G60科创云廊单层铝合金网壳结构设计关键问题分析
引用文献:
周健 李彦鹏 崔家春. G60科创云廊单层铝合金网壳结构设计关键问题分析[J]. 建筑结构,2022,48(09):74-80.
ZHOU Jian LI Yanpeng CUI Jiachun. Key issues in single-layer aluminum lattice shell structure design of the G60 Science and Technology Innovation Cloud Gallery[J]. Building Structure,2022,48(09):74-80.
摘要:介绍了G60科创云廊大跨自由曲面单层铝合金网壳结构设计中的几个关键问题,包括结构方案的确定过程、自由曲面单层网格结构的形态构建方法、网格的布置和优化、超长外露结构的温度应力,以及无覆盖网格结构风荷载的确定、盘式节点抗剪加强和刚度的考虑、网壳的整体稳定及树状柱的极限承载力分析等。结果表明,所采用的形态构建方法合理有效,能够得到受力高效且符合建筑对外形期望的理想形态;构件网格的布置符合力流走向且兼顾了透风率和构件长细比的需求;温度效应的不利影响通过取消长方向冗余构件、合理布置相对低膨胀系数的钢构件得到明显缓解;可采用实体风洞测力与数值风洞测压相结合的方式确定镂空网格结构的风荷载;增设一字或十字腹板连接板的方式可以有效加强传统盘式节点的抗剪承载力。
关键词:铝合金单层网壳,自由曲面形态构建,网格优化,温度效应,无覆盖结构,风荷载,整体稳定
基金:上海市优秀技术带头人计划资助(21XD1430400)。
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[3] 周健,张耀康,王帅,等.长沙冰雪世界跨坑结构的选型及其形态创建[J].建筑钢结构进展,2017,19(5):77-83.
[4] 李彦鹏,周健.基于 GH 平台的自由曲面形态构建与优化[J].建筑结构,2019,49(S1):328-332.
[5] 李欣.自由曲面结构的形态学研究[D].哈尔滨:哈尔滨工业大学,2011.
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[8] 崔家春,周健,潘钧俊.大跨度镂空网格结构风荷载研究[J].建筑结构,2020,50(18):16-21.
[9] 郑德乾,刘帅永,顾明,等.大跨镂空网格屋盖风荷载数值模拟研究[J].郑州大学学报(工学版),2021,42(3):93-98.
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Key issues in single-layer aluminum lattice shell structure design of the G60 Science and Technology Innovation Cloud Gallery
Abstract: Several key issues in the design of a large span free-form single-layer aluminum lattice shell structure of the G60 Science and Technology Innovation Cloud Gallery was introduced, including the structural scheme decision process, morphology and optimization of the free-form single-layer grid structure, topology and optimization of the grid structure, large temperature stress caused by ultra-long exposed structure, the approach to determine the wind load of the unclad grid structure, shear bearing capacity strengthening of plate joints and its stiffness consideration, the overall stability of the reticulated shell and the ultimate bearing capacity analysis of the tree column, etc. The results show that the adopted morphology method is reasonable and effective, and can obtain the form with high efficiency and in line with the architect's expectations. The layout of the component grid is in line with the force flow direction and takes into account the requirements of air permeability and component slenderness ratio. The adverse effects of temperature effects are alleviated by canceling redundant components in the long direction and reasonably arranging steel components with relatively low expansion coefficients. The combination of physical wind tunnel force measurement and numerical wind tunnel pressure measurement is used to determine the wind load of the hollow grid structure; the addition of a straight or cross web connecting plate can effectively enhance the shear bearing capacity of traditional plate joints.
Keywords: single-layer aluminum latticed shell; free-form morphology and optimization; grid optimization; temperature effect; wind load on unclad structure; overall stability
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