Dynamic responses of reinforced concrete beams under double-endinitiated close-in explosion

The reinforced concrete(RC) structural component might suffer a great damage under close-in explosion.Different from distant explosions, blast loads generated by the close-in explosion are non-uniformly distributed on the structural component and may cause both local and structural failure. In this study,an experimental study was conducted to investigate the dynamic responses of RC beams under doubleend-initiated close-in explosions. The experimental results show that the distribution of blast loads generated by the double-end-initiated explosion is much more non-uniform than those generated by single-point detonation, which is caused by the self-Mach-reflection effects. A 3 D finite element model was developed and validated in LS-DYNA by employing the modified K&C model. Intensive numerical calculations were conducted to study the influences of the initiation way, scaled distance and longitudinal reinforcement ratio on the dynamic responses and failure modes of RC beams. Numerical results show that the RC beam suffers greater damage as the cylindrical explosive is detonated at its double ends than the scenario in which the cylindrical explosive is detonated at its central point. RC beams mainly suffer flexural failure and flexure-shear failure under the double-end close-in explosion, and the failure modes of RC beams change from the flexural damage to flexure-shear damage as the scaled distance or the longitudinal reinforcement ratio decreases. The direct shear failure mode is not usually observed in the double-end-initiated explosion, since the intense blast loads is basically concentrated in the midspan of RC beam, which is due to self-Mach-reflection enhancement.

Prediction of Flexural Deformation of Reinforcement Concrete Beams with Polynomial Tension Stiffening Model

Based on an assumption of parabolic bond stress distribution,a simplified model with quartic polynomial function of the relative slip of steel bar and surrounding concrete for reinforced concrete (RC)tensile member was proposed. The post-cracking behavior as well as tension stiffening effect was considered in the new model. The relative slip of bending member could also be determined through the extension of the new model,which could be applied to obtaining the concentrated rotations at certain sections in order to predict the flexural deformation of RC beam. Several examples of four-point bending RC beams were approached to verify the new model,and the predictions of the flexural deflections of RC beams agreed well with experimental results. The new model can be extended to the application of partially corroded RC beam.

功能可恢复RCS混合框架结构研究进展

钢筋混凝土柱-钢梁(RCS)混合框架结构以其结合了混凝土优异的抗压性能及钢材优异的抗弯性能而受到广泛关注,而可恢复功能结构以其震后快速恢复使用功能的能力,也成为地震工程界研究的新热点。功能可恢复RCS混合框架结构可以在弯矩较大的梁端和柱脚部位设置可更换构件,实现结构的功能可恢复能力。文中简述了近年来功能可恢复RCS混合框架结构研究进展,重点关注各类型功能可恢复钢梁、功能可恢复摇摆柱脚的构造研究,介绍了功能可恢复RCS混合框架结构性能分析研究进展。最后,对功能可恢复RCS混合框架结构仍需深入研究的问题进行了展望。

Flexural Performance of Reinforced Concrete Beams Strengthened with Carbon Fiber-Reinforced Polymer(CFRP)under Hygrothermal Environment Considering the Influence of CFRP-Concrete Interface

As an important component,the bond behavior of carbon fiber-reinforced polymer(CFRP)-concrete interface for a reinforced concrete(RC)beam is very significant.In this study,a theoretical model was established to analyze the flexural behavior of CFRP-strengthened RC beams,and the CFRP-concrete interfacial bond-slip relationship under hygrothermal environment was unified into one model.Two failure criteria corresponding to two types of failure modes,i.e.,concrete crushing and intermediate crack(IC)-induced debonding,were developed.Through the theoretical model,the flexural behavior of deflection,interfacial shear stress distribution and ultimate load of a CFRP-strengthened RC beam under hygrothermal environment were obtained and predicted.Moreover,the theoretical model was verified by test results.The results showed that the hygrothermal environment had a significant impact on the CFRP-concrete interface behavior.Compared with the control beam without hygrothermal environment pretreatment,the deflection and ultimate load of the strengthened RC beam decreased by 51.9%and 20%,respectively.

UHPC-RC节段组合梁的抗弯性能分析

为研究低预应力度条件下,不同节段接缝的超高性能混凝土-钢筋混凝土(ultra-high performance concrete-reinforced concrete,UHPC-RC)组合梁的抗弯性能,文章基于ABAQUS有限元软件,建立UHPC-RC节段组合梁的基准有限元模型,并利用已有的试验数据验证该模型的合理性。节段接缝分别为平面干接缝、平面胶接缝、齿键干接缝和齿键胶接缝,在基准有限元模型的基础上,进一步研究节段接缝类型对组合梁抗弯性能的影响。研究发现,在四点受弯加载方式下,接缝的几何特征(平面或齿键)对组合梁的极限荷载和开裂荷载影响较小,环氧树脂胶的使用对组合梁的抗弯性能影响较大。

RCS刚接节点组合加固有限元模拟分析

为了研究经过预埋式外包钢板-增大截面加固后柱贯通型RCS节点的承载能力和受力机理,结合实际工程,通过有限元软件ABAQUS对钢箍板-增大截面加固体系进行模拟计算,分析了钢箍板-增大截面加固体系核心区在作为刚接节点与铰接节点两种工况的设计荷载作用下,各部分结构的应力分布、损伤情况和节点转角。计算结果表明,在两种设计工况的作用下,各部分结构均处于弹性阶段,距离屈服强度还有较大盈余,混凝土结构局部出现损伤。

Limit Analysis for Reinforced Concrete Rectangular Members Under Bending, Shear and Torsion

The ultimate strength of reinforced concrete(RC) rectangular members subjected to combined bending,shear and torsion is obtained from the limit analysis proposed in the present paper. Based on a warped failure surface determined by external loads, and a reasonable assumed stress distribution balancing external loads but not violating the yield condition, the bending-shear-torsion interaction can be derived from equilibrium conditions.According to the definition of lower-bound theorem in limit analysis, the calculated ultimate loads will be carried safely by the structure. The present method is a simple approach to obtain carrying capacities for RC elements under complex external loads. After comparing with the test results, a good agreement has been observed. The present method can be extended to explain the failure mechanism of RC members subjected to axial loads, and it is possible to develop a simple unified theory of RC members for engineering.

爆炸与火荷载联合作用下RC梁耐火极限的数值分析

偶然性爆炸荷载通常会引起建筑结构或构件的破坏和损伤.为了揭示这种损伤对钢筋混凝土(RC)梁抗火灾高温能力的影响机理和规律,本文以分层Timoshenko梁非线性动力有限元方法为基础,在已有的钢筋和混凝土应变速率型弹黏塑性材料本构模型基础上,进一步考虑了温度效应,建立了能够分析爆炸荷载作用后RC梁抗火特性的有限元分析方法,编制了有限元计算程序.采用该程序系统地分析了爆炸荷载对普通RC梁在标准火灾升温过程中耐火极限的影响规律.分析结果表明,爆炸荷载损伤会明显降低RC梁的耐火能力,且梁长度越长,影响越显著.

火灾作用后RC简支梁抗弯承载力试验研究和可靠度分析

建筑物发生火灾后 ,结构的力学性能如何变化一直是研究人员普遍关注的热点问题。但是火灾对建筑物的影响因素较为复杂 ,这些问题至今还没有得到很好的解决。笔者通过试验研究了 11根三面受火钢筋混凝土简支梁在不同初始荷载和配筋下的火灾后抗弯承载力和可靠度 ,并进行了比较。试验结果表明 :在其他条件相同仅配筋不同时 ,钢筋配置适当增加 ,火灾后抗弯承载力下降减少 ,钢筋混凝土梁的抗火能力增强 ;在其他条件相同仅初始荷载不同时 ,初始荷载增加 ,抗弯承载力下降增加 ,火灾后可靠度的下降幅度也增加。试验研究为钢筋混凝土梁的抗火设计和火灾后的修复和加固提供了参考依据。

钢筋钢丝网砂浆加固RC梁的抗剪试验

进行了钢筋混凝土(RC)原梁、钢筋钢丝网砂浆(SWM)加固RC梁和钢筋网砂浆(SM)加固RC梁的抗剪试验研究.结果表明:相对于SM加固法,SWM加固法能大幅度提高加固梁的抗剪承载力;即使在钢丝网用量很少的情况下(施工方便),加固梁仍具有良好的裂缝控制能力和相对较大的变形能力.同时,给出了加固梁的抗剪承载力和斜裂缝宽度的计算公式,其计算结果与试验结果基本吻合.

CFL增强RC梁的疲劳累积损伤模型

通过碳纤维薄板(CFL)增强钢筋混凝土(RC)梁的三点弯曲疲劳试验,得到了构件疲劳寿命曲线及其跨中挠度、抗弯刚度的演化规律;采用增强梁的剩余抗弯刚度来定义损伤变量,建立了描述其损伤、断裂过程的疲劳累积损伤模型,并对CFL增强RC梁的疲劳损伤演化历程进行了数值分析.结果表明,文中提出的疲劳累积损伤模型能够准确地描述包括混凝土开裂、CFL与混凝土剥离、钢筋屈服等破坏模式在内的CFL增强RC梁的疲劳损伤、破坏过程.

无腹筋RC悬臂梁抗剪强度及尺寸效应理论研究

不同于混凝土材料,钢筋混凝土(RC)构件的破坏模式与机制更为复杂,采用混凝土材料尺寸效应理论难以描述构件的尺寸效应行为。我国相关规范中并没有系统考虑构件尺寸及纵筋率对RC梁抗剪承载力的影响。为研究剪跨比及纵筋率对无腹筋RC梁剪切破坏及抗剪强度尺寸效应的影响,采用三维细观数值模拟方法,建立了RC梁剪切破坏力学分析模型,研究了剪跨比及纵筋率对RC梁剪切破坏及抗剪强度尺寸效应的影响机制与规律。研究结果表明,RC梁抗剪强度表现出极为显著的尺寸效应现象;RC梁抗剪强度随剪跨比的增大而减小,随纵筋率的增大而增大;剪跨比较小时,纵筋率对抗剪强度的影响尤为显著。此外,基于Bazant材料层次尺寸效应律,提出了考虑剪跨比及纵筋率影响的RC梁抗剪强度尺寸效应理论公式。对比试验结果,验证了所提公式的准确性与合理性。

海水干湿循环对初始损伤RC梁力学性能的影响

沿海环境下的钢筋混凝土(RC)结构处于荷载作用和环境作用同时存在的工作状态且在正常条件下会出现不同程度的荷载损伤。为了在实验室内模拟其工作状态,对RC梁试件施加幅值分别为0.3P_u、0.4P_u、0.5P_u、0.6P_u和0.7P_u(P_u为单调加载梁的极限荷载)的初始荷载造成不同程度的损伤,经历120次海水干湿循环作用后,进行单调加载试验测试剩余力学性能,并对梁试件钻芯取样测试不同位置及深度处混凝土的氯离子含量。试验结果表明,不同程度初始损伤RC梁经历120次海水干湿循环后,其屈服荷载、极限荷载和延性均随初始荷载幅值的增加而降低;与无损伤梁试件相比,当初始损伤荷载为0.4P_u时,梁试件的屈服荷载和极限荷载降幅分别为10.4%和7.9%,随着初始荷载增大,屈服荷载和极限荷载快速下降,当初始损伤荷载为0.7P_u时,屈服荷载和极限荷载降幅分别达33.7%和32.4%。氯离子含量测试结果表明,梁试件混凝土受拉区氯离子含量均大于受压区氯离子含量;当初始损伤荷载小于0.5P_u时,受拉钢筋表面混凝土的氯离子含量差别不大且小于0.1%,当初始损伤荷载为0.7P_u时,钢筋表面氯离子含量最大达到0.14%。可见,初始荷载损伤与海水干湿循环综合作用对RC梁力学性能及耐久性劣化影响显著。

利用ANSYS对碳纤维布加固RC梁的非线性有限元分析

通过利用大型通用有限元软件ANSYS,对钢筋混凝土(RC)试件梁的5种碳纤维布粘贴方案的抗弯性能,进行了非线性有限元分析。结果发现,屈服荷载和极限荷载的计算值与实测值吻合得很好。这说明通过选用适当的ANSYS单元类型和设置合理的参数,完全可以实现对粘贴碳纤维布加固钢筋混凝土结构的”虚拟试验”。本文目的是确定一些具有共性的参数,以便于其它情况的分析。

环境温度对CFL增强RC梁承载能力的影响

对温度场中碳纤维薄板(CFL)增强钢筋混凝土(RC)梁在不同破坏模式下的承载能力进行理论分析.研究结果表明,环境温度的变化对CFL增强RC梁的承载能力有一定程度的影响:(1)当环境温度升高30K时,CFL厚度分别为0.1、0.2、0.3和0.4mm的增强RC梁的开裂载荷分别提高了5.37%、10.46%、15.9%和20.94%;(2)CFL厚度为0.1mm和0.2mm的增强RC梁的破坏模式为CFL拉断,其极限承载力随环境温度的升高呈下降趋势,但降低幅度小于3.5%;(3)CFL厚度为0.3mm和0.4mm的增强RC梁的破坏模式为混凝土压碎,其极限承载力随环境温度的升高呈上升趋势,但升高幅度小于3.5%.

钢筋与混凝土耦合腐蚀RC梁性能研究

在混凝土结构耐久性的诸多影响因素中,钢筋与混凝土的耦合腐蚀已成为引起混凝土结构过早破坏的一个主要因素。基于不同腐蚀损伤水平条件下的14根简支钢筋混凝土梁抗弯试件的试验结果,分析了混凝土与钢筋耦合腐蚀损伤后梁的基本性能。同时,研究了耦合腐蚀对钢筋混凝土梁承载性能的影响,提出了耦合损伤条件下,钢筋混凝土梁抗弯承载力的一般评价方法,为指导此类构件承载性能评价及后续加固设计提供技术参考。

置入FBG传感器的CFRP加固RC梁在线监测技术研究

近年来,复合材料加固混凝土结构的健康监测已引起国际工程界的广泛关注.使用埋入式布拉格光栅(FBG)传感器可以实现对复合材料加固混凝土结构应变使用状态的远程实时监测.作者首先讨论了FBG传感器埋入碳纤维复合材料(CFRP)层间的界面传递特性,通过实验验证了固化于CFRP中的FBG传感器的应变传感特性.FBG传感器被埋入到用来加固钢筋混凝土(RC)梁的CFRP层间和梁内部受拉钢筋上,通过监测FBG光栅传感器波长的变化就会得到测点的应变值.实验结果表明,FBG传感器测量值与相同位置布设的传统电阻应变片测量值具有很好的一致性,同时测量值与有限元模拟值也十分一致.

表层嵌贴CFRP板加固RC梁的抗弯性能

利用ABAQUS有限元软件对表层嵌贴碳纤维增强复合材料(carbon fiber reinforced polymer/plastic,CFRP)板加固钢筋混凝土(reiforced concrete,RC)梁的抗弯性能进行非线性有限元分析.通过模拟5根表层嵌贴CFRP板加固RC梁,并将数值模拟结果与试验结果、理论计算结果进行对比,以此验证所建模型的正确性.利用验证后的有限元模型深入分析嵌贴长度、开槽数量、加固方式、纵向配筋率对RC梁抗弯性能的影响.模拟结果表明:嵌贴长度和纵向配筋率对RC梁的抗弯性能影响较大;开槽数量、加固方式对RC梁的抗弯性能影响较小.另外,提出了CFRP板的界限加固量公式.

锚栓钢板法加固RC梁桥的计算方法

锚栓钢板法是在既有 RC梁桥受拉边缘打设锚栓 ,用其将钢板固定 ,使 RC梁桥与钢板构成一个可共同受力的一次超静定结构体系。采用极限状态法设计钢板面积 ,用力法原理建立了锚栓钢板法加固 RC梁桥的分析计算迭代公式。结果表明 ,计算方法可靠。

在弯矩、剪力和反复扭矩复合作用下的碳纤维布加固RC箱梁抗扭性能试验研究

为研究碳纤维布加固弯矩、剪力和反复扭矩复合作用下的钢筋混凝土箱梁的抗扭性能,共设计制作了4根钢筋混凝土箱梁试件,其中3根采取碳纤维布加固、1根不加固作为对比试件。试验在自行研制的扭转试验装置上进行,对箱梁试件同步施加弯矩、剪力和反复扭矩作用。以加固方式和加固数量为主要研究参数,分析了箱梁试件的破坏机理、承载能力、变形能力和滞回性能等。通过各箱梁试件的碳纤维布和钢筋的应变变化规律,探讨了碳纤维布加固箱梁的抗扭工作机理;通过测得的各试件的扭矩-扭转角滞回曲线和骨架曲线,提出了碳纤维布加固钢筋混凝土箱梁的抗扭恢复力模型。从而为碳纤维布加固钢筋混凝土箱梁抗扭性能的理论研究和工程应用提供了重要的依据。