A bead core coating method for coating an annular bead core with a belt-shaped rubber sheet including the steps of: winding the rubber sheet extruded on an outer circumferential surface of a rotary drum; sticking a part of the rubber sheet to an outer surface of the bead core which is in rotation; and winding a remaining part of the rubber sheet stuck on the outer surface of the bead core while sequentially sticking the remaining part along the outer surface of the bead core, wherein air is blown to a sheet portion including the end that is not stuck to the outer surface of the bead core in the currently-winding rubber sheet in a first direction toward the end along a sheet surface or a second direction inclined toward an outer surface side of the bead core as compared with the first direction.

A bead core coating method for coating an annular bead core with a belt-shaped rubber sheet, including the steps of: winding the rubber sheet around an outer circumferential surface of a rotary drum; sticking a central portion of the rubber sheet to an outer surface of the bead core; and winding both ends in the width direction of the rubber sheet stuck on the outer surface of the bead core while sequentially sticking both ends in the width direction along the outer surface of the bead core from the central portion in the width direction toward each end in the width direction, wherein in the step of sticking, air is blown to a gap generated between the central portion in the width direction of the rubber sheet and the outer circumferential surface of the rotary drum at a place where the rubber sheet is peeled from the rotary drum.

A bead core coating method for coating an annular bead core with a belt-shaped rubber sheet, including the steps of: winding the rubber sheet around an outer circumferential surface of a rotary drum; sticking a central portion of the rubber sheet to an outer surface of the bead core; and winding both ends in the width direction of the rubber sheet stuck on the outer surface of the bead core while sequentially sticking both ends in the width direction along the outer surface of the bead core from the central portion in the width direction toward each end in the width direction, wherein in the step of sticking, air is blown to a gap generated between the central portion in the width direction of the rubber sheet and the outer circumferential surface of the rotary drum at a place where the rubber sheet is peeled from the rotary drum.

A process and a drum for looping annular anchoring structures in a process for building tyres for vehicle wheels includes: depositing a loop on a drum including a radially expandable/contractible intermediate annular portion and, in a position axially adjacent to the opposite axial ends of the intermediate annular portion, a pair of radially expandable/contractible lateral annular portions; associating an annular anchoring structure with a radially outer annular surface portion of the loop defined at the intermediate annular portion; and turning up each of opposite end edges of the loop on the annular anchoring structure through the lateral annular portions as a result of a thrusting stress imparted by a respective lateral annular portion of the pair of lateral annular portions because of a synchronous radial movement and a synchronous axial displacement of a respective plurality of circumferentially adjacent first angular sectors.

A process and a drum for looping annular anchoring structures in a process for building tyres for vehicle wheels includes: depositing a loop on a drum including a radially expandable/contractible intermediate annular portion and, in a position axially adjacent to the opposite axial ends of the intermediate annular portion, a pair of radially expandable/contractible lateral annular portions; associating an annular anchoring structure with a radially outer annular surface portion of the loop defined at the intermediate annular portion; and turning up each of opposite end edges of the loop on the annular anchoring structure through the lateral annular portions as a result of a thrusting stress imparted by a respective lateral annular portion of the pair of lateral annular portions because of a synchronous radial movement and a synchronous axial displacement of a respective plurality of circumferentially adjacent first angular sectors.

The method includes procuring an annular core 3 of main axis Z3. The core is closed on itself by a core join 6 which occupies, in azimuth about said main axis Z3, a first angular sector S6. Then, a braiding is performed by helically winding, about the core 3, a braid wire 4 that is held closed by a braid join 8, of sleeve 9 type, which occupies a second angular sector S8. A method during which a registration element 16, with respect to which the position of the first angular sector S6 is known, is sought and detected on the core 3, and the azimuthal orientation of the core 3 is adapted during the braiding, with reference to said registration element 16, so that the second angular sector S8 occupied by the braid join 8 does not overlap the first angular sector S6 occupied by the core join 6.

The method includes procuring an annular core 3 of main axis Z3. The core is closed on itself by a core join 6 which occupies, in azimuth about said main axis Z3, a first angular sector S6. Then, a braiding is performed by helically winding, about the core 3, a braid wire 4 that is held closed by a braid join 8, of sleeve 9 type, which occupies a second angular sector S8. A method during which a registration element 16, with respect to which the position of the first angular sector S6 is known, is sought and detected on the core 3, and the azimuthal orientation of the core 3 is adapted during the braiding, with reference to said registration element 16, so that the second angular sector S8 occupied by the braid join 8 does not overlap the first angular sector S6 occupied by the core join 6.

A pneumatic tire 1 comprises an annular bead core 5 embedded in each bead portion 4 of the tire. The bead core 5 is composed of a plurality of wire rings 10 each of which is made of a spirally overlap-wound bead wire 11 and which are arranged in the tire axial direction. The wire rings 11 include a first ring 13 whose bead wire 11 is a twisted cord 13a made of a plurality of filaments 15 twisted together, and a second ring 14 whose bead wire 11 is a monofilament cord 14a made of a single filament.

A pneumatic tire 1 comprises an annular bead core 5 embedded in each bead portion 4 of the tire. The bead core 5 is composed of a plurality of wire rings 10 each of which is made of a spirally overlap-wound bead wire 11 and which are arranged in the tire axial direction. The wire rings 11 include a first ring 13 whose bead wire 11 is a twisted cord 13a made of a plurality of filaments 15 twisted together, and a second ring 14 whose bead wire 11 is a monofilament cord 14a made of a single filament.

A manufacturing method includes feeding a master roll 8a from a master roll table 10 to a belt table 14, and cutting the master roll 8a between the master roll table 10 and the belt table 14. In the step of feeding the master roll 8a from the master roll table 10 to the belt table 14, the master roll 8a is fed by holding a front part of the master roll 8a by a first hand 30 and a rear part of the master roll 8a by a second hand 40, and the front part of the master roll 8a is continuously held by the first hand 30 from start to end of the feeding.