Near Surface Mounted Application for the Strengthening of Rectangular Reinforced Concrete Slender Columns under Eccentric Load

The behavior of slender columns under the effect of eccentric loading has always taken the attention of researchers. When investigating the strengthening of reinforced concrete columns, mainly short and circular columns are the targeted elements. This is why the data about slender columns with rectangular sections is limited and infrequent specially when loaded eccentrically. This paper aims to increase the available experimental data in this specific area. The experimental program consisted of twenty seven specimens. The specimens were divided into three groups; one control group and two groups strengthened using two strengthening schemes. Scheme 1 implied the use of near surface mounted （NSM） longitudinal steel bars, while in scheme 2, NSM longitudinal steel bars partially wrapped with one ply of carbon fibers reinforced polymers （CFRP） sheets was used. The test specimen had an overall length of 2000 mm and a 100 x 200 mm rectangular cross section. In addition to the strengthening schemes, the test parameters included three ratios for the internal longitudinal steel bars ＂μ＂ 1%, 1.57% and 2.26%. The parameters were extended to cover three stirrups＇ volumetric ratio ＂ρv＂ 0.73%, 0.49% and 0.37%. The specimens were tested under the effect of eccentric loading with eccentricity-to-section height e/h equals 0.25. The research revealed that the strength gain in specimens strengthened with scheme 2 was higher than with scheme 1. Analytical modeling of the stress strain relation of the strengthened RC columns considering the effect of strengthening scheme, internal reinforcement ratio μ, and stirrups＇ volumetric ratio ＂ρv＂ was proposed. Verification was made using available experimental data. The proposed model showed a reasonable agreement with the experimental results.

Analysis on Critical Force of Unidirectional CFRP Slender Column

Carbon Fiber Reinforced Polymer(CFRP) has such characteristics as light weight, high strength and corrosion resistance, so it is suitable for corrosive environment and large-span structures. This study investigated the stability of CFRP slender column, whose slenderness is greater than Euler’s critical load. The columns in this study were formed by a two-step process and the fiber direction was along the same direction of column axis. Firstly, we obtained the basic mechanical properties of the material by tensile experiment. Then, we studied the critical force of 10 CFRP columns with different lengths and widths by axial compression test. Finally, by comparing Euler’s formula with the modified Euler formula and combining with existing literature and experimental result of this paper, we proposed a modified Perry formula which could well predict the critical force of unidirectional CFRP extruded column and could be used for CFRP extruded column research and engineering design.

Numerical study of axial-loaded circular concrete-filled aluminum tubular slender columns

Aluminum alloys have been widely applied in coastal and marine structures because of their superior sustainability and corrosion resistance.Concrete-filled double-skin aluminum tubular columns(CFDAT)possess higher strength and better ductility than traditional reinforced concrete structures.However,few studies have been conducted on numerical simulation methods for circular CFDATs.Specifically,there has been no experimental or numerical study on intermediate-to-slender circular CFDATs.Here,a comprehensive numerical study was conducted on a modeling method for the first time to simulate the axial behavior of a slender circular CFDAT.This study outlines the development of numerical modeling techniques and presents a series of comparative studies using various material nonlinearities,confinement effects,and nonlinearity of the initial geometric imperfections for a slender column.The numerical results were compared with more than 80 previously available stub and slender experimental test results for verification.It was confirmed that the proposed numerical technique was reliable and accurate for simulating the axial behavior of intermediate and slender circular CFDAT.Furthermore,a parametric study was conducted to investigate the effects of geometric and material properties on the axial capacity of the CFDAT.Additionally,the slenderness and strength-to-width ratio of CFDAT were compared with those of concrete-filled double-skin steel tubular columns(CFDST).The simulated axial strengths were compared with those predicted using AS 5100 and AISC 360.New design equations for the CFDATs should be proposed based on AS 5100.

Behaviour of Reinforced Concrete Columns Strengthened with Ferrocement under Compression Conditions: Experimental Approach

This paper reports a study based upon experimental investigation which aims to assess the behaviour of reinforced concrete columns strengthened with a new configuration of steel wire mesh as part of ferrocement layer under the action of axial compression loads. Square and circular small scale columns with three different slenderness ratios of 5, 6.7 and 10 were adopted. A comprehensive experimental progarmme was then running to measure the load capacity and both lateral and vertical displacements. The failure mode was also monitored for each tested case. The results obtained was compared with the reference column samples (without wire mesh) and with some expressions suggested by ACI Code. The experimental results showed that the most influential parameter on the property of load carrying capacity is the slenderness of column. As the slenderness increases, the load capacity clearly decreases. The use of wire mesh enhanced the capability of column to resist the axial loads due to confinement role provided by such material. The maximum percentage increase in load carrying capacity for the modified columns compared with those for the reference samples was 53% for the circular column at slenderness ratio of 10. The critical path of the failure mode was similar for all of the tested columns and normally began from the top or bottom ends, then, in some cases, passed through the middle zone of the column. A suitable expression was suggested to be used for calculating the modulus of elasticity of the tested column based upon the value of load carrying capacity under compression loads.

钢管预置集料混凝土中长柱受压性能试验

为了探究钢管预置集料混凝土中长柱受压性能,首先,考虑混凝土类型、混凝土强度、径厚比、长径比和偏心率等参数影响,设计了11根钢管预置集料混凝土中长柱和3根普通钢管混凝土中长柱;其次,通过轴压和偏压试验,并结合有限元分析法,研究了试件破坏形态、承载力、变形特征等变化规律;最后,基于极限平衡理论,提出了适用于钢管预置集料混凝土中长柱轴压与偏压承载力计算公式。研究结果表明:钢管预置集料混凝土中长柱破坏形态与普通钢管混凝土中长柱的破坏形态相似,均为弯曲失稳破坏;钢管预置集料混凝土中长柱承载能力与普通钢管混凝土中长柱承载能力相当,但钢管预置集料混凝土试件轴向刚度是普通钢管混凝土试件轴向刚度的1.2倍左右,表现出良好的抗变形能力;钢管预置集料混凝土中长柱径厚比由39.75降低至19.88,承载能力提高33.8%;长径比由6增大至15时,承载能力降低20.5%;偏心率由0.25增大至1.0时,承载力降低49.5%;钢管预置集料混凝土中长柱稳定系数受混凝土强度和径厚比影响较小,但随着长径比和偏心率增大而近乎呈线性降低趋势。本文提出的承载力计算公式可为钢管预置集料混凝土中长柱设计提供参考。

长细比对内置工字形CFRP型材的圆钢管混凝土构件力学性能影响

目的 研究长细比对内置工字形CFPR型材高强圆钢管高强混凝土轴压构件力学性能的影响,为该类型柱设工程计提供依据。方法 采用ABAQUS有限元软件对组合柱进行有限元模拟,分析不同长细比下钢材强度、混凝土强度等参数对组合柱力学性能的影响。结果 组合柱发生弹性和弹塑性失稳破坏的界限长细比为66.67,经验证理论公式的预测值与模拟值平均误差为3.01%。对于弹性失稳破坏的构件,与钢材强度相比,混凝土强度对构件的极限承载能力影响较大,且钢材屈服强度对钢管内力分配占比的影响较小。在组合构件中,高强混凝土所承担的荷载比例最低可达到普通强度混凝土所承担荷载的1.2倍。结论 发生弹性失稳破坏的构件可以通过提高混凝土强度达到提高构件承载力的目的;与普通强度混凝土相比,在组合柱中采用高强混凝土和高强钢管,可以使组合柱具有更好的组合效应;工字形CFRP对于组合柱极限承载力的提升主要体现在发生弹塑性失稳破坏的构件。

UHPC加固RC柱的轴压性能试验及有限元模拟分析

超高性能混凝土(UHPC)因其优异的力学性能和耐久性能,广泛应用于钢筋混凝土结构的加固中。对UHPC加固钢筋混凝土短柱轴心受压进行试验研究,利用ABAQUS有限元分析软件建立UHPC加固钢筋混凝土短柱轴心受压的有限元模型,峰值荷载模拟值与试验值吻合良好。分析长细比对加固柱荷载及塑性变形性能的影响,每组5个试件长细比分别为2,4,6,8和10,共6组30个试件。结果表明:相同长细比下UHPC加固钢筋混凝土柱能较大提升柱的承载力和延性;随着长细比L 0/d增大,加固柱的承载力降低,破坏时试件的极限位移明显增大;当长细比进一步增大,试件极限承载力降低趋势开始变缓,峰值荷载对应的位移增大,抵抗塑性变形能力变差,该研究为UHPC加固钢筋混凝土柱工程应用提供参考。

基于机器学习的圆钢管再生混凝土长柱偏压承载力计算方法

目的 研究圆钢管再生混凝土长柱偏压承载力与各设计变量之间的映射关系,建立高精度的预测模型,并对机器学习模型进行可解释性分析。方法 建立包含155个样本的数据库,并对机器学习模型所选输入变量进行VIF检验;采用RBFNN、RF、LightGBM及XGBoost算法建立偏压承载力预测模型,基于判定系数R^(2)、均方根误差RMSE及平均绝对误差MAE,选取最适用于圆钢管再生混凝土长柱偏压承载力的预测模型;采用SHAP法解释输入变量对承载力的贡献程度及各输入变量的影响机理。结果 输入变量间的VIF系数小于5,变量间不存在明显的多重共线性;构建的XGBoost算法为最佳预测模型,模型的R^(2)、RMSE及MAE分别为0.998、16.397、7.76。结论 XGBoost模型能够实现圆钢管再生混凝土长柱偏压承载力的高精度预测;偏心率、试件直径是影响其承载力的关键变量;圆钢管再生混凝土长柱偏压承载力随着再生骨料取代率的增加而降低。

7A04-T6铝合金矩管柱抗震性能研究

为研究7A04-T6铝合金矩管柱的抗震性能,在验证有限元模型可行性的基础上,对12根7A04-T6铝合金矩管在低周反复荷载下的加载过程进行模拟。根据模型计算结果分析长细比、轴压比及截面形式对7A04-T6铝合金矩管抗震性能影响,得出随着长细比、轴压比的增大,构件抗震性能变差,与加载方向对应的矩管柱腹板尺寸对其抗震性能起着主导作用。同时提出了可用于预测7A04-T6铝合金矩管抗震性能的骨架曲线模型,并验证了模型的准确性。

圆钢管煤矸石混凝土中长柱轴压性能有限元分析

目的研究圆钢管煤矸石混凝土中长柱的轴压性能,找到各设计参数对试件轴压承载力的影响规律,提出轴压承载力计算式,推广钢-煤矸石混凝土组合结构。方法采用ABAQUS有限元分析软件建立圆钢管煤矸石混凝土中长柱轴压有限元模型,分析典型试件受力全过程的应力分布、荷载分配以及不同参数变化对其轴压承载力的影响。结果相同设计参数下,钢材屈服强度与含钢率是承载力的关键影响因素;而随煤矸石粗骨料取代率的增加,试件的承载力降低幅度未超过3.6%。结论掺入煤矸石粗骨料后的试件仍具有较高承载力,依据《钢管混凝土结构技术规范》(GB 50936—2014)中的方法对计算式进行修正后的误差在10%以内,适用于圆钢管煤矸石混凝土中长柱,能够满足实际需求。

海洋环境纤腰独柱式异形混凝土索塔施工技术

黄茅海跨海通道2座斜拉桥的5座主塔均采用纤腰独柱式异形混凝土索塔,造型优美、结构简洁。结构及施工环境复杂,面临着截面变化剧烈,模板及爬架设计困难;钢筋数量多,高空绑扎效率低安全风险高,保护层厚度控制难度大,影响海洋环境下混凝土耐久性;C55混凝土水泥用量多、水化热大,8cm保护层素混凝土开裂风险高等一系列施工难题。通过采用参数化模板设计、数控机床雕刻加工造型箱模板;钢筋分块部品施工工艺;优化配合比,掺加粘度改性剂,在保护层范围内增设玄武岩纤维等一系列施工措施,解决了相关技术难题,确保了施工质量,提高了施工效率,降低了安全风险,快速优质地完成了异形混凝土索塔的建造,为类似项目的施工提供了借鉴。

冷弯高强钢椭圆管柱力学性能有限元分析

冷弯高强钢椭圆管柱由于其椭圆截面的几何特殊性和优越的力学性能而被广泛应用。然而,目前国内外缺乏系统性的冷弯高强钢椭圆截面的研究和设计指导。现通过数值模拟的方法,分析了冷弯高强钢椭圆管柱的轴压性能,并将得到的有限元数据与现行的欧洲规范进行对比。对比表明,欧洲规范中冷弯高强钢椭圆管柱的屈曲曲线过于保守。由此,提出了新的设计曲线,为冷弯高强钢椭圆管柱提供新的设计参考。

再生混凝土长柱的抗震性能试验研究

为研究再生混凝土框架柱的抗震性能,对剪跨比为4、截面尺寸为450 mm×450 mm的6根再生混凝土柱和1根普通混凝土柱进行低周反复荷载试验.试验参数主要为纵筋率、轴压比、箍筋加密区的体积配箍率,其中配箍率的取值与国家规范的要求接近.结果表明,低轴压、低配箍的再生混凝土柱可实现良好的延性和变形性能,能满足抗震设计的要求;较高轴压、低配箍的再生混凝土柱最终发生剪切压溃,呈现出显著的脆性性质;较高轴压的再生混凝土柱在提高配箍后,延性与耗能性能得以改善.建议轴压比不宜过大,并适当提高配箍要求.此外,分析表明再生混凝土柱极限受弯承载力的计算可采用与普通混凝土柱类似的方法,通过考虑钢筋强化、合理选取再生混凝土的本构模型进行准确计算.

钢管活性粉末混凝土长柱轴压性能试验研究

通过14根钢管活性粉末混凝土(钢管RPC)长柱试件的轴压试验,研究钢管RPC柱的长细比及大长细比下套箍系数对钢管RPC柱轴压性能的影响。结果表明:试件的破坏基本属弹性失稳破坏类型,其中长细比较小的试件除弯曲失稳破坏外还伴随着局部受压鼓曲破坏,长细比越小,试件的延性破坏特点越明显,随着长细比的增加,试件也由弹性破坏逐渐转向失稳破坏;试验得到的钢管RPC长柱轴压荷载—应变曲线主要分为弹性阶段、弹塑性阶段和卸载阶段;在相同套箍系数下,随着长细比的增加,钢管RPC长柱的极限承载力和极限位移均逐渐降低;在大长细比下试件的套箍系数越大,其极限承载力也越大,但增加的幅度逐渐变小,钢管对RPC的约束能力不如普通混凝土。

FRP强约束混凝土配筋柱稳定承载力的试验研究

通过长细比Lb为4.5～17.5的6根截面经圆弧化处理、外包FRP后的矩形截面的钢筋混凝土柱的轴心受压试验,研究了长细比对稳定承载力的影响。结果表明:长细比对FRP约束混凝土柱的稳定承载力影响远比螺旋配筋柱和普通钢筋混凝土严重,但当长细比不大于17.5时,其稳定承载力仍比未包裹柱高20%(约束比ξ=0.188)以上。讨论了影响稳定系数φ的因素,给出了稳定系数的参考值,可供工程设计人员参考。

CFRP与角钢复合加固钢筋混凝土中长柱的受力分析

通过9根外包角钢与碳纤维布复合加固钢筋混凝土中长柱轴心受压试验,把复合加固柱核心混凝土分成有效约束区和弱约束区,研究了有效约束区和弱约束区混凝土的本构关系.在此基础上,把柱截面划分成若干计算单元,编制了全过程分析程序进行数值模拟计算.研究表明,计算结果与试验结果吻合较好,可为工程应用提供参考.

钢管混凝土结构抗震性能的研究

近二十年来,钢管混凝土已广泛应用于高层和超高层建筑中,取得了明显的经济效益。应用日见增多,发展十分迅速。但对这种结构抗震性能的研究还不多,不能满足工程设计的要求,影响了它的推广应用。本文介绍了两端固定框架柱、单层框架和空间桁架体系的抗震性能的研究和试验,得到了钢管混凝土柱不限制轴压比时长细比的限值,可供研究和设计工作者参考。

钢骨-钢管高强混凝土长柱承载力可靠度分析

基于《建筑结构可靠度设计统一标准》(GB50068-2001),利用一次二阶矩法(JC法)对钢骨-钢管高强混凝土轴压长柱的极限承载力进行了可靠度分析,研究了可变荷载组合类型、荷载效应比、混凝土强度等级、钢管壁厚、钢骨截面面积、钢材屈服强度及长细比对组合柱承载力可靠指标的影响。分析结果表明,在工程常用长细比范围内,各公式的可靠指标均能满足规范对延性构件可靠度指标的要求;在所研究参数范围内,长柱的可靠度指标随荷载组合和荷载效应比的变化而变化,随混凝土强度等级的提高而增大,随钢管壁厚的增加而有所降低,钢骨截面面积对长柱的可靠指标无明显影响,同时,钢材屈服强度和长细比对各公式可靠指标的影响各不相同。

四肢钢管混凝土格构柱极限承载力的试验研究与理论分析

进行共计20根缀条为K形布置的四肢钢管混凝土格构柱偏压及轴压极限承载力试验,重点考察偏心率与长细比对钢管混凝土偏压构件受力性能的影响。试验结果表明,长细比对试件承载力有一定影响,偏心率对承载力影响明显,两者对承载力的影响接近独立,试件的斜缀条在试验过程中始终保持弹性状态,近载一侧钢管在试件进入非线性阶段后,泊松比明显增大,钢管开始发生套箍作用,远载一侧,套箍作用不明显,除个别短柱外,试件破坏均为整体失稳破坏。同时,采用半波正弦曲线模拟杆件的变形曲线,在考虑紧箍效应的钢管混凝土应力-应变关系和剪切变形影响的基础上,建立杆件中截面的平衡方程,提出钢管混凝土格构柱弹塑性极限承载力数值方法,该方法不仅适用于两端偏心相等的偏压构件,而且适用于两端偏心不等的偏压构件的弹塑性极限承载力的计算;理论分析结果与试验研究结果对比表明,提出的钢管混凝土格构柱弹塑性极限承载力计算方法具有相当高的精度。

区域约束混凝土轴心受压矩形柱受力性能研究

在试验研究基础上对区域约束混凝土(RCC)轴心受压矩形柱与复合约束混凝土(NCC)矩形柱进行了对比分析,在同等配箍率情况下,在箍筋屈服以前,区域约束混凝土的约束效率经初步推断可提高约50%,峰值前的区域约束混凝土柱应力应变关系更接近于线性;随着荷载的增加,复合约束混凝土柱截面向圆形过渡,核心区内角部混凝土部分脱落,矩形方箍有应力松弛现象,而区域约束混凝土柱始终保持截面为矩形,箍筋的应力一直保持持续增长,受力均匀;区域约束混凝土柱破坏形态也与复合约束混凝土柱完全不同,在承载力下降段,当复合混凝土柱以剪压形式破坏时,区域约束混凝土柱沿中间弱约束处分成细长的小柱,经过很大的变形后,小柱仍然保持很好的完整性,柱的残余承载力在40%以上,预计这种特点将会对结构的抗震性能产生良好的影响。