Tire comprising a circumferential cut-out and a durable stiffening structure and enabling optimized flattening of the tread

The invention claimed is: 1 . A tire comprising: a crown comprising a tread and a crown reinforcement arranged radially inside the tread, the tread having a profile height and comprising ribs separated axially from one another by one or more main circumferential cut-outs that each have a depth greater than or equal to 50% of the profile height; a first sidewall and a second sidewall, which each extend the crown radially inward and which are respectively arranged on a first side and a second side of a median plane of the tire; a first bead and a second bead, which each extend the first sidewall and the second sidewall radially inward respectively and which are respectively arranged on the first side and the second side of the median plane; an internal surface delimiting a toroidal cavity of for inflating the tire; a carcass reinforcement, which is anchored in each of the first and second beads and which extends in each of the first and second sidewalls and in the crown, the carcass reinforcement being radially inside the crown reinforcement in the crown; and a stiffening structure comprising: one or more stiffening elements that each extend continuously in the toroidal cavity from at least one of the first sidewall and the second sidewall or from the first bead and the second bead at least as far as the crown, at least one radially outer reinforcing structure that is: arranged in the crown, distinct from the carcass reinforcement, from the crown reinforcement, and from each stiffening element, and buried in a crown material mass of the crown, which physically separates the at least one radially outer reinforcing structure from the crown reinforcement and from the carcass reinforcement, and at least one radially inner reinforcing structure that is: arranged in one of the first sidewall, the second sidewall, the first bead, and the second bead, distinct from the carcass reinforcement and from each stiffening element, and buried in a sidewall material mass or a bead material mass of the one of the first sidewall, the second sidewall, the first bead, and the second bead, the sidewall material mass or the bead material mass physically separating the at least one radially inner reinforcing structure from the carcass reinforcement, wherein each stiffening element; passes through the internal surface at a radially inner anchor point of the one of the first sidewall, the second sidewall, the first bead, and the second bead to extend from said radially inner anchor point deep into the sidewall material mass or the bead material mass so as to be anchored beneath the internal surface in or around the at least one radially inner reinforcing structure and to be physically separated by the sidewall material mass or the bead material mass from the carcass reinforcement, passes through the internal surface at a radially outer anchor point of the crown to extend from said radially outer anchor point deep into said crown material mass so as to be anchored beneath the internal surface in or around the at least one radially outer reinforcing structure and to be physically separated by said crown material mass from the carcass reinforcement and the crown reinforcement, and comprises a portion extending in the toroidal cavity between the radially inner anchor point and the radially outer anchor point, and wherein the radially outer anchor point for each stiffening element is aligned with one of the ribs. 2 . The tire according to claim 1 , wherein each of the first bead and the second bead comprises at least one circumferential reinforcing element for attaching the tire onto a mounting support, wherein the at least one radially inner reinforcing structure is distinct from the at least one circumferential reinforcing element situated on the same side of the median plane as the one of the first sidewall, the second sidewall, the first bead, and the second bead, and wherein the sidewall material mass or the bead material mass physically separates each stiffening element and the at least one radially inner reinforcing structure from the at least one circumferential reinforcing element situated on the same side of the median plane as the one of the first sidewall, the second sidewall, the first bead, and the second bead. 3 . The tire according to claim 1 , wherein the stiffening structure comprises a plurality of stiffening elements circumferentially distributed in the toroidal cavity. 4 . The tire according to claim 1 , wherein each rib aligned with the radially outer anchor point for each stiffening element: is delimited axially by two axial edges defining a width L of the rib, and has a median plane, which is situated axially equidistantly from the two axial edges and which is at an axial distance l from the radially outer anchor point such that 2×l/L≤0.90. 5 . The tire according to claim 1 , wherein the at least one radially inner reinforcing structure includes: a first radially inner reinforcing structure that is: arranged in the first sidewall or the first bead, distinct from the carcass reinforcement and from each stiffening element, and buried in a first sidewall material mass or a first bead material mass of the first sidewall or the first bead, respectively, which physically separates the first radially inner reinforcing structure from the carcass reinforcement, and a second radially inner reinforcing structure that is: arranged in the second sidewall or the second bead, distinct from the carcass reinforcement and from each stiffening element, and buried in a second sidewall material mass or a second bead material mass of the second sidewall or the second bead, respectively, which physically separates the second radially inner reinforcing structure from the carcass reinforcement, wherein each stiffening element extends continuously from the first sidewall or the first bead to the second sidewall or the second bead via the crown, wherein the or each stiffening element: passes through the internal surface at a first radially inner anchor point of the first sidewall or the first bead to extend from said first radially inner anchor point deep into the first sidewall material mass or the first bead material mass so as to be anchored beneath the internal surface in or around the first radially inner reinforcing structure and to be physically separated by the first sidewall material mass or the first bead material mass from the carcass reinforcement, passes through the internal surface at a first radially outer anchor point of the crown to extend from said first radially outer anchor point deep into said crown material mass so as to be anchored beneath the internal surface in or around the at least one radially outer reinforcing structure, comprises a first portion extending in the toroidal cavity between the first radially inner anchor point and the first radially outer anchor point passes through the internal surface at a second radially inner anchor point of the second sidewall or the second bead to extend from said second radially inner anchor point deep into the second sidewall material mass or the second bead material mass so as to be anchored beneath the internal surface in or around the second radially inner reinforcing structure and to be physically separated by the second sidewall material mass or the second bead material mass from the carcass reinforcement, passes through the internal surface at a second radially outer anchor point of the crown to extend from said second radially outer anchor point deep into said crown material mass so as to be anchored beneath the internal surface in or around the at least one radially outer reinforcing structure, and comprises a second portion extending in the toroidal cavity between the second radially inner anchor point and the s