[1]任兰红,曾 坚*,曾穗平.山地地形对鼓浪屿历史文化街区风荷载作用效应研究[J].山地学报,2019,(01):41-52.[doi:10.16089/j.cnki.1008-2786.000397]
 REN Lanhong,ZENG Jian*,ZENG Suiping.Wind Load of Kulangsu Historical and Cultural District Effected by Hilly Terrain[J].Mountain Research,2019,(01):41-52.[doi:10.16089/j.cnki.1008-2786.000397]
点击复制

山地地形对鼓浪屿历史文化街区风荷载作用效应研究()
分享到:

《山地学报》[ISSN:1008-2186/CN:51-1516]

卷:
期数:
2019年01期
页码:
41-52
栏目:
山地环境
出版日期:
2019-03-10

文章信息/Info

Title:
Wind Load of Kulangsu Historical and Cultural District Effected by Hilly Terrain
文章编号:
1008-2786-(2019)1-041-12
作者:
任兰红1曾 坚1*曾穗平23
1. 天津大学 建筑学院,天津 300072; 2. 天津城建大学 建筑学院,天津 300384; 3. 同济大学 建筑与城市规划学院,上海 200092
Author(s):
REN Lanhong1 ZENG Jian1* ZENG Suiping23
1. School of Architecture, Tianjin University, Tianjin 300072, China; 2. School of Architecture, Tianjin Chengjian University, Tianjin 300384, China; 3.School of Architecture and Urban Planning, Tongji University, Shanghai 200092, China
关键词:
鼓浪屿历史文化街区 山地地形 风速 风压 风荷载体型系数 CFD风环境数值模拟
Keywords:
Kulangsu historical and cultural district hilly terrain wind speed wind pressure wind load shape coefficient CFD simulation of wind environment
分类号:
TU312
DOI:
10.16089/j.cnki.1008-2786.000397
文献标志码:
A
摘要:
山地环境中的街区风荷载与平地条件下有明显不同。鼓浪屿历史文化街区处于台风易发地区,对其开展山地环境下风载作用效应的研究对科学保护历史建筑非常必要。本文以鼓浪屿历史文化街区为研究对象,运用ANSYS Fluent进行数值分析山地地形对鼓浪屿风场与风荷载体型系数的影响并提出对该地区已有建筑防风保护与建筑选址的建议。表明:(1)鼓浪屿的高风速、极值加速比、极值负压和极值风荷载体型系数均集中分布在成十字相交的两轴线的各山顶,两轴线是核心线性防风区域,龙头山、鸡母山和笔架山山顶为防风重点。(2)龙头山山顶近地面处加速比最大,对应产生极值风荷载体型系数。(3)两轴线的横风向加速比均大于顺风向,山顶加速效应大于峡谷侧风面大于峡谷底处。(4)山顶处数值模拟得到的风荷载体型系数与规范值差距不大,峡谷处由规范得出的修正系数较数值模拟值偏小。(5)海拔较低的迎风面和背风面山脚风速低,适合建筑选址。龙头山、鸡母山和笔架山山顶区为高风速频发且极值负压产生的区域,是加强建筑检修与维护、提高防风性能的重点,不宜作为建设选址。
Abstract:
The wind loads on the districts in mountainous environment are obviously different from those on flat land. The historical and cultural district in Kulangsu is located in typhoon-prone area, so it is very necessary for the scientific protection of historical buildings to carry out the research on the wind load effect in mountainous environment. Taking the historical and cultural district in Kulangsu as the research object, this paper used ANSYS Fluent to numerically analyze the influence of mountain topography on wind field and wind load shape coefficient of Kulangsu, and put forward some suggestions on the windproof protection and site selection of the existing buildings in this area. The results showed that:(1)The high wind speed, extreme speed-up ratio, extreme negative wind pressure and extreme wind load shape coefficient of Kulangsu were concentratedly distributed in mountain tops of the two cross-intersecting axes. The two axes were the core linear windproof areas, and the tops of Longtou Mountain, Jimu Mountain and Bijia Mountain were the windproof focus.(2)The maximum speed-up ratio is near the ground at the top of Longtou Mountain, which generated extreme wind load shape coefficient correspondingly.(3)The cross-wind speed-up ratios of the two axes were larger than that of the along-wind direction. The speed-up effect on the mountain top was larger than that on the cross-wind plane of the gorge which was larger than that at the bottom of the gorge.(4)The wind load shape coefficient obtained by numerical simulation at the mountain top was not much different from the value in the Load Code for the Design of Building Structure, and the modified coefficient at the gorge obtained from the Load Code for the Design of Building Structure was smaller than the numerical simulation value.(5)The wind speed was low in windward side and mountain foot at the leeside with low elevation, which were appropriate for building site selection. Hilltops of Longtou Mountain, Jimu Mountain and Bijia Mountain were areas with frequently high wind speed and extreme negative wind pressure. Therefore, these areas were the focus of strengthening building maintenance and improvement of windproof performance, and should not be used as construction site selection.

参考文献/References:

[1] 王唯山. 鼓浪屿历史风貌建筑保护规划[J].城市规划,2002,(7):54-58.[WANG Weishan. The preservation planning for the historical buildings in Gulangyu Island, Xiamen[J].City Planning Review, 2002,(7):54-58]
[2] 楼文娟,吴登国,刘萌萌,等. 山地风场特性及其对输电线路风偏响应的影响[J].土木工程学报,2018,51(10):46-55,77.[LOU Wenjuan, WU Dengguo, LIU Mengmeng, et al. Properties of mountainous terrain wind field and their influence on wind-induced swing of transmission lines[J].China Civil Engineering Journal, 2018, 51(10): 46-55, 77]
[3] 胡伟成,杨庆山,张建. 多国规范山地风速地形修正系数对比研究[J].工程力学,2018,35(10):203-211.[HU Weicheng, YANG Qingshan, ZHANG Jian. Comparative study on wind topography factor of hilly terrain by different codes and standards[J].Engineering Mechanics, 2018,35(10):203-211]
[4] 李正良,徐姝亚,肖正直,等. 山地风速地形修正系数沿山坡的详细插值分布[J].湖南大学学报(自然科学版),2016,43(3):23-31.[LI Zhengliang, XU Shuya, XIAO Zhengzhi, et al. Detailed interpolation distribution of hilly wind topographic factor along hillside[J].Journal of Hunan University(Natural Sciences), 2016, 43(3):23-31]
[5] ABDI D S, BITSUAMLAK G T. Wind flow simulations on idealized and real complex terrain using various turbulence models[J].Advances in Engineering Software, 2014,75(9): 30-41.
[6] BLOCKEN B, HOUT AVD, DEKKER J, et al. CFD simulation of wind flow over natural complex terrain: Case study with validation by field measurements for Ria de Ferrol, Galicia, Spain[J].Journal of Wind Engineering and Industrial Aerodynamics, 2015,147(12): 43-57.
[7] MUGHAL M O, LYNCH M, YU F, et al. Forecasting and verification of winds in an East African complex terrain using coupled mesoscale - And micro-scale models[J].Journal of Wind Engineering and Industrial Aerodynamics, 2018,176(5):13-20.
[8] LIU Zhenqing, ISHIHARA T, HE Xuhui, et al. LES study on the turbulent flow fields over complex terrain covered by vegetation canopy[J].Journal of Wind Engineering and Industrial Aerodynamics, 2016,155(8):60-73.
[9] 楼文娟,梁洪超,李正昊,等. 典型山地地形竖向风速分布特征[J].空气动力学学报,2018,36(5):791-797.[LOU Wenjuan, LIANG Hongchao, LI Zhenghao, et al. Vertical wind velocity distribution in typical hilly terrain[J].Acta Aerodynamic Sinica, 2018,36(5):791-797]
[10] 孙毅,李正良,黄汉杰,等. 山地风场中圆形截面超高层建筑风荷载谱[J].重庆大学学报,2011,34(8):24-30.[SUN Yi, LI Zhengliang, HUANG Hanjie, et al. Analysis of wind load spectrum of super tall buildings with round section in hilly terrain wind field[J].Journal of Chongqing University, 2011,34(8):24-30]
[11] 孙毅,李正良,黄汉杰,等. 山地风场平均及脉动风速特性试验研究[J].空气动力学学报,2011,29(5):593-599.[SUN Yi, LI Zhengliang, HUANG Hanjie, et al. Experimental research on mean and fluctuating wind velocity in hilly terrain wind field [J].Acta Aerodynamic Sinica, 2011,29(5):593-599]
[12] 李正良,魏奇科,孙毅. 复杂山地风场幅值特性试验研究[J].工程力学,2012,29(3):184-191,198.[LI Zhengliang, WEI Qike, SUN Yi. Experimental research on amplitude characteristics of complex hilly terrain wind field[J].Engineering Mechanics, 2012,29(3):184-191, 198]
[13] 李正良, 魏奇科, 黄汉杰, 等. 山地超高层建筑风致响应研究[J].振动与冲击,2011,30(5):43-48.[LI Zhengliang, WEI Qike, HUANG Hanjie, et al. Wind-induced response of super tall buildings in hilly terrain [J]. Journal of Vibration and Shock, 2011,30(5):43-48]
[14] 唐昂. 基于实际峡谷地形的近地风场特性研究[D].杭州:浙江理工大学,2015:23-38.[TANG Ang. Study on characteristics of wind field in ground layer on actual canyon terrain[D]. Hangzhou: Zhejiang Sci-Tech University, 2015: 23-38]
[15] 汪汛,周岱,李煜,等. 重檐歇山顶中国古建筑风压与风场数值模拟分析[J].上海交通大学学报,2017,51(11):1287-1296.[WANG Xun, ZHOU Dai, LI Yu, et al. Numerical simulation on wind pressure and wind field of Chinese ancient buildings with multiple-eave and double-pith roof[J].Journal of Shanghai Jiao Tong University, 2017,51(11):1287-1296]
[16] 潘安平. 沿海农村台风灾害区“避难所”优化布局理论与实践研究--以浙江为例[M].北京:中国建筑工业出版社,2010:167.[PAN Anping. Study on the theory and practice of optimization of shelters' layout in rural coastal typhoon-disaster-affected area-a case study of Zhejiang province[M].Beijing: China Architecture & Building Press, 2010:167]
[17] MOHAMED F Y, MESHARI A, MOHAMED A K. Computational Fluid Dynamics(CFD)simulations on the effect of rough surface on atmosphere turbulence flow above hilly terrain shapes[J].Environmental Forensics, 2014,15(2):159-174.
[18] 任兰红. 福建沿海部分历史文化街区缓减台风灾害措施研究[D].天津:天津大学,2018:129.[REN Lanhong. Study of windproof tactic on partial coastal historical and cultural district in Fujian[D].Tianjin: Tianjin University, 2018:129]
[19] 楼文娟,刘萌萌,李正昊,等. 峡谷地形平均风速特性与加速效应[J].湖南大学学报(自然科学版),2016,43(7):8-15.[LOU Wenjuan, LIU Mengmeng, LI Zhenghao, et al. Research on mean wind speed characteristics and speed-up effect in canyon terrain[J].Journal of Hunan University(Natural Sciences), 2016, 43(7): 8-15]
[20] 丁鑫. 山地地形下低矮坡屋面风荷载数值模拟研究[D].重庆:重庆大学,2014:73-74.[DING Xin. Numerical simulation of wind loads on the roof of low-rise gable-roofed buildings in hilly terrain[D].Chongqing: Chongqing University,2014:73-74]
[21] 雷鹰,李涛,张建国,等. 厦门地区台风风场特性的数值模拟[J].工程力学,2014,31(1):122-128. [LEI Ying, LI Tao, ZHANG Jianguo, et al. Numerical simulation of the characteristics of typhoon wind-field in Xiamen region[J].Engineering Mechanics, 2014,31(1):122-128]
[22] 沈国辉,姚旦,楼文娟,等. 单山和双山风场特征的CFD数值模拟[J].湖南大学学报(自然科学版),2016,43(1):37-44.[SHEN Guohui, YAO Dan, LOU Wenjuan, et al. Investigation of the wind field characteristics on isolate hill and two adjacent hills using CFD numerical simulation[J].Journal of Hunan University(Natural Sciences), 2016,43(1): 37-44]

相似文献/References:

[1]梁 志,师 宇,丁伟宸,等.山地地形下激光雷达风速的精度验证与模拟[J].山地学报,2022,(2):317.[doi:10.16089/j.cnki.1008-2786.000674]
 LIANG Zhi,SHI Yu,DING Weichen,et al.Verification of LiDAR Accuracy and Wind Simulation under Mountainous Terrain[J].Mountain Research,2022,(01):317.[doi:10.16089/j.cnki.1008-2786.000674]

备注/Memo

备注/Memo:
收稿日期(Received date):2018-03-03; 改回日期(Accepted date):2019-01-27
基金项目(Foundation item):国家“十三五”重点研发计划(2016YFC0502903); 国家自然科学基金(51438009,51708387); 教育部人文社科基金(17YJCZH013)。[National Key Research and Development Program of China for the 13th Five-year Plan Period(2016YFC0502903); National Nature Science Foundation of China(51438009, 51708387); Ministry of Education of Humanities and Social Science Foundation(17YJCZH013)]
作者简介(Biography):任兰红(1986-),女,山东临沂人,博士生,主要研究方向:建筑风环境。[REN Lanqing(1986-), female, born in Linyi, Shandong province, Ph.D. candidate, specialized in wind environment of architecture] E-mail:qlyy222@126.com
*通讯作者(Corresponding author):曾坚(1957-),男,博士,教授,研究方向:生态城市与防灾减灾。[ZENG Jian(1957-), male, Ph.D. professor, specialized in ecological city and disaster prevention and mitigation] E-mail: 13602058416@vip.163.com
更新日期/Last Update: 2019-01-30