Full－range nonlinear analysis of fatigue behaviors of reinforced concrete structures by finite element method

The offshore reinforced concrete structures are always subject to cyclic load, such as wave load.In this paper a new finite element analysis model is developed to analyze the stress and strain state of reinforced concrete structures including offshore concrete structures, subject to any number of the cyclic load. On the basis of the anal ysis of the experimental data,this model simplifies the number of cycles-total cyclic strain curve of concrete as three straight line segments,and it is assumed that the stress-strain curves of different cycles in each segment are the same, thus the elastoplastic analysis is only needed for the first cycle of each segment, and the stress or strain corresponding to any number of cycles can be obtained by superposition of stress or strain obtained by the above e lastoplastic analysis based on the cyclic numbers in each segment.This model spends less computer time,and can obtain the stress and strain states of the structures after any number of cycles.The endochronic-damage and ideal offshore concrete platform subject to cyclic loading are experimented and analyzed by the finite element method based on the model proposed in this paper. The results between the experiment and the finite element analysis are in good agreement,which demonstrates the validity and accuracy of the proposed model.

NONLINEAR ANALYSIS OF REINFORCED CONCRETE RECTANGULAR SLABS USING FINITE ELEMENT METHOD

The nonlinear analysis of reinforced concrete rectangular slabs undermonotonic transverse loads is performed by finite element method.The layered rectangu-lar element with 4 nodes and 20 degrees of freedom is developed,in whichbending-stretching coupling effect is taken into account.An orthotropic equivalentuniaxial stress-strain constitutive model of concrete is used.A program is worked out andused to calculate two reinforced concrete slabs.The results of calculation are in goodconformity with the corresponding test results.In addition,the influence of tension stif-fening effect of cracked concrete on the results of calculation is discussed.

Finite Element Method for Design of Reinforced Concrete Offshore Platforms

A design method of reinforced concrete (R. C.) offshore platforms with nonlinear finite element analysis is proposed. According to the method, a computer program is developed. In this program nonlinear constitutive relationships and strength criteria of concrete and steel bars are included, and the progressive cracking and crushing of the concrete are taken into account. Based on the stress distribution obtained by the nonlinear finite element analysis, the amount of reinforcement in the control sections can be computed and adjusted automatically by the program to satisfy the requirement of the design. The amount of reinforcement required in the control sections, which are obtained with the nonlinear finite element analysis, is agreeable to that obtained in the experiment. This shows that the design method of R. C. offshore platform with the nonlinear finite element method proposed by the authors is reliable for practical use.

Numerical Simulation of Surrounding Rock Deformation and Grouting Reinforcement of Cross-Fault Tunnel under Different Excavation Methods

Tunnel construction is susceptible to accidents such as loosening, deformation, collapse, and water inrush, especiallyunder complex geological conditions like dense fault areas. These accidents can cause instability and damageto the tunnel. As a result, it is essential to conduct research on tunnel construction and grouting reinforcementtechnology in fault fracture zones to address these issues and ensure the safety of tunnel excavation projects. Thisstudy utilized the Xianglushan cross-fault tunnel to conduct a comprehensive analysis on the construction, support,and reinforcement of a tunnel crossing a fault fracture zone using the three-dimensional finite element numericalmethod. The study yielded the following research conclusions: The excavation conditions of the cross-fault tunnelarray were analyzed to determine the optimal construction method for excavation while controlling deformationand stress in the surrounding rock. The middle partition method (CD method) was found to be the most suitable.Additionally, the effects of advanced reinforcement grouting on the cross-fault fracture zone tunnel were studied,and the optimal combination of grouting reinforcement range (140°) and grouting thickness (1m) was determined.The stress and deformation data obtained fromon-site monitoring of the surrounding rock was slightly lower thanthe numerical simulation results. However, the change trend of both sets of data was found to be consistent. Theseresearch findings provide technical analysis and data support for the construction and design of cross-fault tunnels.

Improved Simulation Method for Soil-Geogrid Interaction of Reinforced Earth Structure in FEM

The interaction between geogrid and soil is crucial for the stability of geogrid-reinforced earth structure. In finite element （FE） analysis, geogrids are usually assumed as beam or truss elements, and the interaction between geogrid and soil is considered as Coulomb friction resistance, which cannot reflect the true stress and displacement developed in the reinlbrcement. And the traditional Lagrangian elements used to simulate soil always become highly distorted and lose accuracy in high-stress blocks. An improved geogrid model that can produce shear resistance and passive resistance and a soil model using the Eulerian technique, in combination with the coupled Eulerian-Lagrangian （CEL） method, are used to analyze the interaction between geogrid and soil of reinforced foundation test in ABAQUS. The stress in the backfill, resistance of geogrid, and settlement of foundation were computed and the results of analysis agree well with the experimental results. This simulation method is of referential value for FE analysis of reinforced earth structure.

Arc-length technique for nonlinear finite element analysis

Nonlinear solution of reinforced concrete structures, particularly complete load-deflection response, requires tracing of the equilibrium path and proper treatment of the limit and bifurcation points. In this regard, ordinary solution techniques lead to instability near the limit points and also have problems in case of snap-through and snap-back. Thus they fail to predict the complete load-displacement response. The arc-length method serves the purpose well in principle, received wide acceptance in finite element analysis, and has been used extensively. However modifications to the basic idea are vital to meet the particular needs of the analysis. This paper reviews some of the recent developments of the method in the last two decades, with particular emphasis on nonlinear finite element analysis of reinforced concrete structures.

Finite Element Calculation of the Flexural Stiffness of Corroded RC Eccentric Compressive Members

A finite element calculation model of corroded RC eccentric compressive members was build using finite element software ANSYS. The model considers the decline of mechanical properties and the effective section of a corroded steel bar,as well as the deterioration of bond character between corroded reinforcement and concrete. The reliability of the finite element model was evaluated by comparing the results of the finite element calculation with the data from experiments. Based on the finite element analysis results,the influence of corrosion degree,the diameter change of the longitudinal reinforcing bars and the spacing change of stirrups on the flexural stiffness were calculated and analyzed.

正交异性钢-钢纤维混凝土组合桥面板疲劳极限状态研究

为了解正交异性钢-钢纤维混凝土(Steel Fiber Reinforced Concrete,SFRC)组合桥面板的疲劳性能及失效机理,以川南城际铁路临港长江大桥为背景,设计、制作正交异性钢-SFRC组合桥面板足尺模型进行疲劳试验,采用ANSYS软件建立试件有限元模型,研究关键细节的疲劳应力和开裂等情况。基于有限元模型,分析不同设计参数(钢顶板厚度、栓钉布置、SFRC抗拉强度及层厚)下组合桥面板疲劳极限状态的失效模式,并提出了主要控制参数取值建议。结果表明:200万次疲劳加载后足尺模型的实测最大裂缝宽度为0.136 mm,出现在SFRC层上缘,钢结构未开裂,组合桥面板疲劳性能良好;组合桥面板疲劳极限状态主要由SFRC层开裂控制,钢顶板厚度、栓钉布置对组合桥面板疲劳性能的影响较小,SFRC抗拉强度和层厚对组合桥面板疲劳性能影响较大,为主要控制参数;在常规正交异性钢桥面板上铺设薄层(厚度不超过50 mm)SFRC时,SFRC抗拉强度不应小于5 MPa,在常规正交异性钢桥面板上铺设普通SFRC(钢纤维体积含量不高于1%,抗拉强度不高于3 MPa)时,SFRC层厚不宜低于100 mm。

玄武岩纤维增强复合材料拉挤圆管抗弯性能研究

为使玄武岩纤维增强复合材料(Basalt Fiber Reinforced Polymer,BFRP)拉挤圆管在桥梁工程中得到更广泛地应用,对其抗弯性能进行试验及有限元分析。对2根长度为750 mm的BFRP拉挤圆管进行三点抗弯试验;采用LS-DYNA有限元软件对试验过程进行模拟,验证有限元模拟的正确性;在保持BFRP拉挤圆管总厚度不变的条件下,研究内、外层双向纤维布的铺设厚度和角度对抗弯性能的影响。结果表明:试件从加载至破坏分为线弹性阶段、下降阶段和残余阶段,试件破坏后残余强度较大且卸载后迅速回弹恢复几何形状;有限元模拟试件的荷载~滑移曲线、失效现象和试验结果吻合较好,有限元模拟正确;布置适量厚度的内、外层双向纤维布可以提高试件的抗弯承载力;将内、外层双向纤维布铺设方向由90°变为45°后,抗弯承载力进一步提高,随着外层45°纤维布厚度增加,破坏时的挠度下降。建议制作BFRP拉挤圆管时,布置适量厚度的双向纤维布,角度以45°为宜。

钻爆法隧道下穿既有双连拱隧道施工技术研究

钻爆法隧道穿越新建既有双连拱隧道结构,下穿隧道为大跨度隧道,高度大、埋深较深,且在穿越既有隧道时,不能影响其安全运营和造成结构破坏,施工难度大、风险高。采用有限元软件Midas GTS NX对钻爆法隧道下穿既有隧道的变形和受力情况进行数值模拟计算,并研究了下穿施工前对上方隧道间地层采用大管棚和锚杆联合加固产生的效果。研究表明:未加固时,施工侧隧道结构的沉降要大于另一侧,呈现出“一峰二谷”变形形状,既有隧道上下部极易发生结构破坏。采用大管棚及锚杆联合加固,有效地转移了应力集中现象,降低了结构破坏风险,并且既有隧道沉降量仅为前者变化量的1/1.83,在控制标准以内。

带有防火保护的圆钢管约束钢筋混凝土柱抗火性能分析与设计

抗火性能是圆钢管约束钢筋混凝土柱设计时的关键问题之一,尽管目前相关研究已逐渐完善,但带有防火保护条件下该类构件的抗火性能研究与设计仍不充分,已有的行业标准中构件高温稳定承载力公式未与常温公式相连续,且其中的防火保护层设计公式不具有明确的物理意义。基于ABAQUS软件,该文开展了带有防火保护圆钢管约束钢筋混凝土柱在ISO 834标准火灾作用下温度场和耐火极限的有限元分析,研究了荷载比、截面尺寸、长细比、防火保护层厚度等关键参数对构件耐火极限的影响规律,并提出了钢管温度、钢筋温度以及混凝土等效温度的简化计算公式。结果表明:随着防火保护层厚度的增大,构件的耐火极限近似线性增大。基于系统性参数分析,提出了带有防火保护圆钢管约束钢筋混凝土柱高温下截面承载力和稳定承载力设计公式,以用于确定构件达到不同耐火极限所需的防火保护层厚度,该方法保持了与现行标准中常温承载力计算公式的连续性。

锪窝圆角半径对CFRP/Al机械连接结构力学性能影响

碳纤维增强复合材料(CFRP)和铝合金(Al)因其优异的机械/物理性能,广泛应用于新一代商用飞机.CFRP/Al沉头螺栓连接结构是重要的连接形式,其中锪窝圆角半径影响了机械连接性能.研究中设计制造不同锪窝圆角的钻锪一体刀具对锪窝圆角尺寸进行控制,并采用基于复合材料渐进损伤模型的有限元仿真方法对不同锪窝圆角半径连接结构力学性能进行仿真和试验研究,分析了CFRP/Al叠层机械连接失效机理.结果表明,利用钻锪一体锪窝钻头可以有效控制锪窝圆角;锪窝位于CFRP层相比于位于铝合金层有着更大的极限强度;CFRP和铝合金材料均在锪窝圆角半径为1.0 mm时具有最大的极限载荷,即锪窝圆角略大于螺栓圆角有利于获得更好的机械连接性能.

张靖皋长江大桥南航道桥锚体结构精细化分析

张靖皋长江大桥南航道桥为主跨2300 m的双塔双吊跨钢箱梁悬索桥,南、北锚碇采用巨型重力式锚碇,通过后张预应力体系将拉力为7万吨级的主缆锚固在锚体上,锚体结构受力复杂。为指导南航道桥锚体结构设计,以主缆水平分力较大的南锚碇为例,根据设计需求对其开展精细化分析,并给出相应的设计建议。基于锚体的2种控制工况(预应力张拉阶段工况及主缆拉力作用阶段工况),采用有限元软件建立1/2南锚碇有限元模型与中央索股面切块有限元模型,分析锚体的总体、局部及底面应力的分布规律;提出基于主应力迹线和边界面应力分布的力流分析方法,分析锚块内部的主要拉、压力流路径。结果表明:锚体总体应力水平较低,后锚面锚固区及后锚室上、下两侧存在拉应力集中,且后锚室的前方底面存在较大的剪、拉应力组合;后锚面上、下两侧及锚块尾端区域存在较大拉力流。据此给出了延长前、后锚面锚固区钢筋及加密后锚室前方底面的竖向钢筋等配筋构造设计建议。

复材风扇叶片榫头元件低周疲劳和损伤模式

为考核层合结构复材风扇叶片在1.5倍离心载荷下的低周疲劳寿命,制备一批风扇叶片,在薄弱部位取样。通过建立层合结构风扇叶片有限元模型,模拟榫头的应力状态,从而确定拉伸载荷水平,开展拉-拉载荷低周疲劳测试。在相邻铺层间引入内聚力单元,并考虑榫头试样单向带面内损伤,模拟损伤变量随循环数累积的过程,增加虚拟拉伸载荷,得到榫头低周疲劳失效时刻的损伤状态。试验结果说明榫头元件形成分层裂纹的平均寿命为17207次循环,首次出现分层裂纹的位置基本一致。数值仿真结果表明榫头单向带基体和层间损伤累积引起裂纹扩展,导致低周疲劳失效。本研究可为建立层合结构复材风扇叶片低周疲劳寿命试验流程和疲劳失效判据提供支撑。

昆都仑泄洪冲沙洞结构静动力三维有限元配筋计算

昆都仑水库是一座以防洪、供水为主的综合利用的中型水库。为改善水库泄洪条件,新建泄洪冲沙洞并布置于库区右岸山体内。首先,构建了泄洪冲沙洞三维有限元模型,模拟了各结构的精细构造部位;然后,采用三维线性有限单元法对泄洪冲沙洞开展静动力工况下变形、应力分析计算,基于有限元内力法进行内力计算并提出相应配筋方案;最后,进行结构限裂复核验算。选取的配筋计算方案实用可靠,为工程设计提供指导、验证复核作用并成功付诸实施。

钢桥中错位厚板十字接头的力学性能与补强方法

针对钢桥中厚板十字接头出现错位缺陷的问题,采用有限元方法研究了错位缺陷对厚板十字接头力学性能的影响,提出一种分离式焊接钢板补强方法并对补强钢板的尺寸进行优化设计.研究结果表明,错位缺陷对厚板十字接头的力学性能产生较大的影响,板件竖向应力在附加弯矩作用下显著增大.提出的焊接钢板补强方法使得补强后竖向支承板承担大部分轴力与弯矩,强度控制设计截面位于补强钢板底部焊缝处,可通过增加补强钢板的高度提升补强效率,最高可达48%.本文推荐了不同错位量下补强钢板的合理尺寸,可为类似工程中错位厚板十字接头的补强方法提供参考.

基于扩展有限元、内聚力单元和单元失效的受弯钢筋混凝土梁数值模拟分析

利用Abaqus中扩展有限元法、内聚力单元和显示动力分析模块下单元失效分析钢筋混凝土梁的受弯响应,对比混凝土4点受弯梁试验和有限元分析的整体性能、损伤与失效,提出混凝土的精细化建模方法。根据模拟结果可知:扩展有限元法和内置内聚力单元模拟混凝土整体性能和拉裂行为精度较高;扩展有限元法模拟的混凝土裂纹扩展路径自由,适合对受力或相互作用复杂的混凝土进行精细化建模与损伤分析;内置内聚力单元的裂纹形成与扩展依赖单元网格密度与形状,适合在相关理论成熟或试验数据全面的基础上做影响参数分析;设置单元失效准则可同时模拟混凝土的压溃和拉裂行为,但损伤发展较快,精度偏低。

ANALYSIS OF GEOSYNTHETICS REINFORCED EMBANKMENT ON SOFT SOIL BY FEM

The reinforcement effects of geosynthetics in thick soft subsoil case and thin soft subsoil case are studied in this paper,and a Duncan Chang nonlinear numerical model based on the finite element method (FEM) is developed.Moreover,an important conclusion that the thickness of soft subsoil affects greatly the geotechnical behavior of geosynthetic reinforced embankments is drawn.A series of embankment built on soft subsoil is calculated using the FEM program.The results of the computer program,such as the lateral displacements,settlements,and stress level and shear stresses in the subsoil,are presented in great detail and the comparison of those results disposes clearly the huge discrepancy of reinforce benefit between the thick subsoil embankment and thin subsoil embankment.Reinforcement mechanism of geosynthetics is also discussed in this paper and several conclusions are reached.This paper also gives recommendations for design.

套拱法在加固大跨径空腹式石拱桥中的应用

为研究大跨径空腹式石拱桥经套拱加固后的受力状态,文章以某大跨径空腹式石拱桥的套拱加固设计为依托,建立了整体有限元模型,采用双单元法模拟旧石拱圈及新加固钢筋混凝土拱圈。计算分析表明,套拱加固后,在汽车荷载及其他外荷载作用下,旧石拱圈内力和承载能力显著增强,因此该加固方案理论可行,可为今后类似工程设计提供参考。

基于ANSYS平台非线性分析的RC构件建模方法

分离式模型的建立是钢筋混凝土结构和构件仿真中的关键问题,本文基于A N S Y S平台,以某钢筋混凝土实腹深梁为算例,开展2种共节点建模方法和2种不共节点建模方法下的非线性有限元对比分析,探讨建模方法对于仿真结果的影响。结果表明:节点生成切割法与弱耦合法在极限承载力和变形能力等方面的数值模拟结果较接近且均与试验结果较吻合,而强耦合法得出的极限承载力偏高;基于布尔运算切割几何模型的共节点建模方式,适用于形状规整、配筋简单的构件;在钢筋节点与混凝土节点之间,通过节点位移就近耦合的原则建立刚性连接的强耦合法,以及通过节点位移约束方程建立柔性连接的弱耦合法,都有着更强的通用性,能够完成边界条件或配筋方式复杂的构件建模,但相比之下,强耦合法计算精度略低,弱耦合法实现难度较高,所以在工程仿真中需要根据构件的几何特点和配筋方式选择合适的建模方法。