A tire testing machine is for testing a tire, comprising a free roller section configured to include a plurality of rollers having an endmost roller disposed downstream of a lubricator in a conveying direction and farthest from a predetermined reference position, the endmost roller being disposed such that a horizontal distance from the reference position is equal to or greater than a radius of a largest of a plurality of tires set in advance as objects of application of a lubricant.

A functional component in which an electronic component capable of acquiring information inside a tire is housed and which is attachable to an inner peripheral surface of the tire, the functional component including a housing having a housing part for the electronic component and a bottom surface facing the inner peripheral surface of the tire, and a tubular part extending from a peripheral edge of the bottom surface toward the inner peripheral surface.

Processing method for inserting electronic devices that are suitable for communicating in radio frequency into respective rubber sleeves (5); are provided: a conveyor (9) for advancing a first rubber belt (10) arranged along an insertion path; a first feed device (12) for placing the transponder (1) upon an upper surface of the first rubber belt (10); a second feed device (13) for placing upon the upper surface of the first rubber belt (10) and upon each previously placed transponder (1) a corresponding sheet of green rubber (14) that completely covers the transponder (1); and a cutting device (16) arranged downstream of the second feed device (13) along the direction of travel of the first rubber belt (10) for cutting out at least the first rubber belt (10) by performing a cut of a rectangular shape around each transponder (1) in order to separate each sleeve (5) from the rubber belt.

Systems and methods of machine learning for splice improvement. A system can receive, from one or more sensors, one or more values corresponding to manufacture of a tire by the one or more pieces of tire manufacturing equipment. The systems can determine one or more metrics based on the one or more values. The systems can generate a matrix based on the one or more values and the one or more metrics. The systems can predict, via input of the matrix into a machine learning model, a value for a splice tolerance metric. The systems can determine, based on the value for the splice tolerance metric, a parameter of at least one piece of equipment to adjust. The systems can provide a command to adjust the piece of equipment responsive to the value of the splice tolerance metric.

A station for checking the formation of beads of tyres, including: a forming drum for arranging a carcass sleeve with formed beads with the carcass sleeve in rotation, an image acquisition system for acquiring at least an image of a circumferential portion of external surface including the respective edges of the end flaps turned up; a processing unit for processing the image in order to determine a circumferential trend of the axial distance of each edge from an axial reference plane and for detecting possible defects of the beads as a function of such trend.

The invention relates to a tire (1), the tire (1) being rotatable about an axis of rotation (2) in a direction of rotation (3), having at least one electromagnetic transmitting and receiving device (4), at least one bead core (5) and at least one apex (6), wherein the at least one apex (6) is configured from a first homogeneous rubber material (7) and from a second homogeneous rubber material (8), wherein the first homogeneous rubber material (7) is disposed on the at least one bead core (5) and the first homogeneous rubber material (7) in spatial terms is disposed between the at least one bead core (5) and the one second homogeneous rubber material (8), wherein the at least one electromagnetic transmitting and receiving device (4) is disposed within the at least one apex (6).

A molding element having a molding surface forming a contact face and a groove forming rib portion forming the groove comprising two opposed rib side faces and a rib top face connecting two rib side faces. The groove forming rib portion provides at least one space opening to at least one of the rib side faces and/or to the rib top face. An insert is received in the space. The insert comprises a cavity for forming a closing device in the groove. The cavity has two opposed cavity faces and opens to at least two faces of the insert corresponding to the faces of the groove forming rib portion. The insert comprises at least one cutting means extending and/or projecting in a direction the groove forming rib portion extends for cutting a material filled in the cavity during demolding.

A molding element having a molding surface forming a contact face and a groove forming rib portion forming the groove comprising two opposed rib side faces and a rib top face connecting two rib side faces. The groove forming rib portion provides at least one space opening to at least one of the rib side faces and/or to the rib top face. An insert is received in the space. The insert comprises a cavity for forming a closing device in the groove. The cavity has two opposed cavity faces and opens to at least two faces of the insert corresponding to the faces of the groove forming rib portion. The insert comprises at least one cutting means extending and/or projecting in a direction the groove forming rib portion extends for cutting a material filled in the cavity during demolding.

A transfer ring for use in the manufacture of vehicle tires, the transfer ring including a radially expandable and collapsible segmented cylindrical gripping surface defined by a plurality of inwardly facing arcuate surfaces mounted for radial movement toward and away from a central axis of the cylindrical gripping surface, wherein each arcuate surface is mounted to a corresponding set of driven linkages comprising first, second, and third members, each set of driven linkages further including a block-and-rail cam follower secured to at least one of the first, second, and third members and configured to cooperate with the first, second, and third members to limit movement of the arcuate surface to linear movement radially toward and away from the central axis of the cylindrical gripping surface.

Disclosed is a guiding device having a guide roller that is rotatable about a roller axis and that has an exterior guide surface extending in a circumferential direction about the roller axis, wherein the guide roller includes a plurality of roller segments juxtaposed in an axial direction along the roller axis for forming the exterior guide surface, wherein the plurality of roller segments are movable relative to each other to enable the guide roller to be positioned in a maximum bend state in which the roller axis extends along an arc, wherein the plurality of roller segments are interlocked to rotate together about the roller axis in a maximum bend state, wherein the plurality of roller segments extend over an arc length along the arc of the roller axis, wherein the arc length is at least ninety degrees in the maximum bend state.