Compressive Strength Estimation for the Fiber-Reinforced Polymer (FRP)-Confined Concrete Columns with Different Shapes Using Artificial Neural Networks

An evaluation of existing strength of concrete columns confined with fiber-reinforced polymer( FRP) was presented with extensive collection of experimental data. According to the evaluation results, artificial neural networks( ANNs) model to predict the ultimate strength of FRP confined column with different shapes was proposed. The models had seven inputs including the column length,the tensile strength of the FRP in the hoop direction,the total thickness of FRP,the diameter of the concrete specimen,the elastic modulus of FRP,the corner radius and the concrete compressive strength. The compressive strength of the confined concrete was the output data. The results reveal that the proposed models have good prediction and generalization capacity with acceptable errors.

Experimental study on ductility improvement of reinforced concrete rectangular Columns retrofitted with a new fiber reinforced plastics method

Reinforced concrete （RC） columns lacking adequately detailed transverse reinforcement do not possess the necessary ductility to dissipate seismic energy during a major earthquake without severe strength degradation. In this paper, a new retrofit method, which utilized fiber-reinforced plastics （FRP） confinement mechanism and anchorage of embedded bars, was developed aiming to retrofit non-ductile large RC rectangular columns to prevent the damage of the plastic hinges. Carbon FRP （CFRP） sheets and glass FRP （GFRP） bars were used in this test, and five scaled RC columns were tested to examine the function of this new method for improving the ductility of columns. Responses of columns were examined before and after being retrofitted. Test results indicate that this new composite method can be very effective to improve the anti-seismic behavior of non-ductile RC columns compared with normal CFRP sheets retrofitted column.

Axial Bearing Capacity of Short FRP Confined Concrete-filled Steel Tubular Columns

The bearing capacity of FRP confined concrete-filled steel tubular （FRP-CFST） columns under axial compression was investigated. This new type of composite column is a concrete-filled steel tube （CFST） confined with fiber-reinforced polymer （FRP） wraps. Totally 11 short column specimens were tested to failure under axial compression. The influences of the type and quantity of FRP, the thickness of steel tube and the concrete strength were studied. It was found that the bearing capacity of short FRP-CFST column was much higher than that of comparable CFST column. Furthermore, the formulas for calculating the bearing capacity of the FRP-CFST columns are proposed. The analytical calculated results agree well with the experimental results.

Seismic behavior of large-scale FRP–recycled aggregate concrete–steel columns with shear connectors

The application of fi ber-reinforced polymer (FRP) composites for the development of high-performance composite structural systems has received signifi cant recent research attention. A composite of FRP–recycled aggregate concrete (RAC)–steel column (FRSC), consisting of an outer FRP tube, an inner steel tube and annular RAC fi lled between two tubes, is proposed herein to facilitate green disposal of demolished concrete and to improve the ductility of concrete columns for earthquake resistance. To better understand the seismic behavior of FRSCs, quasi-static tests of large-scale basalt FRSCs with shear connectors were conducted. The infl uence of the recycled coarse aggregate (RCA) replacement percentage, shear connectors and axial loading method on the lateral load and deformation capacity, energy dissipation and cumulative damage were analyzed to evaluate the seismic behavior of FRSCs. The test results show that FRSCs have good seismic behavior, which was evidenced by high lateral loads, excellent ductility and energy dissipation capacity, indicating RAC is applicable in FRSCs. Shear connectors can signifi cantly postpone the steel buckling and increase the lateral loads of FRSCs, but weaken the deformation capacity and energy dissipation performance.

含FRP约束环钢筋连接装配柱的抗震性能分析

目的 为了提高装配式混凝土柱节点的连接性能,探索预制装配式构件的数值建模方法。方法 采用OpenSees有限元分析软件建立了采用新型连接方式的宏观单元模型,结合精细化纤维截面分区技术和基于零长度截面单元的应变渗透效应模拟技术,分析应变渗透效应、连接接缝位置以及轴压比等因素对柱抗震性能的影响。结果 连接接缝位置靠近柱根部时,装配柱的滞回性能降低;装配柱的累计耗能稍大于现浇柱;装配柱的延性系数在4.66~5.63内,极限位移角在1/51~1/71,均略小于现浇柱;不同轴压比条件下,装配柱的承载力和延性的变化规律与现浇柱相同。结论 连接接缝位置位于塑性铰区域外时,装配柱的承载力、刚度退化、耗能与现浇柱更为接近,在结构设计时应考虑预制柱连接接缝位置的影响。

Rapid Repair of Earthquake Damaged RC Interior Beam-wide Column Joints and Beam-wall Joints Using FRP Composites

This paper studies the seismic performance of FRP-strengthened RC interior non-seismically detailed beam-wide columns and beam-wall joints after limited seismic damage.Four eccentric and concentric beam-wide column joints and two beam-wall joints,initially damaged in a previous study,were repaired and tested under constant axial loads(0.1fc′Ag and 0.35fc′Ag) and lateral cyclic loading.The rapid repair technique developed,aimed to restore the original strength and to provide minimum drift capacity.The repair schemes were characterized by the use of:(a) epoxy injections and polymer modified cementitious mortar to seal the cracks and replace spalled concrete;and(b) glass(GFRP) and carbon(CFRP) sheets to enhance the joint performance.The FRP sheets were effectively prevented against possible debonding through the use of fiber anchors.Comparison between responses of specimens before and after repair clearly indicated reasonable restoration in strength,drift capacity,stiffness and cumulative energy dissipation capacity.All specimens failed with delamination of FRP sheets at beam-column joint interfaces.The rapid repair technique developed in this study is recommended for mass upgrading or repair of earthquake damaged beam-column joints.

FRP约束混凝土圆柱有软化段时的应力-应变关系研究

试验研究了不同数量、不同类型(高强度、高弹模、高延性)FRP约束混凝土圆柱的应力-应变关系,发现其应力-应变关系曲线可能有软化段也可能没有软化段。指出FRP约束混凝土圆柱的轴向最大应力主要与侧向约束强度或侧向约束刚度有关,而轴向极限应变除了与该两个参数有关外,还与FRP的轴向极限拉应变有关。基于试验及搜集到的数据,提出判断FRP约束混凝土圆柱有无软化段的侧向约束强度与混凝土强度比界限值。基于对FRP侧向约束刚度和强度、FRP轴向极限拉应变、混凝土强度及弹性模量等参数的分析,提出了FRP约束混凝土圆柱有软化段时的峰值应力、峰值应变、极限应力及极限应变计算公式。最后,建议了两个确定FRP约束混凝土圆柱有软化段时的应力-应变关系模型。与大量试验数据的比较表明,本文建议的公式和模型与试验结果均符合较好。

CFRP片材约束混凝土短柱徐变性能及极限承载力试验

通过不同形式轴压短柱试件727d徐变及极限承载力试验，研究长期持续荷载下徐变对CFRP约束混凝土柱极限承载力的影响。研究结果表明：CFRP约束混凝土柱的徐变发展趋势与素混凝土柱及钢筋混凝土柱基本相同；其徐变系数明显小于素混凝土柱，且混凝土强度等级愈低，徐变系数减小愈显著，而轴压比对徐变系数的影响较小，CFRP约束圆柱体的极限应变较CFRP约束棱柱体的极限应变大；长期荷载作用引起CFRP约束柱轴心受压极限变形降低4．5％～4．8％，引起无约束柱轴心受压柱极限变形降低23．2％～35．2％；CFRP能显著提高约束混凝土的极限承载力，且CFRP约束钢筋混凝土柱承载力的提高较CFRP约束素混凝土柱要小。

FRP-圆钢管混凝土短柱轴压性能研究

本文在10根FRP-圆钢管混凝土短柱轴心受压试验研究基础上,建立有限元模型,分析钢管壁厚、混凝土强度、FRP种类和层数及FRP弹性模量对FRP-圆钢管混凝土短柱轴心受压性能的影响。结果表明:随着钢管壁厚的增加,FRP-圆钢管混凝土短柱的屈服荷载和极限荷载增大;提高混凝土强度可小幅度提高短柱的极限荷载,对短柱延性影响不大;增加FRP层数会明显增大短柱极限荷载和延性;FRP层数相同时,与AFRP-圆钢管混凝土柱和CFRP-圆钢管混凝土柱相比,GFRP-圆钢管混凝土柱延性最佳。CFRP抗拉强度相同时,随着其弹性模量增大,短柱的延性减小;结合有限元计算结果,建立FRP-圆钢管混凝土短柱承载力简化计算式,其计算结果与试验结果吻合良好。

纤维增强复合材料(FRP)加固混凝土柱的性能研究进展

纤维增强复合材料(FRP)以其高强轻质、耐腐蚀、耐疲劳、施工便捷和不增加构件尺寸等诸多优点备受土木工程界的关注。本文根据现有资料,从材料性能、截面形式、试验研究和施工工艺等几个方面,对纤维复合材料加固混凝土柱的研究现状进行了评述。最后,对实际工程应用提出了一些建议。

CFRP加固混凝土翼缘受拉T形截面柱试验研究

目的研究碳纤维布(CFRP)加固钢筋混凝土异形柱的受力和变形性能,探讨构件截面几何参数、材料强度、材料用量等与翼缘受拉T形截面柱抗压弯承载力之间的定量关系.方法通过相同截面不同配筋量和碳纤维布粘贴量的试件进行单调一次短期加载对比试验,分析各因素对构件承载力和延性等的影响;运用力的平衡和材料的本构关系了建立构件承载力计算的力学模型.结果得到具有对比性的荷载-柱中挠度、材料应变-荷载的关系曲线并进行分析;得出碳纤维布加固钢筋混凝土翼缘受拉T形截面柱正截面抗压弯承载力计算公式.结论采用碳纤维布加固钢筋混凝土翼缘受拉T形截面柱以提高其正截面抗压弯承载力是可行的,T形截面柱加固的承载力计算公式对于类似的工程设计问题具有借鉴作用.

纤维增强复合材料(FRP)加固混凝土柱研究进展

纤维增强复合材料(FRP)在混凝土结构加固中得到了广泛的应用。依据国内外相关资料,从FRP材料类型与施工方法、试验加载形式、混凝土柱截面形式、加固后柱的强度、延性及破坏模式等方面,对FRP加固混凝土柱的大量研究成果进行了总结评述,并对今后可能的研究方向提出了展望。

大尺寸CFRP约束混凝土方柱落锤动态冲击试验研究

采用FRP增强的混凝土柱在使用过程中,可能受到轴向冲击荷载作用,但目前这方面的研究基本处于空白.通过对7组21个大尺寸CFRP约束混凝土方柱进行落锤轴向冲击试验,研究倒角半径r对约束柱抗冲击性能的影响.试验获取了锤头冲击力时程曲线、压缩变形时程曲线、FRP表面关键点的应变时程曲线和整个破坏过程的高速影像等信息.试验结果表明,CFRP约束混凝土方柱的破坏是由试件中部倒角位置处的CFRP被拉断所导致的,试件的破坏现象与倒角半径r有关;倒角半径r对约束柱的冲击性能有显著影响,r越大,冲击应力峰值和能量密度也越大;CFRP约束混凝土方柱的动力增大系数（DIF）随倒角半径比r.的增大而减小,基本成线性关系,在1.23-1.82之间.

CFRP加固钢筋混凝土腹板受拉L形柱的试验研究

目的研究碳纤维布(CFRP)加固钢筋混凝土异形柱的受力和变形性能,分析碳纤维粘贴量和配筋率对其抗压弯承载力的影响,并且探讨构件截面几何参数、材料强度、材料用量等与腹板受拉L形截面柱抗压弯承载力之间的定量关系.方法通过相同截面不同配筋量和碳纤维布粘贴量的试件进行单调一次短期加载对比试验,分析各因素对构件承载力和延性等的影响,运用力的平衡和材料的本构关系建立了构件承载力计算的力学模型.结果得到具有对比性的荷载-柱中挠度、材料应变-荷载的关系曲线并进行分析,得出碳纤维布加固钢筋混凝土腹板受拉L形截面柱正截面抗压弯承载力计算公式.结论采用碳纤维布加固钢筋混凝土腹板受拉L形截面柱以提高其正截面抗压弯承载力是可行的,L形截面柱加固的承载力计算公式对类似的工程设计具有借鉴作用.

FRP加固在役混凝土柱轴压试验方法

为研究FRP(fiber reinforced plastics)加固在役混凝土柱轴压性能的试验方法,采用后张预应力法对混凝土柱施加初始应力,然后采用附加刚性千斤顶加载法进行模拟FRP加固混凝土柱轴压加载试验,得到应力-应变全曲线。研究结果表明,该试验方法能较好地实现FRP加固在役混凝土柱轴心受压试验。

倒角半径对矩形FRP-钢复合管混凝土轴压性能的影响规律

通过对10个不同倒角半径的矩形纤维增强复合材料(FRP)-钢复合管混凝土试件的轴压性能试验,研究截面倒角半径对其轴压性能的影响。试验结果表明:在FRP断裂之前,钢管的局部屈曲能够得到有效的抑制,FRP的横向约束能够改善矩形钢管混凝土的受力性能,延缓其屈曲过程,相对于钢管混凝土,FRP对其承载力有提高效果;归因于角部的局部应力集中现象,FRP断裂位置都发生在试件中部的倒角部位,改变角部的倒角半径能够改善角部的应力集中,削弱FRP在角部的受力,提高FRP的约束效果;随着矩形截面倒角半径的增大,钢管混凝土或FRP-钢复合管混凝土的受力性能越好。

FRP加固钢筋混凝土构件裂缝研究进展与探讨

外贴FRP材料是一种非常流行的钢筋混凝土结构加固技术,但是与加固后构件承载力相比,在FRP加固构件正常使用性能方面的研究仍不够深入,尚存在许多值得探讨的问题。本文在总结分析国内外已有研究成果的基础上,研究了外贴FRP加固钢筋混凝土构件裂缝开展的机理和特点,分析探讨了我国钢筋混凝土构件裂缝开展性能预测方法用于该类加固构件时的适用性和存在的问题,并探讨了影响FRP加固构件裂缝形成及开展的主要影响因素,最后提出了建立新的裂缝预测模型的必要性。

FRP加固RC圆柱正截面受弯承载力计算(英文)

运用数值计算方法对FRP加固钢筋混凝土(RC)圆柱截面特性进行计算,发现截面破坏时受压区高度主要受轴压比、FRP约束强度比和纵筋配筋特征值3个主要参数影响.根据数值计算的结果进行回归,提出了受压区对应圆心角θ的计算方法.数值计算结果显示,横向约束导致的混凝土应力提高以及纵筋屈服后的强化效应使RC柱破坏时截面受弯承载力远大于规范规定值.根据理论分析和36个大比例试件实测结果提出截面破坏时受弯承载力计算方法,计算结果与试验结果吻合很好.最后,对一个典型柱变形能力进行参数分析,研究轴压比,纵筋配筋特征值和FRP约束强度比对正截面变弯承载力的影响.结果显示FRP加固圆柱破坏时受弯承载力可以比规范规定的未加固柱受弯承载力提高50%左右.

表层嵌贴FRP-混凝土黏结加固研究进展

表层嵌贴FRP修复加固混凝土结构是一种富有前景的新型技术,目前该技术领域的研究主要集中在黏结机理和抗弯加固两方面。论述表层嵌贴FRP-混凝土的试验方法、主要控制参数、破坏模式、黏结机理、界面黏结滑移本构关系等。最后,对目前国内外表层嵌贴FRP-混凝土黏结性能的研究现状进行探讨,希望为表层嵌贴FRP加固技术的进一步研究发展提供方向。

外贴FRP加固钢筋混凝土梁用量显式设计方法

对外贴FRP(纤维增强复合材料)加固钢筋混凝土梁抗弯极限承载力的求解问题,ACI 440F规范及我国CECS 146:2003规程都给出了相应的求解公式,但均为验算形式.这在面向设计,即计算给定目标承载力下的FRP用量时,并不方便.针对矩形截面形式,通过引入原构件配筋特征参数和FRP配筋特征参数,推导出量纲一形式的弯矩增量与参数之间的关系表达式,并给出显式求解FRP用量的计算方法.在此基础上,进一步通过定义截面形状系数,将这一显式求解方法推广至T形及更为一般性的截面形式.