A lateral groove provided in a tread portion has: an opening formed in a tread surface; a minimum portion having the smallest groove width, positioned radially inside the opening; and a maximum portion having the largest groove width, positioned radially inside the minimum portion. The width of the opening increases toward the outside in the tire axial direction.

A tire includes a pattern portion that is formed on a tire surface and in which ridges are arranged in a nest shape having a center point, the ridges including ridgelines CL having a curved portion in plan view, in which a height of each of the ridges is from 0.2 mm to 0.5 mm, and adjacent ridges are arranged at a constant pitch of from 0.15 mm to 0.35 mm.

A tire tread for a heavy-duty vehicle which when new, has a maximum thickness of material to be worn away during running, a tread surface, side faces, a middle region (RM), this tread provided with tread pattern elements having channels, sipes, radial openings and blocking devices, the channels arranged in the tread and connected to the tread surface by radial openings arranged alternating with the blocking devices along the channels, where the tread is devoid of a circumferential groove, the channels arranged below the tread surface when the tread is new, the channels are transverse channels and connect RM to the side faces; each channel connecting the middle region to a side face has a direction change between RM and the side face; and maximum longitudinal distance between points of a transverse channel furthest apart in longitudinal direction is between 10% and 50% of the width of the tread (Lbdr).

A tread (2) for a driven axle of an agricultural vehicle, having a tread pattern elements (21) extending radially towards the outside from a bearing surface (22), the tread pattern elements having a total number N of tread pattern blocks (21) that are separated axially from one another, the tread pattern blocks having a contact face (211), a leading face (212) and a trailing face (213), the leading face being inclined at an angle α towards the rear with respect to the radial direction in the rolling direction (15) of the tread, the tread having a number n of tread pattern blocks in the case of which the angle α is between 50 degrees and 75 degrees, the number n being at least equal to 0.2×N.

A tire includes a pair of shoulder main grooves and one or more center main grooves extending in a tire circumferential direction and four or more rows of land portions defined by the pair of shoulder main grooves and the one or more center main grooves. Each of the pair of shoulder main grooves includes a groove opening portion having a wave-like shape with an amplitude in a tire width direction. Each of the pair of shoulder main grooves includes a groove bottom portion having a zigzag shape with an amplitude in the tire width direction. The groove opening portion in each of the pair of shoulder main grooves has an amplitude A1_sh having a relationship A1_sh<A2_sh with respect to an amplitude A2_sh of the groove bottom portion.

A tire includes a plurality of main grooves extending in a tire circumferential direction and four or more rows of land portions defined by the main grooves. Moreover, a middle land portion and a center land portion have a plurality of through lug grooves that pass through the land portions in a tire width direction, respectively. Pitch lengths of the through lug grooves are in a range of from 7% or greater to 14% or less of a tire maximum ground contact length. Additionally, maximum groove depths of the through lug grooves are in a range of from 5% or greater to 65% or less of maximum groove depths of the main grooves.

The invention relates to a utility vehicle tyre having a tread with at least one circumferential channel (2, 2′, 2″) with a channel base (5) and channel walls (4, 4′), wherein base elevations (7, 7′, 7″) are formed on the channel base (5) in a manner distributed over the circumference and acting centrally as stone ejectors, with a height (h.sub.1, h.sub.3) of 25% to 60% of the profile height (T.sub.1) and a greater extent in the circumferential direction than in the axial direction, which base elevations (7, 7′, 7″) either contact the channel walls (4, 4′) or are at distances (a.sub.1) of up to 4.0 mm therefrom in the axial direction and are bounded in the radial direction by a top surface (8, 8′, 8″) having an encircling surface edge, wherein the channel walls (4, 4′) between the base elevations (7, 7′, 7″) have wall portions (4a, 4′a) which converge toward each other.

The top surface (8, 8′, 8″) of the base elevations (7, 7′, 7″) slopes downward uniformly toward the surface edge, wherein the channel walls (4, 4′) have, to the side of the base elevations (7, 7′, 7″), wall sections (4b, 4′b) which are convexly curved toward one another in a plan view, and wherein the surface edge of the top surface (8, 8′, 8″) follows the profile of the wall sections (4b, 4′b) which are convexly curved toward one another, such that the width of the base elevations (7, 7′, 7″) decreases toward those ends thereof which lie in the circumferential direction.

A tyre includes a tread portion being provided with a longitudinal groove and a land portion being adjacent to the longitudinal groove. The land portion has a ground contact surface defined between a first circumferential edge located on the longitudinal groove side and a second circumferential edge located on an opposite side to the first circumferential edge. The land portion is provided with first lateral grooves and sipes. The first lateral grooves extend from the first circumferential edge and having inner ends thereof terminating within the land portion. The first lateral grooves are provided with tie-bars on the respective inner ends side, the tie-bars having lengths smaller than lengths of the respective first lateral grooves. The sipes include first sipe elements extending form the second circumferential edge to the respective first lateral grooves and second sipe elements extending on the respective tie-bars.

Taking a groove side-wall to a position at a groove depth from a tread face of lug groove as a tread-in side first inclined portion, and taking a groove side-wall from the position at groove depth to a groove bottom as a tread-in side second inclined portion, then the following A1 is set less than the following B1. When viewed in cross-section orthogonal to a length direction of the lug groove: A1 is an area of a region enclosed by an imaginary line passing through an end portion on a tread face side of the tread-in side first inclined portion and perpendicular to the tread face, by an imaginary line passing through an end portion on a groove bottom side of the tread-in side first inclined portion and orthogonal to the imaginary line, and by the tread-in side first inclined portion; and B1 is an area of a region enclosed by an imaginary line passing through an end portion on a tread face side of the tread-in side second inclined portion and perpendicular to the tread face, by an imaginary line passing through the deepest portion of the lug groove and parallel to the tread face, and by the tread-in side second inclined portion.

A tire includes a tread portion being provided with a circumferentially extending main groove to define a first land portion between the main groove and a tread edge. The main groove includes a groove bottom, an outer groove wall extending radially outwardly and inclined toward the tread edge, and an inner groove wall extending radially outwardly and inclined toward the tire equator. The groove bottom extends in a zigzag manner in a tire circumferential direction in such a manner as to alternate between a first location where the groove bottom is located nearest to the tire equator and a second location where the groove bottom is located nearest to the tread edge. An angle 2b of the outer groove wall in a groove cross-section at the second location is greater than an angle 1a of the inner groove wall in a groove cross-section at the first location.