A belt cover layer is disposed in a tire, spanning between shoulder regions, and is formed by winding one belt cover material in a helical shape around a rotation axis on an outer side of the belt layer in a radial direction, the belt cover layer includes a lap winding portion between the shoulder regions, in which parts of circumferential portions, adjacent in a width direction, of the belt cover material wound in a helical shape are lap-wound in the radial direction, a width of the lap winding portion in the width direction is 3-30% of a width of the belt cover layer in the width direction, and in portions of the belt cover layer in the shoulder regions, the circumferential portions, adjacent in the width direction, of the belt cover material are wound with out being lapped in the radial direction.

Provided is a tire in which low rolling resistance is improved by using reinforcing cords containing polyamide multifilaments as reinforcing cords of a reinforcing member of the tire. In a tire (10) that includes at least one belt reinforcing layer (3) covering the full width of a belt (2), the belt reinforcing layer (3) includes, as a constituent, a rubber-cord composite that is formed of a rubber and reinforcing cords containing multifilaments of a semi-aromatic polyamide composed of a polycondensate of an aromatic dicarboxylic acid-containing dicarboxylic acid and a non-aromatic diamine, or a polycondensate of a non-aromatic dicarboxylic acid and an aromatic diamine-containing diamine acid; and, when the width of a maximum-width belt layer constituting the belt (2) is defined as W, a region of at least more than 0.35 W from a tire equatorial plane is a sparse region in terms of the end count of the reinforcing cords in the belt reinforcing layer (3), while regions on the tire width-direction outer side of the sparse region are dense regions.

A pneumatic tire comprising a carcass 11, at least one inclined belt layer 13 having a cord extending inclined at an angle of 30° or more relative to the tire circumferential direction, and a tread 15 arranged outward in the tire radial direction of the inclined belt layer 13, wherein a circumferential cord layer 14 arranged inward in the tire radial direction of the tread 15 has a high-rigidity region and a low-rigidity region and the high-rigidity region has a higher negative ratio in a ground contact width of the tread 15 than the low-rigidity region.

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.

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.

A pneumatic tire includes a carcass layer and belt layers including belt cords inclined with respect to a circumferential direction, the belt cords of different layers being arranged in a criss-cross manner. In at least one belt layer, an inclination angle α of the belt cords with respect to the circumferential direction at a center position and an inclination angle β of the belt cords with respect to the circumferential direction at a belt end position satisfy 15°≤β<α≤35°. A maximum ground contact length L1 and a ground contact length L2 satisfy 0.8≤L2/L1≤1.0, where L1 is the maximum ground contact length in the circumferential direction, W1 is a maximum ground contact width in a radial direction, and L2 is the ground contact length in the circumferential direction at a position 40% of W1 from the center position outward in a lateral direction.

A pneumatic tire is provided with a belt layer and a reinforcing layer provided outside the belt layer in tire radial direction. The reinforcing layer has an inner reinforcing layer in which a strip member having a plurality of cords is wound along tire circumferential direction, and an outer reinforcing layer in which the strip member having a plurality of cords is wound along the tire circumferential direction and is provided outside tire radial direction of the inner reinforcing layer. The outer reinforcing layer has a gap between adjacent strip members in tire width direction.

A band 20 of a tire 2 includes a full band 48 covering an entirety of a belt 14, and a pair of edge bands 50 disposed so as to be spaced apart from each other in an axial direction and each covering an end 46 of the belt 14. A cross-section of the band 20 includes a large number of cross-sections of a band strip 52. In a cross-section of the full band 48, a plurality of cross-sections of the band strip 52 are aligned with a gap therebetween. In a cross-section of each edge band 50, a plurality of cross-sections of the band strip 52 are aligned without any gap therebetween. An inner end 62 of each edge band 50 is located so as to be spaced apart from a bottom BT of a shoulder circumferential groove 24s in the axial direction.

The invention relates to a pneumatic vehicle tire for passenger cars comprising a carcass (2), a tread (6) and a belt (7) which has belt plies (7a, 7b) and which is covered radially outwardly by a belt bandage (8) having strengthening elements oriented approximately in the circumferential direction, wherein the belt bandage (8) has at least one belt bandage ply (8a) whichas viewed in the tire cross sectionconsists of three sections, namely a central section (10) and two lateral sections (11, 12), wherein one lateral section (11) is arranged to the left of the central section (10) and one lateral section (12) is arranged to the right of the central section (10) and wherein the strengthening elements of the central section (10) have the construction x1 and wherein the strengthening elements of the two lateral sections (11, 12) have identical cords consisting of at least two twisted-together yarns.

The invention is distinguished by the fact that the two lateral sections (11, 12) are arranged next to the central section (10), that is to say without overlapping with the central section (10), that the density of the strengthening elements in the central section (10) is less than the density of the strengthening elements in the lateral sections (11, 12), and that the end of the lateral sections (13) that points toward the central section (10) in each case has a distance (14) of 5 mm-30 mm, preferably a distance (14) of 5 mm-15 mm, from the outer end of the widest belt ply (15), where the distance (14) is measured in the axial direction (aR).