent to each other. Note that the tread 16 may be molded (may be assembled) by aligning the fully vulcanized tread rubber pieces 17A while adhering the non-vulcanized cushioning rubber 51 to the fully vulcanized tread rubber pieces 17A. A fully vulcanized tread 16 is thereby formed including cushioning rubber supplementation portions 50 in which the cushioning rubber 51 extends from the tread surface 16A as far as the tread back face 16B.
The fully vulcanized tread 16 is then disposed at the outer circumference of the tire frame member 12 with the non-vulcanized cushioning rubber layer 14 interposed therebetween, and the non-vulcanized cushioning rubber 15 and the non-vulcanized cushioning rubber 51 are vulcanized, such that tread 16 is vulcanization bonded to the tire frame member 12 through the cushioning rubber layer 14. The adjacent tread rubber pieces 17A are also vulcanization bonded together through the cushioning rubber 15. The tire 40 is accordingly complete.
Explanation follows regarding operational advantageous effects of the present exemplary embodiment. Note that explanation regarding operational advantageous effects that are also obtained by the tire 10 of the first exemplary embodiment is omitted.
In the tire 40, the cushioning rubber supplementation portions 58, 60 that each extend around the tire circumferential direction are formed to the respective circumferential direction grooves 18, 20, and the cushioning rubber supplementation portions 52, 54, 56 that each extend along the tire axial direction are formed to the respective center land portions 20, 24, 26. This enables the cushioning rubber 51 to uniformly supplement the cushioning rubber layer 14 over a wider range during vulcanization than in the tire 10 of the first exemplary embodiment, thereby enabling gaps to be effectively suppressed from occurring between the cushioning rubber layer 14 and the tire frame member 12, and between the cushioning rubber layer 14 and the tread 16.
The tread 16 of the first and second exemplary embodiments is configured only of rubber material (the tread rubber 17); however the present invention is not limited to this configuration, and a protective layer may be provided to an inner layer side (the back face side) of the tread 16. Cords (such as organic fiber cords) extending in a wave shape around the tire circumferential direction and formed aligned in the tire axial direction with intervals therebetween, for example, may be employed as the protective layer.
The tire 10 of the first exemplary embodiment and the tire 40 of the second exemplary embodiment of the present invention are both aircraft tires; however, the present invention is not limited thereto. Tires of other exemplary embodiments of the present invention may be bus tires, truck tires, or construction vehicle tires, for example.
Exemplary embodiments have been explained above as exemplary embodiments of the present invention; however, these exemplary embodiments are merely examples, and various modifications may be implemented within a range not departing from the spirit of the present invention. Obviously the scope of rights of the present invention is not limited by these exemplary embodiments.
Test Examples
Five types of tire that are examples in the present invention, and two types of tire of Comparative Examples that are not included in the present invention were prepared, the below tests were carried out, and an evaluation was performed. Tires that each had a size of 30×8.8R15 16PR were employed as the sample tires. Note that Table 1 shows the manufacturing method, the type of tread rubber, and the type of cushioning rubber of each sample tire. The “manufacturing method B” shown in Table 1 indicates the tire manufacturing method of the first exemplary embodiment of the present invention, and the “manufacturing method C” indicates the tire manufacturing method of the second exemplary embodiment of the present invention. The “manufacturing method A” shown in Table 1 indicates a normal manufacturing method (a manufacturing method that is not included in the present invention) in which a belt-shaped pre-cured tread (PCT), without through-holes formed for supplementing a cushioning rubber, is wrapped onto a tire frame member (a casing) with a cushioning rubber layer interposed therebetween, and vulcanization is then performed using a vulcanization can to obtain a tire. Note that there is no cushioning rubber supplementation portion formed to the tires manufactured by the manufacturing method A, as is formed in the tires manufactured by the manufacturing method B and the manufacturing method C. Table 2 shows blending formulations of a rubber A to a rubber E employed as tread rubber and cushioning rubber of the sample tires.
Measurement of Modulus at 100% elongation
A rubber sheet with a thickness of 0.3 mm was cut out from respective locations of each sample tire and cut to form a test sample cut with a DIN 53504-S3A type cutter shape. Under a condition of a stretch speed of 100 mm per minute, the modulus at 100% elongation of the cushioning rubber forming the cushioning rubber layer (AM) and the modulus at 100% elongation of the rubber forming the inner circumferential portion of the tread (BM) were measured for each sample, and the ratio of the moduli at 100% (AM/BM) was derived, as shown in Table 1. Table 1 also shows whether or not each sample tire satisfies Equation (i).
Drum Durability Test
Next, each sample tire was fitted to a standard rim, then attached to a drum test machine and one cycle of test “TSO-C62 d” approved by the U.S. Federal Aviation Administration (FAA) was performed. Durability testing was implemented in which the proportion of a surface area of damaged portions with respect to a surface area without damaged portions on a tread interface (the interface between the tread and the cushion layer) was visually evaluated. The test results for the respective sample tires are shown in Table 1 as indices, with the test result of the Comparative Example 1 as a reference value (100). Note that the higher the value of the durability test result shown in Table 1, the better the result.
As illustrated in Table 1, each of the tires of the examples 1 to 5 has better durability than the tires of the Comparative Example 1 and the Comparative Example 2. It is conceivable that this is because the tires manufactured by the manufacturing method B and the manufacturing method C in the present invention have improved bonding properties between the tread and the tire frame member through the cushioning rubber layer, due to improved bonding properties between the tread and the cushioning rubber layer, such that the durability has improved as a result.
Although the tire of the Comparative Example 1 and the tire of the Comparative Example 2 are both manufactured by the manufacturing method A, the tire of the Comparative Example 1 has obtained a better durability result than the tire of the Comparative Example 2. It is conceivable that this is because the tire of the Comparative Example 1 satisfies Equation (i), whereas the tire of the Comparative Example 2 does not satisfy Equation (i). Specifically, in the tire of the Comparative Example 2, it is conceivable that the modulus at 100% elongation (AM) of the rubber C that is a component of the cushioning rubber is too high compared to that of the rubber A that is a component of the tread rubber, such that a large difference in rigidity has occurred and strain is more liable to concentrate at the tread interface.
When the tire of the Comparative Example 2 and the tire of the Example 3 are compared, although neither the tire of the Comparative Example 2 nor the tire of the Example 3 satisfy Equation (i), the tire of the Example 1 obtained a better durability result than the tire of the Comparative Example 2. It is conceivable that this is because a difference in the bonding properties at the tread interface occurred, due to the tire of the Comparative Example 1 being manufactured by the manufacturing method A, whereas the tire of the Example 3 was manufactured by the manufacturing method B.
When the tire of the Comparative Example 2 is compared with the tire of the Example 1 and the tire of the Example 2, the tire of the Example 1 and the tire of the Example 2 have much better durability than the tire of the Comparative Example 2. It is conceivable that this is because the tire of the Example 1 and the tire of the Example 2 were respectively manufactured by the manufacturing method B and the manufacturing method C in the present invention, and satisfy Equation (i).
The entire contents of the disclosure of Japanese Patent Application No. 2013-115819, filed on May 31, 2013, are incorporated by reference in the present specification.
Number | Date | Country | Kind |
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2013-115819 | May 2013 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2014/064655 | 6/2/2014 | WO | 00 |