钢框架-偏心支撑结构消能梁暗置侧向支撑设计

在钢框架-偏心支撑结构中,针对钢结构住宅等建筑中不能接受常规消能梁侧向支撑的情况,设计了一种在消能梁段端部的楼板内设置型钢连接件及暗梁组成的暗置侧向支撑。有限元模拟分析表明,在规范规定的消能梁段下翼缘侧向水平荷载的作用下,该消能梁暗置侧向支撑能显著减小消能梁的扭转变形和侧向弯曲变形;在考虑消能梁上局部楼板失效的情况下,暗置侧向支撑也能提供消能梁合适的扭转约束刚度。通过某工程的原位静荷载试验,验证了该暗置支撑对消能梁发挥的预期侧向支撑作用。

首钢冬奥广场N3-2转运站抗震加固设计

首钢冬奥广场N3-2转运站拟改造为办公性质的民用建筑,并要求保留原有工业风貌。根据检测鉴定报告结果,既有构筑物综合安全性等级为C_(eu)级,在后续使用年限内综合抗震能力不满足要求,必须采取加固措施。本工程采用屈曲约束支撑既解决了改造后建筑高度超限的问题;同时提高结构的阻尼比,减小了地震作用,一定程度上降低了结构的加固量,提高工程经济效益。框架柱采用外包型钢法加固,既解决了柱轴压比超限的问题,也提高了柱承载力。通过以上措施,将工业构筑物改造为民用建筑,同时又实现了保留原有工业风貌,对加固改造工程有一定的借鉴意义。

Multi-scale analysis of subgrid stress and energy dissipation in turbulent channel flow

In present study, the subgrid scale （SGS） stress and dissipation for multiscale formulation of large eddy simulation are analyzed using the data of turbulent channel flow at Ret = 180 obtained by direct numerical simulation. It is found that the small scale SGS stress is much smaller than the large scale SGS stress for all the stress components. The dominant contributor to large scale SGS stress is the cross stress between small scale and subgrid scale motions, while the cross stress between large scale and subgrid scale motions make major contributions to small scale SGS stress. The energy transfer from resolved large scales to subgrid scales is mainly caused by SGS Reynolds stress, while that between resolved small scales and subgrid scales are mainly due to the cross stress. The multiscale formulation of SGS models are evaluated a priori, and it is found that the small- small model is superior to other variants in terms of SGS dissipation.

BRB加固对高层砼框-剪结构减震影响

根据防屈曲耗能支撑的工作原理与力学性能,进行既有高层框-剪结构布置防屈曲耗能支撑研究.以BRB承担层剪力占比为设计依据,使用SAP2000结构非线性有限元软件研究了单斜式和倒V式两种不同布置形式下,各3种竖向不同楼层布置方案结构动力时程响应、BRB耗能占比、剪力墙应力分布等特点.分析表明:在结构下部布置防屈曲耗能支撑具有减震作用;罕遇地震作用下,结构下部布置防屈曲耗能支撑不仅能够承担较大耗能,也对结构峰值响应下的剪力墙应力的减幅最大,该布置方案可为高层框-剪结构布置防屈曲耗能支撑的工程实践提供参考.

Damping characteristics of friction damped braced frame and its effectiveness in the mega-sub controlled structure system

Based on energy dissipation and structural control principle, a new structural configuration, called the megasub controlled structure （MSCS） with friction damped braces （FDBs）, is first presented. Meanwhile, to calculate the damping coefficient in the slipping state a new analytical method is proposed. The damping characteristics of one-storey friction damped braced frame （FDBF） are investigated, and the influence of the structural parameters on the energy dissipation and the practical engineering design are discussed. The nonlinear dynamic equations and the analytical model of the MSCS with FDBs are established. Three building structures with different structural configurations, which were designed with reference to the conventional mega-sub structures such as used in Tokyo City Hall, are comparatively investigated. The results illustrate that the structure presented in the paper has excellent dynamic properties and satisfactory control effectiveness.

采用牺牲耗能支撑的钢框架-支撑结构抗震性能分析

钢支撑是钢框架-支撑结构中重要的抗侧力构件,研发新型支撑对改进结构的抗震性能具有重要意义。本文以15层钢支撑框架结构为研究对象,采用屈曲约束支撑(BRB)和牺牲-耗能支撑(SED)对比分析结构的抗震性能。弹塑性分析结果表明,BRB始终保持着较高的屈服后强度,结构中与支撑相连的梁、柱在后期承受了附加的轴力,增加了主要结构构件耗能的比例。牺牲-耗能(SED)支撑在达到峰值荷载后,其牺牲元件退出工作,承载力得到有控制的降低,减少了相连框架柱后期所受轴力,使得主结构中的塑性铰得到了一定程度的减少,进而主动吸引更多地震能量消耗在支撑中,达到了在强震作用下更好保护主体结构的目的。

Development and subassemblage cyclic testing of hybrid buckling-restrained steel braces

Buckling-restrained braced frames(BRBFs) are vulnerable to relatively higher post-earthquake residual drifts under high intensity ground shakings. This is primarily due to the low axial elastic and post-elastic stiffness of bucklingrestrained braces(BRBs) satisfying the design force demand requirements. In the present study, a hybrid buckling restrained bracing system consisting of a short yielding core length BRB component and a conventional buckling-type brace component connected in series has been developed with an aim to increase the axial stiffness of braces. This study is focused on the experimental investigation of six hybrid bucking restrained braces(HBRBs) to investigate their overall behavior, loadresisting capacity, strength-adjustment factors and energy dissipation potential. The main parameters varied are the crosssectional area, the yielding length of core elements as well as the detailing of buckling-restraining system of short yielding core length BRBs. Test results showed that the HBRBs with yielding core length in the range of 30% of work-point to workpoint lengths withstood an axial strain of 6% without any instability and can deliver stable and balanced hysteretic response and excellent energy dissipation under reversed cyclic loading conditions.

Seismic performance testing of reinforcement concrete frames strengthened with Y-eccentrically brace

Two single-storey single-span reinforcement concrete （RC） frame structures strengthened with Y-eccentrically brace were designed and manufactured to be 1/3 scale. The pseudo-dynamic testing method was used to study the mechanical characteristics and the seismic performance under E1-Centro earthquake action with different peak acceleration adjusted by China＇s Code for Seismic Design of Buildings. The test results indicate that RC frame structures strengthened with Y- eccentrically steel brace present perfect seismic performance under strong earthquake action owing to the good ductility, strong bearing capability and fine energy absorbing capability provided by energy dissipation element and high lateral stiffness provided by diagonal braces. The seismic performance is also affected by the length of outsourcing steel at the joint between energy dissipation element of eccentric steel brace and RC frame beam. The joint should be considerably designed to make sure that shear failure can firstly occur in energy dissipation element.

Design of Dissipative Braces for an Existing Strategic Building with a Pushover Based Procedure

The research presented in this paper deals with the seismic protection of existing frame structures by means of passive energy dissipation. An iterative displacement-based procedure, based on capacity spectrum, to design dissipative bracings for seismic retrofitting of the frame structures is described, and some applications are discussed. The procedure can be used with any typology of dissipative device and for different performance targets. In this work, the procedure has been applied, with both traditional pushover （load profile proportional to first mode） and multimodal pushover, to an existing RC （reinforced concrete） frame building. In the application, the buckling restrained braces have been used in order to prevent damages to both the structure and non structural elements. The use of multimodal pushover proves to be more effective than pushover based on single mode in case of medium rise RC frame building （higher than 30 m） but, once this building is retrofitted, and therefore regularized, with a bracing system, the difference between using monomodal or multimodal pushover becomes insignificant.

近场脉冲型地震作用下附加支撑双柱式摇摆桥墩的抗震性能研究

为了解决摇摆桥墩承载力和耗能能力不足的问题,该文提出一种附加人字形支撑的双柱式摇摆桥墩结构,支撑为纯耗能支撑或自复位耗能支撑,支撑通过连接装置安装在双柱式摇摆桥墩的盖梁和承台之间。为了研究新型附加人字形支撑双柱式摇摆桥墩的抗震性能,对其进行拟静力分析,将双柱式现浇桥墩和双柱式纯摇摆桥墩作为对比模型,研究附加纯耗能支撑和自复位耗能支撑双柱式摇摆桥墩的滞回性能;分别对这四种桥墩结构进行动力时程分析,探究这四种桥墩在近场对称脉冲、近场非对称脉冲和远场无脉冲地震动作用下的动力响应。研究结果表明:附加支撑的双柱式摇摆桥墩中的墩柱仍具有摇摆机制,可有效避免墩身出现塑性铰发生严重的损伤破坏,同时附加的支撑可以显著提高桥墩的承载能力和耗能能力,有效降低桥墩结构的位移响应,特别是自复位耗能支撑还可额外为桥墩提供自恢复力,有效提高结构的抗震性能。

新型切口厚壁钢管耗能支撑抗震性能研究及参数分析

为了解决现有金属耗能装置连接复杂或容易发生非预期破坏等问题,提出了一种新型切口厚壁钢管耗能支撑(energy-dissipation brace with notched thick-walled steel tube,EDB-NTWST)。该支撑主要依靠首次提出的切口厚壁钢管(notched thick-walled steel tube,NTWST)耗能,震后仅需更换NTWST即可完成修复,因而可提高结构震后修复速度。针对切口厚壁钢管的不同布置方式,给出了两种支撑的构造形式,并推导了NTWST简化力学分析方法。通过试验研究,验证了理论计算及数值模拟的准确性。采用参数化分析方法,设计了16个NTWST试件,在单调加载和循环荷载下分别对其进行了有限元分析。结果表明:EDB-NTWST的滞回曲线饱满,变形能力强,延性高,可将损伤集中于NTWST上,能够实现可重复使用的目标;简化力学分析方法与试验结果吻合较好,可用于EDB-NTWST的初步设计;NTWST的力学性能能够通过调整其设计参数进行改变,承载力的提高可通过加大耗能环厚度来实现,增加耗能环的数量可以显著提高其变形能力,增加耗能环的宽度并减小中径,是提高NTWST延性的有效方法。

自复位支撑钢框架抗震性能评估与损伤演化分析

为研究自复位耗能(SCED)支撑失效前后支撑钢框架结构的抗震韧性及损伤演化规律,设计了一单榀三层自复位支撑钢框架(SCBSF)并对其进行精细化有限元模拟,探究了支撑第二刚度和摩擦力在考虑支撑失效时对结构宏观响应和关键构件损伤状态的影响规律。结果表明,在地震作用下,SCED支撑作为SCBSF第一道抗震防线,激活工作后为结构提供了稳定的耗能与卓越的复位能力,相比屈曲约束支撑(BRB)框架残余变形角最大减小了84.9%,显著降低结构震后修复成本;支撑达到最大行程破坏失效后,结构层间变形加剧,框架梁和柱塑性耗能占比增加了92.33%,主体结构损伤值增加了48.45%,结构的抗震性能与韧性水平明显降低。参数分析结果表明,提升支撑的第二刚度和摩擦力能有效降低结构响应,但具有较大第二刚度和摩擦力的支撑框架仍抵抗不了强震作用时,可能导致更多的支撑失效破坏,结构损伤加剧。因此,设计SCED支撑时,需要适当提高支撑第二刚度和摩擦力,建议第二刚度取值为第一刚度的7/50~4/25,支撑摩擦力与预压力比值取为1~1.2;提升支撑第二刚度相比提升摩擦力对结构损伤值控制效果更好,随着地震动强度增大,摩擦力与第二刚度对结构抗震性能的影响逐渐减小。

自复位支撑钢框架摩擦装配式节点性能研究

自复位支撑在激活后具有较大的刚度和承载力,支撑连接节点及梁柱受力复杂,损伤风险高。提出了一种基于摩擦连接的自复位支撑钢框架装配式节点,利用摩擦滑移连接实现自复位支撑极限轴力可控,并为整体结构提供附加耗能。阐述了该摩擦装配式节点的构造、组装和工作原理,通过数值模拟对其抗震性能进行研究,并分析了该节点设计参数对其性能的影响。结果表明:采用该节点的自复位支撑钢框架滞回响应更为饱满,整体结构耗能能力提升了20.81%,节点对总水平剪力的实际限制作用达17.56%,有效减缓了节点区塑性发展。通过改变支撑连接节点的摩擦片摩擦系数和高强螺栓预紧力,能够实现起滑位移与起滑力可调。

国产TJ-Ⅰ型屈曲约束支撑的性能研究

结合国内外研究和工程现状,以世博会场馆工程为背景,采用国产低屈服点钢(LYP160MPa),Q195,特制低屈服点钢材(LYP225MPa)作为芯材,研制出新型TJ-Ⅰ型屈曲约束支撑。经过一系列试验研究和理论分析,确定了合理的构造和设计准则,研制出更大吨位的并能实际应用于世博会场馆的支撑。在同济大学建筑结构实验室进行了一系列的低周往复加载试验中,本文选取了10根试件的试验结果,设计屈服吨位分别为40kN、90kN、120kN、130kN1、60kN、180kN。通过对试验结果和现象的总结和理论分析,我们可以清晰地看到支撑性能的稳步提高。试验结果表明,TJ-I型屈曲约束支撑具有良好的滞回性能和低周疲劳性能,与国外同类产品的性能相当,是一种十分有效的耗能构件。此次试验采用了宝山钢铁厂生产的国产低屈服点钢,促进了低屈服点钢在抗震工程领域中的应用。

巨型框架-耗能支撑结构的减震性能分析

对巨型框架-耗能支撑结构新体系进行了罕遇地震作用下的弹塑性时程分析,研究该体系的减震性能和耗能支撑的不同布置方式对结构的减震效果。结果表明:如果耗能支撑布置位置得当,可以用较少的耗能支撑个数达到较好的减震效果;巨型框架-耗能支撑结构不但可以减少原巨型框架-支撑结构的层间侧移,还可以减少其底部剪力和顶层加速度反应的峰值。

多高层框排架-支撑结构减震设计及试验研究

为了解决多高层框排架-支撑结构存在的抗震能力较弱、出现薄弱层等问题,以某典型多高层框排架-支撑结构为实例,基于防屈曲支撑(buckling-restrained brace,BRB)消能减震技术设计了3种减震方案,并通过有限元软件对原结构及各方案进行了弹塑性分析.分析结果表明:3种方案均可改善层间位移角分布,提高结构抗震性能,其中降刚度方案的经济性及减震效果均较好.按1∶10缩尺比例分别设计制作原结构及降刚度方案试验模型,通过静力往复加载试验,验证了减震方案提高结构阻尼比及抗震性能的效果.

钢管混凝土减震框架与钢管混凝土框架-剪力墙结构的对比试验研究

设计两榀比例为1:4、梁柱构件尺寸相同的试件:一榀为设置新型三重钢管防屈曲支撑的钢管混凝土减震框架,一榀为普通钢管混凝土框架-剪力墙结构。对两个试件进行反复荷载作用下的抗震性能试验,对比分析两种结构的破坏特征、滞回性能、骨架曲线、强度和刚度退化、耗能能力和关键点应变等抗震性能指标。试验结果表明:钢管混凝土减震框架结构具有与钢管混凝土框架-剪力墙结构相当的承载力,并在变形能力、延性和耗能能力等方面均有明显的提高,对刚度退化和强度退化也有明显的缓解,具有更合理的受力性能和破坏机制,新型三重钢管防屈曲支撑起到良好的耗能减震作用,有效地改善钢管混凝土框架的抗震性能。

新型带耗能支撑-分散核心筒结构的抗震性能研究

为了解决强震作用下核心筒底部损伤严重问题,提出把刚度高度集中的核心筒离散成多个分散筒体,分散筒之间采用框架梁和耗能斜撑联系,建立多道设防的新型带耗能支撑-分散核心筒结构。本文从结构整体响应、构件材料损伤、结构耗能等方面对比普通和新型耗能框架-核心筒结构抗震性能差异,并研究结构的地震损伤模式。研究结果表明:两种结构侧移和侧向刚度等整体响应相差不大。强震作用下,相比传统核心筒结构,新型核心筒结构混凝土受压应变最大减少65%,钢筋受拉应变最大降低55%;滞回耗能主要分布在防屈曲支撑、连梁,少部分分布在剪力墙、框架和钢管混凝土暗柱上。新型核心筒结构中剪力墙总滞回耗能以及底部剪力墙滞回耗能均最少降低50%。防屈曲耗能支撑耗散了超过50%结构总塑性耗能,在结构高度的1/10至4/5范围内充分起到了耗能作用,大大减少了墙肢的损伤程度,地震损伤模式更为合理。

防屈曲支撑应用于底部框架-抗震墙砖房加固的研究

针对7度以上(含7度)设防烈度、重点设防类别中小学校舍的底部框架-抗震墙砖房,对于其底部的加固,提出了增设防屈曲支撑的加固方法。首先介绍了防屈曲支撑的组成特点、耗能特性,提出了可以用于防屈曲支撑的三种中心支撑形式,给出了相关的节点构造,最后结合工程实例,对比分析了底部增设剪力墙、增设防屈曲支撑的性能特点,发现对底部框架-抗震墙砖房这种刚度较大的结构,增设防屈曲支撑有利于结构的耗能,可以提高结构整体的抗震延性。

腹板开孔耗能支撑框架结构抗震性能研究

钢框架中心支撑结构是一种双重抗侧力结构体系,为避免水平荷载作用下中心支撑斜杆发生失稳,提出一种矩形钢管腹板开孔耗能支撑,其与钢框架采用高强螺栓连接,进而形成耗能支撑框架结构,耗能支撑发生破坏后易于替换。耗能支撑的耗能板件采用对称开孔与S形开孔两种形式,利用ABAQUS有限元软件,分析了耗能腹板厚度、长度、开孔间距等参数对耗能支撑以及支撑框架滞回性能的影响。研究结果表明:两种开孔形式的耗能支撑框架结构的支撑斜杆均未发生失稳,结构滞回曲线饱满,无捏缩现象。耗能支撑主要依靠开孔腹板的孔间板件率先进入塑性状态来耗散大部分能量。与S形开孔形式相比,对称开孔形式的耗能支撑框架结构的承载力与刚度更大,但在加载后期,S形开孔形式耗能支撑框架结构变形大的优势发挥得更明显,耗能效率高。