超高层连体分叉核心筒整体提升钢平台模架体系研究
引用文献:
陈逯浩 朱毅敏 徐磊 王少纯. 超高层连体分叉核心筒整体提升钢平台模架体系研究[J]. 建筑结构,2022,48(12):115-120,138.
CHEN Luhao ZHU Yimin XU Lei WANG Shaochun. Research on overall lifting steel platform formwork system for super high-rise with conjoined-bifurcated core tube[J]. Building Structure,2022,48(12):115-120,138.
摘要:整体提升钢平台模架体系以其封闭性好、安全性高、承载能力强、施工速度快等优点,越来越多地应用于超高层结构核心筒的建造中。以吴江绿地中心超高层分叉核心筒钢平台结构设计为例,针对钢平台结构的设计要点进行分析,系统阐述了钢平台分体及组合设计理念。在完成钢平台设计的同时,利用有限元软件分别在正常工作状态下和爬升状态下对钢平台结构进行验算,包括对整体结构及薄弱点进行有限元计算分析。计算结果表明:正常工作状态下,钢平台结构的最大水平位移能够满足设计要求。爬升工作状态下,钢平台结构的最大水平位移、牛腿结构的承载力均满足设计要求,说明钢平台结构设计合理安全,可以满足连体分叉核心筒结构的施工需要。
关键词:整体提升钢平台模架体系;连体分叉核心筒;分体组合设计;装备结构设计;核心筒施工
基金:国家重点研发计划项目(2018YFC0705800)。
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参考文献[1] 吕西林,程明.超高层建筑结构体系的新发展[J].结构工程师,2008,24(2):99-106.
[2] 龚剑,房霆宸,夏巨伟.我国超高建筑工程施工关键技术发展[J].施工技术,2018,47(6):19-25.
[3] 整体爬升钢平台模架技术标准:JGJ 459—2019[S].北京:中国建筑工业出版社,2019.
[4] 超高层建筑施工安全风险评估与控制标准:T/CECS 671—2020[S].北京:中国建筑工业出版社,2020.
[5] 骆艳斌,徐伟,周虹,等.超高层建筑模板体系连续梁模型动力特性区间分析[J].结构工程师,2006,22(2):33-36,12.
[6] 赵一鸣.整体钢平台模架装备的远程安全监控技术研究[J].建筑施工,2019,41(7):1292-1294.
[7] 范峰,王化杰,金晓飞,等.超高层施工监测系统的研发与应用[J].建筑结构学报,2011,32(7):50-59.
[8] LI Q S,LI X,HE Y C.Monitoring wind characteristics and structural performance of a supertall building during a landfall typhoon[J].Journal of Structural Engineering,2016,142(11):04016097.
[9] YUE F,YUAN Y,LI G Q,et al.Wind load on integral-lift scaffolds for tall building construction[J].Journal of Structural Engineering,2005,131(5):816-824.
[10] 朱佳伟,赵金城,黄玉林.超高层建筑施工整体钢平台钢梁螺栓节点刚度影响因素研究[J].钢结构,2017,32(3):41-46.
[11] 王庆春.整体爬升钢平台模架伸缩式竖向支撑装置受力性能分析及设计方法[J].建筑施工,2019,41(8):1517-1520.
[12] 左自波,潘曦,黄玉林,等.超高层ICCP安全监测与控制的预警指标研究[J].中国安全科学学报,2020,30(1):53-60.
[2] 龚剑,房霆宸,夏巨伟.我国超高建筑工程施工关键技术发展[J].施工技术,2018,47(6):19-25.
[3] 整体爬升钢平台模架技术标准:JGJ 459—2019[S].北京:中国建筑工业出版社,2019.
[4] 超高层建筑施工安全风险评估与控制标准:T/CECS 671—2020[S].北京:中国建筑工业出版社,2020.
[5] 骆艳斌,徐伟,周虹,等.超高层建筑模板体系连续梁模型动力特性区间分析[J].结构工程师,2006,22(2):33-36,12.
[6] 赵一鸣.整体钢平台模架装备的远程安全监控技术研究[J].建筑施工,2019,41(7):1292-1294.
[7] 范峰,王化杰,金晓飞,等.超高层施工监测系统的研发与应用[J].建筑结构学报,2011,32(7):50-59.
[8] LI Q S,LI X,HE Y C.Monitoring wind characteristics and structural performance of a supertall building during a landfall typhoon[J].Journal of Structural Engineering,2016,142(11):04016097.
[9] YUE F,YUAN Y,LI G Q,et al.Wind load on integral-lift scaffolds for tall building construction[J].Journal of Structural Engineering,2005,131(5):816-824.
[10] 朱佳伟,赵金城,黄玉林.超高层建筑施工整体钢平台钢梁螺栓节点刚度影响因素研究[J].钢结构,2017,32(3):41-46.
[11] 王庆春.整体爬升钢平台模架伸缩式竖向支撑装置受力性能分析及设计方法[J].建筑施工,2019,41(8):1517-1520.
[12] 左自波,潘曦,黄玉林,等.超高层ICCP安全监测与控制的预警指标研究[J].中国安全科学学报,2020,30(1):53-60.
Research on overall lifting steel platform formwork system for super high-rise with conjoined-bifurcated core tube
Abstract: With the advantages of good sealing, high safety, strong bearing capacity and fast construction speed, overall lifting steel platform formwork system is more and more used in the construction of core tube of super high-rise structure. Based on the structural design of super high-rise bifurcation core tube steel platform in Wujiang Green Space Center, the key points in the structural design of steel platform were analyzed, the design concept of split and composite structure of steel platform was expounded systematically. The design of steel platform was completed, the finite element calculation analysis of its overall structure and weak points were carried out under normal working conditions and the climbing working state. The results of calculation show that under normal working conditions, the maximum horizontal displacement of the steel platform structure can meet the design requirements. Under the climbing working state, the maximum horizontal displacement response of the steel platform structure and the von Mises effective stress in the local compression zone of the corbel structure can meet the design requirements. The safety and the rationality of the steel platform were verified. It can meet the construction needs of the conjoined-bifurcated core tube structure.
Keywords: overall lifting steel platform formwork system; conjoined-bifurcated core tube; split combination design; equipment structure design; core tube construction
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