Welded structural joint between a high-performance thermoplastic matrix composite material and an elastomer

The invention claimed is: 1. A method for producing a welded structural joint between a thermoplastic matrix of a composite material and an elastomer, comprising the steps of: functionalizing an elastomeric material using a nonwoven textile formed from thermoplastic material fibers configured to be welded with the thermoplastic matrix of said composite material, functionalization is carried out by penetration of the non-woven textile into a surface layer of the elastomeric material during vulcanization of the elastomeric material under pressure to provide a functionalized layer of the elastomeric material; and welding the thermoplastic matrix of said composite material to the functionalized layer of the elastomeric material. 2. The method as claimed in claim 1 , wherein the step of welding comprises the steps of heating faying surfaces of two materials to be welded by interposing a woven metal wire cloth between the faying surfaces of the two materials, the woven metal wire cloth functions as a heating resistance and the woven metal wire cloth is impregnated with a thermoplastic material. 3. The method as claimed in claim 2 , further comprising the step of preparing the faying surfaces of the two materials to be assembled prior to the step of welding. 4. The method of claim 3 , wherein the step of preparing comprises the steps of degreasing using a solvent, and cleaning the faying surfaces of the two materials with the solvent. 5. The method of claim 3 , wherein the step of preparing comprises the steps of grinding a surface of the functionalized layer of the elastomeric material forming the elastomer, and cleaning the surface of the functionalized layer with a solvent. 6. The method as claimed in claim 1 , further comprising the step of producing the nonwoven textile from a thermoplastic material that is both weldable to a thermoplastic material forming said composite material and compatible with the elastomeric material. 7. The method as claimed in claim 6 , further comprising the step of producing the nonwoven textile from a thermoplastic material identical to the thermoplastic material forming said composite material. 8. The method as claimed in claim 1 , wherein the step of functionalizing comprises the steps of: cleaning various parts of a vulcanizing mold; applying the nonwoven textile on a surface of the elastomeric material; and vulcanizing the elastomeric material under a pressure so that the nonwoven textile placed at a surface of the elastomer material becomes incorporated therein, at least at the surface, during the vulcanization process. 9. The method as claimed in claim 1 , further comprising the steps of producing the nonwoven textile by: carding thermoplastic material monofilaments; producing webs superposed on one another and held together by needle-punching; and reinforcing the nonwoven textile by hydro-entangling. 10. A method for producing a welded structural joint between a thermoplastic matrix of a composite material and an elastomer, comprising the steps of: functionalizing an elastomeric material using a nonwoven textile formed from thermoplastic material fibers configured to be welded with the thermoplastic matrix of said composite material, functionalization is carried out by penetration of the non-woven textile into a surface layer of the elastomeric material during vulcanization of the elastomeric material under pressure to provide a functionalized layer of the elastomeric material; welding the thermoplastic matrix of said composite material to the functionalized layer of the elastomeric material; and wherein said composite material is a carbon/polyetheretherketone composite; wherein the elastomeric material is of a hydrogenated nitrile butadiene rubber type; and wherein the nonwoven textile is formed from polyetherimide fibers. 11. The method as claimed in claim 10 , wherein the step of welding comprises the steps of heating faying surfaces of two materials to be welded by interposing a woven metal wire cloth between the faying surfaces of the two materials, the woven metal wire cloth functions as a heating resistance and the woven metal wire cloth is impregnated with a thermoplastic material. 12. The method as claimed in claim 11 , further comprising the step of preparing the faying surfaces of the two materials to be assembled prior to the step of welding. 13. The method of claim 12 , wherein the step of preparing comprises the steps of degreasing using a solvent, and cleaning the faying surfaces of the two materials with the solvent. 14. The method of claim 12 , wherein the step of preparing comprises the steps of grinding a surface of the functionalized layer of the elastomeric material forming the elastomer, and cleaning the surface of the functionalized layer with a solvent. 15. The method as claimed in claim 10 , wherein the step of functionalizing the elastomeric material comprises the steps of: setting up following elements on a bottom plate of a vulcanizing mold and covering the elements with a top plate of the vulcanizing mold to provide a stack: a first set of two superposed layers of Teflon-coated glass cloth; a sheet of nonwoven textile composed of polyetherimide fibers; sheets of unvulcanized raw elastomeric material; a set of edging blocks; and a second set of two superposed layers of Teflon-coated glass cloth; and placing the stack on plate of a heating press preheated to a temperature θ 2 of 140° C.; hot pressing the stack by applying a nominal pressing cycle of the elastomer in question is applied; removing the vulcanizing mold from the heating press which maintains the temperature θ 2 of 140° C.; and removing the functionalized layer of elastomeric material from the vulcanizing mold to cool to a room temperature. 16. The method as claimed in claim 15 , wherein the nominal pressing cycle comprises: a phase of gradual increase in temperature to a high temperature θ 1 of 230° C. at a gradient of 2.5° C./min; a phase of maintaining the temperature θ 1 for 10 minutes; and a phase of temperature decrease to the temperature θ 2 of 140° C. at a gradient of 2.5° C./min. 17. The method as claimed in claim 10 , wherein the step of welding comprises the steps of: setting up and arranging the following elements in order on a plate of heat-insulating material to provide a stack: a first film of heat-resistant polyimide; the functionalized layer of elastomeric material; a first film of polyetherimide; a woven metal wire cloth pre-impregnated with polyetherimide; a second film of polyetherimide; the thermoplastic composite material; a second film of heat-resistant polyimide; a layer of heat-insulating material; and a glass cloth; producing a bladder under a vacuum with a third film of heat-resistant polyimide arranged to allow the woven metal wire cloth to stand out and ensuring a hermeticity of the bladder by a high-temperature mastic; placing the bladder under the vacuum, connecting an electric power supply unit to the woven metal wire cloth, and applying different values of current according to a predetermined cycle; and removing the third film of heat-resistant polyimide serving as a vacuum enclosure and dismounting the stack. 18. The method as claimed in claim 17 , further comprising the steps of applying a current of 15.6 amps to the woven metal wire cloth for 200 seconds, and then applying a current of 10 amps to the woven metal wire cloth for 100 seconds. 19. A method for producing a welded structural joint between a thermoplastic matrix