초록 ▼

The invention relates to a method of assembling pre-impregnated plies by local isolated polymerization of the assembly region (30) under the action of a radiation to which the resin of the prepreg is sensitive. The assembly method makes it possible in particular to produce very large sized gossamer

The invention relates to a method of assembling pre-impregnated plies by local isolated polymerization of the assembly region (30) under the action of a radiation to which the resin of the prepreg is sensitive. The assembly method makes it possible in particular to produce very large sized gossamer structures (7) in the form of a concertina-folded tube which is deployed by injecting pressurized gas once in space then stiffened by polymerization under the effect of the same radiation. The pylon concerned (7) thus comprises two structural elements (10, 20) secured end to end while at the same time maintaining its flexibility and firmness qualities.

대표청구항 ▼

1. A method of assembling a first structural element comprising a first prepreg ply extending in a first direction and a second structural element comprising a second prepreg ply extending in the first direction, the method comprising: superimposing the first prepreg ply of the first structural elem

1. A method of assembling a first structural element comprising a first prepreg ply extending in a first direction and a second structural element comprising a second prepreg ply extending in the first direction, the method comprising: superimposing the first prepreg ply of the first structural element and the second prepreg ply of the second structural element to form a junction zone, wherein the junction zone comprises: a first assembly strip having a width W1 in the first direction and a length L1 in a second direction, which is perpendicular to the first direction;a second assembly strip having a width W2 in the first direction and a length L2 in the second direction; andan intermediate strip, which separates the first assembly strip and the second assembly strip; andirradiating discrete points of the first assembly strip and the second assembly strip with visible light, UV light, or electrons, thereby locally cross polymerizing and bonding the first and second prepregs at the discrete points in the first and second assembly strips,wherein the first and second prepregs are at least partially polymerizable under a predetermined radiation and are not polymerized and remain juxtaposed in the intermediate strip,wherein the discrete points in the first assembly strip are arranged such that: projections of each of the discrete points in the first assembly strip, in the first direction, onto an imaginary line extending along the length L1 forms a continuous line C1 along the entire length of the imaginary line extending along the length L1, wherein at each location along the continuous line C1 a single discrete point projects onto the continuous line C1 from the first assembly strip; andprojections of each of the discrete points in the first assembly strip, in the second direction, onto an imaginary line extending along the width W1 forms a continuous line C1′ along the entire width of the imaginary line extending along the width W1,wherein the discrete points in the second assembly strip are arranged such that: projections of each of the discrete points in the second assembly strip, in the first direction, onto an imaginary line extending along the length L2 forms a continuous line C2 along the entire length of the imaginary line extending along the length L2, wherein at each location along the continuous line C2 a single discrete point projects onto the continuous line C2 from the second assembly strip; andprojections of each of the discrete points in the second assembly strip, in the second direction, onto an imaginary line extending along the width W2 forms a continuous line C2′ along the entire width of the imaginary line extending along the width W1. 2. The method of claim 1, further comprising: placing a mask comprising an opaque part and a part enabling the passage of the radiation on the junction zone prior to the irradiation; and thenirradiating through the mask, thereby cross polymerizing the discrete points,wherein the discrete points have a geometry of the mask. 3. The method of claim 1, wherein the irradiating is carried out with light, and the first and second prepregs comprise a fibrous material impregnated with a composition comprising: an epoxy or epoxy-acrylate resin; anda photo-initiator,wherein the photo-initiator is an iron-arene complex salt of formula (I): wherein: A is an arene group; andX is a non nucleophilic anion. 4. The method of claim 1, wherein the first structural element further comprises a first film on a face of the first prepreg ply and the second structural element further comprises a second film on a face of the second prepreg ply, wherein the first and second film are each transparent to the radiation. 5. The method of claim 1, wherein the first and second structural elements are tubular and the method further comprises: positioning the first element and the second element end to end on a mandrel. 6. The method of claim 1, further comprising, prior to assembly: folding an end portion of the first element. 7. The method of claim 1, further comprising, after the assembly: folding a non folded part of the first element, the junction zone, and the second element. 8. An inflatable space structure, obtained by a method of assembling a first structural element comprising a first prepreg ply extending in a first direction and a second structural element comprising a second prepreg ply extending in the first direction, the method comprising: superimposing the first prepreg ply of the first structural element and the second prepreg ply of the second structural element to form a junction zone, wherein the junction zone is divided into: a first assembly strip having a width W1 in the first direction and a length L1 in a second direction, which is perpendicular to the first direction;a second assembly strip having a width W2 in the first direction and a length L2 in the second direction; andan intermediate strip, which separates the first assembly strip and the second assembly strip,irradiating discrete points of the first assembly strip and second assembly strip with visible light, UV light, or electrons, thereby locally cross polymerizing and bonding the first and second prepegs at the discrete points in the first and second assembly strips,wherein the first and second prepregs are at least partially polymerizable under a predetermined radiation and are not polymerized and remain juxtaposed in the intermediate strip,wherein the discrete points in the first assembly strip are arranged such that: projections of each of the discrete points in the first assembly strip, in the first direction, onto an imaginary line extending along the length L1 forms a continuous line C1 along the entire length of the imaginary line extending along the length L1, wherein at each location along the continuous line C1 a single discrete point projects onto the continuous line C1 from the first assembly strip; andprojections of each of the discrete points in the first assembly strip, in the second direction, onto an imaginary line extending along the width W1 forms a continuous line C1′ along the entire width of the imaginary line extending along the width W1,wherein the discrete points in the second assembly strip are arranged such that: projections of each of the discrete points in the second assembly strip, in the first direction, onto an imaginary line extending along the length L2 forms a continuous line C2 along the entire length of the imaginary line extending along the length L2, wherein at each location along the continuous line C2 a single discrete point projects onto the continuous line C2 from the second assembly strip; andprojections of each of the discrete points in the second assembly strip, in the second direction, onto an imaginary line extending along the width W2 forms a continuous line C2′ along the entire width of the imaginary line extending along the width W1. 9. The inflatable space structure of claim 8, wherein the first and second prepregs comprise a fibrous material impregnated with a composition comprising: an epoxy or epoxy-acrylate resin; anda photo-initiator,wherein the photo-initiator is an iron-arene complex salt of formula (I): wherein: A is an arene group; andX is a non nucleophilic anion. 10. A structure, comprising: a first element comprising a first prepreg ply extending in a first direction; anda second element comprising a second prepreg ply extending in the first direction,wherein the first and second prepreg ply are sensitive to a polymerization radiation,wherein the first prepreg ply and the second prepreg ply are superimposed to form a junction zone, wherein the junction zone comprises: a first assembly strip having a width W1 in the first direction and a length L1 in a second direction, which is perpendicular to the first direction;a second assembly strip having a width W2 in the first direction and a length L2 in the second direction; andan intermediate zone, which separates the first assembly strip and the second assembly strip,wherein the first and second prepregs are bonded together in the first and second assembly strips by irradiating discrete points of the first and second assembly strips with visible light, UV light, or electrons, thereby cross polymerizing and bonding the first and second prepegs at the discrete points in the first and second assembly strips, and wherein the first and second prepegs are juxtaposed without cross-linking polymerization in the intermediate zone,wherein the discrete points in the first assembly strip are arranged such that: projections of each of the discrete points in the first assembly strip, in the first direction, onto an imaginary line extending along the length L1 forms a continuous line C1 along the entire length of the imaginary line extending along the length L1, wherein at each location along the continuous line C1 a single discrete point projects onto the continuous line C1 from the first assembly strip; andprojections of each of the discrete points in the first assembly strip, in the second direction, onto an imaginary line extending along the width W1 forms a continuous line C1′ along the entire width of the imaginary line extending along the width W1,wherein the discrete points in the second assembly strip are arranged such that: projections of each of the discrete points in the second assembly strip, in the first direction, onto an imaginary line extending along the length L2 forms a continuous line C2 along the entire length of the imaginary line extending along the length L2, wherein at each location along the continuous line C2 a single discrete point projects onto the continuous line C2 from the second assembly strip; andprojections of each of the discrete points in the second assembly strip, in the second direction, onto an imaginary line extending along the width W2 forms a continuous line C2′ along the entire width of the imaginary line extending along the width W1. 11. The structure of claim 10, wherein the first and second elements are tubular and the junction zone extends over the circumference of a tube. 12. The structure of claim 10, having at least a part that is concertina folded. 13. The structure of claim 10, comprising a fold in the junction zone. 14. An inflatable space manipulation pylon, comprising the structure of claim 10. 15. The structure of claim 10, wherein the first and second prepregs comprise a fibrous material impregnated with a composition comprising: an epoxy or epoxy-acrylate resin; anda photo-initiator,wherein the photo-initiator is an iron-arene complex salt of formula (I): wherein: A is an arene group; andX is a non nucleophilic anion.