A hooping reinforcement of a tire for a heavy duty civil engineering type vehicle is disclosed. The crown reinforcement (3) of the tire (1), radially on the inside of a tread (2), comprises a protective reinforcement (6), a working reinforcement (5) and a hooping reinforcement (7). Said hooping reinforcement (7) has an axial width at most equal to the smallest axial width (L61, L62) of the two working layers (61, 62), and comprises at least two hooping layers (71, 72) that are formed from strips each made up of elastic metal reinforcers. Each hooping layer (71, 72) is made up of an axial juxtaposition of contiguous turns of the strip (8), which are circumferentially wound around the working layer (51). Each strip (8) is at least 35 mm and at most 250 mm thick, and its distributed breaking tension is at least equal to 100 daN/mm.

A pneumatic tire includes a tread portion, and a belt layer including a plurality of belt plies on an inner side in a tire radial direction of the tread portion. In such a pneumatic tire, a mounting direction of the pneumatic tire on a vehicle is specified; the belt layer includes a circumferential reinforcing layer, circumferential reinforcing layer cords being disposed side by side in a tire width direction in the circumferential reinforcing layer, the circumferential reinforcing layer cords being inclined with respect to a tire circumferential direction within a range of ±5° in the tire width direction; and a cord count, namely a number of the circumferential reinforcing layer cords in the tire width direction, of the circumferential reinforcing layer is greater on an inner side in a vehicle mounting direction than on an outer side in the vehicle mounting direction, based on a tire equatorial plane.

The pneumatic motorcycle tire includes a spiral belt, wherein: an aspect ratio of the tire is 60% or more; at a standard condition, each lap of reinforcing cords is located at a constant spacing along a periphery of the spiral belt among the entire tire width direction; in the tire widthwise cross section, a spacing A along the periphery of the spiral belt between each lap of the reinforcing cords adjacent in the tire width direction is 3.5 mm or more and 6.0 mm or less; a spacing B along the periphery of the spiral belt between the two reinforcing cords for forming the strip member is 0.8 mm or more and 1.5 mm or less; and a rupture strength of one of the reinforcing cords is 200 N or more and 1000 N or less.

An aircraft pneumatic tire includes a spirally wound belt layer in which a ribbon-shaped first strip material with a first belt cord including organic fibers and being covered with rubber is spirally wound; and zigzag belt layers in which a ribbon-shaped second strip material with a second belt cord including organic fibers and being covered with rubber extends and is wound in a circumferential direction while bending zigzag by being folded back at width directional end edges to an outer circumferential side of the spirally wound belt layers. The maximum width of the spirally wound belt layers is wider than the maximum width of the zigzag belt layers, and the width of the second strip material is wider than the width of the first strip material.

A pneumatic tire comprising a belt formed of two inclined belt layers formed of a rubberized layer of cords extending in a manner inclined with respect to a tire circumferential direction, the cords crossing each other between the layers, wherein: the two inclined belt layers have different tire widthwise widths W1 (mm) and W2 (mm); a ratio W2/W1 satisfies a relation expression 0.25≦(W2/W1)≦0.8; a tire radial outer side of the belt further includes a reinforcing belt formed of one or more circumferential belt layers formed of a rubberized layer of cords extending along the tire circumferential direction; and a circumferential rigidity of the reinforcing belt in a tire widthwise region between an end of the one inclined belt layer and an end of the other inclined belt layer is higher than a circumferential rigidity of the reinforcing belt in a tire widthwise inner side of the region.

Improve endurance of tire for heavy-duty vehicle of construction plant type. A hoop reinforcement has an axially continuous first hooping layer and axially discontinuous second hooping layer, first layer has an axial width LF1 at least equal to 25% and at most 75% of axial width LT of working reinforcement, the discontinuous second hooping layer consists of two hooping strips symmetrical with respect to equatorial plane (XZ) of tire, each extends axially from axially interior end as far as axially exterior end over an axial width LF2 which is at least equal to 10% and at most 35% of axial width LF1 of the first hooping layer, and the distributed tension at break TR of each hooping strip defined as the product of number D of reinforcers per mm times the force at break FR of each reinforcer expressed in daN, is at least equal to 100 daN/mm.

In a pneumatic tire, a belt cover layer is provided on an outer circumferential side of a belt layer in a tread portion and includes organic fiber cords helically wound along a tire circumferential direction. As the organic fiber cord, a polyethylene terephthalate fiber cord is used which has a single yarn size fineness of 700 dtex or less and in which the number of twists is 30 twists or more/100 mm. A layer thickness of the belt cover layer is 1.6 times or more as large as a cord diameter of the organic fiber cord.

A tire reinforcement fabric is woven with predipped and heat-set single cords as warp bound together with weft materials, and a pneumatic tire includes a tire reinforcement fabric. The tire reinforcement fabric is obtained by weaving individually dipped cords as warp material and a plurality of any kind of weft materials.

Provided are: an elastomer-metal cord composite which can improve various performance of a tire, such as steering stability, corrosion propagation resistance, and belt layer separation resistance; and a tire including the same. In an elastomer-metal cord composite (10), a metal cord (2) composed of a bundle of plural metal filaments (1) that are arranged in a single row without being twisted together is coated with an elastomer (3). A gap is provided between adjacent metal filaments, and when the diameter of the metal filaments is defined as D (mm), a gap amount, which is a distance between the surfaces of the adjacent metal filaments that is measured in a direction orthogonal to an extending direction of the metal cord, is defined as G (mm), and the number of metal filaments constituting the metal cord is defined as N (filaments), the elastomer-metal cord composite (10) satisfies a relationship expressed by the following Formula (1): 0.45≤[(D/2).sup.2×π×N]/{D×[D×N+G×(N−1)]}≤0.77 (1) wherein, D and G>0, and N is an integer.

In a pneumatic tire according to an embodiment, a belt layer is configured such that the angle of a belt cord relative to the tire circumferential direction is more than 30° and 40° or less. An organic fiber cord of a belt-reinforcing layer, which is placed on the radially outer side of the belt layer, is configured such that when the number of twists per 10 cm length is T (twists/10 cm), the fineness is D (dtex), and the fiber density is ρ (g/cm.sup.3), the twist coefficient K defined as T×(D/ρ).sup.1/2 is 900 to 2,600, and the product of the load at 5% elongation LASE 5% (N) of the organic fiber cord and the end count E (cords/25 mm) of the organic fiber cord is 1,000 N or more.