登录
注册
Effects on Aerodynamics of Long-Span Bridges with Different Vertical Clearance Under Bridges Decks
-
摘要: 为研究桥下不同净高对大跨度桥梁加劲梁气动特性的影响,以大带东桥主桥加劲梁为例,采用雷诺时均Navier-Stokes (RANS)方程和SST k-ω湍流模型,数值模拟了自然风场内不同桥下净高加劲梁断面绕流场,获得了加劲梁气动参数,并与文献报道的风洞试验结果进行了对比,分析了加劲梁气动参数随净高变化的流动机理。
研究表明,桥下净高对加劲梁表面压力分布、升力和阻力,以及漩涡脱落St数均有一定程度影响。桥下净高减小,升力和阻力系数均增大;相比桥下净高5B,桥下净高仅为0.4B时升力和阻力系数分别增大87.8%和13.3%;漩涡脱落St数也随桥下净高的减小而稍增大。加劲梁表面压力监测表明,桥下净高小时,风嘴前缘下斜腹板峰值压力增大,且加劲梁上下表面迎风侧棱角的负压峰值同时减小,但上表面迎风侧棱角减小更显著。研究认为,当大跨度桥梁桥下净高明显偏小时,桥下水面对加劲梁产生明显的气动力干扰效应,从桥梁抗风的角度,需考虑桥下净高明显偏小可能导致的加劲梁风荷载增大。Abstract: In order to investigate aerodynamics of long-span bridges with different vertical clearance under bridges stiffening girder, the Reynolds-Averaged Navier-Stokes Equations and SST k-ω turbulent model were employed to solve the flow field around bridge girder of the Great Belt East Bridge main span with different vertical clearance in natural wind. The aerodynamic coefficients under various vertical clearance is presented and compared to wind tunnel test, and its flow mechanism relating to those changes is analyzed.
The results find that the variation of vertical clearance presents mix effects on pressure distribution on girder surface, on lift and drag acting on girder, and on vortex shedding St number. When the vertical clearance decreases, the lift and drag coefficients will increase. Compared to the results from vertical clearance of 5B, the vertical clearance of 0.4B produces an increase of 87.8% for lift coefficient and an increase of 13.3% for drag coefficient, and the vortex shedding St number also indicates slightly increase. The monitored pressure distribution on girder surface indicates that when the vertical clearance is small, the peak pressure at the positive zone ahead of leading edge of the girder increases, and the peak negative pressure at the windward corner of the deck and bottom also increase, with significant increase observed at the deck corner. It is concluded that when the vertical clearance under the bridge is very small, the water surface will generate significant aerodynamic interference to the bridge girder, hence the increase wind loads acting on the bridge girder due to significantly small vertical clearance should be considered as to insure bridge safety against wind.-
Key words:
- long-span bridges /
- wind loads /
- vertical clearance under bridge /
- CFD /
- vortex shedding
-
[1] 中华人民共和国住房和城乡建设部.内河通航标准:GB 50139—2014[S]. 北京: 中国计划出版社, 2015. (GB 50139—2014 The standards of inland waterway navigation[S]. Beijing: Planning press of China, 2015(in Chinese)) [2] 祝志文.基于二维RANS模型计算扁平箱梁漩涡脱落的可行性研究[J].中国公路学报,2015,28(6):24-33.Zhi-Wen Zhu, Feasibility Investigation on Prediction of Vortex Shedding of Flat Box Girders Based on 2D RANS Model[J], China Journal of Highway and Transport, 2015,28(6):24-33. (In Chinese) [3] Menter F R. Two-equation eddy-viscosity turbulence models for engineering applications[J]. AIAA Journal, 1994,32: 269-289. [4] 祝志文,陈魏,袁涛.桥梁主梁CFD模拟之基准模型测压试验与气动特性分析[J].中国公路学报,2016,29(11):49-56.Zhi-Wen Zhu, Wei Chen, Tao Yuan, Pressure measurement and aerodynamics investigation on benchmark model for bridge girder CFD simulations[J], China Journal of Highway and Transport. 2016, 29(11):49-56. (In Chinese) [5] Larsen A. Aerodynamic aspects of the final design of the 1624 m suspension bridge across the Great Belt[J]. J. Wind Eng. Ind. Aerodyn., 1993, 48:261-285. [6] 中华人民共和国交通运输部.公路桥梁抗风设计规范:JTG/T 3360-01—2018[S].北京:人民交通出版社股份有限公司,2019. JTG/T 3360-01-2018, Wind-resistant design specification for highway bridge[S]. [7] 祝志文,颜爽,王钦华,等.两自由度平板大幅振动的气动特性与稳定性的CFD研究[J].振动工程学报,2021, 34(2):271-282. [8] 祝志文,李宏博.风洞模型棱角制作误差对扁平箱梁气动力和涡脱特性的影响[J].振动与冲击,2020,39(6):181-188. [9] 祝志文,陈政清.数值模拟桥梁断面的颤振导数和颤振临界风速[J].中国公路学报,2004,15(4):41-50. -
点击查看大图
计量
- 文章访问数: 231
- HTML全文浏览量: 57
- PDF下载量: 11
- 被引次数: 0
下载:
