Assembly for a tire, tire and associated manufacturing methods

The invention claimed is: 1. An assembly for a tire comprising: a first structure formed by first cord elements, the first structure having a longitudinal edge extending in a first direction which defines a first axis; a second structure formed by second cord elements, the second structure comprising a longitudinal edge extending in a second direction which defines a second axis, the first axis and the second axis being parallel; a bearing structure comprising bearing cord elements linking the first cord elements of the first structure and the second cord elements of the second structure; and at least one cord securing element fixed to each of the first cord elements and to the second cord elements, wherein the at least one cord securing element comprises a gimped cord element comprising a core around which a gimp yarn is wound, wherein the core of the at least one cord securing element exhibits an elongation at rupture lower than a ratio between a conformation height h of the assembly and a sum of a thickness of the first structure, of a thickness of the second structure, and of a lock length: A rupture_core <h /( E+e 1 +e 2 ) in which: A rupture_core is the elongation at rupture of the core, h is the conformation height of the assembly, corresponding to a height between opposite faces of the first structure and of the second structure when the bearing cord elements are taut, e 1 is the thickness of the first structure, e 2 is the thickness of the second structure, and E is the lock length, and wherein the gimp yarn of the at least one cord securing element exhibits an elongation at rupture greater than an elongation equal to the ratio between the conformation height h of the assembly and the sum of the thickness of the first structure, of the thickness of the second structure, and of the lock length: A rupture_gimp >h /( E+e 1 +e 2 ) in which: A rupture_gimp is the elongation at rupture of the gimp yarn. 2. The assembly of claim 1 , wherein the at least one cord securing element exhibits a first secant rigidity and the core exhibits a first elongation at rupture, wherein the gimp yarn exhibits a second secant rigidity and a second elongation at rupture, wherein the first secant rigidity of the securing element is strictly greater than the second secant rigidity of the gimp yarn, and wherein the first elongation at rupture of the core is strictly lower than the second elongation at rupture of the gimp yarn. 3. The assembly of claim 1 , wherein the at least one cord securing element has two opposing free ends and is anchored to the first cord elements and to the second cord elements at its free ends and is locked in the first structure and in the second structure between its free ends. 4. The assembly of claim 1 , wherein the at least one cord securing element has two opposite free ends and is anchored to the first cord elements and to the second cord elements at the free ends and at a plurality of points between the free ends wherein the elongation at rupture of the core is lower than a ratio A 2 between the conformation height h of the assembly and the sum of the thickness of the first structure and of the thickness of the second structure: A rupture_core <A 2 =h /( e 1 +e 2 ), and wherein the elongation at rupture of the gimp yarn is greater than the ratio A 2 between the conformation height h of the assembly and the sum of the thickness of the first structure and of the thickness of the second structure: A rupture_gimp >A 2 =h /( e 1 +e 2 ). 5. The assembly of claim 1 , wherein a secant rigidity of the gimp yarn of the at least one cord securing element is lower than or equal to a maximum rigidity which corresponds to a ratio between a force undergone by the gimp yarn of the at least one cord securing element upon application of a predetermined shaping pressure so as to form a space separating the first structure and the second structure from one another, and an elongation of the at least one cord securing element at the predetermined shaping pressure: E max =F gimp /A in which: F gimp corresponds to the force undergone by the gimp yarn of the at least one cord securing element at the predetermined shaping pressure, and A corresponds to the elongation of the securing element at the shaping pressure. 6. The assembly of claim 1 , wherein a secant rigidity of the at least one cord securing element is greater than or equal to a minimum rigidity which corresponds to a ratio of a force undergone by the at least one cord securing element under a predetermined winding tension and of an elongation that the securing element is capable of undergoing under the predetermined winding tension: E min =F T_reinforcement /A T in which: F T_reinforcement corresponds to the force undergone by the at least one cord securing element under the winding tension T, and A T corresponds to the elongation that the at least one cord securing element is capable of undergoing under the winding tension. 7. A manufacturing method of the assembly of claim 1 comprising the following steps: placing the first structure on the second structure so that the first axis and the second axis are substantially parallel; and fixing the first structure onto the second structure by fixing at least one cord securing element to each of the first cord elements and to the second cord elements, wherein the at least one cord securing element comprises the gimped cord element comprising the core around which the gimp yarn is wound, wherein the core of the at least one cord securing element exhibits the elongation at rupture lower than a ratio A 1 between the conformation height h of the assembly and the sum of the thickness of the first structure, of the thickness of the second structure, and of the lock length: A rupture_core <A 1 =h /( E+e 1 +e 2 ) in which: A rupture_core is the elongation at rupture of the core, h is the conformation height of the assembly, corresponding to the height between opposite faces of the first structure and of the second structure when the bearing cord elements are taut, e 1 is the thickness of the first structure, e 2 is the thickness of the second structure, and E is the lock length, and wherein the gimp yarn of the at least one cord securing element exhibits the elongation at rupture greater than an elongation equal to the ratio A 1 between the conformation height h of the assembly and the sum of the thickness of the first structure, of the thickness of the second structure, and of the lock length: A rupture_gimp >A 1 =h /( E+e 1 +e 2 ) in which A rupture_gimp is the elongation at rupture of the gimp yarn. 8. The manufacturing method of claim 7 , wherein the at least one cord securing element exhibits a first secant rigidity and the core exhibits a first elongation at rupture, the gimp yarn exhibits a second secant rigidity and a second elongation at rupture, the first secant rigidity of the securing element being strictly greater than the second secant rigidity of the gimp yarn, and the first elongation at rupture of the core being strictly lower than the second elongation at rupture of the gimp yarn. 9. The manufacturing method of claim 7 , wherein the at least one cord securing element has two opposite free ends, the fixing step comprising the substeps of anchoring the at least one cord securing element to the first cord elements and to the second cord elements at the free ends and of locking the at least one cord securing element in the first structure and the second structure between the fr