A vehicle comprises a chassis, wheels rotationally mounted to the chassis, each wheel being disposed within a respective wheel well, and a tire mounted to each wheel. A tire sensor disposed within the wheel well senses a tire condition and generates and outputs a tire condition signal indicative of the tire condition. A repair controller receives the tire condition signal from the tire sensor and processes the tire condition signal to determine whether to repair the tire. The repair controller is configured to generate and output a tire repair signal. A 3D printing device disposed in the wheel well and communicatively connected to the repair controller receives the tire repair signal and 3D prints an additive reparation to the tire by drawing a tire repair compound from a supply container within the vehicle and by depositing the tire repair compound on the tire to repair 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.

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 dual tire buffing apparatus includes a turntable having a first end and an opposite second end. The turntable is rotatable about a central axis between first and second positions. A first expandable hub is rotatably coupled to the turntable proximate the first end. The first expandable hub is configured to receive a first tire casing. A second expandable hub is rotatably coupled to the turntable proximate the second end. The second expandable hub is configured to receive a second tire casing. A rasp head is positioned to operatively engage the first tire casing on the first expandable hub when the turntable is in the first position to perform a buffing operation on the first tire casing, and to operatively engage the second tire casing on the second expandable hub when the turntable is in the second position to perform a buffing operation on the second tire casing.

A dual tire buffing apparatus includes a turntable having a first end and an opposite second end. The turntable is rotatable about a central axis between first and second positions. A first expandable hub is rotatably coupled to the turntable proximate the first end. The first expandable hub is configured to receive a first tire casing. A second expandable hub is rotatably coupled to the turntable proximate the second end. The second expandable hub is configured to receive a second tire casing. A rasp head is positioned to operatively engage the first tire casing on the first expandable hub when the turntable is in the first position to perform a buffing operation on the first tire casing, and to operatively engage the second tire casing on the second expandable hub when the turntable is in the second position to perform a buffing operation on the second tire casing.

A device for removing a tread from a wheel (e.g., a closing wheel of a planter, a gauge wheel of a planter, a gauge wheel of a cultivator, a gauge wheel of seed drill etc.) includes a body configured to support the wheel, and a fastener coupled to the body. The fastener is configured to engage the wheel when the wheel is supported by the body, and position the wheel on the body, and then compress the wheel against the body to thereby allow removal of a tread from the wheel.

A device for removing a tread from a wheel (e.g., a closing wheel of a planter, a gauge wheel of a planter, a gauge wheel of a cultivator, a gauge wheel of seed drill etc.) includes a body configured to support the wheel, and a fastener coupled to the body. The fastener is configured to engage the wheel when the wheel is supported by the body, and position the wheel on the body, and then compress the wheel against the body to thereby allow removal of a tread from the wheel.

Technology for controlling in-vehicle three dimensional (3D) printer(s) that replenish road engaging surfaces of the vehicle assembly. In some embodiment the 3D printer is controlled to replenish the road engaging surface while the vehicle is being driven. In some embodiments, an Internet of Things (IoT) sensor is used to detect wear on the road engaging surface to help control the location(s) where the 3D printer adds the additive material.

Technology for controlling in-vehicle three dimensional (3D) printer(s) that replenish road engaging surfaces of the vehicle assembly. In some embodiment the 3D printer is controlled to replenish the road engaging surface while the vehicle is being driven. In some embodiments, an Internet of Things (IoT) sensor is used to detect wear on the road engaging surface to help control the location(s) where the 3D printer adds the additive material.

A method for the cold retreading of a tyre (1) comprising the following steps: —a removal step, during which the old, worn tread is removed from the tyre in order to expose an equatorial surface (2) of a casing (3) of the tyre (1); —a deposition step, during which a cushion (4) and a pre-cured tread strip (6) provided with a tread pattern are deposited around the equatorial surface (2) of the casing (3); and—a curing step, during which the cushion (4) arranged between the casing (3) and the pre-cured tread strip (6) is cured. The retreading method also comprises a conductive interposition step, during which a conductive adhesive compound (5) is deposited between said cushion (4) and said pre-cured tread strip (6) and/or between said cushion (4) and said casing (3). The conductive adhesive compound (5) comprises at least one conductive material in a quantity ranging from 5 to 20% by weight and chosen among graphene, graphite and a carbon black having a surface area which is greater than or equal to 300 m.sup.2/gr. The curing step comprises a connection operation, during which said conductive adhesive (5) compound is connected either to a heat source (S) or to a power source (S) so as to transmit the heat to the cushion (4).