A method for producing separated strip-like laminate components including an electronic component embedded between two laminate layers of a tape-like material. Individual components are placed at defined intervals by a placement device onto a tape-like, lower first laminate layer moved in a conveying direction by a transport device, after which a tape-like, upper second laminate layer moved in the conveying direction is applied to the first laminate layer with embedding of the components to form a laminate tape. The individual strip-like laminate components are cut from the laminate tape by a cutting device having a movable cutting blade, which laminate components are picked up by a gripper device and transported away. The front end of the laminate tape is gripped by the gripper device in the region of a component and moved synchronously with the clocked movement of the transport device by a predetermined distance through the cutting device and positioned relative to the cutting blade. The actual position of the component in the laminate component in relation to the conveying direction is detected by a measuring device connected downstream of the cutting device. When a deviation of the actual position from a defined target position is detected, the synchronous movement of the transport device and the gripper device is controlled in dependence on the detected deviation.

A pneumatic tire (1) having: a toroidal carcass (2), which consists of a body ply (3) partially collapsed onto itself and therefore having two lateral flaps; two annular beads (4), each of which is surrounded by the body ply (3) and has a bead core (5) and a bead filler (6); an annular tread (7); a pair of sidewalls (11) arranged externally to the body ply (3) between the tread (7) and the beads (4); a pair of abrasion gum strips (12) arranged externally to the body ply (3) under the sidewalls (13) and at the beads (4); and a transponder (13) which is arranged in contact with the body ply (3) at a flap of the body ply (3) and is located below an edge (19) of the body ply (3) between the edge (19) of the body ply (3) and the bead (4).

A tire and membrane system includes a tire, an electronics package, and a membrane body attached to the electronics package. A width of the membrane body is less than 120% of a width of a tread of the tire. A length of the membrane body is less than 50% of a circumference of the tire. A bottom surface of the membrane body is configured to lie flat against an inner surface of the tire. The membrane body is not attached to the tire.

An assembly (10) for positioning sensors within a tire is provided that has first and second bead sensors (14,16), and first and second side-wall/shoulder sensors (18, 20). A first actuator (30) moves the sensors in a radial direction of the tire, and a second actuator (32) moves the first and second bead sensors in the axial direction of the tire. A third actuator (34) is present and moves the first and second bead sensors in the axial direction relative to the first and second sidewall/shoulder sensors. A fourth actuator (36) moves the first and second bead sensors in the axial direction relative to one another, and a fifth actuator (38) moves the first and second sidewall/shoulder sensors in the axial direction relative to one another.

A method to manufacture an electronic device to be applied to rubber article. The device comprises an electronic element, two layers of thermoplastic material which are arranged in a sandwich-like manner so as to contain, between one another, the electronic element, and at least an outer rubber layer arranged to cover an outer surface of at least one of the respective thermoplastic layers. The method comprises a preliminary step comprising (a) a deposition operation, during which an adhesive solution consisting of a basic water solution comprising a latex of an elastomer rubber and a combination of resorcinol and formaldehyde is applied on at least one outer surface of one of the layers of thermoplastic material; and (b) a heating operation, during which the layers of thermoplastic material on which the adhesive solution was applied are kept at a temperature ranging from 120 to 230 C. for an amount of time ranging from 2 to 15 min.

Disclosed is a liner reel, a cassette, a let off station and a method for collecting a liner, wherein the liner reel has a core and a shell that is concentrically mountable to said core for rotation together with said core about a liner reel axis, wherein the shell has a collection wall that extends in a circumferential direction about the liner reel axis when the shell is mounted to the core, wherein the collection wall is arranged for receiving the liner, wherein the core has a support wall extending in the circumferential direction for supporting the collection wall at least with a vector component in a radial direction perpendicular to the liner reel axis, wherein the collection wall is at least partially contractible in said radial direction when the shell is removed from the core.

A method for encapsulating electronic devices comprises, successively, placing a profiled strip on a conveyor belt, the profiled strip comprising a base, at least one flap protruding with respect to said base; positioning an electronic device, in the longitudinal direction, on the receiving zone of the profiled strip; and plastically deforming the flap by application of an application force in a predetermined direction.

A pneumatic tire includes: a tire inner surface rubber layer constituting a tire inner surface; and an electrically conductive member, at least a part of the electrically conductive member being disposed on an inner cavity side of the tire inner surface rubber layer. The electrically conductive member includes a knitted fabric including a yarn, at least a part of the yarn having electrical conductivity, the knitted fabric having stretchability. The electrically conductive member is electrically connected to an electrical device provided in the tire. The electrically conductive member is disposed extending along the tire inner surface in a tire radial direction, and a direction in which the electrically conductive member extends aligns with a direction in which the knitted fabric has stretchability. The knitted fabric is configured by mixing a yarn having electrical conductivity and a yarn having non-electrical conductivity.

A tire electronics assembly includes a base and a plurality of modules. The base is mechanically attached to the tire and includes an electronic device. A plurality of mechanical attachment elements are arranged on the base in a circular array. Each module includes an electronic device and a mechanical attachment element. Each mechanical attachment element on a module is configured to releasably mechanically attach to any one of the mechanical attachment elements on the base. In this configuration, the modules are interchangeably mechanically attachable to the base in the circular array. The base further includes a plurality of electrical terminals arranged in a circular array. Each module has an electrical terminal that is configured to releasably electrically connect with any one of the electrical terminals on the base, whereby the modules are interchangeably electrically connectable with the base in the circular array.

A tire suitable for running flat comprises a crown, two sidewalls and two beads, a carcass reinforcement with at least one carcass ply anchored in each bead and a sidewall insert placed axially internally relative to at least the carcass ply, wherein the tire is equipped with an electronic device comprising at least one radiofrequency transponder and wherein, each bead comprising a bead wire of revolution about a reference axis and H being one of the points of the bead wire closest to the axis of revolution, the electronic device is placed axially in a zone of the tire bounded by at least one of the beads and one of the sidewalls and radially externally at a radial distance larger than 20 mm from the point H.