Reconfigurable shape memory polymer support tooling
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
B29C-033/38
B29C-033/48
B29C-033/04
출원번호
US-0288393
(2011-11-03)
등록번호
US-8945455
(2015-02-03)
발명자
/ 주소
Everhart, Joel James
Margraf, Thomas Wood
Havens, David E.
출원인 / 주소
Spirit AeroSystems, Inc.
대리인 / 주소
Hovey Williams LLP
인용정보
피인용 횟수 :
0인용 특허 :
88
초록▼
A support apparatus and method for providing structural support to a shape memory polymer (SMP) apparatus during fabrication of composite parts. The support apparatus may comprise an adjustable, rigid structural member and a plurality of SMP support components transitionable between a rigid and mall
A support apparatus and method for providing structural support to a shape memory polymer (SMP) apparatus during fabrication of composite parts. The support apparatus may comprise an adjustable, rigid structural member and a plurality of SMP support components transitionable between a rigid and malleable state and fixed to an outer surface of the rigid structural member. The rigid structural member may extend in at least one cross-sectional dimension toward the SMP apparatus, pressing the SMP support components, in their malleable state, against the SMP apparatus. The SMP support components may thereby conform to a first surface of the SMP apparatus, then return to their rigid state while pressed against the SMP apparatus, thus providing a rigid load path between the SMP apparatus and the rigid structural member. Then composite material may be applied to a second surface of the SMP apparatus, opposite of the first surface.
대표청구항▼
1. A support apparatus configured for providing structural support to any apparatus, mold, tooling, or shape memory polymer (SMP) apparatus for forming composite parts, the support apparatus comprising: an adjustable, rigid structural member having adjustable cross-sectional dimensions, wherein the
1. A support apparatus configured for providing structural support to any apparatus, mold, tooling, or shape memory polymer (SMP) apparatus for forming composite parts, the support apparatus comprising: an adjustable, rigid structural member having adjustable cross-sectional dimensions, wherein the rigid structural member comprises an inner mandrel having a substantially “C”-shaped or split-ring cross-section configured to flex when edges thereof are squeezed together or forced apart from each other; anda plurality of shape memory polymer (SMP) support components comprising shape memory polymer, each spaced apart from each other and fixed to an outer surface or end portion of the adjustable rigid structural member, wherein the SMP support components are configured to transition between a rigid state and a malleable state and to be independently deformable in the malleable state when pressure is applied thereto. 2. The support apparatus of claim 1, wherein the SMP support components are configured to be in the rigid state at a temperature below Tg and to become malleable at a temperature above Tg. 3. The support apparatus of claim 1, wherein the rigid structural member further comprises a spacer piece configured to be inserted between the two edges, length-wise, of the inner mandrel and to actuate the inner mandrel to flex outward, thereby increasing the cross-sectional area within the inner mandrel. 4. The support apparatus of claim 1, wherein the SMP support components are solid pieces of SMP material. 5. The support apparatus of claim 1, wherein the SMP support components comprise a hollow outer shell or skin of SMP material filled with particulate. 6. The support apparatus of claim 5, wherein the particulate is solid, hollow, or filled with a solid, gas, or secondary particulate. 7. A method of forming a composite part on an SMP apparatus composed of shape memory polymer (SMP) and having a first surface and a second surface opposite the first surface, the method comprising: placing a support apparatus proximate to at least one surface of the SMP apparatus, wherein the support apparatus comprises: an adjustable, rigid structural member having mechanically adjustable cross-sectional dimensions, wherein the rigid structural member is adjustable between a first configuration and a second configuration, wherein at least one of the cross-sectional dimensions of the rigid structural member is greater in the second configuration than in the first configuration, anda plurality of shape memory polymer (SMP) support components comprising shape memory polymer, each spaced apart from each other and fixed to an outer surface or end portion of the adjustable rigid structural member, wherein the SMP support components are configured to transition between a rigid state and a malleable state and to be independently deformable in the malleable state when mechanical force is applied thereto, wherein the SMP support components are configured to be in the rigid state at a temperature below Tg and to begin changing to the malleable state at a temperature above Tg;triggering the SMP support components from the rigid state into the malleable state;actuating the rigid structural member to increase in at least one cross-sectional dimension, such that the SMP support components are pressed against at least one surface of the SMP apparatus;triggering the SMP support components from the malleable state to the rigid state while the SMP support components are pressed against the at least one surface of the SMP apparatus, thus providing a rigid load path between the SMP apparatus and the rigid structural member; andapplying uncured composite material to a surface of the SMP apparatus opposite of the at least one surface of the SMP apparatus in contact with the SMP support components. 8. The method of claim 7, wherein the SMP support components are in the rigid state at temperatures below Tg and are actuated into the malleable state when heated above Tg. 9. The method of claim 7, further comprising extending or retracting rods of the rigid structural member to place the SMP support components in contact with the SMP apparatus. 10. The method of claim 7, wherein the rigid structural member comprises an inner mandrel having a substantially “C”-shaped or split-ring cross-section configured to flex when edges thereof are squeezed together or forced apart from each other. 11. The method of claim 10, further comprising inserting a spacer piece between the two edges, length-wise, of the inner mandrel, such that the inner mandrel flexes outward, thereby increasing the cross-sectional area within the inner mandrel. 12. The method of claim 7, further comprising: curing the composite material to form the composite part;actuating the rigid structural member to decrease in at least one cross-sectional dimension; andremoving the support apparatus and the SMP apparatus from the composite part. 13. The method of claim 7, wherein the SMP support components are solid pieces of SMP material. 14. The method of claim 7, wherein the SMP support components comprise a hollow outer shell or skin of SMP material filled with particulate. 15. The method of claim 14, wherein the particulate is solid, hollow, or filled with a solid, gas, or secondary particulate. 16. A support apparatus configured for providing structural support for forming composite parts, the support apparatus comprising: an adjustable, rigid structural member having mechanically adjustable cross-sectional dimensions, wherein the rigid structural member is adjustable between a first configuration and a second configuration, wherein at least one of the cross-sectional dimensions of the rigid structural member is greater in the second configuration than in the first configuration;a plurality of shape memory polymer (SMP) support components comprising shape memory polymer, each spaced apart from each other and fixed to an outer surface or end portion of the adjustable rigid structural member, wherein the SMP support components are configured to transition between a rigid state and a malleable state and to be independently deformable in the malleable state when mechanical force is applied thereto, wherein the SMP support components are configured to be in the rigid state at a temperature below Tg and to begin changing to the malleable state at a temperature above Tg; andan SMP apparatus made of SMP material having a first surface and a second surface opposite the first surface, wherein the second surface is configured to have uncured composite material applied thereto, wherein at least some of the plurality of SMP support components are pressed against the first surface of the SMP apparatus when the rigid structural member is in the second configuration, such that the SMP support components provide a structural load path from the SMP apparatus to the rigid structural member. 17. The support apparatus of claim 16, wherein the rigid structural member comprises a centerframe piece and mechanically extendible spokes attached to the center frame piece, wherein the SMP support components are attached to ends of the spokes and the spokes are configured to actuate between a first length in the first configuration and a second length in the second configuration, wherein the first length is shorter than the second length. 18. The support apparatus of claim 16, wherein the rigid structural member comprises an inner mandrel having a substantially “C”-shaped or split-ring cross-section configured to flex when edges thereof are squeezed together or forced apart from each other, wherein the rigid structural member further comprises a spacer piece configured to be inserted between the two edges, length-wise, of the inner mandrel and to actuate the inner mandrel to flex outward, thereby increasing the cross-sectional area within the inner mandrel and placing the rigid structural member in the second configuration. 19. The support apparatus of claim 16, wherein the SMP support components are solid pieces of SMP material. 20. The support apparatus of claim 16, wherein the SMP support components comprise a hollow outer shell or skin of SMP material filled with particulate. 21. A support apparatus configured for providing structural support to any apparatus, mold, tooling, or shape memory polymer (SMP) apparatus for forming composite parts, the support apparatus comprising: an adjustable, rigid structural member having adjustable cross-sectional dimensions, wherein the rigid structural member comprises a center frame piece and extendible spokes attached to the center frame piece, wherein the SMP support components are attached to ends of the spokes and the spokes are configured to actuate between a plurality of lengths; anda plurality of shape memory polymer (SMP) support components comprising shape memory polymer, each spaced apart from each other and fixed to an outer surface or end portion of the adjustable rigid structural member, wherein the SMP support components are configured to transition between a rigid state and a malleable state and to be independently deformable in the malleable state when pressure is applied thereto. 22. The support apparatus of claim 21, wherein the SMP support components are configured to be in the rigid state at a temperature below Tg and to become malleable at a temperature above Tg. 23. The support apparatus of claim 21, wherein the SMP support components are solid pieces of SMP material. 24. The support apparatus of claim 21, wherein the SMP support components comprise a hollow outer shell or skin of SMP material filled with particulate. 25. The support apparatus of claim 24, wherein the particulate is solid, hollow, or filled with a solid, gas, or secondary particulate.
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