Thermoset/supramolecular hybrid composites and resins that can be hot-formed and recycled

The invention claimed is: 1. A hybrid resin material that has undergone transesterification, wherein the hybrid resin material comprises a three dimensional network featuring ester functions, hydroxyl functions, and associative groups, and wherein the hybrid resin is formed by combining and reacting: at least one thermosetting resin precursor with a hardener composition; wherein the at least one thermosetting resin precursor comprises hydroxyl functions, epoxy groups, or a combination of hydroxyl functions and epoxy groups; wherein the hardener composition comprises at least one transesterification catalyst, at least one hardener and at least one grafting compound; wherein the at least one hardener is selected from polycarboxylic acids and anhydrides thereof; and wherein the at least one grafting compound comprises at least one associative group and at least one grafting function capable grafting to the at least one thermosetting resin precursor, the at least one hardener, or a reaction product of the at least one thermosetting resin precursor and the at least one hardener. 2. The hybrid resin material as claimed in claim 1 , wherein the at least one transesterification catalyst is present in a total molar amount ranging from 1% to 25% of the total molar amount of hydroxyl functions and epoxy groups that are contained in the thermosetting resin precursor. 3. The hybrid resin material as claimed in claim 1 , wherein the at least one thermosetting resin precursor is an epoxy resin precursor. 4. The hybrid resin material as claimed in claim 1 , wherein the at least one grafting compound is chosen from those corresponding to the following general formula: A-L-R in which A represents an associative group, L represents a linker arm, R represents a function R 1 that is reactive with carboxylic acids, or a function R 2 that is reactive with epoxy functions or with alcohol functions. 5. The hybrid resin material as claimed in claim 4 , wherein the amount of at least one hardener is chosen such that the resin is in the form of a network, and: N O denoting the number of moles of hydroxyl functions in the at least one thermosetting resin precursor, N X denoting the number of moles of epoxy groups in the at least one thermosetting resin precursor, N 1 denoting the number of moles of R 1 groups in the at least one grafting compound, N 2 denoting the number of moles of R 2 groups in the at least one grafting compound, N A denoting the number of moles of carboxylic acid functions of the at least one hardener which are capable of forming a bond with a hydroxyl function or with an epoxy group of the at least one thermosetting resin precursor: N A −N 1 <N O +2N X −N 2 . 6. The hybrid resin material as claimed in claim 4 , wherein R represents NH 2 or COOH, L is chosen from aryl, aralkyl, alkanepoly-yl, and alkenepoly-yl functions, optionally interrupted with one or more groups chosen from an ether, amine, thioether, amide, ester, urea, urethane, anhydride and carbonyl bridge, L comprising from 1 to 50 carbon atoms and up to 6 heteroatoms, A is chosen from groups capable of associating with one another via 1 to 6 hydrogen bonds. 7. The hybrid resin material as claimed in claim 4 , wherein the compound A-L-R is chosen from the following molecules: and n represents an integer 1<n<23 and 8. The hybrid resin material as claimed in claim 4 , wherein N 1 denoting the number of moles of R 1 groups in the at least one grafting compound, N 2 denoting the number of moles of R 2 groups in the at least one grafting compound, N B representing the number of hydroxyl functions and epoxy groups of the at least one thermosetting resin precursor that are capable of reacting with R 2 , N A denoting the number of moles of carboxylic acid functions of the at least one hardener that are capable of forming a bond with a hydroxyl function or with an epoxy group of the at least one thermosetting resin precursor: N 1 and N 2 confirm the following two proposals: N 1 >0.01 N A or N 2 >0.01 N B N 1 <0.9 N A and N 2 <0.9 N B . 9. The hybrid resin material as claimed in claim 1 , wherein the at least one grafting compound is obtained by reacting at least one compound of polyfunctional carboxylic acid type with an associative molecule comprising a function that is reactive with carboxylic acids. 10. The hybrid resin material as claimed in claim 1 , wherein the at least one hardener is chosen from: fatty acid dimers and trimers, and polyoxoalkylenes comprising carboxylic acids at the ends. 11. The hybrid resin material as claimed in claim 1 , wherein the at least one transesterification catalyst is chosen from: metal salts of zinc, of tin, of magnesium, of cobalt, of calcium, of titanium and of zirconium. 12. The hybrid resin material as claimed in claim 1 , wherein the at least one transesterification catalyst is dissolved in a mixture of the at least one hardener and the at least one grafting compound. 13. A composite material comprising at least one hybrid resin material as claimed in claim 1 , and at least one material chosen from: one or more polymers, pigments, dyes, fillers, plasticizers, fibers, flame retardants, antioxidants, lubricants, wood, glass and metals. 14. A material or composite for motor vehicles, for aeronautical construction, electronics, sport, construction, printing, packaging and cosmetics, wherein the material or composite comprises the hybrid resin material of claim 1 . 15. A process for manufacturing an article based on the hybrid resin material as claimed in claim 1 , this process comprising: a) combining and reacting the at least one thermosetting resin precursor with the hardener composition, b) forming the material resulting from step a), c) applying energy to cure the material, d) cooling the cured material. 16. An article obtained by the process as claimed in claim 15 . 17. The article as claimed in claim 16 , resulting from the curing of the material resulting from step a), which is characterized by a viscosity of between 10 5 and 5×10 10 Pa·s at temperatures of between 150° C. and 300° C. 18. A process for transforming at least one article as claimed in claim 16 , this process comprising: applying a mechanical stress to the article and raising the temperature of the article to a temperature (T) above ambient temperature. 19. The process as claimed in claim 18 , which is a process for assembling, bonding or repairing said at least one article. 20. An article obtained by a process as claimed in claim 18 . 21. A process for recycling an article as claimed in claim 16 , this process comprising: a) reducing the article to particles by application of mechanical grinding, b) using the particles of step a) in a transformation process comprising applying a mechanical stress to the article and raising the temperature of the article to a temperature (T) above ambient temperature. 22. A process for recycling an article as claimed in claim 16 , this process comprising: a) using the article as starting material, b) applying a mechanical stress, and optionally simultaneously raising the temperature, so as to transform this article into a collection of elemental units, c) cooling the collection of elemental u