- 摘 要
-
(1 同济大学土木工程学院, 上海 200092; 2 同济大学建筑设计研究院(集团), 上海 200092;3 北京江河幕墙股份有限公司, 北京 101300)
[摘要]结合杭州火车东站工程,对温差引起的巨型斜柱外包不锈钢幕墙温度应力及其内部钢龙骨支撑的内力效应进行了研究。通过不同季节的现场监测,得到了相应部位的应力、轴力随温度及时间变化的规律。采用ANASYS有限元软件建立了巨型斜柱、幕墙龙骨、不锈钢板的整体模型,计算了不同温差工况下不锈钢板应力及龙骨轴力的变化。通过现场监测及数值模拟的对比研究,验证了该幕墙体系能经受较大室外温度变化,且表面变形不明显,能满足建筑结构的正常使用要求。
[关键词]钢结构; 巨型斜柱; 不锈钢; 幕墙; 温度效应
中图分类号:TU391,TU511.3文献标识码:A文章编号:1002-848X(2014)01-0032-06
Study on temperature effects for outsourcing stainless steel curtain wall system of the mega steel truss column
Jia Bin1, Lei Ke1, Yang Bin1, Yang Zonglin2, Zhang Qilin1, Chen Deyi3
(1 School of Civil Engineering, Tongji University, Shanghai 200092, China; 2 Tongji Architectural Design(Group)Co., Ltd., Shanghai 200092, China; 3 Beijing Jangho Curtain Wall Co., Ltd., Beijing 101300, China)
Abstract: Study was carried on the thermal stress, internal force effect caused by temperature difference about outsourcing stainless steel curtain wall of the mega steel truss column based on Hangzhou East Railway Station project.The variation rule of stress and axial force in corresponding position of curtain wall system was obtained by site monitoring in different seasons. An entire mathematical model of mega-column, curtain keel and corrosion resistant plate was established by ANASYS, furthermore the stainless steel sheets and steel keels were calculated at different temperature conditions. Through comparative study between site monitoring and numerical simulation, it has been verified that the curtain wall system can withstand the test of ambient temperatures, and deformation of the curtain wall surface system is much small. In general, this curtain wall system has good performance to meet the demand of normal use.
Keywords: steel structure; mega-column; stainless steel; curtain wall; temperature effect
*国家十二五科技支撑计划项目(2011BAJ08B10)。
作者简介:贾斌,博士研究生,Email:dr_jiabin@sina.com。
参考文献
[1]宋秋之,刘志海.我国玻璃幕墙发展现状及趋势[J].玻璃深加工,2009(2):29-31.
[2]陆津龙,左蔚文,刘雄,等. 国内外幕墙的发展历史及现状[J].住宅科技,2009(4):46-49.
[3]范重,王喆,唐杰.国家体育场大跨度钢结构温度场分析与合拢温度研究[J].建筑结构学报,2007,28(2):32-40.
[4]AL SANEA SAMI A. Thermal performance of building roof element[J]. Building and Enviroment,2002, 37(7):665-675.
[5]徐芝纶. 弹性力学[M]. 4版. 北京:高等教育出版社,2006.
[6]TONG M, THAM L G, AU F T K, et al. Numerical modeling for temperature distribution in steel bridges[J]. Computers and Structures, 2000,(79):583-593.
[7]郑毅敏,刘永璨,卢宇航,等. 某体育场环形超长结构温度应力分析[J].结构工程师,2007,23(4):30-34.
[8]李红梅,金伟良,叶甲醇,等.建筑围护结构的温度场数值模拟[J].建筑结构学报,2004,25(6):93-98.
[9]杨庆祥,张运坤,张跃,等. 304不锈钢热处理过程温度场和应力场数值模拟[J].材料热处理学报,2009,30(2):183-186.
[10]张玉平,杨宁,李传习. 无铺装层钢箱梁日照温度场分析[J]. 工程力学,2011,28(6):156-162.
