Abstract: A pneumatic tire mounted with surface fastener members for attaching an object to a tire inner surface, comprises: at least eight surface fastener members having an intermittent arrangement on a tread inner circumferential surface, the surface fastener members having a uniform cross-sectional dimension, an overall band-like shape, and a length in a tire axial direction from 50% to 120% of a maximum belt width of the pneumatic tire; wherein an angle ? between a longitudinal direction of the surface fastener members and the tire axial direction is from 0 degrees to 45 degrees; and an installation period in a tire circumferential direction is from 80% to 150% of the length in the tire axial direction of the surface fastener members.

Abstract: A heavy-duty tire includes a tread part formed such that the tread part includes a crown profile including tire equator, and a pair of shoulder profiles extending from outer sides of the crown profile to tread edges. In a tire cross section including tire rotation axis in 5% internal pressure state in which the tire is mounted to a normal rim, filled with air at internal pressure of 5% of normal internal pressure and loaded with no load, each of the crown and shoulder profiles has an arc shape convex toward tire radial direction outer side such that ratio Rc/Rs of curvature radius Re of the crown profile to curvature radius Rs of each shoulder profile is 7.0 or more, and a tire axial direction distance from the equator to a connecting point between the crown profile and each shoulder profile is 0.70 or more times a tread half width.

Abstract: A continuous method for synthesizing a diene elastomer includes modifying the diene elastomer in a functionalizing device by: a kinetic model according to which the ratio of the rate constants is greater than 1, and a flow represented by a residence time distribution in the functionalizing device that is expressed according to equations 1 or 3: (i) in a functionalizing device having at least one tubular continuous reactor or having at least one cascade of at least two stirred reactors, E 1 ? ( t ) = 1 2 ? ( P ?? 1 ? t ) 1 2 ? e - P ? ( ? 1 - t ) 2 4 ? ? 1 ? t Eq ? ? 1 (ii) in a functionalizing device that is a combination of the device (i) and of a device having at least one continuous stirred reactor, having a residence time distribution characterized by the following equation: E 2 ? ( t ) = e ( - t ? 2 ) ? 2 Eq ? ? 2 the device (ii) having a residence time distribution characterized by the

Abstract: A tire having a crown reinforcement (5), comprising at least one crown layer (51), and a carcass reinforcement (6), comprising at least one turned-up carcass layer (61), the turned-up carcass layer (61) comprising mutually parallel reinforcers turned up, within each bead, from the inside towards the outside of the tire around a bead wire (7), to form a turn-up (8) comprising a free end (E). The turned-up carcass layer (61) comprises a crown portion (611) and a lateral portion (612), the crown portion (611) extending axially between a first and a second end (E1, E?1) which is symmetric about the equatorial plane (P), the lateral portion (612) extending radially inwards, from a first end (E2) as far as a second end (E3). The reinforcers of the lateral portion (612) and the reinforcers of the turn-up (8) form, with the circumferential direction (X), specified angles.

Abstract: An object of the present invention is to provide a pneumatic tire of which rolling resistance is reduced without impairing wear resistance. Specifically, the pneumatic tire of the present invention comprises: a tread portion; a pair of side wall portions; a pair of bead portions; a carcass constituted of at least one carcass ply extending in a toroidal shape between bead cores in the respective bead portions; a belt disposed on the outer peripheral side of a crown region of the carcass and formed by at least one inclined belt layer made of cords extending to be inclined with respect to the equatorial plane of the tire; and a tread rubber disposed on the radially outer side of the belt, wherein a ratio of BD/BW satisfies the following formula: (0.062×tire aspect ratio?0.01)<BD/BW<(0.062×tire aspect ratio+0.

Abstract: The present invention aims at providing a pneumatic tire for a motorcycle, capable of improving steering stability and wear resistance in a turning situation with maintaining good turning performance achieved by a relatively wide auxiliary belt layer. Specifically, the present invention provides a pneumatic tire for a motorcycle, characterized in that: the auxiliary belt layer is sectioned into a middle area Am overlapping a region where the belt layer is provided and respective side areas As each extending beyond the region where the belt layer is provided; the cords in the middle area Am extend at an inclination angle ?m in the range of 70° to 90° with respect to the tire circumferential direction; and the cords in each side area As extend, in at least a portion of the side area, at an inclination angle ?s different from the inclination angle ?m with respect to the tire circumferential direction.

Abstract: A belt structure for a two-wheeled vehicle made by means of strip-like segments or elements, each including parallel cords embedded in an elastomeric layer, sequentially laid along the circumferential extension of a toroidal support so as to form a reinforcing layer having a continuous circumferential extension around a geometric rotation axis of the toroidal support, wherein each strip-like element is laid in a laying trajectory defining, at each point, a laying angle; at each point of the laying trajectory a laying gap is formed between adjacent strip-like elements; the laying trajectory is formed starting from preselected laying angles on the shoulder and on the crown of the tire; the laying gap between adjacent strip-like elements varies along at least one length of said laying trajectory between crown and shoulder so as to cause variation of the laying angle and obtain the preselected angles on the shoulder and on the crown.

Abstract: A pneumatic tire having a carcass and a belt reinforcing structure wherein the belt reinforcing structure is a composite belt structure having at least one radially inner spiral layer and at least one zigzag belt reinforcing structure located radially outward of said spiral layer. The zigzag belt width is preferably wider than the spiral layer.

Abstract: A tire for a construction vehicle according to the present invention provides a tire for a construction vehicle having a belt formed by plural layers on the radially outer side of a crown portion of a carcass toroidally extending between a pair of bead portions, in which an outermost belt layer located on the radially outermost side of the belt has a width of 50% or more of a tread width, and a narrow groove is provided such that a distance between an end portion of the outermost belt layer and a bottom portion of the narrow groove is in the range of 15% to 100% of a tread thickness T, where T is a tread thickness at the end portion of the outermost belt layer.

Abstract: A pneumatic tire is described which includes a tread, a carcass and a belt structure interposed between the carcass and the tread. The belt structure includes a pair of working belts, wherein the angle of the working belts range from about 15 degrees to about 30 degrees, wherein the belt structure further includes a zigzag belt structure located between the working belts. The zigzag belt structure is formed of at least two layers of cords interwoven together from a strip of rubber reinforced with one or more cords, wherein the strip forming the zigzag belt structure is layed up in a first zigzag winding extending from a first lateral belt edge to a second lateral belt edge in a zigzag wavelength having a first amplitude W1 followed by a second amplitude W2, and a second zigzag winding formed of a zigzag wavelength having a first amplitude W2 followed by a second amplitude W1.

Abstract: A pneumatic tire comprises a tread, a carcass and a belt structure interposed between the carcass and the tread. The belt structure includes a zigzag belt structure formed of at least two layers of cords interwoven together from a strip of rubber reinforced with one or more cords. The strip forming the zigzag belt structure is layed up in a winding pattern in accordance with the following formula: for i=1 through L, the ith winding pattern is: [WL-(i-1)Wi]×N for each drum revolution, wherein L is the number of different amplitudes used to define the zigzag cycle and L?2, and N is the number of zigzag cycles per drum revolution and N is either an integer ?1 or N=1/2n wherein n is an integer ?1.

Abstract: Provided is a base tire securing cut resistance while retaining rolling resistance performance of the tire and a tire built on such a base tire. A base tire includes a base rubber which forms the outer periphery of the base tire to which a tread rubber is applied, a pair of mini side rubbers, each protecting the axial edge of the base rubber, and a pair of outer rubber layers, each overlapping the axially outer side of the mini side rubber.

Abstract: There is provided a pneumatic tire having excellent uneven wear resistance performance, low rolling resistance and durability of side portion's appearance. The pneumatic tire comprises a carcass as a framework consisting of at least one carcass ply troidally extending between bead portions embedded with a pair of bead cores and turned around the bead cores from an inner side to an outer side in a tire width direction, a belt comprising at least one inclined belt layer and a tread successively disposed on a radially outer side of a crown portion of the carcass, wherein a ratio BD/BW is in a range between 0.01 and 0.

Abstract: An aeroplane tire comprising a tread, a crown reinforcement radially on the inside of the tread and comprising at least one crown layer, the radially interior crown layer having an axial width (L2) at least equal to two-thirds of the maximum axial width (L1) of the tire and comprising a concave portion of which the axial limits (M2, M?2), on either side of the equatorial plane (XZ), are the radially exterior points of the said crown layer, carcass reinforcement radially on the inside of the crown reinforcement and comprising at least one carcass layer, the radially exterior carcass layer comprising a concave portion of which the axial limits (M3, M?3), on either side of the equatorial plane (XZ), are the radially exterior points of the said carcass layer.

Abstract: A heavy load pneumatic radial tire according to the present invention includes in order, on the radial direction outer side of a carcass extending toroidally between a pair of bead portions, at least one belt reinforcing layer, two or more inclined belt layers, and a tread. When the tire is mounted on a prescribed rim, with prescribed internal pressure applied and in a no-load condition, a width direction edge of the belt reinforcing layer is located further toward the width direction outer side than the tread edge.

Abstract: A heavy duty radial tire comprises a tread portion divided into four or five circumferential ribs and a tread reinforcing belt including a maximum width belt ply. The width Bw of the maximum width belt ply is 0.90 to 0.98 times the tread width Tw. The contour shape of the tire footprint has a ground contacting length CB at a 70% width position and a ground contacting length CC at a 97% width position, wherein the ratio CB/CC is 1.00 to 1.06. In a tread edge near region J, (1) the axially outermost shoulder rib is provided with no circumferential groove having a width of less than 5 mm, and a ratio Rs/Rc of an axial width Rs of the shoulder rib to an axial width Rc of a center rib is 1.25 to 1.

Abstract: A pneumatic tire includes: a pair of bead portions including a bead core and a bead filler; a carcass layer having a single-layered structure and extending between the bead portions; and a plurality of belt layers disposed at outer circumference of the carcass layer, wherein the carcass layer is folded around the bead core to enfold the bead filler and to have a folded portion that extends to a position beneath a side edge portion of one of the belt layers, and wherein the pneumatic tire further includes a rubber reinforcing layer made of rubber having JIS hardness in a range from 70 to 100 and having average thickness in a range from 0.5 mm to 3.0 mm, the rubber reinforcing layer being disposed on the folded portion at a side wall portion to extend across a maximum width position Pm of the carcass layer.

Abstract: An object of the present invention is to provide a pneumatic tire which can be easily manufactured and can reliably reduce cavity resonance sound.

Abstract: In the manufacture of a tire, a belt structure is made by means of strip-like segments or elements, each comprising parallel cords embedded in an elastomeric layer, sequentially laid along the circumferential extension of a toroidal support, in such a manner that: each strip-like element is laid in a laying trajectory defining, at each point, a laying angle; at each point of the laying trajectory a laying gap is formed between adjacent strip-like elements, the laying trajectory being formed starting from preselected laying angles on the shoulder and on the crown of the tire, the laying gap between adjacent strip-like elements varying along at least one section of the laying trajectory between crown and shoulder so as to cause variation of the laying angle and to obtain the preselected angles on the shoulder and on the crown.

Abstract: A tire comprising a crown reinforcement which is itself capped radially with a tread, the crown reinforcement containing at least one layer of circumferential reinforcing elements distributed axially at a variable pitch. The layer of circumferential reinforcing elements comprising five parts, these being a central part, two intermediate parts and two axially exterior parts, the pitch in the central part being in the range between 1 and 1.5 times the pitch of the axially exterior parts and the pitch in an intermediate part being in the range between 1.6 and 2 times the pitch of the axially exterior parts.

Abstract: In a cross section in a tire width direction when a tire is mounted on a prescribed rim (7), a belt has a flat shape in the tire width direction, the height (SWh) of the position where the tire width is the maximum is more than half the cross-sectional height (SH) of the tire, and a path length (CSR1) of the carcass from an intersection (I1) to an intersection (I2), is longer than a path length (CSR2) of the carcass from the intersection (I1) to an intersection (I3).

Abstract: A tire with a radial carcass reinforcement comprising a crown reinforcement formed from at least two working crown layers of inextensible reinforcing elements and from at least one layer of circumferential reinforcing elements positioned radially between two working crown layers, the working crown layers adjacent to the layer of circumferential reinforcing elements being on each side of the equatorial plane and in the axial continuation of the layer of circumferential reinforcing elements coupled over an axial width, in order thereafter to be decoupled. A layer of polymer blend having a thickness greater than 1.5 mm over an axial width greater than 0.1×d is positioned axially between the axially exterior end of the layer of circumferential reinforcing elements and the axially interior end of the coupling zone of the working crown layers.

Abstract: A pneumatic tire having an impact resistant construction is provided. More specifically, a tire is provided that has increased resistance to travel conditions that can cause pinch shock. Reinforcements of a particular orientation are provided in portions of the tire where pinch shock typically occurs. A range of orientations for the cords used in such reinforcements is described.

Abstract: The present invention enhances noise performance and anti-uneven wear performance. A pneumatic tire 1 includes a belt layer 7 including at least one belt ply in which belt cords 15 are arranged at an angle of 10 to 40° with respect to a tire equator C. A tread pattern formed on a surface of the tread portion 2 includes a pitch line 22 in which at least two kinds of pattern-constituting units 21 having different pitches in a circumferential direction of the tire are arranged in the circumferential direction of the tire. The belt cords 15 are arranged relatively densely on an inner side of the pattern-constituting unit 21 having a small pitch, and relatively thinly on an inner side of the pattern-constituting unit 21 having a large pitch.

Abstract: A pneumatic tire having a carcass and a belt reinforcing structure wherein the belt reinforcing structure is a composite belt structure having at least one radially inner spiral layer and at least one zigzag belt reinforcing structure located radially outward of said spiral layer. The zigzag belt width is preferably wider than the spiral layer.

Abstract: A pneumatic tire includes at least three belts arranged on a tire-radial-direction outer side of a carcass and a belt edge cushion arranged between a tire-width-direction outer end portion of a second belt that is secondly arranged from the tire-radial-direction outer side and a tire-width-direction outer end portion of a third belt that is thirdly arranged. The second belt is curved to a tire-radial-direction inner side in an area of the belt edge cushion in a tire width direction. A tire-width direction outer end of a first belt that is firstly arranged from the tire-radial-direction outer side is provided in a position close to a tire-width-direction inner end of the belt edge cushion in the tire width direction.

Abstract: A pneumatic tire includes two cross belts having codes forming 5 to 30 degrees to a tire circumferential direction; a circumferential reinforcing layer having a width smaller than the cross belts, and having codes forming 0 to 5 degrees to the tire circumferential direction; and a carcass located inside, in a tire diameter direction, relative to a cross belt being inside among the cross belts. At 100% internal inflation pressure, a distance X1 between an equatorial plane and an outer edge of the circumferential reinforcing layer is 60% to 75% of a distance W between the equatorial plane and an outermost section of the carcass, and at 5% internal inflation pressure, a distance Y between the equatorial plane and a separation section of the carcass and a belt outwardly adjoining the carcass is 95% to 105% of a distance X2 between the equatorial plane and the outer edge.

Abstract: A pneumatic tire wherein a distance t from an equatorial plane of a tire to outer circumferential main grooves and a distance b from the equatorial plane of the tire to an edge of a belt edge cushion in the width direction of the tire satisfy 0.85?t/b?0.90, in a cross-section in a meridian direction of the tire. Moreover, a distance d, which is half the width of a belt ply having the largest width, and a distance u from the equatorial plane of the tire to narrow grooves, satisfy 0.97?d/u?1.03. Furthermore, a distance a, which is half the width of a belt ply in the outermost layer, and a distance t, of outer circumferential main grooves, satisfy 1.15?a/t?1.25.

Abstract: Provided is a pneumatic radial tire including a main belt layer and at least one circumferential-direction reinforcement layer, which are provided in the tread portion. The main belt layer includes two belt layers in which steel cords are disposed in a manner that the steel cords of a first one of the two belt layers intersect the steel cords of a second one of the two belt layers. In the circumferential-direction reinforcement layer, steel cords are disposed in a substantial tire circumferential direction. The ratio Wo/Wm of the width Wo of the circumferential-direction reinforcement layer to the maximum width Wm of the main belt layer is 0.5 to 0.9. The ratio Ee/Ec of the reinforcement-cord elastic modulus Ee of the steel cords in the edge portions of the circumferential-direction reinforcement layer to the reinforcement-cord elastic modulus Ec of the steel cords in the center portion of the circumferential-direction reinforcement layer is not less than (0.85?0.5 Wo/Wm) and not more than 0.8.

Abstract: A tire comprising a carcass-type reinforcement structure formed from reinforcing elements anchored on each side of the tire to a bead, the base of which is intended to be mounted on a rim seat, each bead being extended radially outwards by a sidewall, the sidewalls joining, radially outwards, a tread and having, beneath the tread, a crown reinforcement structure consisting of at least two layers of reinforcing elements called working layers, said reinforcing elements of the working layers being of identical nature. In a given circumferential plane, the extensional stiffness per unit width of a first working layer measured along the principal direction of the reinforcing elements of said first layer is strictly higher than the extensional stiffness per unit width of a second working layer measured along the principal direction of the reinforcing elements of said second working layer, the second working layer being radially further away from the carcass structure than said first working layer.

Abstract: Provided is a pneumatic tire for a motorcycle which does not produce a failure such as early wear or uneven wear and which has improved grip while turning. The pneumatic tire for a motorcycle is a pneumatic tire for a motorcycle including a ring-shaped tread portion. The tire has, inside in the tire radial direction of the crown portion, at least one spiral belt layer having a width narrower than the width of the tread portion; at the shoulder portion of the tread portion, an inner layer rubber having a smaller modulus at 300% elongation at room temperature than that of a surface layer rubber is arranged; the inner layer rubber extends to a buttress portion; and the range of the ratio of the moduli between the inner layer rubber and the surface layer rubber is from 0.3 to 0.9.

Abstract: A tire having a radial carcass reinforcement comprising a crown reinforcement formed of at least two working crown layers of inextensible reinforcement elements, which are crossed from one ply to the other, forming angles of between 10° and 45° with the circumferential direction, which itself is topped radially by a tread, said tread being joined to two beads by means of two sidewalls and the axially widest working crown layer being radially internal to the other working crown layers.

Abstract: The present invention provides a belt formed of a spirally wound strip member constituted of a few juxtaposed cords and rubber coating thereon, with a structure which can absorb influence of difference in winding diameter at the unit width portion of the strip member without deteriorating productivity of the tire.

Abstract: A tire for a heavy vehicle, with radial carcass reinforcement, having an outside radius R greater than 1000 mm, comprising a crown reinforcement radially interposed between the carcass reinforcement and the tread, said crown reinforcement having at least one protective crown reinforcement radially adjacent to the tread. The tire comprises a complex having at least one layer of polymer mix with an axial width that is less than the width of the working crown reinforcement and with a thickness that is greater than 16 mm, the elastic modulus of said complex having a radial gradient, the lowest elastic modulus being greater than 15 MPa.

Abstract: A pneumatic tire having a carcass and a belt reinforcing structure wherein the belt reinforcing structure is a composite belt structure having at least one radially inner spiral layer and at least one zigzag belt reinforcing structure located radially outward of said spiral layer. The zigzag belt width is preferably wider than the spiral layer.

Abstract: A tire having a radial carcass reinforcement comprising a crown reinforcement formed of at least two working crown layers of inextensible reinforcement elements, which are crossed from one ply to the other, forming angles of between 10° and 45° with the circumferential direction, at least one protective layer being radially to the outside of the working crown layers, said crown reinforcement being topped radially by a tread, said tread being joined to two beads by means of two sidewalls. The tire additionally comprises in each shoulder at least one layer of reinforcement elements which are parallel to each other in the additional layer and are oriented circumferentially, the axially inner end of said additional layer being radially adjacent and external to the radially outermost working layer and said axially inner end of the additional layer being radially adjacent and internal to at least part of the protective layer.

Abstract: The present invention generally relates to light weight tire devices comprising a plurality of layers of steel belts. The layers are each a predetermined fraction of the footprint width, and the width of each layer can vary from one layer to another. Some embodiments also include a pair of wedge strips disposed between two reinforcing layers. Furthermore, some embodiments can include a split belt, wherein the gap between the split belts is substantially occupied by a gum strip. Additionally, the belt ply cords can be angled according to one or more patterns.

Abstract: A tire having a radial carcass reinforcement comprising a crown reinforcement formed of at least two working crown layers of inextensible reinforcement elements, which are crossed from one ply to the other, forming angles of between 10° and 45° with the circumferential direction, which itself is topped radially by a tread, said tread being joined to two beads by means of two sidewalls and the axially widest working crown layer being radially internal to the other working crown layers.

Abstract: This invention relates to a rubber composition capable of improving wear resistance without losing low heat buildup and a heavy duty pneumatic tire in which the low heat buildup and the wear resistance are simultaneously established, and more particularly to a rubber composition characterized by comprising 40 to 60 parts by mass of a carbon black based on 100 parts by mass of a rubber component composed of natural rubber and a diene-based synthetic rubber and satisfying a relation of the following formula (1): ?E?<0.29×A?11??(1) [wherein ?E? is a difference between a storage modulus (MPa) at a strain of 0.1% and a storage modulus (MPa) at a strain of 2% measured at 25° C., and A is an amount (parts by mass) of the carbon black compounded based on 100 parts by mass of the rubber component] and a heavy duty pneumatic tire characterized by using the rubber composition in a tread.

Abstract: A reinforcing belt 10 in a belt layer which goes around in a circumferential direction of a pneumatic tire according to the present invention comprises plural steel cords arranged in parallel over overall length thereof, covered with a rubber, the steel cord of the reinforcing belt is arranged such that an angle ?1 between the steel cord and a tire circumferential direction satisfies 0.9?R?W/tan ??1.1?R when a reinforcing belt width is W and a reinforcing belt diameter is R, the reinforcing belt in its developed state shows a parallelogram comprising circumferential direction sides 11 and 12 having the same length, parallel to a tire circumferential direction, and inclined sides 13 and 14 connecting edges of the circumferential direction sides, and the steel cord is arranged in parallel to the inclined sides.

Abstract: Provided is a pneumatic tire having an improved driving stability with reduced weight by use of an inner liner layer including a film made of a thermoplastic resin or a thermoplastic elastomer composition obtained by blending a thermoplastic resin with an elastomer. A pneumatic tire of the present invention includes: a pair of bead portions; a carcass layer bridged between the pair of bead portions; a belt layer disposed on an outer circumferential side of the carcass layer; an inner liner layer disposed along an inner surface of the carcass layer, the inner liner layer including a film made of a thermoplastic resin or a thermoplastic elastomer composition that is obtained by blending a thermoplastic resin with an elastomer; and bead cores buried in the bead portions, respectively. The inner liner layer is wound up around the bead cores from an inner side of the tire to an outer side thereof.

Abstract: A pneumatic tire is provided with a main groove extending along a tire circumferential direction, and a land portion comparted by the main groove in a tread surface. A reinforcing member having a cord which is inclined at an angle between 75 and 90 degrees with respect to the tire circumferential direction is buried in the vicinity of a groove bottom height of the main groove in an inner region of the land portion.

Abstract: A pneumatic tire has a belt arranged in such a manner that cords are inclined with respect to a tire circumferential direction. A quarter portion is set to a portion which is between 50 to 80% of a belt width around a tire equator line, a center portion is set to a portion which is inside than the quarter portion, and a shoulder portion is set to a portion which is outside than the quarter portion. A relation ?c>?s>?q is satisfied on the assumption that a cord angle in the quarter portion is set to ?q, a cord angle in the center portion is set to ?c, and a cord angle in the shoulder portion is set to ?s, with regard to the cord angle of the belt with respect to the tire circumferential direction.

Abstract: A tire for two-wheeled motorcycles of the present invention includes a first carcass layer folded back along circumferential surfaces of bead cores, a second carcass layer folded back along circumferential surfaces of turnbacks of the first carcass layer 5, a belt layer wound spirally along a tire circumferential direction and an intermediate carcass layer provided between the first and second carcass layers 7 and in an inner circumferential side of the belt layer and extending close to a tire maximum width.

Abstract: A two-piece tire assembly 10 with a removable tread belt 12 for installing about the circumference of a tire carcass 14 is provided. The two-piece tire assembly 10 includes a tread belt 12 has a belt structure 90 having two or more belt layers 100, 110, 120, 130 each layer having one or more belts. The tread belt 12 has a radially inner surface 70 having one or more protruding circumferential ribs 72 or grooves 74 that fit into complementary grooves 18 or ribs 19 on an outer crown surface of the tire carcass 14. The tread belt 12 has a maximum axial belt width W at a radially inner surface. The carcass 14 has a maximum section width SW and ply line 20 having a maximum width P wherein W?0.95P, BW?5 0.85P and P<SW.

Abstract: A pneumatic tire comprises a tread, a carcass and a belt structure interposed between the carcass and the tread. The belt structure includes a zigzag belt structure formed of at least two layers of cords interwoven together from a strip of rubber reinforced with one or more cords. The strip forming the zigzag belt structure is layed up in a winding pattern in accordance with the following formula: for i=1 through L, the ith winding pattern is: [WL-(i-1)Wi]×N for each drum revolution, wherein L is the number of different amplitudes used to define the zigzag cycle and L?2, and N is the number of zigzag cycles per drum revolution and N is either an integer ?1 or N=½n wherein n is an integer ?1.

Abstract: A pneumatic tire including a tread part contacting a road surface, at least two belt layers each formed of a plurality of parallel cords covered with rubber, and a pair of bead toes. An angle at which the line segment BQ and the line segment SW cross is 50° or smaller when, in a cross section including the axis of rotation: the ends of a shortest belt layer, which is the shortest one, in length in a tire width direction, of the belt layers are set to be points B; points on a tire surface, between which the width of the tire is the widest, are set to be points Q; a line segment connecting each point B and the corresponding one of the points Q is set to be a line segment BQ; and a line segment connecting the pair of points Q is set to be a line segment SW.

Abstract: A pneumatic tire includes a tread portion on each side of the equatorial plane. At least two circumferential main grooves and three land portions are formed in the tread portion. In a cross section in a meridian direction of the pneumatic tire, profile lines of the land portions form arcs, and an intersection of extension lines of profile lines of adjacent land portions forms an inflection point in a circumferential main groove. Tensile strength of a reinforcing layer in the land portions is larger than that in the circumferential main groove having the inflection points.

Abstract: A pneumatic tire for mounting on an aircraft wheel has a radial carcass and flipper reinforcement. The tire has a pair of bead cores, at least two or more axially inner plies greater than or equal to, extending between the bead cores, a crown reinforcement radially outward of the plies having a maximum belt width BW, and at least one flipper reinforcement wrapped around each bead core. Each bead core has a radially extending cross sectional length B. Each flipper reinforcement extends along an inner surface of the bead core to the axially inner end located in an area that is between 0.01 BW to 0.25 BW as measured from the belt edge toward a centerline of the tire preferably in the range of 0.05 BW to 0.125 BW and wherein one flipper reinforcement has an axially outer end lower than the top of the bead core.

Abstract: The invention relates to a tire having a radial carcass reinforcement comprising a crown reinforcement formed of at least two working crown layers of inextensible reinforcement elements, which are crossed from one layer to the other, forming with the circumferential direction angles of between 10° and 45°, which itself is topped radially by a tread, said tread being joined to two beads by means of two sidewalls and the crown reinforcement comprising at least one layer of circumferential reinforcement elements of an axial width less than that of at least one of the working crown layers. According to the invention, the ratio of the axial width of at least one layer of circumferential reinforcement elements to the axial width of the tread is greater than 0.6, and preferably greater than 0.65, and the ratio of the axial width of the tread to the maximum axial width of the tire is strictly greater than 0.89.