
风致静力扭角对桥梁颤振性能影响的节段模型试验研究
Effect of Wind-induced Static Torsional Angle on Flutter Performance of Bridges via Sectional Model Test
摘 要:自由振动试验识别得到的气动参数已包含了一定的、但与实桥不严格相似的风致静力扭角的影响。为了在颤振分析中能精确考虑风致静力扭角的影响,首先必须消除节段模型试验中风致静力扭角对气动导数识别结果的影响。通过在试验过程中使节段模型作受控反向旋转可以消除平均风附加攻角,然后将消除平均风附加攻角后的试验结果与常规试验结果相比较,以象山港大桥为背景,对风致静力扭角对节段模型系统的阻尼比、气动导数和临界风速的影响进行了初步讨论。象山港大桥节段模型的研究结果表明:风致静力扭角对模型扭转阻尼比和与扭转有关的气动导数有明显的影响。象山港大桥节段模型在+3°攻角发生颤振时风致静力扭角约为0.32°,攻角修正以后节段模型颤振临界风速识别结果提高了7%。
Abstract: Wind-induced static torsional angle has significant influence on the results of sectional model test. To accomplish accurate flutter analysis, wind-induced static torsional angle should be adjusted in sectional model test. An attack angle control facility was used to eliminate static wind induced additional attack angle. A comparison of test results before and after the attack angle adjustment based on the Xiang Shan Gang Bridge shows that static wind induced additional attack angle has influence on aerodynamic tortional damping ratio, aerodynamic derivatives related to torsional movement and critical wind speed. Before the adjustment, the wind induced additional attack angle on the sectional modal under critical wind speed was 0.32°at 3°initial attack angle. After the adjustment, the critical wind speed increased by 7%.
风致静力扭角 / 阻尼比 / 颤振临界风速 / 气动导数 {{custom_keyword}} /
Static wind induced additional attack angle / Damping ratio / Critical flutter wind speed / Aerodynamic derivatives {{custom_keyword}} /
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