Simulation Analysis of Steel Structure Construction of the Main Building Roof of Zhuhai Airport Terminal II

Xiuhai Long; Tong Ou; Songwei Lin; Lele Zhang; Xuyang Shi; Junnan Dai

doi:10.3724/j.gjgS22112501

Volume 39 Issue 3

Mar. 2024

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Xiuhai Long, Tong Ou, Songwei Lin, Lele Zhang, Xuyang Shi, Junnan Dai. Simulation Analysis of Steel Structure Construction of the Main Building Roof of Zhuhai Airport Terminal II[J]. STEEL CONSTRUCTION(Chinese & English), 2024, 39(3): 38-46. doi: 10.3724/j.gjgS22112501

Citation:

Xiuhai Long, Tong Ou, Songwei Lin, Lele Zhang, Xuyang Shi, Junnan Dai. Simulation Analysis of Steel Structure Construction of the Main Building Roof of Zhuhai Airport Terminal II[J]. STEEL CONSTRUCTION(Chinese & English), 2024, 39(3): 38-46. doi: 10.3724/j.gjgS22112501

Citation:

Xiuhai Long, Tong Ou, Songwei Lin, Lele Zhang, Xuyang Shi, Junnan Dai. Simulation Analysis of Steel Structure Construction of the Main Building Roof of Zhuhai Airport Terminal II[J]. STEEL CONSTRUCTION(Chinese & English), 2024, 39(3): 38-46. doi: 10.3724/j.gjgS22112501

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Simulation Analysis of Steel Structure Construction of the Main Building Roof of Zhuhai Airport Terminal II

doi: 10.3724/j.gjgS22112501

1. Guangdong Architectural Design and Research Institute Co., Ltd., Guangzhou 510010, China;
2. School of Civil Engineering, Guangzhou University, Guangzhou 510006, China;
3. China Construction Second Construction Engineering Bureau Co., Ltd., Beijing 100160, China;
4. Zhejiang Southeast Space Frame Group, Hangzhou 311209, China

Received Date: 2022-11-25
Available Online: 2024-05-31
Publish Date: 2024-03-22

Abstract

Abstract

The grid structure is a spatial grid structure with various forms. Because of its advantages of good force performance, light weight, large rigidity, good seismic performance, low cost and easy forming, it is widely used in the roof of terminals, hangars, gymnasiums, theaters, exhibition halls, stations and other buildings. The roof of the main building of Terminal 2 of Zhuhai Airport adopts a largespan continuous ultra-long variable curvature hyperboloid local evacuation steel grid structure system. The modeling characteristics and structural system composition of the roof are introduced, and the construction process is carried out by partition and blocking cumulative lifting process according to its complexity, and the construction sequence is proposed and the lifting scheme is given. The construction steps of the steel structure of the main building roof are expounded, the construction steps of each step are simulated and analyzed, and the design load is applied to the grid structure after the unloading of the supporting frame, and the displacement and stress indicators of the whole process of the steel structure roof construction of the main building are obtained, and the performance of the steel structure of the main building based on construction simulation under the design and use load is evaluated. The construction technology that combines the whole process monitoring of the grid frame with the construction simulation is adopted, and the lifting status and block size of the grid are adjusted in real time through the comparison and analysis of the stress and strain values in the actual monitoring data and the simulation, so as to realize the accurate control of the force state of the grid lifting process. The results show that the construction scheme of the steel structure roof of the main building is feasible, and the structural deformation and internal force meet the requirements during the lifting process. After considering the influence of the construction process, the vertical deflection of mid span of the steel grid increases, and reliable measures should be taken to reduce the adverse effects caused by the increase of deflection; in the process from the beginning of construction to the final forming of the steel grid frame, the force mode of the local member changes from length to slenderness ratio control to force control, and the cross-section needs to be enlarged; it is necessary for the large-span grid frame to be reviewed by using the load input construction simulation analysis model according to the design after the construction simulation unloads the tire frame. The monitoring results show that the measured stress displacement of the grid frame is basically consistent with the construction simulation, which indicates the accuracy of the construction simulation analysis.

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References(18)

References

[1]	张连飞,区彤,刘雪兵,等.顺德德胜体育馆含悬挂斗屏索穹顶结构防连续倒塌分析研究[J].钢结构(中英文), 2022, 37(1):21-30.
[2]	张连飞,区彤,谭坚,等.广州新白云国际机场T2航站楼钢屋盖结构设计[J].建筑结构,2016,46(21):64-69.
[3]	莫涛涛.双向大跨钢屋盖网架结构整体提升关键技术研究[J].钢结构(中英文),2019,34(6):78-82.
[4]	唐阳明,李咏安.大跨度钢屋盖整体提升施工数值分析及控制研究[J].钢结构,2018,33(9):105-110.
[5]	曾令权,郭正兴,罗斌,等.潮汕机场航站楼钢屋盖整体提升技术[J],施工技术,2011(1):70-72.
[6]	李建全,陈至诚,匡礼毅,等.浦东机场波音机库钢屋盖结构液压整体提升施工技术[J].钢结构,2010,25(8):65-67 ,82.
[7]	陈适才,闫维明,周海洋,等.首都机场大跨网架结构累积提升施工技术的相关问题分析[J].工业建筑, 2010, 40(11):105-110.
[8]	陈冬冬.大跨度网架结构整体提升技术研究与应用[D].重庆:重庆大学,2010.
[9]	程浩,苏铁斌,邹义任.大跨度钢网架与钢桁架组合结构整体提升技术[J].钢结构,2014,29(2):57-61.
[10]	黄三珊.大跨度钢网架结构整体提升施工关键技术及BIM应用研究[D].广州:华南理工大学,2014.
[11]	范重,刘先明,胡天兵,等.国家体育场钢结构施工过程模拟分析[J].建筑结构学报,2007, 28(2):134-143.
[12]	周观根,张珈铭,刘坚,等.杭州奥体博览中心主体育场结构施工模拟分析[J].施工技术,2014,43(8):1-5.
[13]	田黎敏,郝际平,李存良,等.大跨度钢屋盖结构的整体提升施工技术[J].建筑科学,2014(11):103-106,111.
[14]	李祥,卢彩霞.大跨度钢屋盖网架结构施工关键技术[J].建筑施工,2015(11):1280-1282.
[15]	Guo M,Sun M X,Pan D,et al. High-precision detection method for large and complex steel structures based on global registration algorithm and automatic point cloud generation[J/OL]. Measurement, 2020,172[2022-11-25]. https://doi.org.10.1016/j.measurement.2020.108765.
[16]	谭坚,张连飞,区彤,等.保利国际广场二期施工模拟分析与健康监测[J].建筑结构,2016(增刊2):574-580.
[17]	Lan T T,Xue S D,Wang B B. Special issue for recent spatial structures in China[J]. Journal of the International Association for Shell and Spatial Structures,2006,47(2):79-88.
[18]	中华人民共和国住房和城乡建设部.钢结构设计标准:GB 50017-2017[S].北京:中国建筑工业出版社,2018.