Disclosed herein, a tire tread cutting apparatus for cutting a length of a tire tread is described. The tire tread cutting apparatus includes a track having a first track end and a second track end downstream of the first track end. The track includes a plurality of rollers positioned between the first track end and the second track end. The plurality of rollers is configured to facilitate the tire tread along the track. A tire hub is positioned downstream of and adjacent to the second track end. The tire hub is configured to receive a tire casing. The tire casing defines a tire casing circumference along an outer surface of the tire casing. A tread dispenser is positioned upstream of the track and configured to dispense tire tread. The tread dispenser includes a drive roller configured to drive tire tread downstream toward the second track end.

Systems and methods of buffing tire casings are provided. A tire buffing machine includes a tire hub assembly selectively rotating a mounted casing, a buffer configured to buff the casing, a tire belt detection apparatus having two or more sensors to detect a first belt depth of one or more belts at a first lateral position in a tire casing and a second belt depth of the one or more belts at a second lateral position within the tire casing, and an electronic controller. The controller determines the first belt depth and the second belt depth using a belt detection apparatus having two or more sensors of the belt detection apparatus and adjusts the operation of the buffer based on the first belt depth or the second belt depth.

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.

Method and station for the skiving of the equatorial surface of the casing of a pneumatic tire during a retreading process of the same pneumatic tire; the old worn tread is removed from the pneumatic tire in order to expose the equatorial surface of the casing of the pneumatic tire; the presence of any damage on the equatorial surface of the casing is identified by capturing a three-dimensional profile of the equatorial surface of the casing by means of a laser type profilometer and by analyzing the same three-dimensional profile; and the equatorial surface of the casing is skived where there is damage resulting from the formation of craters on the equatorial surface.

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.

A flux leakage detection system and a method for providing a quality indicator for a flux leakage detection system are provided.

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.

Systems and methods of buffing tire casings are provided. A tire buffing machine includes a tire hub assembly selectively rotating a mounted casing, a buffer configured to buff the casing, a tire belt detection apparatus having two or more sensors to detect a first belt depth of one or more belts at a first lateral position in a tire casing and a second belt depth of the one or more belts at a second lateral position within the tire casing, and an electronic controller. The controller determines the first belt depth and the second belt depth using a belt detection apparatus having two or more sensors of the belt detection apparatus and adjusts the operation of the buffer based on the first belt depth or the second belt depth.

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.