The pneumatic tire according to the present embodiment includes a shoulder land portion that is formed between a ground contact end and the shoulder main groove, a central land portion that is formed on the other side of the shoulder main groove in the tire width direction, a plurality of first inclined grooves that are provided in the central land portion at intervals in the tire circumferential direction, and a plurality of second inclined grooves that are provided in the shoulder land portion at intervals in the tire circumferential direction. The first inclined groove of which one end is open to the shoulder main groove and the other end terminates in the central land portion extends in a direction inclined with respect to the tire circumferential direction, and the second inclined groove is open to the shoulder main groove and provided on an extension of the first inclined groove.

A pneumatic vehicle tire, in particular all-terrain or off-road tire, having a tread divided by circumferential grooves, which have a profile depth (T), into block rows running in encircling fashion in a circumferential direction and/or profile ribs which are structured in the manner of profile blocks. Block rows are divided by transverse grooves into blocks and, like the profile ribs structured in the manner of profile blocks, are equipped with blind grooves proceeding from the circumferential grooves. Transverse and/or blind grooves are provided which, owing to a connection of blocks adjacent in the circumferential direction and/or of the block-like structures, have a depth smaller than profile depth (T). The connection has at least two connection steps of different heights, the lowest is formed in each case at the region in which the transverse grooves and/or blind grooves open into the circumferential grooves. The highest connection step is formed in the middle region of transverse grooves and in an inner end region of the blind grooves.

The tread profile of a vehicle tire has a circumferential rib. Grooves are formed in the circumferential rib with a width, which increases along its entire extent, wherein the grooves are formed with a vertex point between a first portion and a second portion. The groove direction from the beginning to the vertex point is formed with a greater directional component in the circumferential direction than in the axial direction and between the vertex point and the entry into the circumferential groove is formed with a greater directional component in the axial direction than in the circumferential direction. The groove is formed in the first portion with a depth T.sub.1, which increases continuously from the beginning over the first portion up to reaching its maximum value T.sub.1max at the vertex point and is formed with a constant depth T.sub.2 in the second portion wherein T.sub.2T.sub.1max.

A tire center slant groove near tread surface tire equatorial plane extends toward reverse rotation-direction of designated rotation-direction while slanting from a tire equatorial plane side to a tire-width direction outer side, an extension direction angle forms with respect to a tire circumference-direction within range, 3-10; and at center slant groove-end portion in reverse rotation-direction, at least a tire-width direction outer side groove-edge of the center slant groove forms into a circular-arc-shaped portion to have the tire-width direction outer side groove-edge angle formed with respect to tire circumference-direction, the angle increasing toward reverse rotation-direction, the tire-width direction outer side groove-edge angle of the center slant groove forms with respect to tire circumference-direction larger than an angle of a tire-width direction inner side groove-edge of the center slant groove forms with respect to tire circumference-direction, and the center slant groove depth gradually decreases toward the center slant groove-edge in reverse rotation-direction.

A motorcycle tire includes a tread portion provided with inclined main grooves arranged between the tire equator and a first tread edge and sub-grooves smaller than the inclined main grooves in groove width. The inclined main grooves include inner main grooves each extending from a first end located on the tire equator side to a second end located on the first tread edge side with an inclination with respect to a tire circumferential direction, wherein no other grooves are provided between the first end of each inner main groove and the tire equator. The sub-grooves include first sub-grooves extending from the inner main grooves toward the tire equator with an opposite inclination direction to the inner main grooves with respect to the tire circumferential direction and terminating on the tire equator side without being communicated with any other grooves.

A tire includes a tread surface portion with inclined grooves, 2ND longitudinal grooves, and shoulder longitudinal grooves; and an indicator portion that indicates a rotation direction of the tire in which a vehicle travels forward. The inclined groove gradually extends forward in the rotation direction toward a tire equator from the outside in the tire width direction. A front surface among inner surfaces defining the inclined groove includes a first side surface with an inner end portion to which the 2ND longitudinal groove is open, a second side surface positioned closer to an inside than the first side surface and of which an outer end portion is positioned closer to a rear side than the inner end portion of the first side surface, and a stepped surface that connects an inner edge of the first side surface to an outer edge of the second side surface and faces the outside.

A pneumatic tire includes a shoulder block on an outer side in the tire width direction. The pneumatic tire includes an edge portion protruding from an end portion of the shoulder block located on the outer side in the tire width direction toward a tire step-in side so as to be inclined toward the center side in the tire width direction.

A pneumatic tire 1 is provided in the tread portion 2 with a pair of center main grooves 3 arranged on both sides of the tire equator C, and a pair of shoulder main grooves 4 arranged on both sides thereof, and is provided on both sides of the equator C with middle land portions 6 defined between the center main grooves 3 and the shoulder main grooves 4. The middle land portions 6 are provided with a plurality of middle oblique grooves 10. Each middle oblique groove 10 extends toward the tire equator C from the outer end 10o in the tire axial direction communicating with the shoulder main groove 4, and the inner end 10i terminates without reaching to the center main groove 3. In an outer end 10o side of the middle oblique groove 10, an outer shallow bottom portion 12 having a depth less than the maximum depth of the middle tilted groove 10 is provided.

A tire includes an outboard tread edge and an inboard tread edge to be located on an outboard side and an inboard side of a vehicle, respectively, circumferentially and continuously extending main grooves, and land portions divided by the main grooves. The land portions include an outboard shoulder land portion, an outboard middle land portion, an inboard shoulder land portion, and an inboard middle land portion. Each of the outboard shoulder land portion, the inboard shoulder land portion, and the inboard middle land portion is provided with axially extending lateral grooves. The outboard middle land portion is provided with outboard middle lateral grooves extending from an edge of the outboard middle land portion on the outboard tread edge side toward the inboard tread edge. The outboard middle lateral grooves are inclined with respect to a tire circumferential direction at angles smaller than those of the lateral grooves.

A pneumatic radial tire 1 for a passenger car comprises a carcass 6 having a radial structure, a belt layer 7, and a tread portion 2. The tread portion 2 has an outer tread edge (To) and an inner tread edge (Ti). A tread pattern is formed in an asymmetric shape with respect to a tire equator (C). The tread portion 2 is divided into a plurality of circumferential land regions by a plurality of main grooves 10. The circumferential land regions include an outer shoulder land region 16, an inner shoulder land region 17, and a middle land region 18 arranged therebetween. The outer shoulder land region 16 is larger than the inner shoulder land region 17 with respect to rigidity in a tire circumferential direction and the rigidity in a tire axial direction.