Tread profile of a pneumatic vehicle tyre—in particular for commercial vehicles—comprising a regroovable tread profile with radially raised profile elements (1, 2, 3, 4, 5) and with grooves (6, 7, 8, 9), which respectively separate two adjacent profile elements (1, 2, 3, 4, 5) from one another, wherein the grooves (6, 7, 8, 9) are bounded inwards in the radial direction R by a groove base (10) and on both sides in the axial direction by a profile element flank, forming the groove wall (12, 13), and wherein at least one regrooving indicator (14) for indicating the regrooving depth is respectively formed in one or more grooves (3), characterized in that, in at least one groove (8), all of the regrooving indicators (14) formed therein are formed in a groove wall (12) at a height H measured in the radial direction R of H>0 mm above the groove base (10), wherein the height H corresponds to the maximum radial abrasion position of the tyre for regrooving.

Tread profile of a pneumatic vehicle tyre—in particular for commercial vehicles—comprising a regroovable tread profile with radially raised profile elements (1, 2, 3, 4, 5) and with grooves (6, 7, 8, 9), which respectively separate two adjacent profile elements (1, 2, 3, 4, 5) from one another, wherein the grooves (6, 7, 8, 9) are bounded inwards in the radial direction R by a groove base (10) and on both sides in the axial direction by a profile element flank, forming the groove wall (12, 13), and wherein at least one regrooving indicator (14) for indicating the regrooving depth is respectively formed in one or more grooves (3), characterized in that, in at least one groove (8), all of the regrooving indicators (14) formed therein are formed in a groove wall (12) at a height H measured in the radial direction R of H>0 mm above the groove base (10), wherein the height H corresponds to the maximum radial abrasion position of the tyre for regrooving.

Systems and methods are disclosed herein for estimating or predicting operating conditions/states (e.g., tire wear) based on signal reconstruction from low frequency data sources. A processor periodically receives signals generated from a monitoring device at a first (lower) sampling rate, and further determines a reference signal representing one cycle of the generated signals, and a period of the received signals based on analysis across multiple cycles of generated signals, wherein the period is not an integer multiple of the first sampling rate. A curve is constructed corresponding to signals generated from the monitoring device at a second (higher) sampling rate, at least by correlating multiple cycles of signals at the first sampling rate and the reference signal. Current conditions/states are estimated, substantially in real time, based at least in part on the constructed curve, and an output signal is selectively generated based on the estimated current conditions/states.

A multi-function portable optoelectronic apparatus to determine the profile of a brake disk and the profile of the tread of a tyre comprising an optoelectronic assembly for emitting a laminar beam of light along an optical emission axis so as to project onto the brake disk or onto the tread a luminous line and acquire an image containing the projected luminous line, a tubular case which can be gripped by hand, which contains optoelectronic assembly and is designed to be arranged resting on the brake disk during determination of the profile of the brake disk and an angular adapter member designed to be coupled in a stable but easily removable manner to the case and shaped to be arranged resting on the tread during determination of the profile of the tread; an electronic system configured to receive the image and determine the profile of the brake disk or the profile of the tread on the basis of the luminous line contained in the image.

An object surface managing method comprising: (a) emitting detecting light to the groove via alight source; (b) receiving first reflected detecting light from the surface and second reflected detecting light from a bottom of the groove via a light sensor; and (c) calculating a groove depth of the groove according to the first reflected detecting light and the second reflected detecting light.

A tire device has a tire side device and a vehicle body side system, and determines a road surface condition and detects a tire wear state. The tire side device includes a vibration detection unit that outputs a detection signal according to a magnitude of a tire vibration, a control unit extracts a feature amount during one rotation of the tire, and a first data communication unit that transmits a road surface data including a feature amount. The vehicle body side system includes a second data communication unit that receives road surface data, a road surface determination part that determines a road surface condition based on the road surface data, an integral calculation part that calculates an integral value of the feature amount in a specific frequency band included in the road surface data, and a wear determination part that detects the tire wear state from the integral value.

A wear detection system for truck steer tires is provided. A plurality of sipe groups are located in a tread rib of the tire. Each sipe group includes a first sipe group portion having an axially inward directed apex and a second sipe group portion having an axially outwardly directed apex, such that an axially directed wear force component causes the apex of the sipe group directed in the direction of the wear force component to be more tactilely detectable by a human fingertip than the apex of the other sipe group portion.

A wear detection system for truck steer tires is provided. A plurality of sipe groups are located in a tread rib of the tire. Each sipe group includes a first sipe group portion having an axially inward directed apex and a second sipe group portion having an axially outwardly directed apex, such that an axially directed wear force component causes the apex of the sipe group directed in the direction of the wear force component to be more tactilely detectable by a human fingertip than the apex of the other sipe group portion.

A tire condition detecting apparatus includes a transmitting section, a receiving section, a control section, a property detecting section, and a battery, which is a power source for the apparatus. The control section operates in a control mode that is selected from a normal mode and a power saving mode. In the power saving mode, power consumption associated with reception of the wirelessly transmitted signal from the external device is less than that in the normal mode. When the amount of change in the electrical property of a valve stem detected by the property detecting section exceeds a reference change amount, the control section switches the control mode to the normal mode. The control section also switches the control mode to the power saving mode when a termination condition is met in the normal mode

A motor vehicle includes a rear bumper and a microphone. The rear bumper includes an internal cavity that is open towards a front portion of the vehicle. The microphone includes a sound pickup component arranged to acquire a sound signal generated by at least one tire of the vehicle, each of which includes at least one audible wear indicator. The sound pickup component of the microphone is attached to a wall of the rear bumper, and is positioned at a transverse level located between rear tires of the vehicle, preferably in the internal cavity.