偏心受压钢筋混凝土长柱承载力分析

采用考虑混凝土材料非线性及长柱几何非线性的有限元方法 ,对偏心受压钢筋混凝土长柱的承载力进行计算和分析 ,提出了一种较为实用的分析方法。计算结果表明 。

钢骨-钢管混凝土轴压短柱承载力研究

把钢骨-钢管混凝土组合柱视为一个新型组合材料的统一体,结合试验成果,分析轴压短柱承载力的影响因素,提出影响组合柱承载力和延性的因素,即约束指标,提出钢骨-钢管混凝土轴压短柱的承载力公式。

考虑单肢轴向变形影响时钢缀板柱承载力的一种理论分析方法

一、基本假定双肢缀板柱是在钢结构中广泛运用的一种构件。本文系将双肢缀板柱视作由弹性肢杆和刚性缀板组成的结构体系,拟考虑按两弹性肢杆轴向变形不同对缀板柱整体承载力的影响,提出一种理论分析方法。该分析方法作如下基本假定:

柱失效方程中荷载相关特性对承载力抗震设计可靠度的影响

以竖向荷载和水平地震作用组合下的钢筋混凝土柱和钢柱为对象,研究了失效方程中荷载相关特性对柱承载力抗震可靠性的影响。根据现行《混凝土结构设计规范》和《钢结构设计规范》分析了不同柱弯矩轴力相关曲线的特性。结合多个框架结构实例,对比了柱失效方程中荷载相关曲线与规范考虑情形的异同。实例分析表明:水平地震和竖向荷载组合作用下,小偏压RC柱和工字型钢柱的荷载相关曲线与规范考虑的情形较为符合,均近似为负相关的直线;水平地震和竖向荷载组合作用下,大偏压RC柱的荷载相关曲线则与规范考虑的情形有较大出入,存在明显的正相关段部分。在此基础上,考虑失效方程复杂特性,依据已有的荷载和抗力变量概率模型,采用Monte Carlo法分析了水平地震和竖向荷载组合作用下柱的可靠性。结果表明:钢柱和小偏压RC柱的承载力抗震可靠度随轴压力荷载效应比值的变化幅度较小,与规范模式计算结果较接近;大偏压RC柱的承载力抗震可靠度随轴压力荷载效应比值的变化会有较大幅度波动,与规范模式计算结果差异较大;当轴压力荷载效应比值为负时,大偏压RC柱的承载力抗震可靠度会低于规范计算值较多,现行柱可靠性设计方法会偏于不安全。

不同柱梁抗弯承载力比对框架结构抗倒塌性能的影响

设计不同柱梁抗弯承载力比(ηc-bua)的5个纤维增强混凝土(FRC)框架结构及3个钢筋混凝土(RC)框架结构,利用性能评估软件Perform-3D进行Pushover及IDA计算分析,得出其破坏机制及易损性曲线。结果表明,柱、梁端部局部采用FRC后,承载力有一定提高,峰值位移有较大提高;ηc-bua对FRC框架结构的破坏机制影响很大;ηc-bua对FRC框架结构地震反应也有一定的影响,其比值越大,超越概率越小,且随期望破坏程度的加重,这种影响也趋于明显,当ηc-bua在1.2以上时,结构的倒塌概率均小于10%,满足大震不倒的概率要求。

FRP加固轴压混凝土矩形截面柱的承载力计算

在分析FRP约束混凝土矩形截面柱受力机理的基础上,建立了FRP约束混凝土矩形柱截面的有效受压区的计算模型,结合已有的试验数据,提出了FRP加固混凝土轴心受压矩形截面柱极限承载力的实用计算公式.

地基承载力特征值和桩端承载力特征值的比较研究

工程中常涉及到地基承载力特征值fa及桩端阻力qpa,作为同量纲的地基指标,对同一土层后者往往要比前者高得多。运用梅耶霍夫地基极限承载力理论,分析了随基础埋深的加大地基土破坏形式的变化,对浅基础及桩基础破坏形式、地基承载力特征值fa与桩端承载力特征值qpa作了对比。研究结果将有利于建立及区别地基承载力特征值及桩端端阻力特征值的物理概念,对实际工程具有指导意义。

顶升可缩式钢管混凝土支柱试验研究与工程应用

针对沿空留巷巷旁支护存在的问题,提出基于顶升可缩式钢管混凝土支柱的巷旁支护技术。设计了顶升可缩式钢管混凝土支柱结构与留巷工艺,为验证该支柱增阻让压性能,开展了不同让压结构的可缩承载试验,研究表明:杨木可缩阶段承载力200 kN、极值承载力700 kN,松木可缩阶段承载力500 kN、极值承载力900 kN,钢筋网柱可缩阶段承载力400 kN、极值承载力750 kN,以松木的压缩率最高,达到77.7%,可见,松木更适合作为让压结构。通过分析钢管混凝土短柱和长柱承载力试验结果,验证了钢管混凝土支柱高承载力特征,修正了支柱承载力长细比折减系数,优化了顶升可缩式钢管混凝土支柱承载力计算公式。通过文献分析选取了合理的巷旁支护阻力和压缩量计算方法,以鲁西煤矿3_(下)A02工作面沿空留巷为例,进行了巷旁支护阻力和压缩量计算分析,以试验研究为基础,开展了顶升可缩式钢管混凝土支柱结构设计、支柱受力分析和工程实践研究。实践表明采用单排φ299 mm×10 mm顶升可缩式钢管混凝土支柱+一排φ21.6 mm×10300 mm控顶锚索的巷旁支护,辅以挡风帘+网喷层的采空区隔离方案,能够保证沿空留巷长期稳定,该技术具有顶升初撑效果好、增阻变形能力强、支护承载力高等特点,在基本顶沉降运动剧烈的留巷工程中具有较好的应用前景,若进一步配合采空区侧切顶卸压和支柱外壳钢管回收复用,留巷效果将更优。

常温及火灾后自应力轻骨料钢管混凝土柱轴压力学性能试验研究

自应力钢管陶粒混凝土不仅具有轻质、高强的特点,并可弥补轻集料混凝土因弹性模量较小而导致钢管约束不足的缺陷。本文通过对4组12根受火后的钢管自应力陶粒混凝土短柱及9根未受火钢管混凝土短柱受力性能的对比试验,分析了不同参数的钢管自应力陶粒混凝土短柱火灾后轴压承载力和破坏形态。重点讨论了试件的自应力大小(膨胀剂掺量)、含钢率及受火条件等因素对钢管自应力陶粒混凝土短柱火灾后轴压承载力及相关力学性能的影响。结果表明,自应力大小对钢管陶粒混凝土短柱火灾后轴压承载力的影响与试件含钢率有关,且初始自应力对含钢率相对较低试件的火灾后轴压性能的改善效果更加显著;试件含钢率越高,轴压力作用下的火灾后钢管自应力陶粒混凝土短柱的延性则越好。膨胀剂掺量为51 kg/m3(P2型)的试件,无论受火温度为700℃还是900℃,其火灾后的线弹性刚度受试件含钢率影响的规律基本一致。

矩形钢管混凝土轴压短柱研究

针对矩形钢管混凝土轴压短柱其钢管对核心混凝土的约束作用对轴压构件的承载力影响的问题,通过理论计算与试验数据分析对比,提出了用一个一次二项式来拟合相关系数与截面形状系数的关系及用截面形状系数来修正圆钢管混凝土轴压短柱承载力公式在实际应用中的可行性。

翼缘宽度对预期损伤部位采用FRC增强的梁柱组合件破坏机制影响的试验研究及数值模拟

为研究现浇板翼缘宽度和纤维增强混凝土(FRC)材料对框架结构破坏机制的影响,设计制作一组纵梁腹板两侧各6倍和8倍板厚翼缘宽度,且带有横交梁的梁柱组合件,试件的预期损伤部位采用FRC材料,柱梁抗弯承载力比分别取1.2和1.4;对试件进行拟静力试验,考察试件的破坏过程和破坏形态,分析其破坏机制和翼缘板内钢筋的应变分布,研究试件的变形和耗能能力、强度和刚度退化等抗震性能。在试验研究基础上,对试件原型破坏过程进行数值模拟,并进行了参数分析。结果表明,预期损伤部位范围内的梁、柱和板采用FRC材料,在一定程度上可以减小板对梁抗弯承载力影响的范围,易于实现"强柱弱梁"的破坏机制;考虑8倍板厚翼缘宽度的梁柱组合件更易于实现"强柱弱梁"的破坏机制,并且能显著降低其强度退化系数,提高其耗能能力。

柱梁端受弯承载力比对局部FRC增强的梁柱组合体破坏机制影响的试验研究

为研究在预期损伤部位采用纤维增强混凝土(FRC)和柱梁端受弯承载力比对框架结构破坏机制的影响,设计了5个带有翼缘板的不同柱梁端受弯承载力比值的梁柱组合体,其中4个试件的预期损伤部位采用FRC材料增强,1个试件全部采用普通混凝土。通过对试件进行拟静力试验,分析其破坏机理、变形和耗能性能以及承载力等。研究结果表明,与普通钢筋混凝土梁柱组合体相比,预期损伤部位采用FRC梁柱组合体的峰值荷载提高了13%,极限层间侧移角增大了17%,总耗能提高了40%,抗损伤能力明显提高;考虑梁两侧各6倍板厚翼缘宽度内钢筋对梁端弯矩的影响,当柱梁端受弯承载力比为1.2时,可基本实现强柱弱梁破坏机制,当比值为1.4时,可完全实现强柱弱梁破坏机制。

新旧建筑抗震设计规范关于“强柱弱梁”的对比和分析

从框架柱弯矩调整系数、抗震构造措施等方面对我国新旧建筑抗震设计规范(GB 50011-2010和GB 50011-2001)关于"强柱弱梁"上规定的差异进行了比较分析,详细地分析了影响"强柱弱梁"实现的主要因素。采用新旧两个抗震设计规范分别对抗震等级为一、二、三级的3个钢筋混凝土现浇楼板框架结构进行了计算分析,分别计算新旧两个规范下,考虑现浇楼板及其钢筋对框架梁抗弯承载力的贡献时节点处柱梁端实际抗弯承载力比,并对其进行了比较分析。

Ultimate flexural strength of normal section of FRP-confined RC circular columns

Numerical analysis is carried out to study the sectional properties of the fiber-reinforced polymer（FRP）-confined reinforced concrete（RC）circular columns. The axial load ratio, the FRP confinement ratio and the longitudinal reinforcement characteristic value are the three main parameters that can influence the neutral axis depth when concrete compression strain reaches an ultimate value. The formula for computing the central angle θ, corresponding to the compression zone, is established according to the data regression of the numerical analysis results. The numerical analysis results demonstrate that the concrete stress enhancement from transverse confinement and strain hardening of the longitudinal reinforcement can cause a much greater flexural strength than that defined by the design code. Based on the analytical studies and the test results of 36 large scale columns, the formula to calculate the flexural strength when columns fail under seismic loading is proposed, and the calculated results agree well with the test results. Finally, parametric studies are conducted on a typical column with different axial load ratios, longitudinal reinforcement characteristic value and FRP confinement ratios. Analysis of the results shows that the calculated flexural strength can be increased by 50% compared to that of unconfined columns defined by the code.

现浇楼板对钢筋混凝土框架结构抗震性能的影响

本文通过PKPM结构计算软件建模并求得配筋,通过改变楼板厚度来分析在梁的每侧不同板翼缘宽度的情况下现浇楼板对于梁端承载力和柱端承载力的影响,进而分析是否会发生"强梁弱柱"这种破坏机制.结果表明,边节点和中节点的梁端承载力会随着梁的每侧板翼缘宽度的增加而增加,并且随着现浇楼板厚度的增大,梁端承载力增加的幅度也会增大.但是,由于边节点柱是构造配筋,柱的承载力会提高很多,所以不会发生"强梁弱柱"这种破坏机制,而中节点在考虑现浇楼板对梁端承载力影响的情况下则会发生"强梁弱柱"这种破坏机制.

Strength of circular concrete columns under concentric compression

An experimental study, in which six columns were loaded concentrically toinvestigate the behavior of reinforced normal strength and high strength circular columns underconcentric compression, is described. The concrete strengths of the columns were 30 MPa and 60 MPa.The primary variables considered were the concrete strength and the amount of transversereinforcement. Test results indicate that smaller hoop spacing provides higher column capacity andgreater strength enhancement in a confined concrete core of columns. For the same lateralconfinement, high strength concrete columns develop lower strength enhancement than normal strengthconcrete columns. Both the strength enhancement ratio (f'_(cc) /f'_(co)) and the column capacityratio (P_(test)/P_o) were observed to show linear increase variations with rho_s f_(yt)/f'_c incircular columns.

Mechanical Behavior of Rectangular Steel-Reinforced ECC/Concrete Composite Column under Eccentric Compression

In order to improve the seismic performance, deformation ability and ultimate load-carrying capacity of columns with rectangular cross section, engineered cementitious composite （ECC） is introduced to partially substitute concrete in the edge zone of reinforced concrete columns and form reinforced ECC/concrete composite columns. Firstly, based on the assumption of plane remaining plane and the simplified constitutive models, the calculation method of the load-carrying capacity of reinforced ECC/concrete columns is proposed. The stress and strain distribu- tions and crack propagation of the composite columns in different states of eccentric compressive loading are ana- lyzed. Then, nonlinear finite element analysis is conducted to study the mechanical performance of reinforced ECC/concrete composite columns with rectangular cross section. It is found that the simulation results are in good agreement with the theoretical results, indicating that the proposed method for calculating the load-carrying capacity of concrete/ECC composite columns is valid. Finally, based on the proposed method, the effects of ECC thickness, com- pressive strength of concrete and longitudinal reinforcement ratio on the mechanical performance of reinforced ECC/ concrete composite columns are analyzed. Calculation results indicate that increasing the thickness of ECC layer or longitudinal reinforcement ratio can effectively increase the ultimate load-carrying capacity of the composite column with both small and large eccentricity, but increasing the strength of concrete can only increase the ultimate Ioad- carrying capacity of the composite column with small eccentricity.

Unified bearing capacity model of confined concrete column subjected to axial compression

To better study the behavior of confined concrete, this paper presents the basic hypothesis of uhimate equilibrium of confined concrete and the unified yield criteria of confining material. Based on the static equilibrium condition and yield criteria of components, a unified bearing capacity model of confined concrete column is proposed, and a simplified calculating equation of the model is also given. The model captures the character of confined concrete column. Effects of the confinement effect ratio, the lateral confinement ratio, unconfined concrete strength and the properties of confining material on the bearing capacity of confined concrete column are carefully considered. The model may be applicable to the calculation of bearing capacity of steel-confined concrete, concrete filled steel tube and FRP-confined concrete. The predictions of the model agree well with test data.

Seismic Behavior of Specially Shaped Column Joints with X-Shaped Reinforcement

To investigate the seismic behavior of specially shaped column joints with X-shaped reinforcement,two groups of specimens with or without X-shaped reinforcement in joint core region were tested under constant axial compression load and low reversed cyclic loading,which imitated low to moderate earthquake force.The seismic behavior of specially shaped column joints with X-shaped reinforcement in terms of bearing capacity,displacement,ductility,hysteretic curve,stiffness degradation and energy dissipation was studied and compared to that without Xshaped reinforcement in joint core region.With the damage estimation model,the accumulated damage was analyzed.The shearing capacity formula of specially shaped column joints reinforced by X-shaped reinforcement was proposed with a simple form.The test results show that X-shaped reinforcement is an effective measure for improving the seismic behavior of specially shaped column joints including deformation behavior,ductility and hysteretic characteristic.All specimens were damaged with gradual stiffness degeneration.In addition,X-shaped reinforcement in the joint core region is an effective way to lighten the degree of cumulated damage.The good seismic performance obtained from the specially shaped column joint with X-shaped reinforcement can be used in engineering applications.The test value is higher than the calculated value,which indicates that the formula is safe for the design of specially shaped column joints.

Parametric analysis of thermal effect on hydrostatic slipper bearing capacity of axial piston pump

Hydrostatic slipper was often used in friction bearing design, allowing improvement of the latter's dynamic behavior. The influence of thermal effect on hydrostatic slipper bearing capacity of axial piston pump was investigated. A set of lumped parameter mathematical models were developed based on energy conservation law of slipper/ swash plate pair. The results show that thermal equilibrium clearance due to solid thermal deformation periodically changes with shaft rotational angle. The slipper bearing capacity increases dramatically with decreasing thermal equilibrium clearance. In order to improve the slipper bearing capacity, length-to-diameter ratio of fixed damper varies from 3.5 to 8.75 and radius ratio of slipper varies from 1.5 to 2.0. In addition, the higher slipper thermal conductivity is useful to improve slipper bearing capability, but the thermal equilibrium clearance is not compromised.