Claims
- 1. A structural assembly comprising:
a rigid hoop structure having a plurality of rigid appendages extending outwardly therefrom and forming struts that are arranged to maintain a prescribed structural periphery depth and radial distance from a centerline axis defined by said structural assembly, wherein at least one strut is formed as a telescoping tube member; a plurality of pivot elements distributed within said hoop structure, and at interfaces of said hoop structure and said rigid appendages, and being configured to collapse and deploy said hoop structure; and tensioned, flexible, generally inextensible cable members connected to said hoop structure and said rigid appendages.
- 2. A structural assembly according to claim 1, wherein said rigid hoop structure is formed as a single member hoop structure.
- 3. A structural assembly according to claim 1, wherein said rigid appendages extending outwardly to form said struts are configured in a triangular configuration.
- 4. A structural assembly according to claim 1, wherein said struts further comprise upwardly and downwardly extending struts.
- 5. A structural assembly according to claim 4, wherein each of said upwardly extending struts comprise a pair of strut members.
- 6. A structural assembly according to claim 4, where each of said upwardly extending struts comprise a single strut member.
- 7. A structural assembly according to claim 4, wherein adjacent upwardly extending struts are joined at distal ends thereof.
- 8. A structural assembly according to claim 4, wherein said upwardly extending struts are spaced apart at distal ends thereof.
- 9. A structural assembly according to claim 1, wherein said rigid appendages further comprise folding hoop members.
- 10. A structural assembly according to claim 9, wherein said folding hoop members comprise at least one telescoping tube member.
- 11. A structural assembly according to claim 1, wherein said hoop structure includes a plurality of rigid elements joined end-to-end to form a polygon, such that each end-to-end junction forms a corner of said polygon.
- 12. A structural assembly according to claim 1, wherein said tensioned, flexible, generally inextensible elements include cords that are connected to said struts to maintain a prescribed length and force between distal ends of said struts and between end-to-end junctions.
- 13. A structural assembly according to claim 1, wherein said pivot elements include pivot elements at corners of said hoop structure, configured to fold said rigid elements from a deployed polygonal shape to a stowed orientation that is generally parallel to said centerline axis.
- 14. A structural assembly according to claim 13, wherein said pivot elements at said corners are configured to fold said appendages to an orientation that is generally parallel to said centerline axis.
- 15. A structural assembly according to claim 14, further including pivot elements at midpoints of said rigid elements, that are configured to fold said rigid elements into an orientation that is generally parallel to said centerline axis.
- 16. A structural assembly according to claim 15, further including pivot elements at midpoints of selected appendages, and configured to fold said selected appendages into an orientation that is generally parallel to said centerline axis.
- 17. A structural assembly according to claim 1, further including a network of tensioned cords having pluralities of generally horizontal top and bottom components connected with generally vertical cords therebetween forming a planar truss, and being supported by said appendages.
- 18. A structural assembly according to claim 17, further including an energy directing surface supported by said network of tensioned cords.
- 19. A structural assembly according to claim 1, wherein a respective pivot element comprises a geared power transmission and hinge assembly that is configured to transmit power through a moving hinge to effect opening or closing thereof, and to maintain synchronous motion from one side of said hinge to another throughout all stages of motion of said hinge, and including torsion shafts within said rigid elements that transmit power among plural geared power transmission hinge assemblies.
- 20. A structural assembly according to claim 19, wherein a respective geared power transmission and hinge assembly includes a pair of gears rotatable about respective pivot axes, and coupled with a torsion shaft.
- 21. A structural assembly according to claim 19, wherein a respective geared power transmission and hinge assembly includes a rigid frame that supports and maintains a pair of hinges in a constant geometric relationship to each other through all stages of hinge motion.
- 22. A structural assembly according to claim 21, wherein a respective geared power transmission and hinge assembly further includes an idler gear situated between said gears of said pair to effect a rotation reversal in a deployment transmission path.
- 23. A structural assembly according to claim 1, wherein said rigid hoop structure comprises a multi-sided hoop structure, a respective side of which is configured as a four-bar linkage having upper and lower hoop members coupled at ends thereof to a platform linkage, a respective lower hoop member attaching to a lower part of said platform linkage, and a respective upper hoop member attaching to an upper part of said platform linkage, a respective platform linkage containing four pivots attached to two pairs of upper and lower hoop members.
- 24. A structural assembly comprising:
a rigid hoop structure having a plurality of rigid appendages extending outwardly therefrom and forming upwardly and downwardly extending struts that are arranged to maintain a prescribed structural periphery depth and radial distance from a centerline axis defined by said structural assembly, wherein each upwardly extending strut comprises a single strut member; a plurality of pivot elements distributed within said hoop structure, and at interfaces of said hoop structure and said rigid appendages, and being configured to collapse and deploy said hoop structure; and tensioned, flexible, generally inextensible cable members connected to said hoop structure and said rigid appendages.
- 25. A structural assembly according to claim 24, wherein said rigid hoop structure is formed as a single member hoop structure.
- 26. A structural assembly according to claim 24, wherein said rigid appendages further comprise folding hoop members.
- 27. A structural assembly according to claim 26, wherein said folding hoop members comprise at least one telescoping tube member.
- 28. A structural assembly according to claim 24, wherein said hoop structure includes a plurality of rigid elements joined end-to-end to form a polygon, such that each end-to-end junction forms a corner of said polygon.
- 29. A structural assembly according to claim 24, wherein said tensioned, flexible, generally inextensible elements include cords that are connected to said struts to maintain a prescribed length and force between distal ends of said struts and between end-to-end junctions.
- 30. A structural assembly according to claim 24, adjacent upwardly extending struts are joined at distal ends thereof.
- 31. A stowable and deployable support architecture to which an energy directing surface is attachable, comprising a multi-sided foldable hoop structure having hoop members, a plurality of foldable joints, and generally radial struts connected to hoop members and that extend from and are foldable about corner joints of said multi-sided hoop structure, wherein said struts comprise at least one telescoping tube member and at least one drive mechanism coupled to foldable joints of said multi-sided hoop structure, and being operative to unfold and deploy said multi-sided foldable hoop structure and said plurality of generally radial telescoping struts, and thereby said energy directing surface from a folded, stowed configuration to an unfolded, deployed configuration.
- 32. A stowable and deployable support architecture according to claim 31, wherein distal ends of respective pairs of adjacent radial struts that extend from corner joints of said multi-sided foldable hoop support structure are hinged together, and wherein mid-points of alternate segmented radial telescoping struts are hinged together by folding mid-strut hinge joints, so as to allow hinged together radial telescoping strut pairs to be folded about said corner hinge joints and stowed parallel to a respective hoop member of a side of said multi-sided foldable hoop structure, said radial struts being connected to said corner joints by multi-axis, synchronously driven hinges.
- 33. A stowable and deployable support architecture according to claim 32, further including an upper tensioning ring of tensioned upper cords that join together distal ends of upper radial struts, and a lower tensioning ring of tensioned lower cords that joint together distal ends of lower radial struts, and tension-only cord elements interconnecting distal ends of upper radial struts with distal ends of lower radial struts, so as to stabilize distal ends of said radial struts and impart stiffness to said support architecture in its deployed state.
- 34. A stowable and deployable support architecture according to claim 31, wherein a respective side of said multi-sided hoop structure is segmented into a pair of hoop members that are joined together by a driven hinge joint, upper and lower radial struts are coupled to corner joints of said multi-sided hoop structure by multi-axis driven hinge joints, and including a hinge drive mechanism that is configured synchronously drive each driven hinge joint.
- 35. A stowable and deployable support architecture according to claim 34, wherein distal ends of said radial struts are not hinged together, and further including an upper tensioning ring of tensioned upper cords that join together distal ends of upper radial struts, a lower tensioning ring of tensioned lower cords that joint together distal ends of lower radial struts, and tension-only cord elements interconnecting distal ends of upper radial struts with distal ends of lower radial struts, so as to stabilize distal ends of said radial struts and impart stiffness to said support architecture in its deployed state.
- 36. A method of manufacturing a stowable and deployable energy director comprising the steps of:
(a) providing a stowable and deployable support structure to which an energy-directing surface is attachable, said support structure having a multi-sided foldable hoop having a plurality of foldable joints, and generally radial struts that extend from and are foldable about corner joints of said multi-sided hoop, wherein at least one of said struts is formed as a telescoping tube member and at least one drive mechanism coupled to foldable joints of said multi-sided hoop, and being operative to unfold and deploy said multi-sided foldable hoop and said plurality of generally radial telescoping struts, and thereby said energy-directing surface from a folded, stowed configuration to an unfolded, deployed configuration; (b) providing a tensioning cord truss attachment framework for attaching an unfurlable energy-directing surface to said support structure provided in step (a); (c) incorporating said energy-directing surface with said tensioning cord truss attachment framework provided in step (b) to form a composite energy-directing surface assembly; and (d) attaching said composite surface assembly formed in step (c) to said stowable and deployable support structure provided in step (a).
- 37. A method according to claim 36, wherein step (d) comprises attaching said composite surface assembly to selected ones of said generally radial struts of said stowable and deployable support structure.
- 38. A method according to claim 36, wherein step (b) comprises forming individual cord truss elements of an upper cord truss assembly as generally planar shaped structures, and wherein step (c) comprises assembling said generally planar shaped structures into a two-dimensional network containing a tensioned, mesh fabric of which said energy-directing surface is formed, and adjusting said two-dimensional network to which said tensioned, mesh fabric of which said energy-directing surface has been assembled, so as to conform with a prescribed geometry specification.
- 39. A method according to claim 38, wherein step (d) further comprises adjusting attachment points between said composite antenna surface assembly and said stowable and deployable support structure.
RELATED APPLICATION
[0001] This application is a continuation-in-part application based upon prior filed copending application Ser. No. 09/330,959, filed Jun. 11, 1999.
Continuation in Parts (1)
|
Number |
Date |
Country |
Parent |
09330959 |
Jun 1999 |
US |
Child |
10004334 |
Oct 2001 |
US |