《高层建筑气动弹性模型风洞试验》:该文是关于风洞论文范文,为你的论文写作提供相关论文资料参考。
摘 要:以高层建筑为研究背景,制作了气动弹性模型,通过风洞试验测得结构的时程响应结果,采用频谱分析求得结构的动力特性,采用自然激励技术法(NExT)和ARMA模型时序法以及改变模态阶数的方法获得结构的气动阻尼比,研究了结构气动阻尼比随风速的变化规律.在强风下,对顺风向的加速度响应时程结合滤波方法,消除横风向能量转移的影响,同时发现了涡激共振现象.考虑气动阻尼影响的情况下,刚体模型测压和测力得到的峰值加速度响应结果,和气动弹性模型风洞试验结果十分接近,验证气动弹性模型风洞试验结果的正确性.对于刚体模型,不考虑气动阻尼时,峰值加速度比气动弹性模型试验结果大很多,差值最大达到41%,但在某种工况下,气动阻尼的影响使结构的响应值增大,验证了考虑气动耦合作用在高层抗风研究中的必要性.
关键词:高层建筑;气动弹性模型;风洞试验;动力特性;气动阻尼;峰值加速度
中图分类号:TU973.32 文献标识码:A
Abstract: This paper studied the aeroelatic effect on tall buildings. An aeroelastic model was designed and manufactured for wind tunnel tests. With the timehistory responses of the structure obtained from the aeroelastic model in the wind tunnel test, we could identify the structural dynamic characteristics by spectral analysis, and get the aerodynamic damping from the natural excitation technique method (NExT), the ARMA method, combined with a change in mode order, and then study the rules of aerodynamic damping changing with wind speeds. In a strong wind situation, filter technique was used to analyze the alongwind timehistory acceleration response to eliminate the influence of the acrosswind energy transfer. And vortexexcited resonance existed in the process of identifying the aerodynamic damping. The peak acceleration responses of the rigid models by pressure test and highfrequencyforcebalance test, which considered the aerodynamic damping ratios, were very close to the results of the aeroelastic model test. The accuracy of the aeroelastic model test was verified. For the rigid models, irrespective of aerodynamic damping ratios, the peak acceleration responses were much larger than the results of the aeroelastic model test. The biggest difference was 41%. However, in some cases, the aerodynamic damping ratios increased the responses, and the necessity of considering the aerodynamic coupling effect on the windresistant design of flexible highrise buildings has been verified.
Key words: tall buildings; aeroelastic model; wind tunnel test; dynamic characteristics; aerodynamic damping; peak acceleration
Kareem and Gurley [1] 和Vickery and Steckley[2]得出了折算风速在6到10之间,高层建筑的气动阻尼会出现正的最大值,随后气动阻尼随折算风速的增加而急剧减小,当折算风速在10~11之间时会出现负的最大值,加剧结构的风振响应.由此可见,气动阻尼对高层建筑风致振动响应的影响有时是不能忽略的,特别是当结构的气动阻尼出现负值时,会使结构总阻尼降低,导致高层建筑动力响应较高,这在高层建筑抗风设计研究中应引起重视.
在测压试验中引入了气动阻尼比,得出了响应的简化计算方法;全涌(2001)[4]将气动弹性模型结果和高频测力天平试验结果进行了对比,并在2003年 [5-7]用随机减量法研究顺风向及横风向气动阻尼;黄东梅(2008)[8]讨论了气动弹性模型模态分析的3种方法,给出了各方法的适用情况;吴海洋(2010)[9]运用改进的随机减量技术,分析了风场类别、结构阻尼比等因素对横风向气动阻尼比的影响.
风洞论文参考资料:
结论:高层建筑气动弹性模型风洞试验为关于风洞方面的论文题目、论文提纲、娱乐风洞设备价格论文开题报告、文献综述、参考文献的相关大学硕士和本科毕业论文。