TREAD FOR AN EARTHMOVER TIRE, COMPRISING INCISED BLOCKS

Abstract

The tread comprises a plurality of blocks, each block being delimited by transverse or oblique grooves and circumferential grooves. Each block is provided with a sipe which has three branches. The branches have common ends. A first branch is oriented in a transverse or oblique direction. A second branch and a third branch each open when new into a transverse groove delimiting the block. The angle formed between the first and second branches is 100 to 125 degrees, and the angle formed between the first and the third branches is 100 to 125 degrees. After wear, each sipe represents between 45% and 70% of the total wearable thickness, such that the lengths of the three branches measured on the new tread surface, L1′, L2′, L3′ respectively, are shorter than the lengths L1, L2, L3 respectively measured on the tread surface when new.

Claims

1. a tread for a tire for a construction plant vehicle, this tread having a surface-13 referred to as tread surface—intended to come into contact with the ground when the tire is running, this tread having a wearable thickness of material at least equal to 60 mm and comprising on its tread surface a tread pattern design formed of a plurality of blocks of material, each block being delimited by transverse or oblique grooves—which means to say grooves making an angle at least equal to 45 degrees with the circumferential direction-and circumferential grooves, wherein a plurality of blocks are provided with a sipe having three incised branches these three branches having one end in common, a first branch being oriented in a transverse or oblique direction, a second branch and a third branch each opening when new into a transverse groove delimiting the block, each sipe being such that the angle formed between the first branch and the second branch is at least equal to 100 degrees and at most equal to 125 degrees and such that the angle formed between the first branch and the third branch is at least equal to 100 degrees and at most equal to 125 degrees, this sipe being, after wear representing between 45% and 70% of the total wearable thickness, such that the lengths of the three branches measured on the new tread surface, L1′, L2′, L3′ respectively, are shorter than the lengths L1, L2, L3 respectively measured on the tread surface when new, and the reductions in length are at least equal to 30% of the respective initial lengths.

2. The tread according to claim 1 wherein the reductions in length of the branches of the sipes are at least equal to 30% and at most equal to 60% of the respective initial lengths of each branch.

3. The tread according to claim 1 wherein after wear representing more than 95% of the total wearable thickness, the lengths of the three branches measured on the new tread surface, respectively L1″, L2″, L3″ are shorter than the initial lengths—L1, L2, L3 respectively—measured on the tread surface when new.

4. The tread according to claim 1 wherein the first branch comprises, on the tread surface when new, two ends one of which is common to the other two branches and another of which is situated axially between the common end and the equatorial midplane of the tire.

5. The tread according to claim 4 wherein the first branch of the sipe is provided at its end not common to the other two branches with a well of a diameter greater than the width of the first branch so as to reduce the stresses at this end and encourage the removal of heat produced in the tread during running, this well extending depthwise at least as far as the reduction in length of the first sipe incision.

6. The tread according to claim 5 wherein in order to encourage the removal of the heat generated in the tread, the well formed at the end of the first branch that is not common to the other two branches has a depth at least equal to 30% of the total wearable thickness.

7. The tread according to claim 1 wherein the depths from which the lengths of the second and third branches of the sipes are reduced differ from one another so as to increase the movement of air in these branches and thus increase the removal of heat.

8. The tread according to claim 1 wherein, when new, the three branches of the sipe interconnect at a well with a maximum surface dimension at least equal to 10% and at most equal to 20% of the circumferential length of the block.

9. The tread according to claim 8 wherein the well to which the three branches of the sipe are connected has a cross section that decreases with depth so as to limit the possibility of trapping foreign bodies liable to damage the tire provided with this tread.

10. The tread according to claim 1 wherein the second and third branches are provided with undulations in two directions whereas the first branch is provided with undulations in the depthwise direction.

Description

BRIEF DESCRIPTION OF THE FIGURES

[0031] FIG. 1 depicts a partial view of a tread according to the disclosure;

[0032] FIG. 2 depicts a partial view of a tread after partial wear;

[0033] FIG. 3 shows a view of a block of a tread when new according to another alternative form.

DETAILED DESCRIPTION OF THE ENABLING EMBODIMENTS

[0034] To make the figures easier to read, the same reference signs are used for describing alternative forms of the disclosure where these reference signs refer to elements that are the same in nature whether structurally or indeed functionally.

[0035] FIG. 1 depicts a partial view of a tread of a construction plant tire according to the disclosure.

[0036] This tire comprises a carcass reinforcement surmounted by a crown reinforcement the latter itself being surmounted by a tread of which a surface—referred to as tread surface—is intended to come into contact with the ground when the tire is being driven on.

[0037] This tread has a variable thickness of wearable material at least equal to 60 mm. This thickness corresponds to the thickness of material between the tread surface when new and a level corresponding to maximum wear. This tread on its tread surface comprises a tread pattern design, this design being formed of a plurality of blocks 1 of material, each block 1 being delimited by transverse grooves 11—which means to say grooves making an angle equal to 90° with the circumferential direction (indicated by the arrow X) and grooves 12 of circumferential orientation.

[0038] This FIG. 1 depicts two blocks 1 each comprising a contact face 10 forming part of the tread surface of the tread. Each contact face 10 of each block 1 is delimited by lateral edge corners and leading and trailing edge corners. The lateral edge corners 103, 104 border the circumferential grooves delimiting the blocks. The leading edge corner 101 corresponds to the frontal edge corner that is first to come into contact with the ground, while the trailing edge corner 102 corresponds to the rear edge corner of the contact face that is last to come into contact.

[0039] Opening onto the contact face 10 of each block 1 is a three-branched sipe 2, the three branches 21, 22, 23 having in common one end that forms a radial well 31 of a depth P corresponding to the maximum depth of the sipe 2. A first branch 21 is oriented in a transverse direction parallel to the direction of the transverse grooves 11 delimiting the block 1, a second branch 22 and a third branch 23 each when new open into a transverse groove delimiting the block.

[0040] In this alternative form, the angle formed between the first branch 21 and the second branch 22 of the sipe 2 is at least equal to 100 degrees and at most equal to 125 degrees and the angle formed between the first branch 21 and the third branch 23 is at least equal to 100 degrees and at most equal to 125 degrees.

[0041] In this alternative form, the three branches of the sipe 2 open when new into the grooves. The first branch has a length L1 measured on the contact face when new, while the second and third branches have lengths L2 and L3 respectively.

[0042] After wear representing between 45% and 70% of the total wearable thickness measured between the tread surface when new and a wear limit of the tread, and as shown in FIG. 2, the sipe 2 maintains its three branches which remain connected along the same radial well 31 while having lengths measured on the new tread surface, L1′, L2′, L3′ respectively, which are shorter than the respective lengths L1, L2, L3 measured on the tread surface when new. The reductions in length are at least equal to 30% of the respective initial lengths: that means for example that L1′ is less than 70% of L1. In the scenario depicted, the variations in length of the three branches are expressed as identical percentages. These three branches of the sipe remain present on the tread surface until the tread is completely worn.

[0043] Through this measure it is possible to strike a balance in operation both from a mechanical standpoint and from a thermal standpoint.

[0044] FIG. 3 shows, in another alternative form of the disclosure, a block 1 of a tread when new, this block being provided with a three-branch sipe 2. In this alternative form, the well 31 to which the three branches 21, 22, 23 of the sipe 2 are connected has a cross section of circular shape with a diameter equal to three times the mean width of each branch of the sipe, this width being measured on the tread surface when new. The cross-sectional diameter of the well 31 on the tread surface when new is comprised between 10% and 20% of the circumferential length Lc of the block 1.

[0045] In this layout, the three branches 21, 22, 23 are interconnected via this well 31 while at the same time being slightly offset from the center of the circle of the cross section of the well.

[0046] Furthermore, the first branch 21 of the sipe 2 ends inside the block 1 in a second radial well 32 of cross section similar to that of the well 31 to which the three branches of the sipe are connected. In combination with these two wells, a third well 33 is formed in that part of the element that is delimited by the second and third branches of the sipe and has no other sipe. This third well 33 is not connected to the sipe and its purpose is to balance the block from a mechanical and thermal standpoint. For preference, the wells 31, 32, 33 used here are frustoconical in shape, namely have a cross section that decreases with tread wear so as to avoid trapping foreign bodies that could potentially damage the tread.

[0047] The disclosure described with these examples is not limited to these examples alone and various modifications may be made thereto without departing from the scope defined by the claims. In particular, the blocks may be bounded by grooves of curvilinear geometries and in such cases the sipes may adopt curvilinear geometries rather than the rectilinear geometries shown in FIGS. 1 to 3.