基于OpenSees平台的钢管混凝土结构力学性能数值模拟

基于非线性纤维梁-柱单元理论,以OpenSees为求解平台分别进行了钢管混凝土结构滞回曲线计算和弹塑性动力时程分析等数值模拟,计算结果与试验吻合良好。钢管内核心混凝土采用考虑钢管约束效应的应力—应变关系,钢材采用随动强化本构模型。在传统纤维模型法的基础上,通过直接在截面层次定义非线性剪切恢复力的方法建立了考虑非线性剪切效应的剪力墙结构数值模型,结果表明该模型能较好地模拟组合剪力墙的抗剪承载力、捏缩效应以及刚度退化等力学性能。对输入不同地震波下钢管混凝土框架体系的动力时程分析表明,基于OpenSees求解平台的非线性纤维模型法能够较好地模拟钢管混凝土框架结构的非线性动力特性。     

钢筋混凝土筒体的非线性有限元分析模型

本文提出了一种反复荷载下混凝土材料的本构模型，该模型采用平面应力状态下的弥散正交裂缝假设，钢筋采用弥散假设，并考虑了屈服、应变硬化、循环卸载与再加载规则等因素。该本构模型与其他模型相比，具有简便有效的优点。在此基础上，本文采用八结点平面应力单元建立了钢筋混凝土核心筒体非线性有限元分析模型，并对试验模型进行了非线性分析，计算结果与试验结果吻合较好。     

地震动空间效应对大跨度桥梁非线性地震响应的影响

由于大跨度桥梁的桥墩间距离较大,其地震响应分析应考虑地震动输入的空间效应。本文建立了多点激励下大跨度桥梁地震响应分析方法,采用损伤塑性本构模型模拟混凝土材料特性,考虑地震动空间效应对大跨度连续刚构桥进行非线性地震响应分析,从而分析地震动空间效应对大跨度桥梁地震响应的影响。研究表明:考虑行波激励或多点激励时桥梁地震响应较一致激励而言有所差异,考虑地震动空间效应时可能会夸大或减小桥梁结构的动力响应;多点激励时桥梁地震响应会随视波速的改变而变化。由此得出结论,对于大跨度桥梁地震响应分析应合理的考虑地震动空间效应。     

预静载对全级配混凝土梁动弯拉强度的影响

为了探讨预静载对全级配混凝土梁动弯拉强度的影响,本文从全级配混凝土的细观层次出发,将梁的纯弯段视为由水泥砂浆、粗骨料及两者间的黏结带所组成的复合材料。采用既考虑应变率强化效应又计及损伤弱化效应的动态本构模型反映细观单元的损伤退化。通过自编的以位移控制的有限元程序对全级配混凝土梁在不同预静载作用下的破坏机制进行了数值模拟,给出了相应的应力一应变曲线和动弯拉强度。计算结果显示：全级配混凝土梁的动弯拉强度随着预静载的增加而上升。     

三级配混凝土梁在动荷载作用下的数值模拟

从三级配混凝土的细观层次出发,将梁的纯弯段视为由水泥砂浆,粗骨料及两者间的粘结带所组成的复合材料.采用既考虑应变率强化效应又计及损伤弱化效应的动力本构模型反映细观单元的损伤退化.通过自编的以位移控制的有限元程序对三级配混凝土梁在冲击荷载和三角形循环荷载作用下的破坏机制进行了数值模拟,给出了相应的应力-应变曲线和动弯拉强度.研究结果表明数值模拟所得的结果与实验结果吻合较好.     

岩石膨胀的三维本构关系和1976年唐山地震前垂直形变的有限元模拟

本文研究了岩石在应力作用下的膨胀问题。依据实验资料和参考Nur的岩石膨胀二维本构关系,提出了岩石介质膨胀的三维非线性本构关系的一般表达式。並将这组非线性关系式推导成增量形式的有限元矩阵表达式。 考虑到导出的膨胀的本构关系矩阵是非对称矩阵,因此,本文编制了非对称全带宽存储及直接求解的三维非线性有限元程序。为了模拟实际断层的情况,考虑断层的蠕滑,在程序中还专门设计一种非线性空间断层单元,以便在研究真实地震问题或有关岩石膨胀的问题中作数值模拟。 用上述带有弹性-膨胀矩阵三维非线性有限单元法,假设不同模型,对唐山大震前出现的明显隆起进行三维数值模拟研究,並结合小震分布等震前现象,对1976年7月28日唐山地震的孕育过程提出看法。     

基于Park三参数模型的剪切滞变模型

针对深梁、短柱和剪力墙等剪跨比较小的构件在结构非线性分析中需要考虑剪切效应的情况,在Park三参数滞变模型的基础上,参考大量文献后,建议了短柱、剪力墙和核心筒三种构件的剪力-剪切变形曲线本构关系特征点的参数取值,给出了剪跨比较小构件的剪切滞变模型。采用该模型分别对短柱、剪力墙和核心筒三个试验模型进行了模拟和分析,分析结果与试验结果的对比表明,所给模型可较好地模拟试件的剪切效应及实际抗剪承载力水平。该模型的建立可为结构非线性分析中有效考虑剪切效应提供参考。     

精细化纤维梁柱单元模拟分析平台FENAP的开发

为精细化模拟桥梁结构的非线性行为,在深入分析纤维梁柱单元模型原理的基础上,本文基于ABAQUS建立了钢筋混凝土精细化纤维梁柱单元模拟平台FENAP,开发了与其相适应的材料模型库FENAP/MAT,涵盖了多种材料本构模型,能够有效考虑构件的刚度退化和强度退化等损伤效应,以及模拟轴力和弯矩的多维耦合效应等复杂非线性动力行为,且可考虑箍筋对混凝土的约束作用等。利用该FENAP平台数值模拟了一个钢筋混凝土矩形截面悬臂梁,进行了Pushover分析,考虑了箍筋对核心混凝土约束效应的影响,并与OpenSEES的计算结果进行对比。结果表明:FENAP平台可有效模拟桥梁构件的多种复杂非线性行为,且具有很好的计算效率和求解精度。     

基于OpenSEES的高强钢组合K形偏心支撑框架精细化建模分析

为研究高强钢组合K形偏心支撑框架在反复荷载作用下的受力性能,在已有拟静力试验的基础上,利用有限元软件OpenSEES对一个高强钢组合K形偏心支撑框架模型进行了精细化建模研究。首先,探讨了模型的单元选择,纤维截面划分和材料本构参数定义问题。同时,考虑到在地震荷载作用下,高强钢组合K形偏心支撑框架主要依靠消能梁段的剪切变形来耗能,因此,如何模拟结构中消能梁段的剪切效应成为研究的关键。本文采用OpenSEES提供的组合截面和零长度单元两种方法来对消能梁段进行建模,剪切材料分别考虑了Steel 02和滞回材料。将不同消能梁段建模方法的模拟滞回曲线和骨架曲线与试验结果进行比较。结果表明:精细化模型的数值模拟结果和试验结果具有较好的吻合度,验证了数值模型的正确性和可行性;采用零长度单元和Steel 02的组合方式来模拟消能梁段的剪切效应能够同时满足计算效率和计算精度的要求,为进一步利用OpenSEES进行高强钢组合K形偏心支撑框架的动态响应分析和复杂模型分析提供了建模参考依据。     

基于极大初始时间步法的非线性静动力联合分析

静动力联合分析是考虑非线性条件下结构响应分析的关键技术问题之一。本文通过分析非线性有限元静、动力平衡方程的内在联系,并结合Newmark积分算法的隐式求解特点,提出了一种基于极大初始时间步法的非线性静动力耦合算法,可保证结构在静动荷载的耦合激励下获得合理的非线性地震响应。通过对Koyna重力坝的地震响应数值分析算例,验证了该算法的合理性与有效性。另外,该算法在各类隐式求解的通用有限元程序中均易于实现,可操作性强,便于工程应用。     

A new model for analyzing nonlinear torsion behavior of concrete filled steel tube columns with rectangular section

An experimental study on concrete filled steel tube columns with rectangular section subjected to compressionflexure-torsion combined action has been carried out. The failure modes and load-deformation hysteretic relations were obtained. Based on the principles of classical material mechanics, the relations between the torsion curvature of the section and the shear strain of the fiber on the section were established. Then the strain distribution on the rectangular section of concrete filled steel tube columns subjected to torsion was analyzed. The three-dimensional refined finite element model was also built, in order to make the precision verification. The matrix forms of the relation between the torsion curvature of the section and the shear strain of the fiber on the section were derived, and introduced into the fiber beam model considering nonlinear torsion effect on the section. The comparison between test results and calculation results showed that the fiber beam model considering nonlinear torsion effect had high modeling efficiency and solution precision for predicting the torsion behavior of concrete filled steel tube columns with rectangular sections, and was suitable for analyzing the dynamic response of various structures subjected to the combined cyclic load caused by the earthquake load.     

Modeling RC column flexural failure modes under intensive seismic loading

The aim of this work is to model beam‐column behavior in a computationally effective manner, revealing reliably the overall response of reinforced concrete members subjected to intensive seismic loading. In this respect, plasticity and damage are considered in the predominant longitudinal direction, allowing for fiber finite element modeling, while in addition the effect of inelastic buckling of longitudinal rebars, which becomes essential at later stages of intensive cyclic loading, is incorporated. Α smooth plasticity‐damage model is developed for concrete, accounting for unilateral compressive and tensile behavior, nonlinear unloading and crack closure phenomena. This is used to address concrete core crushing and spalling, which triggers the inelastic buckling of longitudinal rebars. For this reason, a uniaxial local stress‐strain constitutive relation for steel rebars is developed, which is based on a combined nonlinear kinematic and isotropic hardening law. The proposed constitutive model is validated on the basis of existing experimental data and the formulation of the buckling model for a single rebar is developed. The cross section of rebar is discretized into fibers, each one following the derived stress‐strain uniaxial law. The buckling curve is determined analytically, while equilibrium is imposed at the deformed configuration. The proposed models for concrete and rebars are embedded into a properly adjusted fiber beam‐column element of reinforced concrete members and the proposed formulation is verified with existing experimental data under intensive cyclic loading.     

方钢管混凝土柱的三维非线性分析

本文建立了一个三维非线性有限元计算模型,旨在用来准确,有效地分析钢－混凝土组合结构,其中混凝土材料模型在于亚弹性亚弹性正交异性理论,采用Ｓａｒｇｉｎ的非线性应力－应变方程表达以及拉伸,压缩破坏面,钢单元采用等向强化的Ｖｏｎ Ｍｉｓｅｓ弹塑性模型,试验和计算比较表明该计算模型是一个比较简单但准确,有效的模型。     

爆炸荷载作用下钢柱的动力响应与影响因素分析

采用有限元软件ANSYS/LS-DYNA,建立钢柱有限元模型,模拟爆炸荷载作用下钢柱的动力响应,并对影响钢柱动力响应的主要因素进行数值分析。考虑了不同爆炸荷载、材料失效应变、单元网格密度、柱高、柱截面尺寸和柱承担的轴向压力等参数的影响。通过对钢柱动力响应时程曲线进行分析,研究爆炸荷载作用下钢柱响应特性及其破坏机理;通过分析,得到各参数对其动力响应的影响规律。分析结果表明：增大柱的截面尺寸,能够降低柱跨中水平位移;增大柱截面高度,能有效地提高钢框架柱的抗爆承载力;在钢柱抗爆设计中,应控制其所承受的轴向压力大小,轴压比值不宜超过0.3。     

约束高强度Q460钢柱抗火性能分析

为了研究高强度约束钢柱在火灾下的反应,根据高强度结构钢Q460在高温下的力学性能参数,建立了约束高强度钢柱受火分析模型,得到了高强度约束钢柱在火灾下的轴向位移、跨中挠度、最大应力以及临界温度。采用有限元分析对理论结果进行了验证,两者吻合很好。利用验证过的该文计算方法计算了2种荷栽比、长细比和约束刚度比条件下的高强钢柱的抗火性能;采用CECS200：2006的力学性能参数计算了约束普通钢柱的抗火性能。通过对高强钢和普通钢的抗火性能分析发现,轴向约束明显降低钢柱的临界温度,长细比、荷载比越大,临界温度越低;高强钢的抗火性能要优于普通钢。     

Fiber-based hysteretic model for simulating strength and stiffness deterioration of steel hollow structural section columns under cyclic loading

An efficient component model has been developed that captures strength and stiffness deterioration of steel hollow structural section (HSS) columns. The proposed model consists of two fiber-based segments at a member's ends along with an elastic segment in between. The fibers exhibit nonlinear uniaxial stress–strain behavior, which is explicitly defined by uniaxial monotonic tensile and cyclic round coupon tests. The postbuckling behavior of an HSS column is traced through a proposed uniaxial effective stress–strain constitutive formulation, which includes a softening branch in compression and an energy-based deterioration rule to trace the influence of cyclic deterioration in the inelastic cyclic straining. These may be inferred by uniaxial stub-column tests. The component model captures the coupling between the column axial force and flexural demands. Consistent model parameters for a number of steel materials used in the steel construction in North America and Japan are proposed along with the associated model calibration process. The efficiency of the proposed model in predicting the hysteretic behavior of HSS columns is demonstrated by comparisons with physical steel column tests subjected to various loading histories, including representative ones of ratcheting prior to earthquake-induced collapse. The proposed model is implemented in an open-source finite element software for nonlinear response history analysis of frame structures. The effectiveness of the proposed model in simulating dynamic instability of steel frame buildings is demonstrated through nonlinear response simulations of a four-story steel frame building, which was tested at full-scale through collapse. Limitations as well as suggestions for future work are discussed.     

Finite element analysis of damage and failure of reinforced concrete members under earthquake loading

This paper presents a three‐dimensional analysis framework, based on the explicit finite element method, for the simulation of reinforced concrete components under cyclic static and dynamic loading. A recently developed triaxial constitutive model for concrete is combined with a material model for reinforcing steel which can account for rupture due to low‐cycle fatigue. The reinforcing bars are represented with geometrically nonlinear beam elements to account for buckling of the reinforcement. The strain penetration effect is also accounted for in the models. The modeling scheme is used in a commercial finite element program and validated with the results of experimental static and dynamic tests on reinforced concrete columns and walls. The analyses are supplemented with a parametric study to investigate the impact of several modeling assumptions on the obtained results.     

车载作用下箱形截面梁振动特性的瞬态动力学分析

论文根据磁浮交通道岔梁的结构及受力特点,通过建立合理的瞬态动力学数值模型,把列车作为高速运行的荷载动态作用于道岔梁上。采用瞬态拟动力学方法模拟钢结构梁动力响应特性。研究了道岔梁上关键点位置相应的振幅、反应加速度及其时效特性。通过计算比较精确地获得工程实际中最为关注的梁的最大振动位移和加速度。研究成果可为高速磁浮实际工程设计提供借鉴。     

SRC框格复合墙抗剪承载力计算及影响因素分析

SRC框格复合墙是在普通RC密肋复合墙基础上结合型钢混凝土概念而提出来的一种复合墙板,以轻钢龙骨代替框格内原有纵向受力钢筋,通过焊接或螺栓连接在梁柱轻钢龙骨节点处实现刚性或半刚性连接.在SRC框格复合墙模型试验基的础上,利用ANSYS程序对墙体受力过程进行了非线性有限元分析,提出了SRC框格复合墙抗剪承载力的实用计算公式,并对框格含钢率、轻钢强度等影响因素进行了有限元分析.研究结果表明:所提出的SRC框格复合墙抗剪承载力计算公式,与非线性有限元计算结果吻合较好,能够适应框格含钢率等不同因素变化的计算精度要求;提高肋梁中轻钢强度或含钢率可以有效提高墙体抗剪承载力,而不宜单独采用提高混凝土强度的方法.     

地震区居民建筑钢结构极限承载力测试与分析

传统方法一般依据静力检测数据测试居民建筑钢结构的极限承载力,对构件数量的要求较高,无法量测隐蔽构件,测试结果精度低。因此提出基于振动参数以及动力模型修正的地震区居民建筑钢结构极限承载力预测与分析方法,分析建筑钢结构振动参数与极限承载能力的关系,塑造地震区居民建筑钢结构简化以及振动方程,获取其极限载荷与振动参数间的关系。采用基于动力模型修正的极限承载力评估方法,基于动力模型修正理论,采用线性屈曲法、几何非线性法以及双重非线性分析法,对地震区居民建筑钢结构极限承载力进行检测。实验结果说明,所提方法能对居民建筑钢结构立柱轴向性和大钩荷载关系以及荷载-扰度曲线,且实施数值运算效果好,预测获取的极限承载力值精度高,建筑的钢结构状态比较稳定。