Helicopter blade mandrel with roller assembly
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
B29C-070/44
출원번호
US-0277095
(2011-10-19)
등록번호
US-8510946
(2013-08-20)
발명자
/ 주소
Callis, Richard A.
Johnston, Wayne
Gray, Nate
Bailey, David P.
출원인 / 주소
Hexcel Corporation
대리인 / 주소
Bielawski, W. Mark
인용정보
피인용 횟수 :
0인용 특허 :
11
초록▼
Methods and apparatus are provided for making a rotor blade spar from composite material wherein a multi-component mandrel is used to form the composite spar. The mandrel is made using a number of components that are assembled and held in place using a roller assembly. The roller assembly is removed
Methods and apparatus are provided for making a rotor blade spar from composite material wherein a multi-component mandrel is used to form the composite spar. The mandrel is made using a number of components that are assembled and held in place using a roller assembly. The roller assembly is removed after pre-cure lay up and compaction of the composite material. Once the roller assembly is removed, the remaining mandrel components can be separated from each other and easily removed from the spar. The mandrel components, including the roller assembly, can then be re-assembled and re-used to form additional composite spars.
대표청구항▼
1. A method for molding a spar for a helicopter rotor blade that extends parallel to the longitudinal axis of said rotor blade, said longitudinal axis extending from the root of said rotor blade to the tip of said rotor blade, said spar having interior surfaces that defines a spar cavity that also e
1. A method for molding a spar for a helicopter rotor blade that extends parallel to the longitudinal axis of said rotor blade, said longitudinal axis extending from the root of said rotor blade to the tip of said rotor blade, said spar having interior surfaces that defines a spar cavity that also extends longitudinally from the root of said rotor blade to the tip of said rotor blade, said spar interior surfaces including a leading edge surface that comprises an upper leading edge portion and a lower leading edge portion, a trailing edge surface that comprises an upper trailing edge portion and a lower trailing edge portion, an upper surface that extends between said leading edge upper portion and said trailing edge upper portion and a lower surface that extends between said leading edge lower portion and said trailing edge lower portion, said method comprising the steps of: A) providing a mandrel that comprises:a) a forward component that comprises an exterior surface that is shaped to provide said leading edge surface of said spar interior surfaces, said forward component comprising an upper rear edge comprising an outer surface that is shaped to provide said upper leading edge portion and a lower rear edge that is shaped to provide said lower leading edge portion;b) a rearward component that is shaped to provide said trailing edge surface of said spar interior surfaces, said rearward component comprising an upper forward edge that is shaped to provide said upper trailing edge portion and a lower forward edge that is shaped to provide said lower trailing edge portion;c) an upper component that is shaped to provide said upper surface of said spar interior surfaces, said upper component comprising a forward edge that is connected to said upper rear edge of said forward component and a rearward edge that is connected to said upper forward edge of said rearward component, said upper component extending from the root of said spar cavity to the tip of said spar cavity;d) a lower component that is shaped to provide said lower surface of said spar interior surfaces, said lower component comprising a forward edge that is connected to said lower rear edge of said forward component and a rearward edge that is connected to said lower forward edge of said rearward component, said lower component extending from the root of said spar cavity to the tip of said spar cavity; ande) a roller assembly located between said upper component and said lower component, said roller assembly comprising a plurality of upper rollers that contact said upper component and a plurality of lower rollers that contact said lower component; andB) applying uncured composite material to the exterior surface of said mandrel to form an uncured spar. 2. A method for molding a helicopter rotor blade according to claim 1 which comprises the additional steps of: removing said roller assembly from said mandrel;removing said forward component, rearward component, upper component and lower component from said spar cavity; andcuring said uncured spar to form said spar. 3. A method for molding a helicopter rotor blade according to claim 1 which comprises the additional steps of: curing said uncured spar to form said spar;removing said roller assembly from said mandrel; andremoving said forward component, rearward component, upper component and lower component from said spar cavity. 4. A method for molding a helicopter blade according to claim 1 wherein said roller assembly comprises a rib cage structure to which said upper rollers and said lower rollers are attached. 5. A method for molding a helicopter rotor blade according to claim 1 wherein each of said upper rollers rotates about a rotational axis and each of said lower rollers rotates about a rotational axis and wherein said rotational axis of said upper rollers and said rotational axis of said lower rollers is substantially perpendicular to said longitudinal axis of said rotor blade. 6. A method for molding a helicopter rotor blade according to claim 4 wherein said rib cage structure comprises a composite material. 7. A method for molding a helicopter rotor blade according to claim 1 wherein each of said upper rollers rotates about a rotational axis and each of said lower rollers rotates about a rotational axis, wherein said upper rollers comprise a plurality of forward upper rollers and a plurality of rearward upper rollers and wherein the rotational axis of said forward upper rollers is substantially co-planar with the rotational axis of said rearward upper rollers to provide a plurality of co-planar upper rollers. 8. A method for molding a helicopter rotor blade according to claim 7 wherein said lower rollers comprise a plurality of forward lower rollers and a plurality of rearward lower rollers and wherein the rotational axis of said forward lower rollers is substantially co-planar with the rotational axis of said rearward lower rollers to provide a plurality of co-planar lower rollers. 9. A method for molding a helicopter rotor blade according to claim 8 wherein the rotational axis of said co-planar upper rollers is substantially parallel to the rotational axis of said co-planar lower rollers. 10. A method for molding a helicopter rotor blade according to claim 9 wherein said co-planar upper rollers and said co-planar lower rollers are located at the root of said spar cavity. 11. A method for molding a helicopter rotor blade according to claim 1 wherein each of said upper rollers rotates about a rotational axis and each of said lower rollers rotates about a rotational axis, wherein said upper rollers comprise a plurality of forward upper rollers and a plurality of rearward upper rollers and wherein the rotational axis of said forward upper rollers is not co-planar with the rotational axis of said rearward upper rollers to provide a plurality of non-planar upper rollers. 12. A method for molding a helicopter rotor blade according to claim 11 wherein said lower rollers comprise a plurality of forward lower rollers and a plurality of rearward lower rollers and wherein the rotational axis of said forward lower rollers is not planar with the rotational axis of said rearward lower rollers to provide a plurality of non-planar lower rollers. 13. A method for molding a helicopter rotor blade according to claim 12 wherein the rotational axis of said rearward upper rollers and the rotational axis of said rearward lower rollers converge towards each other. 14. A method for molding a helicopter rotor blade according to claim 13 wherein said non-planar upper rollers and said non-planar lower rollers are located at the tip of said spar cavity. 15. A method for molding a helicopter rotor blade according to claim 6 wherein said composite material is a quasi-isotropic composite material comprising randomly oriented chips of unidirectional fibers in a resin matrix. 16. A method for molding a helicopter rotor blade according to claim 1 wherein said upper rollers and said lower rollers comprise cylinders having a diameter and a length wherein the length of said cylinders are greater than the diameter of said cylinders. 17. A method for making a mandrel for use in molding a helicopter rotor blade wherein said rotor blade includes a spar that extends parallel to the longitudinal axis of said rotor blade, said longitudinal axis extending from the root of said rotor blade to the tip of said rotor blade, said spar having interior surfaces that defines a spar cavity that also extends longitudinally from the root of said rotor blade to the tip of said rotor blade, said spar interior surfaces including a leading edge surface that comprises an upper leading edge portion and a lower leading edge portion, a trailing edge surface that comprises an upper trailing edge portion and a lower trailing edge portion, an upper surface that extends between said leading edge upper portion and said trailing edge upper portion and a lower surface that extends between said leading edge lower portion and said trailing edge lower portion, said method comprising the steps of: providing a forward component that comprises an exterior surface that is shaped to provide said leading edge surface of said spar interior surface, said forward component comprising an upper rear edge comprising an outer surface that is shaped to provide said upper leading edge portion and a lower rear edge that is shaped to provide said lower leading edge portion;providing a rearward component that is shaped to provide said trailing edge surface of said spar interior surface, said rearward component comprising an upper forward edge that is shaped to provide said upper trailing edge portion and a lower forward edge that is shaped to provide said lower trailing edge portion;providing an upper component that is shaped to provide said upper surface of said spar interior surface, said upper component comprising a forward edge and a rearward edge;providing a lower component that is shaped to provide said lower surface of said spar interior surface, said lower component comprising a forward edge that is connected to said and a rearward edge that is connected to said lower forward edge of said rearward component;providing a roller assembly that comprises a plurality of upper rollers and a plurality of lower rollers;connecting said forward edge of said upper component to the upper rear edge of said forward component;connecting said rearward edge of said upper component to the upper forward edge of said rearward component;connecting said forward edge of said lower component to the lower rear edge of said forward component; andconnecting said rearward edge of said lower component to the lower forward edge of said rearward component wherein said upper, lower, forward and rearward components are connected together such that said roller assembly is located between said upper component and said lower component and wherein said plurality of upper rollers contact said upper component and said plurality of lower rollers contact said lower component. 18. A method for making a mandrel for use in molding a helicopter rotor blade according to claim 17 wherein said roller assembly comprises a rib cage structure that comprises a composite material wherein said composite material is a quasi-isotropic composite material comprising randomly oriented chips of unidirectional fibers in a resin matrix.
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이 특허에 인용된 특허 (11)
Doolin Leonard J. (Milford CT) Olsen Eric G. (Woodbury CT) Reinfelder William C. (Woodbridge CT) Capowich George (Shelton CT), Advanced composite rotor blade.
Simkulak Richard J. (Meriden CT) Boustead Terry M. (West Haven CT) Folts Robert L. (St. Charles MO) Sepe George N. (Trumbull CT), Apparatus for molding hollow composite articles having internal reinforcement structures.
Reinfelder William C. ; Jones Corey D. ; Degnan William ; Kovalsky David A. ; Purse Jeffry C., Fiber reinforced composite spar for a rotary wing aircraft and method of manufacture thereof.
Mouille RenL. (Aix-en-Provence FRX) Declerco Marc (Pelissane FRX) Jalaguier Jean-Pierre (Vitrolles FRX) Jaugey Bernard (Marseilles FRX), Process for manufacturing a variable pitch multi-blade propeller by molding resin-impregnated fails around a preform.
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