IPC분류정보
국가/구분 |
United States(US) Patent
등록
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국제특허분류(IPC7판) |
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출원번호 |
US-0358126
(2003-02-04)
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발명자
/ 주소 |
- Cadogan, David P.
- Scarborough, Stephen E.
- Lin, John K. H.
- Sapna, III, George H.
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출원인 / 주소 |
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대리인 / 주소 |
Stevens, Davis, Millier &
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인용정보 |
피인용 횟수 :
3 인용 특허 :
11 |
초록
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A boom structure deployed by inflating the structure to a desired shape and rigidizing the structure via an external influence. The structure frame has a series of frame members which are made of a fibrous material and a resin material. This frame is encased in between a pair of membrane layers, an
A boom structure deployed by inflating the structure to a desired shape and rigidizing the structure via an external influence. The structure frame has a series of frame members which are made of a fibrous material and a resin material. This frame is encased in between a pair of membrane layers, an inner membrane inflatable to move the frame into its desired shape and an outer membrane that allows for folding the structure. Following inflation of the inner layer, an external influence acts on the resin material to solidify it, and render the structure rigid. The external influence may also act on the resin material to soften it when it is already rigid, to allow for collapsing and folding of the structure.
대표청구항
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1. An inflatable and rigidizable structure comprising:a foldable frame having a predetermined shape comprising a plurality of longitudinal frame members and at least one helical frame members; each of said frame members extending a length of the frame; each of said frame members made of a matrix tha
1. An inflatable and rigidizable structure comprising:a foldable frame having a predetermined shape comprising a plurality of longitudinal frame members and at least one helical frame members; each of said frame members extending a length of the frame; each of said frame members made of a matrix that is activated to harden or soften upon application of an external influence, wherein the longitudinal frame members and said at least one helical frame members are connected together at crossover points in a grid pattern via nodal connections; and an inflatable inner membrane located inside the frame that expands to move the foldable frame into the predetermined shape, wherein upon application of the external influence following an inflation of the inflatable membrane, the structure is rigidized. 2. The inflatable and rigidizable structure as described in claim 1 further comprising an outer membrane covering the foldable frame.3. The inflatable and rigidizable structure as described in claim 2, wherein the inner and outer membranes are made of a thin polymeric film.4. The inflatable and rigidizable structure as described in claim 3, wherein the thin polymeric film is polyimide.5. The inflatable and rigidizable structure as described in claim 3, wherein the inner membrane is 0.5-2.0 mil thick and the outer membrane is 0.3-1.0 mil thick.6. The inflatable and rigidizable structure as described in claim 2, wherein the foldable frame is incased between the inner and outer membranes.7. The inflatable and rigidizable structure as described in claim 1, wherein the structure folds into a volume smaller than a volume of the structure when the structure is deployed via inflation of the inner membrane and application of the external influence.8. The inflatable and rigidizable structure as described in claim 1, wherein the frame members comprise a fiber material and a resin material.9. The inflatable and rigidizable structure as described in claim 8 wherein the resin material is a thermoplastic material made of a combination of one or more of the materials selected from a group consisting of nylon, polyetheretherketone, polyethylene, polypropylene polyurethane and epoxy.10. The inflatable and rigidizable structure as described in claim 8 wherein the fiber material is made of one or more materials selected from the group of graphite, carbon fiber, composite plastic, liquid crystal polymer and glass.11. The inflatable and rigidizable structure as described in claim 8 wherein the resin material is one of thermosetting resin, shape memory resin, thermoplastic resin, UV curable resin and solvent-based resin.12. The inflatable and rigidizable structure as described in claim 11 wherein the external influence is heat energy, exposure to chemical constituents of a gas or inflation gas or exposure to particular wavelengths of electromagnetic radiation.13. The inflatable and rigidizable structure as described in claim 1, wherein the foldable frame has an equal number of helical and longitudinal members.14. The inflatable and rigidizable structure as described in claim 13, wherein the helical and longitudinal members are arranged to form a polygonal grid pattern.15. The inflatable and rigidizable structure as described in claim 14, wherein the helical and longitudinal members are arranged to form an equilateral triangle grid pattern.16. The inflatable and rigidizable structure as described in claim 1, wherein each nodal connector is a fiber-reinforced thermosetting adhesive, a hot melt adhesive or a mechanical attachment.17. The inflatable and rigidizable structure as described in claim 1, wherein the structure is incorporated into a larger assembly.18. The inflatable and rigidizable structure as described in claim 2, wherein the structure has mounted therein one or more components selected from the group consisting of conductive fibers, circuit elements, integrated circuits, light emitting diodes, solar cells, antennas, embedded controllers and artificial muscle fibers.19. The inflatable and rigidizable structure as described in claim 2, wherein the structure has reinforcement elements at ends thereof connecting to the frame members and the inner and outer membranes.20. A method for deploying and storing a structure having a foldable frame with a predetermined shape comprising a plurality of longitudinal frame members and at least one helical frame member extending a length of the frame each made of a matrix that is activated to harden or soften upon application of an external influence, wherein the longitudinal and said at least one helical member are connected together at crossover points via nodal connectors, an inflatable membrane located inside the frame that expands to move the foldable frame into the predetermined shape and an outer membrane encasing the foldable frame in conjunction with the inner membrane, said method comprising:(a) placing a portion of the structure in a desired location; (b) inflating the inflatable membrane with a gas until the frame is moved into the predetermined shape; and (c) applying the external influence to the structure to rigidify the frame members. 21. The method as described in claim 20 further comprising the steps of:(e) reapplying the external influence to soften the frame members; and (f) collapsing the structure into a flat shape for storage. 22. The method as described in claim 21 further including the step of:(g) folding the flat shaped structure about a small diameter causing the structure to overlap itself. 23. The method as described in claim 22 wherein the step of folding includes alternatively folding the flat shaped structure about the small diameter at least two times.24. The method as described in claim 23, wherein flat shaped structure has a generally Z-shaped folding pattern.25. The method as described in claim 21 wherein the steps of applying and reapplying the external influence includes a device outside the structure heating the structure, propagating particular wavelengths of electromagnetic radiation towards the structure or exposing the structure to chemical constituents of a gas.26. An inflatable and rigidizable structure comprising:a foldable frame having a predetermined shape comprising a plurality of frame members extending a length of the frame forming a grid pattern, each made of a matrix that is activated to harden or soften upon application of an external influence wherein the frame members are connected together at intersections in the grid pattern via nodal connectors; an inner inflatable membrane located inside the frame that expands to move the foldable frame into the predetermined shape, and an outer membrane encasing the foldable frame in conjunction with the inner membrane wherein upon application of the external influence following an inflation of the inflatable membrane, the structure is rigidized and upon application of the external influence while the structure is rigidized, the structure is softened allowing folding of the structure. 27. The inflatable and rigidizable structure as described in claim 26 wherein the external influence is heat energy, exposure to chemical constituents of a gas or inflation gas or exposure to particular wavelengths of electromagnetic radiation.28. The inflatable and rigidizable structure as described in claim 27, wherein the frame members comprise a fiber material and a resin material.29. The inflatable and rigidizable structure as described in claim 28 wherein the resin material is a thermoplastic material made of a combination of one or more of the materials selected from a group consisting of nylon, polyetheretherketone, polyethylene, polypropylene, polyurethane and epoxy.30. The inflatable and rigidizable structure as described in claim 28 wherein the fiber material is made of one or more materials selected from the group of graphite, carbon fiber, composite plastic, liquid crystal polymer and glass.31. The inflatable and rigidizable structure as described in claim 26 wherein the grid pattern forms equilateral triangles.32. The inflatable and rigidizable structure as described in claim 26, wherein the structure has reinforcement elements at ends thereof connecting to the frame members and the inner and outer membranes.33. The inflatable and rigidizable structure as described in claim 26, wherein each nodal connector is a fiber-reinforced thermosetting adhesive, a hot melt adhesive or a mechanical attachment.34. The inflatable and rigidizable structure as described in claim 26, wherein the inner and outer membranes are made of a polymeric resin.35. The inflatable and rigidizable structure as described in claim 34, wherein the polymeric resin is polyimide.
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