Experimental Aerodynamic Control of a Long-Span Suspension Bridge Section Using Leading- and Trailing-Edge Control Surfaces

Kevin Gouder; Xiaowei Zhao; David J. N. Limebeer; J. Michael R. Graham

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Experimental Aerodynamic Control of a Long-Span Suspension Bridge Section Using Leading- and Trailing-Edge Control Surfaces

机译：使用前缘和后缘控制面的大跨度悬索桥截面的实验空气动力学控制

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We experimentally investigate the suppression of flutter in long-span suspension bridges. A rigid sectional model of a long-span suspension bridge is mounted in a wind tunnel on a suspension system. Control surfaces, which are used to suppress flutter, are movable flaps that are fitted to the bridge section’s leading and trailing edges. The flaps are responsive to the deck’s heave and pitch motions. In this paper, the aerodynamic force is modeled using a thin aerofoil theory, although other modeling techniques can be used. The controller has a second-order passive transfer function with inputs of a combination of the deck’s pitch angle and heave position, and outputs of the flaps’ angular positions. The control system design problem is solved as an optimization problem.

机译：我们通过实验研究了大跨度悬索桥颤振的抑制。大跨度悬索桥的刚性截面模型安装在悬索系统的风洞中。操纵面用来抑制晃动，是可移动的襟翼，可装在桥形部分的前缘和后缘。襟翼可响应甲板的升沉和俯仰运动。在本文中，虽然可以使用其他建模技术，但使用薄翼型理论对空气动力进行建模。该控制器具有二阶被动传递功能，其输入包括甲板的俯仰角和升沉位置的组合以及襟翼的角位置的输出。控制系统设计问题作为优化问题解决。

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《IEEE Transactions on Control Systems Technology》 |2016年第4期|1441-1453|共13页
作者
Kevin Gouder; Xiaowei Zhao; David J. N. Limebeer; J. Michael R. Graham;
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Department of Aeronautical Engineering, Imperial College London, London, U.K.;

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正文语种 eng
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Buffeting; control surfaces; flaps; flutter; long-span suspension bridge; robust control; thin aerofoil theory; wind tunnel experiments; wind tunnel experiments.;

机译：抖振;控制面;襟翼;颤振;大跨度悬索桥;鲁棒控制;薄翼型理论;风洞实验;风洞实验。;

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2. Aeroelastic Wing with Leading- and Trailing-Edge Control Surfaces [J] . Earl H. Dowell, Donald B. Bliss, Robert L. Clark Journal of Aircraft . 2003,第3期

机译：具有前缘和后缘控制面的气动弹性翼
3. Theoretical framework of feedback aerodynamic control of flutter oscillation for long-span suspension bridges by the twin-winglet system [J] . Li K., Ge Y. J., Guo Z. W., Journal of Wind Engineering and Industrial Aerodynamics: The Journal of the International Association for Wind Engineering . 2015,第Null期

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4. Analysis of Active Flutter Suppression with Leading- and Trailing-Edge Control Surfaces via μ-Method [C] . Ying Teng, Hsin-Piao Chen AeroTech Congress and Exhibition . 2006

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5. Experimental determination of aeroelastic and aerodynamic parameters of long-span bridges. [D] . Singh, Lakshmeshwar. 1997

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6. Long-Term In-Service Monitoring and Performance Assessment of the Main Cables of Long-Span Suspension Bridges [O] . Yang Deng, Yang Liu, Suren Chen 2017

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7. Experimental aerodynamic control of a long-span suspension bridge section using leading- and trailing-edge control surfaces [O] . Gouder, K, Zhao, X, Limebeer, DJN, 2015

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Experimental Aerodynamic Control of a Long-Span Suspension Bridge Section Using Leading- and Trailing-Edge Control Surfaces

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