苏州第二工人文化宫结构变刚度设计思考与实践
引用文献:
张谨 杨律磊 路江龙 沈晓明. 苏州第二工人文化宫结构变刚度设计思考与实践[J]. 建筑结构,2022,48(20):104-111.
ZHANG Jin YANG Lülei LU Jianglong SHEN Xiaoming. Research and application on structural design of Suzhou No.2 Workers’ Cultural Palace considering variable stiffness[J]. Building Structure,2022,48(20):104-111.
摘要:对于边界条件复杂的结构,其在施工、使用、加固与改造等过程中结构刚度将发生较大变化,故应采用变刚度的设计思想。以苏州第二工人文化宫为例,针对其不同的单体结构与不同的状态提出了相应的变刚度设计方案。苏州第二工人文化宫地上分为A区(场馆区)、B区(中庭及影剧院区)、C区(游泳馆及配套区)三个大区。A区屋面采用大跨度钢梁+轻钢屋面形式,采用常规设计方法时钢梁端部弯矩较大。采用变刚度设计方法,通过施工过程措施释放了恒载下的梁端弯矩,有效降低了焊缝、螺栓与埋件的设计需求。B区结构连接关系复杂,各单体动力特性差异较大,而中庭结构无法与其相邻建筑实现脱开设计,采用铅芯橡胶支座连接中庭与相邻单体,实现了在不同荷载工况下的变刚度设计,通高柱应力比小于设计目标,中庭屋面变形满足规范要求。C区室内游泳馆屋盖为张弦木梁结构,通过多种模型对比分析,发现考虑木撑杆蠕变效应与初始缺陷造成的刚度变化将导致屋盖结构竖向变形、木撑杆与木梁应力的增大以及钢拉索应力的减小,且初始缺陷的影响更为显著。
关键词:苏州第二工人文化宫;变刚度设计;施工过程;铅芯橡胶支座;蠕变;初始缺陷
基金:
尊敬的用户,本篇文章需要2元,点击支付交费后阅读
限时优惠福利:领取VIP会员
全年期刊、会议视频
全部免费!培训视频打折!
全年期刊、会议视频
全部免费!培训视频打折!
参考文献[1] 建筑结构荷载规范:GB 50009—2012[S].北京:中国建筑工业出版社,2012.
[2] 王建,李烨,李青,等.加固、改造设计的变刚度分析方法[J].建筑结构,2007,37(S1):193-195.
[3] 建筑抗震设计规范:GB 50010—2010[S].2016年版.北京:中国建筑工业出版社,2016.
[4] 叶智武,罗永峰,陈晓明,等.施工模拟中分步建模法的改进实现方法及应用[J].同济大学学报(自然科学版),2016,44(1):73-80.
[5] 王坚.铅芯橡胶支座动力学特性及其在钢结构中减震应用研究[D].北京:北京交通大学,2017.
[6] 刘非微.意杨旋切板胶合木梁在长期荷载作用下的受力性能研究[D].扬州:扬州大学,2018.
[7] 冯远,龙卫国,欧加加,等.大跨度胶合木结构设计探索[J].建筑结构,2021,51(17):43-49.
[8] 邓彪.荷载、含水率及温度作用下桉树木材蠕变特性研究[D].长沙:中南林业科技大学,2013.
[9] Eurocode 5:design of timber structures part 1-1:general common rules and rules for buildings:ENV 1995-1-1[S].Brussels:European Committee for Standardization,2014.
[10] Eurocode 5:design of timber structures part 1-2:general-structural fire design:ENV 1995-1-2[S].Brussels:European Committee for Standardization,2004.
[11] 钢结构设计标准:GB 50017—2017[S].北京:中国建筑工业出版社,2018.
[2] 王建,李烨,李青,等.加固、改造设计的变刚度分析方法[J].建筑结构,2007,37(S1):193-195.
[3] 建筑抗震设计规范:GB 50010—2010[S].2016年版.北京:中国建筑工业出版社,2016.
[4] 叶智武,罗永峰,陈晓明,等.施工模拟中分步建模法的改进实现方法及应用[J].同济大学学报(自然科学版),2016,44(1):73-80.
[5] 王坚.铅芯橡胶支座动力学特性及其在钢结构中减震应用研究[D].北京:北京交通大学,2017.
[6] 刘非微.意杨旋切板胶合木梁在长期荷载作用下的受力性能研究[D].扬州:扬州大学,2018.
[7] 冯远,龙卫国,欧加加,等.大跨度胶合木结构设计探索[J].建筑结构,2021,51(17):43-49.
[8] 邓彪.荷载、含水率及温度作用下桉树木材蠕变特性研究[D].长沙:中南林业科技大学,2013.
[9] Eurocode 5:design of timber structures part 1-1:general common rules and rules for buildings:ENV 1995-1-1[S].Brussels:European Committee for Standardization,2014.
[10] Eurocode 5:design of timber structures part 1-2:general-structural fire design:ENV 1995-1-2[S].Brussels:European Committee for Standardization,2004.
[11] 钢结构设计标准:GB 50017—2017[S].北京:中国建筑工业出版社,2018.
Research and application on structural design of Suzhou No.2 Workers’ Cultural Palace considering variable stiffness
Abstract: For the structure with complex boundary conditions, the structural stiffness changes greatly in the process of construction, use, reinforcement and transformation, so the design idea of variable stiffness should be adopted. Taking Suzhou No. 2 Workers' Cultural Palace as an example, according to its different unit structures and different states, the corresponding variable stiffness design schemes were put forward. Suzhou No.2 Workers' Cultural Palace was divided into three areas: Area A(venue area), Area B(atrium and cinema area), and Area C(natatorium and supporting area). The roof of Area A adopted the form of large-span steel beam + light steel roof, and the bending moment of the end of the steel beam was large when the conventional design method is adopted. With the method of variable stiffness design, the beam end bending moment under dead load was released through the construction process measures, which effectively reduced the design requirements of welds, bolts and embedded parts. The structural connection relationship of Area B was complex, and the dynamic characteristics of each unit were quite different. However, the atrium structure could not be designed to be separated from its adjacent buildings. The lead-core rubber bearing was used to connect the atrium and the adjacent monomers, and the variable stiffness design under different load conditions was realized. The full-height column stress ratio was less than the design target, and the atrium roof deformation met the specification requirements. The roof of the indoor swimming pool in Area C was the structure of stretched strings and wooden beams. Through the comparative analysis of various models, it shows that considering the creep effect of the wooden struts and the stiffness change caused by the initial defects leads to the vertical deformation of the roof structure, the increase of stress of the wooden struts and the wooden beams, and the decrease of steel cable stress, and the influence of initial defects is more significant.
Keywords: Suzhou No.2 Workers' Cultural Palace; variable stiffness design; construction process; lead-core rubber bearing; creep; initial defect
390
0
0