Design optimization and testing of a morphing leading-edge with a variable-thickness compliant skin and a closed-chain mechanism
Design optimization and testing of a morphing leading-edge with a variable-thickness compliant skin and a closed-chain mechanism
Climate warming and the increased demand in air travels motivate the aviation industry to urgently produce technological innovations. One of the most promising innovations is based on the smoothly continuous morphing leading-edge concept. This study proposes a two-step process for the design of a morphing leading-edge, including the optimization of the outer variable-thickness composite compliant skin and the optimization of the inner kinematic mechanism. For the compliant skin design, an optimization of the variable thickness composite skin is proposed based on a laminate continuity model, with laminate continuity constraint and other manufacturing constraints. The laminate continuity model utilizes a guiding sequence and a ply-drop sequence to describe the overall stacking sequence of plies in different thickness regions of the complaint skin. For the inner kinematic mechanism design, a coupled four-bar linkage system is proposed and optimized to produce specific trajectories at the actuation points on the stringer hats of the compliant skin, which ensures that the compliant skin can be deflected into the aerodynamically optimal profile. Finally, a morphing leading-edge is manufactured and tested. Experimental results are compared with numerical predictions, confirming the feasibility of the morphing leading-edge concept and the overall proposed design approach.
Compliant skin, Control surfaces, Design, Kinematics, Leading-edge, Morphing wing, Optimization
285-300
Wang, Zhigang
8e212c5d-6064-4cb8-9968-69583e000c09
Sun, Xiasheng
9f5595e4-4019-4da6-878e-3dea2734e7f0
Yang, Yu
f2e3049f-3750-4497-ba13-7a9072f4b562
Ge, Wenjie
b151b571-d540-4f8d-9b1c-201c811ca553
Li, Daochun
d5f49ad4-89de-423c-b12e-017770e699d5
Xiang, Jinwu
152c446b-5c17-4c00-b47b-08e909420b59
Bao, Panpan
fe913e6a-c775-4052-a873-f0785c3a859a
Wu, Qi
d34c5ac0-d7eb-4c79-a509-3cdb3110d111
Da Ronch, Andrea
a2f36b97-b881-44e9-8a78-dd76fdf82f1a
23 July 2024
Wang, Zhigang
8e212c5d-6064-4cb8-9968-69583e000c09
Sun, Xiasheng
9f5595e4-4019-4da6-878e-3dea2734e7f0
Yang, Yu
f2e3049f-3750-4497-ba13-7a9072f4b562
Ge, Wenjie
b151b571-d540-4f8d-9b1c-201c811ca553
Li, Daochun
d5f49ad4-89de-423c-b12e-017770e699d5
Xiang, Jinwu
152c446b-5c17-4c00-b47b-08e909420b59
Bao, Panpan
fe913e6a-c775-4052-a873-f0785c3a859a
Wu, Qi
d34c5ac0-d7eb-4c79-a509-3cdb3110d111
Da Ronch, Andrea
a2f36b97-b881-44e9-8a78-dd76fdf82f1a
Wang, Zhigang, Sun, Xiasheng, Yang, Yu, Ge, Wenjie, Li, Daochun, Xiang, Jinwu, Bao, Panpan, Wu, Qi and Da Ronch, Andrea
(2024)
Design optimization and testing of a morphing leading-edge with a variable-thickness compliant skin and a closed-chain mechanism.
Chinese Journal of Aeronautics, 37 (7), .
(doi:10.1016/j.cja.2024.04.021).
Abstract
Climate warming and the increased demand in air travels motivate the aviation industry to urgently produce technological innovations. One of the most promising innovations is based on the smoothly continuous morphing leading-edge concept. This study proposes a two-step process for the design of a morphing leading-edge, including the optimization of the outer variable-thickness composite compliant skin and the optimization of the inner kinematic mechanism. For the compliant skin design, an optimization of the variable thickness composite skin is proposed based on a laminate continuity model, with laminate continuity constraint and other manufacturing constraints. The laminate continuity model utilizes a guiding sequence and a ply-drop sequence to describe the overall stacking sequence of plies in different thickness regions of the complaint skin. For the inner kinematic mechanism design, a coupled four-bar linkage system is proposed and optimized to produce specific trajectories at the actuation points on the stringer hats of the compliant skin, which ensures that the compliant skin can be deflected into the aerodynamically optimal profile. Finally, a morphing leading-edge is manufactured and tested. Experimental results are compared with numerical predictions, confirming the feasibility of the morphing leading-edge concept and the overall proposed design approach.
Text
1-s2.0-S1000936124001511-main
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More information
Accepted/In Press date: 20 March 2024
e-pub ahead of print date: 27 April 2024
Published date: 23 July 2024
Keywords:
Compliant skin, Control surfaces, Design, Kinematics, Leading-edge, Morphing wing, Optimization
Identifiers
Local EPrints ID: 493266
URI: http://eprints.soton.ac.uk/id/eprint/493266
ISSN: 1000-9361
PURE UUID: 8dffc42c-6d96-47e8-abaf-8fd64c58ea48
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Date deposited: 29 Aug 2024 16:39
Last modified: 12 Nov 2024 02:49
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Contributors
Author:
Zhigang Wang
Author:
Xiasheng Sun
Author:
Yu Yang
Author:
Wenjie Ge
Author:
Daochun Li
Author:
Jinwu Xiang
Author:
Panpan Bao
Author:
Qi Wu
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