Methods and systems for manufacturing composite parts with female tools
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
B28B-007/32
B28B-007/28
B32B-005/00
출원번호
UP-0899660
(2004-07-26)
등록번호
US-7622066
(2009-12-02)
발명자
/ 주소
Brustad, Val G.
Cundiff, Thomas R.
Hanks, Dennis J.
Woods, Jack A.
Modin, Andrew E.
출원인 / 주소
The Boeing Company
대리인 / 주소
Perkins Coie LLP
인용정보
피인용 횟수 :
37인용 특허 :
26
초록▼
Methods and systems for manufacturing fiber-reinforced resin parts are disclosed herein. In one embodiment, a method for manufacturing a fiber-reinforced resin part includes positioning a plurality of fibers on a mold surface of a female tool, and covering the fibers with a sealing layer. The metho
Methods and systems for manufacturing fiber-reinforced resin parts are disclosed herein. In one embodiment, a method for manufacturing a fiber-reinforced resin part includes positioning a plurality of fibers on a mold surface of a female tool, and covering the fibers with a sealing layer. The method further includes pressing a portion of the covered fibers against an interior transition region (e.g., an internal radius) of the mold surface. While the portion of covered fibers is pressed against the interior transition region, air is removed from between the sealing layer and the mold surface to draw at least a partial vacuum between the sealing layer and the mold surface.
대표청구항▼
We claim: 1. A method for manufacturing a fiber-reinforced resin part, the method comprising: positioning a plurality of fibers on a mold surface of a tool, the mold surface including a first side region, a second side region, and an interior transition region positioned between the first and secon
We claim: 1. A method for manufacturing a fiber-reinforced resin part, the method comprising: positioning a plurality of fibers on a mold surface of a tool, the mold surface including a first side region, a second side region, and an interior transition region positioned between the first and second side regions; covering the fibers with a sealing layer; pressing a first portion of the covered fibers against the first side region of the mold surface with a tooling aid without pressing a second portion of the covered fibers against the second side region of the mold surface; while pressing the first portion of covered fibers against the first side region, pressing a third portion of the covered fibers against the interior transition region of the mold surface by inflating an expandable member operably coupled to the tooling aid against the sealing layer to compress the third portion of covered fibers between the expandable member and the interior transition region, without pressing the second portion of covered fibers against the second side region of the mold surface; while pressing the third portion of covered fibers against the interior transition region of the mold surface with the pressing device, allowing the second portion of covered fibers on the second side region to move toward the interior transition region; and removing air from between the sealing layer and the mold surface to draw at least a partial vacuum between the sealing layer and the mold surface. 2. The method of claim 1 wherein pressing a third portion of the covered fibers against the interior transition region includes inflating the expandable member against the sealing layer to compress the third portion of covered fibers, without inflating the expandable member against the second portion of covered fibers on the second side region of the mold surface. 3. The method of claim 1 wherein inflating an expandable member includes inflating a bladder against the sealing layer to compress the third portion of covered fibers between the bladder and the interior transition region, without inflating the bladder against the second portion of covered fibers on the second side region of the mold surface. 4. The method of claim 1, further comprising pressing the second portion of covered fibers against the second side region of the mold surface while removing the air from between the sealing layer and the mold surface. 5. The method of claim 1, further comprising flowing resin between the sealing layer and the mold surface to infuse the plurality of fibers with resin. 6. The method of claim 1, further comprising flowing resin between the sealing layer and the mold surface after removing at least some air from between the sealing layer and the mold surface. 7. The method of claim 1, further comprising, after pressing the third portion of covered fibers against the interior transition region, flowing resin between the sealing layer and the mold surface to infuse the plurality of fibers with resin. 8. The method of claim 1 wherein pressing a third portion of the covered fibers against the interior transition region includes moving the pressing device toward the third portion of covered fibers to compress the third portion of covered fibers between the pressing device and the interior transition region, without moving the pressing device toward the second portion of covered fibers to compress the second portion of covered fibers against the second side region of the mold surface, and wherein the method further comprises moving the pressing device away from the third portion of covered fibers after drawing at least a partial vacuum between the sealing layer and the mold surface and before curing resin infusing the plurality of fibers. 9. The method of claim 1 wherein pressing a third portion of the covered fibers against the interior transition region includes moving the pressing device toward the third portion of covered fibers to compress the third portion of covered fibers between the pressing device and the interior transition region, without moving the pressing device toward the second portion of covered fibers to compress the second portion of covered fibers against the second side region of the mold surface, and wherein the method further comprises: moving the pressing device away from the third portion of covered fibers after drawing at least a partial vacuum between the sealing layer and the mold surface; and after moving the pressing device away from the third portion of covered fibers, flowing resin between the sealing layer and the mold surface to infuse the plurality of fibers with resin. 10. The method of claim 1 wherein positioning a plurality of fibers on a mold surface of a tool includes positioning a plurality of fibers on a female mold surface, the female mold surface including the interior transition region positioned between the first side region and the second side region, and wherein the first side region is positioned at an angle of from about 80 degrees to about 100 degrees relative to the second side region. 11. The method of claim 1 wherein pressing a third portion of the covered fibers against the interior transition region of the mold surface includes pressing the third portion of covered fibers against a first interior transition region, and wherein the method further comprises: pressing a fourth portion of the covered fibers against a second interior transition region of the mold surface spaced apart from the first interior transition region while pressing the third portion of the covered fibers against the first interior transition region, wherein the fourth portion of covered fibers are pressed against the second interior transition region of the mold surface without pressing a fifth portion of the covered fibers against a third side region of the mold surface positioned opposite to the second side region of the mold surface; and while pressing the fourth portion of covered fibers against the second interior transition region of the mold surface, allowing the fifth portion of covered fibers on the third side region of the mold surface to move toward the second interior transition region. 12. A method for manufacturing a fiber-reinforced resin part, the method comprising: positioning a plurality of fibers on a mold surface of a female tool, the mold surface including a first side region, a second side region, and an interior transition region positioned between the first and second side regions; covering the fibers with a sealing layer; compressing a first portion of the fibers against the first side region of the mold surface with a first portion of a tooling aid without compressing a second portion of the fibers against the second side region of the mold surface; while compressing the first portion of fibers against the first side region of the mold surface, inflating an expandable member between a second portion of the tooling aid and the sealing layer to compress a third portion of the fibers between the expandable member and the interior transition region of the mold surface without compressing the second portion of fibers against the second side region of the mold surface; allowing the uncompressed second portion of fibers on the second side region to move toward the interior transition region as the third portion of fibers is compressed between the expandable member and the interior transition region; and while the expandable member is inflated, removing air from between the sealing layer and the mold surface to at least partially draw a vacuum between the sealing layer and the mold surface. 13. The method of claim 12 wherein inflating an expandable member between a second portion of the tooling aid and the sealing layer includes inflating an elongate bladder against the sealing layer. 14. The method of claim 12, further comprising positioning a contoured former proximate to the interior transition region of the mold surface after covering the fibers with the sealing layer, wherein inflating an expandable member between a second portion of the tooling aid and the sealing layer to compress a third portion of the fibers includes inflating the expandable member against the contoured former to compress the third portion of fibers between the contoured former and the interior transition region of the mold surface. 15. The method of claim 12 wherein the expandable member is a first expandable member and the interior transition region is a first interior transition region, and wherein the method further comprises inflating a second expandable member against the sealing layer to compress a fourth portion of the fibers between the second expandable member and a second interior transition region of the mold surface spaced apart from the first interior transition region, wherein the fourth portion of fibers are compressed against the second interior transition region without compressing a fifth portion of the fibers against a third side region of the mold surface positioned opposite to the second side region of the mold surface. 16. The method of claim 12 wherein inflating an expandable member includes inflating an expandable member supported by the tooling aid. 17. The method of claim 12 wherein the interior transition region of the mold surface is a first interior transition region, wherein inflating an expandable member includes inflating a first expandable member supported by the tooling aid against the sealing layer to compress the third portion of fibers between the first expandable member and the first interior transition region, and wherein the method further comprises: inflating a second expandable member supported by the tooling aid against the sealing layer to compress a fourth portion of the fibers between the second expandable member and a second interior transition region of the mold surface spaced apart from the first interior transition region, wherein the fourth portion of covered fibers are pressed against the second interior transition region of the mold surface without pressing a fifth portion of the covered fibers against a third side region of the mold surface positioned opposite to the second side region of the mold surface; and while pressing the fourth portion of covered fibers against the second interior transition region of the mold surface, allowing the fifth portion of covered fibers on the third side region of the mold surface to move toward the second interior transition region. 18. A method for manufacturing a fiber-reinforced resin part, the method comprising: positioning a plurality of fibers on a mold surface of a tool, the mold surface including a first, second, and third side regions and first and second interior transition regions, wherein the first interior transition region is positioned between the first and second side regions, and the second interior transition region is positioned between the first and third side regions; covering the fibers with a sealing layer; pressing a first portion of the covered fibers against the first side region of the mold surface with a tooling aid; while pressing the first portion of covered fibers against the first side region, moving a first pressing device toward the first interior transition region of the mold surface by inflating a first expandable member against the sealing layer and pressing a second portion of the covered fibers against the first interior transition region without pressing a third portion of the covered fibers against the second side region of the mold surface; while pressing the first portion of covered fibers against the first side region, moving a second pressing device toward the second transition region of the mold surface by inflating a second expandable member against the sealing layer and pressing a fourth portion of the covered fibers against the second interior transition region without pressing a fifth portion of the covered fibers against the third side region of the mold surface, wherein the first and second pressing devices are operably coupled to the tooling aid; while pressing the first, second, and fourth portions of covered fibers, allowing the third portion of covered fibers on the second side region to move toward the first interior transition region, and allowing the fifth portion of covered fibers on the third side region to move toward the second interior transition region; and removing air from between the sealing layer and the mold surface to draw at least a partial vacuum between the sealing layer and the mold surface. 19. The method of claim 18, further comprising flowing resin between the sealing layer and the mold surface after removing air from between the sealing layer and the mold surface. 20. The method of claim 18 wherein positioning a plurality of fibers on a mold surface of a tool includes positioning a plurality of fibers on a curved, outer mold line tool. 21. The method of claim 18 wherein positioning a plurality of fibers on a mold surface of a tool includes positioning a plurality of fibers on a female tool for making portions of aircraft fuselage frames. 22. The method of claim 18 wherein pressing a second portion of the covered fibers against the first interior transition region includes pressing the second portion of covered fibers against a continuous and elongate interior transition region.
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