HK1260437A1 - Tyre for vehicle wheels - Google Patents

Description

Tyre for vehicle wheels

Technical Field

The present invention relates to a tyre for vehicle wheels, in particular for heavy vehicle wheels.

The expression "heavy vehicle" is used to indicate vehicles belonging to categories M2-M3, N2-N3 and O2-O4 defined in "classification and definition of motor vehicles and trailers" page 52-59 of attachment 7 in united states of vehicle construction (r.e.3) (1997), such as trucks (lorry), trucks (truck), tractors, buses, vans and other vehicles for transporting heavy loads.

Background

EP1782970 describes a tyre whose tread band is provided with three-dimensional sipes which, when the tread band is worn, assume the shape of conventional grooves.

EP2072286 describes a tire comprising a sipe the base of which is designed to improve significantly the endurance against fatigue cracks.

EP2463121 describes a tread band having a ground imprint which varies with wear due to the presence of a "submerged" groove, in other words, a groove formed in a radially inner position with respect to the rolling surface when the tyre is new.

Disclosure of Invention

The following definitions apply:

the terms "radial" and "axial" and the expressions "radially inner/outer" and "axially inner/outer" are used to refer to the directions perpendicular and parallel, respectively, to the axis of rotation of the tyre, while the terms "circumferential" and "circumferentially" are used to refer to the direction of toroidal extension of the tyre, i.e. the rolling direction of the tyre, which corresponds to the direction lying on a plane coincident with or parallel to the equatorial plane of the tyre. Thus:

the term "radial direction" is used to indicate a direction substantially perpendicular to the rotation axis of the tyre;

the term "axial direction" is used to indicate a direction parallel to the rotation axis of the tyre;

the term "circumferential direction" is used to indicate a direction parallel to the rolling direction of the tyre.

The term "groove" is used to indicate a cut formed in the tread band of a tyre and having a width greater than 3 mm.

The term "sipe" is used to indicate a thin cut formed in the tread band of a tyre and having a width not greater than 3mm, at least in a portion of its radial depth. Generally, the width of the sipe is such as to allow the incision to close completely when subjected to the load pressure during passage (in the footprint of the tread portion including the sipe).

The term "substantially continuous extension" is used to indicate an extension of a circumferential cut, regardless of whether the circumferential cut is in the form of a groove or sipe, wherein the extension extends along a trajectory defined by a single straight line or curve or broken line for at least 90% of the circumferential extension, wherein the term "broken line" refers to a line comprising two or more continuous rectilinear portions inclined with respect to one another.

The term "cross section" of the sipe is used to indicate the section of the sipe taken on a plane perpendicular to the trajectory of the sipe.

The term "substantially parallel" with reference to the walls of the sipe facing each other is used to indicate that these walls are parallel and/or that they may be inclined with respect to each other by an angle of less than or equal to 5 °. Thus, references such as aggregate, discrete, etc., relating to the walls of the sipe facing each other are used to indicate that the inclination between these walls is greater than 5 °.

The term geometric centre of the maximum width portion of the radial section of the sipe is used to indicate, respectively, the median point of a line segment if this maximum width portion is this line segment; if the maximum width portion is flat, it is the center of gravity of the flat.

The term "footprint" means the portion of the tread surface that is in contact with the ground.

Tyres for vehicles generally comprise a carcass structure around which a tread band is circumferentially applied after the insertion of one or more belt layers.

The tread band generally has a tread pattern comprising a plurality of longitudinal and/or transverse incisions, the task of which is to provide, in the footprint, suitable drainage channels of the water and/or snow present on the travelling path and to produce grip edges that improve grip on the terrain. The number and size of the incisions in the tread pattern significantly affect different performance aspects of the tire.

All tyres intended for heavy vehicles generally require optimal handling characteristics, both on dry and wet or snowy ground, including traction, acceleration, directionality and controllability (or lateral stability), as well as endurance characteristics, in other words the tendency to keep their functional characteristics at a satisfactory level for as long as possible.

In heavy vehicles, a particular market segment known as "road" is tires for long distances on roads and motorways. A particular concern in this market segment is to allow low fuel consumption, in other words low rolling resistance, thanks to the high smoothness of movement.

Other market segments are the so-called "areas" (for tyres at medium distances), "cities" (tyres intended mainly for urban and suburban areas) and "winter" (tyres intended for cold and/or snowy roads).

Low rolling resistance requires the use of an elastomeric material with low hysteresis and which is preferentially stiff to limit the deformation experienced in the footprint and the consequent energy dissipation.

During travel, the tread band of the tyre is subjected to stresses which, when passing through the footprint, cause the sidewalls respectively defining the incisions to approach each other and to separate them when leaving the footprint. In particular, the sidewalls of the sipes present in the tread pattern may be close to each other until they are in contact with each other.

The applicant has observed that this closure effect of the sipes increases the rigidity of the tread, thus reducing the deformation of the tread portion when it contacts the ground. In the presence of compound hysteresis, such deformation can be considered as one of the causes of energy dissipation when the tire rolls. The applicant has identified the possibility of reducing the rolling resistance of the tyre by reducing the width of some of the incisions in the tread pattern.

The applicant believes that providing a tread pattern that reduces the number of cuts and preferably the width of the cuts will facilitate the limitation of rolling resistance and durability.

Furthermore, these requirements contrast with those derived from the need to achieve good performance in terms of handling, in particular on wet or snowy roads, which generally tend to increase with increasing number and width of the indentations present in the tread pattern.

The applicant has also observed that the performances of the tyre, both in terms of rolling resistance and in terms of handling, tend to vary during the life cycle of the tyre itself. In particular, the applicant has noticed that at the beginning of the working life of a single tyre, the deformation under load of the tread band and the consequent dissipation of power by hysteresis are the greatest. Thereafter, as the tread band wears, both deformation and power dissipation tend to decrease.

Furthermore, the ageing process of the elastomeric material tends to cause it to become increasingly stiff, which on the one hand tends to lead to a reduction in the handling and driving safety, if on the one hand the rolling resistance of the tyre can be advantageously reduced.

Wear of the tread with a gradual reduction in groove depth also tends to reduce the variability of the tread, promoting rolling resistance, but is detrimental to handling performance, particularly on wet and/or snowy roads.

According to the invention, it has been found that by arranging in the tread pattern a deep circumferential sipe having a variable width along its radially extending portion, for example with its maximum width portion substantially at the mid-point of its depth, it is advantageously possible to obtain an optimal running smoothness when the tyre is new and to compensate more quickly for the increased rigidity of the tread band due to ageing and wear phenomena. The maintenance of optimal grip and handling characteristics is thus improved, promoting performance and reduced rolling resistance throughout the tread band life cycle. In particular, it has been found that arranging the maximum width zone at a height comprised between 40% and 60% of the total radial depth of the sipe makes it possible to give the driver a sensation of maintaining the above-mentioned performances over the service life of the tire, by mutual separation of the sipe walls (which are local and do not excessively elongate along their radial extent), while still keeping the maximum width value of the sipe within tolerable limits. The use of sipes having a high slenderness ratio, the maximum width of which is nominally not more than 2 times the minimum detectable width of the radially outer portion of the sipe, makes it possible to improve the wear resistance of the tire and to simplify the moulding operations used during vulcanisation and the operations of extracting the tire from the mould.

The object of the present invention is a tyre for vehicle wheels comprising a tread band having a radially external surface on which a tread pattern is formed, the tread pattern comprising at least one circumferential sipe extending with a substantially continuous extension. In a radial section of the tyre, said circumferential sipe has, starting from the radially external surface of the tread band, a profile comprising a first region close to said radially external surface, said first region comprising sidewalls facing each other and substantially parallel, and having a minimum width W1. For example, such a width W1 may be local or constant over the entire radial extent of the first region or over a portion thereof.

In a second, radially inner region with respect to the first region, precisely in a part thereof, the side walls facing each other are discrete from each other. The second zone also has a maximum width portion in which the sipe has a maximum cross-sectional width W2.

Preferably, in a third zone, radially internal with respect to the second zone, having its own maximum width W3, the sidewalls of the circumferential sipes facing each other are connected to a bottom portion defining the total depth of the sipe equal to or greater than 10 mm.

Preferably, W3 is less than W2.

Preferably, the ratio between W2 and W1 is greater than 1 and equal to or less than 2.

Preferably, the geometric center of the maximum width portion is located at a depth greater than 40% and less than 60% of the total depth of the sipe.

Thus, according to the applicant, by arranging in the tread pattern one or more circumferential sipes, each having the following characteristics, substantially constant performances are facilitated in terms of movement smoothness, handling and durability:

the mutual contact of the sidewalls of the sipes at the passage in the footprint at the initial stage of the tyre life gives satisfactory characteristics of low rolling resistance;

as wear and ageing progress, the sipes can remain open while passing through the footprint, symbolically close to about half of the tread band life, to promote handling and grip characteristics in a wet environment, compensating for the loss of grip due to ageing and wear causing the compound to harden;

as the wear progresses further toward the end of the tread band life, the handling performance does not suddenly decrease.

One or more of the following preferred features are also envisioned:

preferably, the maximum width portion extends radially by an amount no greater than 25% of the total depth of the sipe.

Preferably, in the maximum width portion, the side walls of the sipe have a rectilinear extension up to respective end points equidistant from said geometric centre.

Preferably, the first zone extends radially towards the rotation axis of the tyre up to a depth comprised between 25% and 40% of the total depth of the circumferential sipe.

Therefore, the dependence on sipe closure to achieve low rolling resistance is optimized until compaction, ageing and wear of the tyre cause a reduction in the deformability of the tread band to compensate for the lack of sipe closure. The inclusion of an extension within the indicated limits also contributes to a gradual increase in the width of the sipe towards the maximum width portion, thus promoting the extractability of the tyre from the mould at the end of vulcanisation.

Preferably, the first area extends to a depth comprised between 3mm and 6 mm.

Preferably, W1 is less than 3mm, preferably less than 2.5mm, even more preferably less than 2.2 mm.

Preferably, W1 is greater than 0.6 mm.

Preferably, the second zone extends radially by an amount of at least 25%, preferably at least 30%, of the total depth of the circumferential sipe.

Preferably, the second zone extends radially by an amount less than 80%, preferably less than 60%, of the total depth of the circumferential sipe.

Preferably, W2 is included between 10% and 30% of the total depth of the circumferential sipe.

A relatively elongated sipe is thus obtained, which extends in depth sufficiently to make a permanent contribution to the handling performance, promoting a uniform behaviour of the tyre during wear.

Preferably, W2 is greater than or equal to 1.5 times W1.

Preferably, W2 is greater than or equal to 1.5 times W3.

Preferably, W2 is less than or equal to 2.2 times W3.

Preferably, W2 is greater than or equal to 2 mm.

Preferably, W2 is less than or equal to 6mm, preferably less than or equal to 5 mm.

Preferably, the bottom portion has an arcuate profile.

Preferably, the bottom portion has a semi-circular profile.

The above parameters, alone, and in particular in combination with each other, promote the undulating extension of the inner sidewalls of the sipes, the structural strength of the tread band being improved since there is no discontinuity capable of presenting a possible starting point of cracking or breaking.

Preferably, the second zone has a transition portion in which the sidewalls of the circumferential sipe are discrete from each other from the first zone to the maximum width portion.

Preferably, in the transition portion, the sidewalls of the circumferential sipe extend towards the inside of the circumferential sipe with a convex arched profile.

Preferably, in the transition portion, the sidewalls of the circumferential sipe extend in an arched profile tangential to the same sidewalls in the maximum width portion and in the first zone.

Preferably, in the transition portion, the sidewalls of the circumferential sipe extend in an arched profile having a radius of curvature greater than or equal to 8 mm.

Preferably, in the transition portion, the sidewalls of the circumferential sipe extend in an arched profile having a radius of curvature less than or equal to 35 mm.

Preferably, at the transition portion, the sidewalls of the circumferential sipe diverge from each other at an angle greater than or equal to 10 ° while moving away from the first region.

Preferably, at the transition portion, the sidewalls of the circumferential sipe diverge from each other at an angle less than or equal to 30 ° while moving away from the first region.

Preferably, in the second zone, the sidewalls of the sipes converge towards the third zone until they are at a mutual distance not less than 80% of W1.

Preferably, the second zone has a connecting portion in which the sidewalls of the circumferential sipe converge towards each other towards the third zone.

Preferably, in the connecting portion, the side walls of the circumferential sipe extend towards the inside of the circumferential sipe in a convex arched profile.

Preferably, in the connecting portion, the sidewalls of the circumferential sipe extend according to an arched profile tangent to the same sidewalls in the maximum width portion and in the third zone.

Preferably, in the connecting portion, the sidewalls of the circumferential sipe extend in an arched profile having a radius of curvature greater than or equal to 10 mm.

Preferably, in the connecting portion, the sidewalls of the circumferential sipe extend in an arched profile having a radius of curvature less than or equal to 30 mm.

Preferably, the sidewalls of the circumferential sipe at the connecting portion converge towards each other at an angle greater than or equal to 8 ° towards the third region.

Preferably, the sidewalls of the circumferential sipe at the connecting portion converge towards each other at an angle less than or equal to 25 ° towards the third region.

Preferably, in the vicinity of the maximum width portion, the sidewalls of the circumferential sipe extend towards the inside of the circumferential sipe in a concave arched profile.

Preferably, in the vicinity of the maximum width portion, the sidewalls of the circumferential sipe extend according to an arched profile tangential to the same sidewalls in the transition portion and in the connecting portion.

Preferably, in the vicinity of the maximum width portion, the sidewalls of the circumferential sipe extend in an arched profile having a radius of curvature greater than or equal to 10 mm.

Preferably, in the vicinity of the maximum width portion, the sidewalls of the circumferential sipe extend in an arched profile having a radius of curvature less than or equal to 18 mm.

Preferably, the first region has a mouth, wherein the sidewalls have respective tops converging towards each other starting from the radially outer surface of the tread band.

Preferably, the depth of the mouth is less than 50% of the radial depth of the first region.

Preferably, the radial depth of the mouth is less than 20% of the total depth of the circumferential sipe.

Preferably, the tread pattern further comprises at least one circumferential groove defined between respective opposite sidewalls, said circumferential grooves being spaced apart from each other by an amount greater than 3 mm.

Preferably, the opposite side walls of the groove are interconnected on opposite sides of the radially outer surface by a base portion defining the maximum depth of the groove.

Preferably, the groove has at least one tread wear indicator projecting from the base and defining a remaining depth less than the maximum depth of the groove.

Preferably, the bottom portion of the circumferential sipe is arranged at a depth smaller than the maximum depth of said groove.

Preferably, the bottom portion of the circumferential sipe is arranged at a depth smaller than the remaining depth defined by the wear indicator.

Preferably, the bottom portion of the circumferential sipe is arranged at a depth less than or equal to 85% of the remaining depth defined by the wear indicator.

Preferably, the bottom portion of the circumferential sipe is arranged at a depth greater than or equal to 70% of the remaining depth defined by the wear indicator.

The inclusion of the depth of the sipes to a suitable value makes it possible to obtain a better smoothness of movement in the initial phase of the tread band lifecycle. As the consumption progresses beyond the maximum width portion, the depth of the sipes may be increased by removing material from the third region to restore the optimum handling performance of the tyre until the end of the life cycle, without significantly compromising the smoothness of travel.

Preferably, said at least one groove extends in a substantially continuous extension along the entire circumferential extension of the tread band, axially spaced apart from the at least one circumferential sipe.

Drawings

Figure 1 shows a radial section of a tyre according to the invention.

Fig. 2 shows a plan view of the tread portion of the tire of fig. 1.

Fig. 3 shows an enlarged detail of fig. 1, in which the geometric and dimensional characteristics of the circumferential sipe are highlighted.

Detailed Description

In fig. 1, reference numeral 1 indicates as a whole a tyre for vehicle wheels according to the invention, in particular a wheel, steering or steering tyre 1 for heavy vehicles.

The tyre 1 comprises a carcass structure 102, the carcass structure 102 comprising at least one carcass ply 103, preferably two plies, generally formed of metallic reinforcing cords, included in an elastomeric matrix.

The carcass ply 103 has opposite end flaps 103a engaged with the corresponding rims 104. The rim 104 is arranged in an area 105 of the tyre 1, the area 105 being generally identified by the name "bead".

An elastomeric filler 106 is applied to the outer peripheral edge of the rim 104 so as to occupy the space defined between the carcass ply 103 and the respective end flaps 103a of the carcass ply 103. The rim 104 suitably fixes the tyre 1 to an anchoring seat suitably foreseen in the rim, to prevent the beads 105 from coming out therefrom during operation.

At the beads 105 there may be specific reinforcing structures (not shown) having the function of improving the torque transmission to the tyre 1.

In a radially external position with respect to the carcass structure 102, the belt structure 109 preferably comprises a plurality of belt layers (three layers 109a, 109b, 109c are shown in the particular example shown) arranged radially side by side with each other and generally having metallic reinforcing cords with a crossed orientation and/or substantially parallel to the circumferential extension direction of the tyre 1.

At a radially external position with respect to the belt structure 109, a tread band 2 is applied, the tread band 2 also being made of elastomeric material.

On the side surfaces of the carcass structure 102, each extending from one of the opposite side edges 100a of the tread band 2 to the respective bead 105, sidewalls 111 of elastomeric material are also respectively applied.

With reference to fig. 1-2, the tread band 2 comprises a central portion L1 and two shoulders L2, L3.

The central portion L1, arranged astride the equatorial plane X-X, is clearly separated from the shoulders L2, L3 by means of the two circumferential grooves 3, 4.

At least one circumferentially extending central circumferential groove 6 is additionally or alternatively provided, preferably arranged astride the equatorial plane X-X of the tyre 1.

The circumferential grooves 3, 4 and/or 6 are provided mainly to ensure the water discharge from the footprint, in particular during the straight travel of the tyre 1 itself.

To this end, the circumferential grooves 3, 4 and/or 6 preferably each have a respective width K3, K4, K6 greater than 3mm and in any case less than 20mm, preferably less than 15mm, for example equal to 7 mm. The width of each circumferential groove 3, 4, 6 is defined between respective sidewalls 3a, the sidewalls 3a being interconnected on opposite sides of the radially outer surface S of the tread band 2 by bases 3b, 4b, 6b, the bases 3b, 4b, 6b defining the maximum depth H3, H4, H6 of the grooves 3, 4, 6.

Advantageously, the maximum depths H3, H4, H6 are greater than 10mm, preferably greater than 15mm, in any case less than 30mm, for example equal to 22 mm.

The choice of providing a first circumferential groove 3, 4 and/or 6 with a greater depth makes it possible to obtain good characteristics, preferably over the entire life cycle of the tread band 2.

In one or more of the grooves 3, 4, 6, at least one tread wear indicator TWI may be arranged so as to project radially from the base portion 3b, 4b, 6b to define a residual depth less than the maximum depth H3, H4, H6. In a method known per se, the tread wear indicator TWI may be used (possibly with the aid of suitable measuring means) as a reference for detecting the wear condition of the tread band 2.

The tread band 2 also has one or more circumferential sipes 10, which are axially spaced apart from the circumferential grooves 3, 4 and/or 6. In the example shown, two circumferential sipes 10 are provided, preferably arranged in the central portion L1. Each circumferential sipe 10 is arranged in an axially inner position with respect to one of the first circumferential grooves 3, 4. Preferably, each circumferential sipe 10 is substantially equidistant between the respective groove 3, 4 and the central groove 6.

Advantageously, the total radial depth H10 of the circumferential sipe 10 may be greater than 10mm, preferably greater than 15mm, in any case less than 30mm, for example equal to 16 mm.

Good characteristics can be obtained by choosing to provide the circumferential sipes 10 with a greater depth and to extend this function of the sipes 10 for a majority, nominally more than half, of the useful life cycle of the tread band 2.

The circumferential sipes 10 and the grooves 3, 4 and/or 6 may extend circumferentially in a rectilinear or dispersed manner, for example in order to increase the traction of the tread band 2 in the direction of forward movement of the tyre 1.

However, it is preferably foreseen to have the circumferential sipes 10 and the circumferential grooves 3, 4 and/or 6 with a substantially continuous extension, in other words without interruptions which occupy more than 10% of the circumferential extension of the tread band 2 as a whole.

In the tread band 2, the transverse cuts 20 may be set so as to be suitably distributed along the axial and circumferential extension according to a desired so-called tread band, and cooperate with the grooves 3, 4, 6 and the circumferential sipes 10 to delimit a plurality of shoulder blocks 30 and a plurality of central blocks 35.

Fig. 1 shows, in dashed lines, the bottom profile of the transverse recess 20, which may have a constant or variable depth along the extension.

With particular reference to fig. 3, each circumferential sipe 10 is shaped and sized to have a profile which, while being radially distant from the radially outer surface S of the tread band 2, comprises a first zone Z1, a second zone Z2 radially internal to the first zone Z1, and a third zone Z3 radially internal to the second zone Z2.

Near the radially outer surface S in the first zone Z1, the sidewalls 11 of the sipe 10 facing each other are substantially parallel to each other. The first zone Z1 has a minimum cross-sectional width W1.

In the second zone Z2, the sidewalls 11 of the circumferential sipe 10 are discrete from each other up to a maximum width portion Pmax, in which the sipe 10 has a maximum section width W2.

The third zone Z3 has its own maximum width W3, which is less than W2.

In the third zone Z3, the sidewalls 11 of the circumferential sipe 10 are connected to a bottom portion Pf, preferably having an arched profile, defining a total depth H10 of the sipe 10.

In a preferred embodiment, the bottom portion Pf has a semicircular profile.

Preferably such that the stresses transmitted at the footprint during use of tyre 1 promote a minimum width W1 of mutual contact of sidewalls 11.

Preferably, it is foreseen to have a minimum width comprised symbolically between 0.6 and 3mm, preferably less than 2.5mm, even more preferably less than 2.2 mm.

The first zone Z1 extends radially away from the radially external surface S up to a depth HZ1, this depth HZ1 being comprised symbolically between 3mm and 6mm, and preferably between 25% and 40% of the total depth H10 of the circumferential sipe 10

The sidewalls 11 may be substantially parallel to each other throughout the extension of the first zone Z1, or, as shown in fig. 3, the sidewalls 11 in the first zone Z1 may have top portions 11a converging towards each other starting from the radially outer surface S of the tread band 2 to define a mouth portion Z1a of the first zone Z1 preferably the top portions 11a converge towards each other by an angle β 1 included between 45 ° and 70 °, preferably equal to 60 °.

Preferably, the crests 11a converge towards each other starting from a mutual distance D1 on the radially external surface S, D1 being symbolically between 2.5mm and 4mm, for example equal to 3.5 mm. The radial depth HZ1a of the mouth Z1a is preferably less than 20% of the total depth H10 of the circumferential sipe 10. The radial depth HZ1a of the mouth Z1a is preferably less than 50% of the radial depth HZ1 of the first zone Z1.

Preferably, the second zone Z2 extends radially in the amount of HZ2, HZ2 being comprised between 25% and 80%, more preferably between 30% and 60%, of the total depth H10 of the circumferential sipe 10.

Preferably, the maximum width portion Pmax is arranged substantially at the mid-point of the total depth H10 of the circumferential sipe 10, the geometric centre G2 being located at a depth PG, which is nominally comprised between 40% and 60% of the total depth H10.

In the example shown, the maximum width portion Pmax has a zero radial extent and is therefore defined along the lateral wall 11 by two points at maximum distance apart, respectively equidistant from the radially external surface S. In this case, the geometric center G2 of the maximum width portion Pmax is located on a line segment R connecting two maximum distance points.

Alternatively, the maximum width portion Pmax may preferably extend radially by an amount no greater than 25% of the total depth H10 of the sipe 10. In this case, it is possible to identify analytically the geometric centre G2 of the maximum width portion Pmax as the centre of gravity of the flat shape defined by the radial section portions, in which the sidewalls 11 of the circumferential sipe 10 facing each other are kept at a mutual maximum distance W2.

The ratio between the maximum section width W2 and the first minimum section width W1 is greater than 1 and equal to or less than 2.

Furthermore, the maximum section width W2 is preferably comprised between 10% and 30% of the total depth H10 of the circumferential sipe 10.

Preferably, the maximum cross-sectional width W2 is greater than or equal to 1.5 times the minimum width W1. In some preferred examples, the maximum cross-sectional width W2 is comprised between 1.5 and 2.2 times the maximum width W3 of the third region Z3. The maximum section width W2 may be greater than 1.2mm, preferably less than 6mm, preferably comprised between 2 and 5 mm.

Preferably, in the second zone Z2, the transition zone Pt and/or the joining zone Pr can be identified in a radially outer position and a radially inner position with respect to the maximum width portion Pmax, respectively.

In at least one, preferably both, of said transition portion Pt and connection portion Pr, the side wall 11 of the circumferential sipe 10 preferably extends towards the inside of the circumferential sipe 10, following an at least partially convex arched profile.

In the maximum width portion Pmax, it is foreseen that the side wall 11 of the circumferential sipe 10 instead extends towards the inside of the circumferential sipe 10 following a concave arched profile, and preferably has a radius of curvature between 10mm and 18mm, for example equal to 14 mm. Preferably, the arched profile of each side wall in the region of maximum width is defined by a circular arc RPmax.

Preferably, in the transition region Pt, the convex arched profile of the side walls 11 is tangent to the same side walls 11 in the first region Z1 and to their concave arched profile in the maximum width portion Pmax.

In the connecting region Pr, the convex arched profile of the side walls 11 is preferably tangent to the same side walls 11 in the third region Z3, and to their concave arched profile in the maximum width portion Pmax.

In the transition portion Pt, the sidewalls 11 of the circumferential sipe 10 preferably diverge from one another from the first zone Z1 towards the maximum width portion Pmax at an angle β 2 (at the tangent point to the concave arched profile defining the sidewall 11 in the maximum width portion Pmax) comprised between 10 ° and 30 ° (for example equal to 14 °).

The arched profile of each side wall 11 in the transition portion Pt may be defined by a circular arc and preferably has a radius of curvature RPt comprised between 15mm and 35mm, for example equal to 25 mm.

In the connecting portion Pr, the sidewalls 11 of the circumferential sipe 10 preferably converge towards each other from the maximum width portion Pmax towards the third zone Z3 at an angle β 3 (at the point of tangency with the sidewalls 11 in the third zone Z3) comprised between 8 ° and 25 ° (for example equal to 12 °). in said point of tangency identifying the transition between the second zone Z2 and the third zone Z3, the mutual spacing distance of the sidewalls 11 is greater than or equal to 80% of the minimum width W1.

The arcuate profile of each side wall 11 in the connecting portion Pr may be defined by a circular arc and its radius RPr is preferably less than or equal to the radius RPt defining the arcuate profile of the transition portion Pt. For example, the radius of curvature RPr of the connecting portion Pr may be comprised between 10mm and 30mm, for example equal to 20 mm.

Claims (19)

1. A tyre for vehicle wheels, comprising a tread band (2), said tread band (2) having a radially external surface (S) on which a tread pattern is formed, said tread pattern comprising:

at least one circumferential sipe (10) extending according to a substantially continuous extension;

wherein, in a radial section of the tyre (1), the circumferential sipe (10) has, starting from the radially external surface (S) of the tread band (2), a profile comprising:

a first zone (Z1) close to the radially external surface (S), the first zone (Z1) comprising side walls (11) facing each other and substantially parallel and having a minimum width W1;

a second zone (Z2) radially internal with respect to the first zone (Z1), the second zone (Z2) having a portion (Pt) in which the sidewalls (11) facing each other are discrete from each other and a maximum width portion (Pmax) in which the circumferential sipe (10) has a maximum section width W2; and

a third zone (Z3) arranged radially inside with respect to the second zone (Z2) and having a maximum width W3;

wherein, in said third zone (Z3), the sidewalls (11) of the circumferential sipe (10) facing each other are connected to a bottom portion (Pf) defining the total depth (H10) of the circumferential sipe (10) equal to or greater than 10 mm;

wherein W3 is less than W2;

wherein the ratio between W2 and W1 is greater than 1 and equal to or less than 2;

wherein the geometric centre (G2) of the maximum width portion (Pmax) is located at a depth (PG) greater than 40% and less than 60% of the total depth (H10) of the circumferential sipe (10).

2. Tyre according to claim 1, wherein said maximum width portion (Pmax) extends radially in an amount not greater than 25% of the total depth (H10) of the circumferential sipe (10).

3. A tyre as claimed in one of the preceding claims, wherein said first region (Z1) extends from said radially outer surface of the tread band (2) to a depth (HZ1) comprised between 25% and 40% of said total depth (H10) of the circumferential sipe (10).

4. Tyre according to any one of the preceding claims, wherein between 10% and 30% of the total depth (H10) of the circumferential sipe (10) comprises W2.

5. Tyre according to any one of the preceding claims, wherein said second zone (Z2) has a transition portion (Pt) in which said sidewalls (11) of said circumferential sipe (10) diverge from one another from said first zone (Z1) to said maximum width portion (Pmax).

6. Tyre according to claim 5, wherein, in said transition portion (Pt), said side wall (11) of said circumferential sipe (10) extends towards the inside of said circumferential sipe (10) with a convex arched profile.

7. Tyre according to claim 5 or 6, wherein, in said transition portion (Pt), said sidewalls (11) of said circumferential sipe (10) extend according to an arched profile tangential to the same sidewalls (11) in said maximum width portion (Pmax) and in said first zone (Z1).

8. Tyre according to any one of claims 5 to 7, wherein the sidewalls (11) of the circumferential sipe (10) at the transition portion (Pt) are discrete from each other by an angle (β 2) comprised between 10 ° and 30 ° while moving away from the first zone (Z1).

9. Tyre according to any one of the preceding claims, wherein, in said second zone (Z2), the sidewalls (11) of the circumferential sipe (10) converge towards said third zone (Z3) until the mutual distance is not less than 80% of W1.

10. Tyre according to any one of the preceding claims, wherein said second zone (Z2) has a connecting portion (Pr) in which said sidewalls (11) of said circumferential sipe (10) converge towards each other towards said third zone (Z3).

11. A tyre as claimed in claim 10, wherein, in said connecting portion (Pr), said sidewalls (11) of said circumferential sipe (10) extend towards the inside of said circumferential sipe (10) according to a convex arched profile.

12. Tyre according to claim 10 or 11, wherein, in said connecting portion (Pr), said sidewalls (11) of said circumferential sipe (10) extend according to an arched profile tangential to the same sidewalls (11) in said maximum width portion (Pmax) and in said third zone (Z3).

13. Tyre according to any one of claims 10 to 12, wherein the sidewalls (11) of the circumferential sipe (10) at the connecting portion (Pr) converge with each other towards the third region, preferably at an angle comprised between 8 ° and 25 °.

14. Tyre according to any one of the preceding claims, wherein, in the vicinity of said maximum width portion (Pmax), said sidewalls (11) of said circumferential sipe (10) extend towards the inside of said circumferential sipe (10) with a concave arched profile.

15. Tyre according to any one of the preceding claims, wherein, in said second zone (Z2), the sidewalls (11) of the circumferential sipe (10) extend with an arched profile tangential to the same sidewalls (11) in the transition portion (Pt) and the connecting portion (Pr).

16. Tyre according to any one of the preceding claims, wherein said first region (Z1) has a mouth (Z1a) in which said sidewalls (11) have respective tops (11a) converging with each other starting from said radially outer surface (S) of said tread band (2).

17. A tyre according to any one of the preceding claims, wherein said tread pattern further comprises at least one circumferential groove (3, 4, 6), said circumferential groove (3, 4, 6) being delimited between respective opposite side walls (3a, 4a, 6a), said opposite side walls (3a, 4a, 6a) being connected to each other on opposite sides of said radially outer surface (S) by means of a base defining a maximum depth of said circumferential groove, said bottom portion (Pf) of said circumferential sipe (10) being arranged at a depth smaller than said maximum depth of said circumferential groove (3, 4, 6).

18. Tire according to any one of the preceding claims, wherein W2 is greater than or equal to 1.5 times W3.

19. Tire according to any one of the preceding claims, wherein W2 is less than or equal to 2.2 times W3.