«上一篇/Previous Article|本期目录/Table of Contents|下一篇/Next Article»

《建筑科学与工程学报》[ISSN:1673-2049/CN:61-1442/TU]

卷:

40卷

期数:

2023年01期

页码:

103-111

栏目:

建筑结构

出版日期:

2023-01-10

文章信息/Info

Title:

Study on wind tunnel test of urban wind environment under thermal effects

文章编号:

1673-2049(2023)01-0103-09

作者:

杨 瑛¹,胡嘉懿¹,沈 炼^1,2,汪 阔¹,孙 昱³,许赤士³

(1. 长沙理工大学 桥梁工程安全控制技术与装备湖南省工程技术研究中心,湖南 长沙 410076; 2. 长沙学院 土木工程学院,湖南 长沙 410012; 3. 湖南省建筑设计院集团股份有限公司,湖南 长沙 410208)

Author(s):

YANG Ying¹, HU Jiayi¹, SHEN Lian^1,2, WANG Kuo¹, SUN Yu³, XU Chishi³

(1. Hunan Province Research Center for Safety Control Technology and Equipment of Bridge Engineering, Changsha University of Science & Technology, Changsha 410076, Hunan, China; 2. School of Civil Engineering, Changsha University, Changsha 410012, Hunan, China; 3. Hunan Architectural Design Institute Group Co., Ltd, Changsha 410208, Hunan, China)

关键词:

理查逊数;  风洞试验;  风场分析;  热力效应;  风环境

Keywords:

Richardson number;  wind tunnel test;  wind field analysis;  thermal effect;  wind environment

分类号:

TU119

DOI:

10.19815/j.jace.2021.07043

文献标志码:

A

摘要:

温度作为影响城市舒适度的主要因素之一,对流场的作用机理到目前为止尚不明确。为揭示温度场对流场的影响规律,基于大尺寸风洞,对不同热力条件下的平均风进行试验研究,得出不同理查逊数R_b作用下的人行高度风速、相关测点顺风向速度和雷诺剪切应力分布并进行详细分析。以长沙市某小区为研究背景,探究了不同热力效应下人行高度风场的分布规律,获取了热力条件下典型测点的相关性系数,并利用超越概率的方法定量评估了热力效应下的小区人行高度风环境。结果表明:在-0.38<R_b<0范围内,空风洞流场随着热力效应增大,在近地面风速增长相对较大,且随着高度的增加其增幅逐渐减缓; 实际中小区人行高度风环境受温度影响整体较小,主要影响集中在风速比0.6以下,最大均方根为0.635,风速比在0.6以上时温度对风速影响效果相对较小; 热力效应对人行高度风场的相关性与舒适度影响较小,其最大影响值分别为8%和3.87%。

Abstract:

Temperature is one of the main factors affecting the comfort of the city, the mechanism of the flow field is not clear so far. In order to reveal the influence of temperature field on the flow field, based on the large-scale wind tunnel, the average wind under different thermal conditions was tested and studied. The wind speed at pedestrian height, the along-wind speed of relevant measuring points and the distribution of Reynolds shear stress under different Richardson numbers R_b were obtained and analyzed in detail. Taking a residential district in Changsha as the research background, the distribution law of wind field at pedestrian height under different thermal effects was explored, the correlation coefficient of typical measuring points under thermal conditions was obtained, and the wind environment at pedestrian height under thermal effects was quantitatively evaluated by the method of exceedance probability. The results show that in the range of -0.38<R_b<0, the flow field of the empty wind tunnel increases with the thermal effect, and the near-surface wind speed increases relatively large, and the increase gradually slows down with the increase of height. In practice, the wind environment of pedestrian height in the community is less affected by temperature as a whole. The main influence is concentrated below the wind speed ratio of 0.6, and the maximum root mean square is 0.635. When the wind speed ratio is above 0.6, the effect of temperature on wind speed is relatively small. The thermal effect has little influence on the correlation and comfort degree of pedestrian height wind field, and the maximum influence values are only 8% and 3.87%.

参考文献/References:

[1] BELCHER S E.Mixing and transport in urban areas[J].Philosophical Transactions of the Royal Society A,Mathematical,Physical,and Engineering Sciences,2005,363(1837):2947-2968.
[2]BLOCKEN B,JANSSEN W D,VAN HOOFF T.CFD Simulation for pedestrian wind comfort and wind safety in urban areas:general decision framework and case study for the Eindhoven University Campus[J].Environmental Modelling & Software,2012,30:15-34.
[3]DU Y X,MAK C M,LIU J L,et al.Effects of lift-up design on pedestrian level wind comfort in different building configurations under three wind directions[J].Building and Environment,2017,117:84-99.
[4]何仲阳,宋梦譞,张 兴.地表温度对风场模拟的影响[J].化工学报,2012,63(增1):7-11.
HE Zhongyang,SONG Mengxuan,ZHANG Xing.Influence of terrain surface temperature on wind farm simulation[J].CIESC Journal,2012,63(S1):7-11.
[5]CHENG W C,LIU C H.Large-eddy simulation of turbulent transports in urban street canyons in different thermal stabilities[J].Journal of Wind Engineering and industrial aerodynamics,2011,99(4):434-442.
[6]LI X X,LIU C H,LEUNG D Y C.Large-eddy simulation of flow and pollutant dispersion in high-aspect-ratio urban street canyons with wall model[J].Boundary-layer Meteorology,2008,129(2):249-268.
[7]LI X X,BRITTER R E,KOH T Y,et al.Large-eddy simulation of flow and pollutant transport in urban street canyons with ground heating[J].Boundary-layer Meteorology,2010,137(2):187-204.
[8]LI X X,BRITTER R E,NORFORD L K,et al.Flow and pollutant transport in urban street canyons of different aspect ratios with ground heating:large-eddy simulation[J].Boundary-layer Meteorology,2012,142(2):289-304.
[9]CHAUDHRY H,CALAUTIT J,HUGHES B,et al.CFD and experimental study on the effect of progressive heating on fluid flow inside a thermal wind tunnel[J].Computation,2015,3(4):509-527.
[10]UEHARA K,MURAKAMI S,OIKAWA S,et al.Wind tunnel experiments on how thermal stratification affects flow in and above urban street canyons[J].Atmospheric Environment,2000,34(10):1553-1562.
[11]ALLEGRINI J,DORER V,CARMELIET J.Wind tunnel measurements of buoyant flows in street canyons[J].Building and Environment,2013,59:315-326.
[12]ALLEGRINI J,DORER V,CARMELIET J.Buoyant flows in street canyons:validation of CFD simulations with wind tunnel measurements[J].Building and Environment,2014,72:63-74.
[13]KOVAR-PANSKUS A,MOULINNEUF L,SAVORY E,et al.A wind tunnel investigation of the influence of solar-induced wall-heating on the flow regime within a simulated urban street canyon[M]//SOKHI R S,BARTZIS J G.Urban Air Quality — Recent Advances.Dordrecht:Kluwer Academic Publishers,2002:555-571.
[14]欧阳琰,蒋维楣,胡 非,等.城市小区环境流场及污染物扩散的风洞实验研究[J].南京大学学报(自然科学),2003,39(6):770-780.
OUYANG Yan,JIANG Weimei,HU Fei,et al.Experimental study in wind tunnel in the field of air flows and pollutant dispersion in the urban sub-domain[J].Journal of Nanjing University(Natural Science),2003,39(6):770-780.
[15]HAJRA B,STATHOPOULOS T,BAHLOUL A.A wind tunnel study of the effects of adjacent buildings on near-field pollutant dispersion from rooftop emissions in an urban environment[J].Journal of Wind Engineering and Industrial Aerodynamics,2013,119:133-145.
[16]HAJRA B,STATHOPOULOS T.A wind tunnel study of the effect of downstream buildings on near-field pollutant dispersion[J].Building and Environment,2012,52:19-31.
[17]日本风洞实验指南研究委员会.建筑风洞实验指南[M].孙 瑛,武 岳,曹正罡,译.北京:中国建筑工业出版社,2011.
Research Committee for Building Wind Tunnel Experiment Guide of Japan.Building wind tunnel experiments guide[M].Translated by SUN Ying,WU Yue,CAO Zhenggang.Beijing:China Architecture & Building Press,2011.
[18]范绍佳,林文实,苏雄晖,等.理查逊数Ri在沿海近地层大气稳定度分类中的应用[J].热带气象学报,1999,15(4):370-375.
FAN Shaojia,LIN Wenshi,SU Xionghui,et al.Study on the application of Richardson number's stability classifying schemes of the surface layer over coastal region[J].Journal of Tropical Meteorology,1999,15(4):370-375.
[19]SHAW R H,BRUNET Y,FINNIGAN J J,et al.A wind tunnel study of air flow in waving wheat:two-point velocity statistics[J].Boundary-layer Meteorology,1995,76(4):349-376.
[20]RAUPACH M R,ANTONIA R A,RAJAGOPALAN S.Rough-wall turbulent boundary layers[J].Applied Mechanics Reviews,1991,44(1):1-25.
[21]SU H B,SHAW R H,PAW U K T.Two-point correlation analysis of neutrally stratified flow within and above a forest from large-eddy simulation[J].Boundary-layer Meteorology,2000,94(3):423-460.
[22]BOTTEMA M.A Method for optimisation of wind discomfort criteria[J].Building and Environment,2000,35(1):1-18.

相似文献/References:

[1]王松帆,汤华.超高层建筑的风振响应及等效静风荷载研究[J].建筑科学与工程学报,2010,27(01):102.
　WANG Song-fan,TANG Hua.Research on Wind Vibration Response and Equivalent Static Wind Loads of Super High-rise Buildings[J].Journal of Architecture and Civil Engineering,2010,27(01):102.
[2]董锐,赵林,葛耀君.大型冷却塔人字柱临时期最优拆除位置分析[J].建筑科学与工程学报,2011,28(03):56.
　DONG Rui,ZHAO Lin,GE Yao-jun.Analysis of Optimal Removing Location of Diagonal Columns in Large Cooling Towers' Temporary Period[J].Journal of Architecture and Civil Engineering,2011,28(01):56.
[3]汤华,王松帆.基于风洞试验的高层建筑风荷载研究及抗风设计[J].建筑科学与工程学报,2012,29(02):96.
　TANG Hua,WANG Song-fan.Wind Load Research and Wind-resistant Design of High-rise Buildings Based on Wind Tunnel Test[J].Journal of Architecture and Civil Engineering,2012,29(01):96.
[4]柯世堂,赵林,葛耀君,等.超大型排烟冷却塔风压分布及双孔道位置优化[J].建筑科学与工程学报,2009,26(02):52.
　KE Shi-tang,ZHAO Lin,GE Yao-jun,et al.Wind Pressure Distribution and Double Holes Position Optimization for Super Large-scale Cooling Towers with Flue Gas[J].Journal of Architecture and Civil Engineering,2009,26(01):52.
[5]沈世钊,武岳.膜结构风振响应中的流固耦合效应研究进展[J].建筑科学与工程学报,2006,23(01):1.
　SHEN Shi-zhao,WU Yue.Research Progress on Fluid-Solid Interaction Effect of Wind-Induced Vibration Response of Membrane Structure[J].Journal of Architecture and Civil Engineering,2006,23(01):1.
[6]沈之容,王之宏.上海北外滩酒店中庭结构风洞试验[J].建筑科学与工程学报,2006,23(04):74.
　SHEN Zhi-rong,WANG Zhi-hong.Wind Tunnel Test on Atrium Structure in Shanghai North Bund Hotel[J].Journal of Architecture and Civil Engineering,2006,23(01):74.
[7]刘健新,李加武.中国西部地区桥梁风工程研究[J].建筑科学与工程学报,2005,22(04):32.
　LIU Jian-xin,LI Jia-wu.Study of wind project of bridge in western area of China[J].Journal of Architecture and Civil Engineering,2005,22(01):32.
[8]涂 俊,王玉银,刘永健,等.大跨钢箱拱-波形钢-桁架组合梁拱桥抗风性能[J].建筑科学与工程学报,2019,36(04):47.
　TU Jun,WANG Yu-yin,LIU Yong-jian,et al.Wind Resistance of Large-span Steel Box Arch-corrugated Steel-truss Composite Beam Arch Bridge[J].Journal of Architecture and Civil Engineering,2019,36(01):47.
[9]何晗欣,张亮亮,杨鹏瑞,等.外凸式矩形高层建筑风压研究[J].建筑科学与工程学报,2019,36(06):72.
　HE Han-xin,ZHANG Liang-liang,YANG Peng-rui,et al.Study on Wind Pressure of Outer Convex Rectangular High-rise Building[J].Journal of Architecture and Civil Engineering,2019,36(01):72.
[10]李加武,朱长宇.基于表面风压分析的分离式双箱梁流场特性研究[J].建筑科学与工程学报,2021,38(02):69.[doi:10.19815/j.jace.2020.09081]
　LI Jia-wu,ZHU Chang-yu.Study on Flow Field Characteristics Around Separated Twin-box Girder Based on Surface Wind Pressure Analysis[J].Journal of Architecture and Civil Engineering,2021,38(01):69.[doi:10.19815/j.jace.2020.09081]

备注/Memo

备注/Memo:

收稿日期:2021-07-08
基金项目:国家自然科学基金项目(51808059); 长沙市杰出青年创新培育计划项目(kq195004);
湖南省教育厅科学研究重点项目(22A0595); 长沙理工大学桥梁工程安全控制技术与装备湖南省工程技术研究中心开放基金项目(18KC04,14KC07)
作者简介:杨 瑛(1964-),男,工学博士,教授级高级工程师,E-mail:517596653@qq.com。

常用功能

更新日期/Last Update: 2023-01-01