冷弯薄壁型钢方钢管混凝土梁的滞回性能试验研究

进行了六片方形冷弯型钢钢管混凝土梁在反复荷载作用下的试验研究和非线性有限元分析,研究不同跨高比和截面宽厚比对冷弯型钢钢管混凝土梁的滞回性能、延性和耗能能力等的影响。结果表明:(1)方型冷弯薄壁钢管混凝土梁的荷载-位移滞回曲线比较饱满,没有明显的捏缩现象,具有很好的延性和耗能能力;(2)跨高比和宽厚比会严重影响方型冷弯薄壁钢管混凝土梁的滞回性能和延性;(3)建立的非线性有限元模型能够预测冷弯薄壁钢管混凝土梁的弹塑性行为和抗震性能,计算结果与实测结果基本吻合,可以进一步应用方型冷弯薄壁钢管混凝土梁的参数影响分析计算。     

受火侵袭波纹腹板钢梁的侧向弯扭屈曲及其参数分析

基于ANSYS的有限元数值计算,考查了简支波纹腹板钢梁在火灾作用下的侧向弯扭屈曲。通过与平腹板钢梁的临界温度作比较,研究了波纹腹板钢梁分别在纯弯矩和集中载荷作用下的抗火性能,并分析了栽荷比、初始缺陷等因素对波纹腹板钢梁抗火性能的影响。分析表明,波纹腹板钢梁与平腹板钢梁在火灾作用下有相同的侧向弯扭屈曲性能。     

高温下受弯钢梁的弹塑性弯扭屈曲分析

基于弹塑性理论,通过建立钢梁截面的弯矩曲率关系作弯矩作用平面内的弹塑性分析等几个步骤,对火灾高温作用下受弯简支钢梁在弹塑性阶段的弯扭屈曲性能变化进行了分析,给出了钢梁的临界屈曲弯矩的计算表达式。通过算例分析了钢梁弹塑性阶段临界屈曲弯矩随温度的变化,并利用ANSYS有限元软件模拟了钢梁在火灾燃烧不同时刻的竖向变形。结果表明,随着温度的升高,钢梁弹塑性阶段的临界弯矩呈现出逐渐降低的趋势,而其竖向变形则逐渐增大,文中对这2个变量在不同温度条件下的具体变化情况分别进行了详细的分析和描述。     

火灾下轴压钢柱破坏的判断准则分析

介绍了火灾下轴压钢柱的破坏准则。利用数值分析的方法,根据不同的破坏准则计算火灾下轴压钢柱的临界温度。火灾下钢材的力学性能分别参照EC3和CECS选取。通过对临界温度计算结果的对比分析,发现：①2个变形准则给出的结果基本相同,但以变形准则为判断依据往往会高估构件的临界温度;②应用变形准则需具备一定条件,即火灾下构件的破坏形式为整体失稳或截面强度破坏,若构件发生局部屈曲,变形准则不适用;③同一破坏准则下,火灾下钢材性能分别按照EC3和CECS选取,临界温度计算结果相差超过200℃。最后,给出临界温度设计曲线的上、下限,以方便工程应用。     

H型平面布置多层冷弯薄壁型钢结构抗震分析

基于H型钢截面良好的受力性能,设计了一种H型平面布置的多层冷弯薄壁型钢结构。结合有限元分析软件,对该结构进行了不同工况下的弹塑性地震时程计算,分析了结构的位移响应、层间位移、顶层加速度等参数。结果表明:(1)6种地震烈度下,结构层间位移角均满足规范要求。9度罕遇地震下,结构顶层X向最大位移为9.213mm,Y向最大位移为5.432mm,位移响应较小;(2)结构在高烈度地震下,顶层加速度超过10000mm/s2,结构颤动频率高,但是构件均未进入塑性,结构处于安全状态。综合分析结果,采用H型平面布置的多层冷弯薄壁型钢结构具有较好的抗震能力,建议工程中考虑使用该种平面布置方式。     

基于FENAP平台的RC高桥墩破坏过程模拟及分析

为精细模拟钢筋混凝土高桥墩在静力推覆荷载作用下的破坏过程,本文基于钢筋混凝土精细化纤维梁柱单元模型分析平台FENAP,对一实际的西部山区空心截面高桥墩进行了Pushover分析,通过对构件、截面和纤维层次的力-位移关系曲线分析,模拟了桥墩从墩底混凝土开裂、纵筋屈服到受压区混凝土压碎的完整破坏过程。并将FENAP平台与OpenSees计算结果进行对比,结果表明,FE-NAP平台可有效地模拟高墩在静力推覆荷载下的破坏过程和软化行为,具有较高的求解精度。进一步比较了不同轴压比、是否考虑约束混凝土效应及纵筋屈曲效应等因素对分析结果的影响,得出结论,轴压比和约束混凝土效应对高桥墩的破坏过程发展有较大影响,而纵筋屈曲效应影响较小,可忽略不计。     

高强钢筋高强混凝土短肢剪力墙抗震性能试验研究与数值模拟分析

通过对6个L形和6个一字形高强钢筋高强混凝土短肢剪力墙进行拟静力试验和OpenSees有限元模拟相结合的方法,研究构件的抗震性能,得到试件的破坏形态及滞回曲线,骨架曲线,承载力等性能指标,并模拟分析了同高厚比下试件的轴压比依次从0.1增加到0.6,的抗震性能。结果表明:在低周往复荷载作用下试件主要为弯剪破坏;OpenSees能较好的模拟高强钢筋高强混凝土短肢剪力墙的弹塑性行为,试验结果与数值模拟结果吻合较好;采用高强钢筋高强混凝土使试件承载力显著提高,极限位移增大;承载力随轴压比提高,但高轴压比下腹板受压时易造成试件的迅速破坏,承载力迅速降低,提高配箍率使试件承载力提高,且能延缓试件端部损伤,提高试件后期的塑形变形能力。     

考虑材料损伤累积的空间网格结构弹塑性分析建模方法

传统的轴向受力构件二次屈曲效应模拟方法计算结果在构件前次屈曲后残余变形及材料硬化效应不明显时与试验值差异较大,无法精确模拟,对此文中提出了考虑损伤累积效应的混合硬化材料模型结合纤维梁单元的轴向受力构件建模方法。通过试验数据与数值模拟结果的对比,表明该方法可以更精确地模拟构件在轴向往复荷载作用下二次屈曲及屈曲后的力学行为,是空间网格结构弹塑性分析时构件建模的适用方法,并通过最后的柱面网壳算例分析表明该方法的对网格结构弹塑性时程计算有较大意义。     

中间加劲C型钢构件压弯滞回性能非线性模拟

为克服普通薄壁C型钢构件在宽厚比较大时滞回性能差的缺点,首先对具有相同宽厚比的C型钢和加劲C型钢压弯构件的滞回性能进行了比较,结果表明加劲可有效改善此类构件的滞回性能;然后对具有中间加劲的C型钢构件在压弯循环荷载下的滞回性能、变形情况以及破坏模式进行了深入分析;研究了加劲设置对构件性能的影响,得出了合理的加劲布置方式;最后采用延性系数对中间加劲薄壁C型钢构件的抗震性能进行了评价,给出了设计建议。     

火灾高温作用下波纹腹板钢梁剪切屈曲系数研究

波纹腹板钢梁具有优良的抗剪切性能,在常温条件下,它的剪切屈曲模式通常有3种：局部剪切屈曲、总体剪切屈曲和相关剪切屈曲。根据火灾燃烧不同时刻波纹腹板钢梁的温度变化,考虑火灾高温对结构钢材料性能的影响,研究了波纹腹板钢梁在火灾高温作用下的3种剪切屈服模式,给出了高温下波纹腹板钢梁临界剪切屈曲应力和剪切屈曲系数的计算表达式,分析了其随火灾温度的变化趋势,提出在进行火灾高温作用下的波纹腹板钢梁的力学性能分析时,应首先根据钢梁剪切屈曲系数的变化,准确判断其在火灾燃烧不同阶段所处的受力状态,从而使火灾高温下波纹腹板钢梁的受力分析更加精确合理。     

薄壁型钢管/胶合竹板复合柱抗震性能试验

对9根带约束拉杆的方形薄壁型钢管/胶合竹板复合空芯柱(SBCCB)试件进行低周反复拟静力测试,考察SBCCB的破坏过程和形态,分析试件的长细比、胶合竹净横截面面积、截面组合方式对其受力和抗震性能影响。结果表明:SBCCB破坏形态主要为柱脚胶合面的开裂破坏和胶合竹板断裂破坏,截面组合方式对其破坏模式有显著影响。SBCCB试件有较好的弹性变形能力和抗震耗能性能,增大复合柱截面尺寸和长细比能改善抗震性能;约束拉杆有效保证了试件的整体性,抑制基体开胶破坏,间接提高了抗震性能。     

升—降温全过程中约束钢梁的有限元与试验分析

以轴向支撑连接方式,利用自制的加热炉对约束钢梁进行了升—降温全过程的试验研究。重点研究了钢梁的跨中挠度随温度变化的规律,以及梁端不同轴向支撑刚度和钢柱不同轴压比条件下约束钢梁的屈曲模式及其梁端轴向支撑的破坏形态。基于ANSYS有限元软件,采用温度场和结构耦合中的间接法,对升-降温全过程中的约束钢梁进行了有限元分析。数值计算结果与试验结果吻合较好,验证了有限元模型和参数设置的合理性。根据对比分析,讨论了我国现行钢结构防火技术规范中存在的关键问题,特别提出了钢结构抗火设计应有的内涵,为钢结构抗火研究提供了新的思路。     

Conceptual study of X-braced frames with different steel grades using cyclic half-scale tests

In this paper,an experimental and analytical study of two half-scale steel X-braced frames with equal nominal shear strength under cyclic loading is described.In these tests,all members except the braces are similar.The braces are made of various steel grades to monitor the effects of seismic excitation.Internal stiffeners are employed to limit the local buckling and increase the fracture life of the steel bracing.A heavy central core is introduced at the intersection of the braces to decrease their effective length.Recent seismic specifications are considered in the design of the X-braced frame members to verify their efficiency.The failure modes of the X-braced frames are also illustrated.It is observed that the energy dissipation capacity,ultimate load capacity and ductility of the system increase considerably by using lower grade steel and proposed detailing.Analytical modeling of the specimens using nonlinear finite element software supports the experimental findings.     

薄壁方钢管混凝土柱劲化设计及轴压性能探讨

对于薄壁方形钢管混凝土柱,有效且经济地提高柱的承载力、刚度和延性,增强其抵抗局部屈曲的能力是目前的一项重要研究课题。据此,进行8个薄壁方形钢管混凝土轴压试件的研究,比较普通薄壁钢管混凝土柱与劲化薄壁钢管混凝土柱的轴压极限承载力、延性性能、局部屈曲模态及相应耗钢量,研究表明:劲化设置在增加较少用钢量的情况下,使钢管壁对核心混凝土的约束作用相对于普通钢管混凝土柱和单纯加设约束拉杆的钢管混凝土柱更趋均匀,提高了整体约束效应,混凝土强度得以提高,本构关系明显改善。从而增加了钢管混凝土柱的轴压承载力和延性,改变了钢管的局部屈曲变形状态,其实用效益与经济效益极其可观,具有良好推广价值。     

火灾下约束钢柱临界温度的参数分析

利用经实验验证过的ABAQUS有限元模型对轴力和弯矩共同作用下的约束钢柱进行了参数分析。以钢柱的屈曲温度和临界温度作为主要的评价指标,主要考虑了轴力荷载比、弯矩荷载比、轴向约束刚度比、转动约束刚度比、长细比和钢柱端部弯矩比等参数的影响,并且对不同参数之间的耦合性进行了分析。参数分析结果表明,轴向约束刚度的增大将会明显降低约束钢柱的屈曲温度,但是对其临界温度的影响相对较小;端部弯矩比对钢柱的临界温度影响很小;当钢柱的轴力荷载比和弯矩荷载比较小、轴向约束刚度比和长细比较大时,考虑屈曲后性能可以显著提高钢柱的抗火能力。     

钢管混凝土组合柱在标准火与真实火中的行为比较

以实际工程中常用的钢管混凝土组合柱为研究对象,通过ABAQU S大型有限元软件模拟钢管混凝土组合柱在标准火和真实火中的截面温度分布、应力、变形、破坏形态、耐火极限等力学行为。其中标准火选用ISO-834标准火模型,真实火采用欧洲规范Eurocode 1 Part 1-2中的参数火模型来近似模拟真实火灾的温度—时间关系。研究发现,钢管混凝土柱在两种火场环境中的行为差异很大,真实火中的冷却过程对钢管混凝土的破坏起重要的影响。基于本研究,还初步得到火灾过程中环境温度的升温速度、柱火灾荷载比等对钢管混凝土组合柱的抗火性能的影响。     

Study of a new-type of steel buckling-restrained brace

The rectangle core plate of all-steel buckling-restrained braces(BRBs) usually exhibit obvious local buckling, due to the lack of longitudinal restraint from the encasing tube. To eliminate the undesirable effects, a novel steel BRB is proposed. In this new-type steel BRB, two T-shaped steels are adopted as the minor restraint elements to restrain the core plate instead of infilled concrete or mortar. Meanwhile, the ingot-iron material with low yielding strength and high elongation is applied to the steel core to study the mechanical properties of steel BRBs. To validate the theoretical requirements for the width-to-thickness ratio of the steel core and the thickness of angle steel, quasi-static tests of eight specimens were conducted. The tests focused on the energy dissipation capacity and failure modes of the proposed steel BRBs. Nonlinear finite element analysis was also carried out to validate the experimental results. Both the aforementioned results imply that appropriately designed steel BRBs can meet the performance requirements for BRB components.     

Experimental research on the seismic behavior of CSPSWs connected to frame beams

The seismic performance of composite steel plate shear walls (CSPSWs) that consist of a steel plate shear wall (SPSW) with reinforced concrete (RC) panels attached to one or both sides by means of bolts or connectors is experimentally studied. The shear wall is connected to the frame beams but not to the columns. This arrangement restrains the possible out-of-plane buckling of the thin-walled steel plate, thus significantly increasing the bearing capacity and ductility of the overall wall, and prevents the premature overall or local buckling failure of the frame columns. From a practical viewpoint, these solutions can provide open space in a floor as this type of composite shear walls with a relatively small aspect ratio can be placed parallel along a bay. In this study, four CSPSWs and one SPSW were tested and the results showed that both CSPSWs and SPSW possessed good ductility. For SPSW alone, the buckling appeared and resulted in a decrease of bearing capacity and energy dissipation capacity. In addition, welding stiffeners at corners were shown to be an effective way to increase the energy dissipation capacity of CSPSWs.     

Dynamic instability of frames having thin-walled columns

Dynamic instability of single storey frames having thin-walled columns has been investigated. The lateral loads sustained by the frame are dynamic in character, while the axial loads are deemed to be quasi-statically applied. The analytical model employed by the authors has the capability of modelling the combined action of the two ‘companion’ local modes whose amplitudes are variable along the length of the column and any type of end conditions of the members. For given levels of axial loads sustained by the columns, the magnitudes of lateral loads causing instability can be significantly smaller than those corresponding to static buckling, provided the dynamic load is of sufficient duration. There exists, however, a threshold value of axial force carried by the columns, below which there is no elastic instability—static or dynamic. For columns with overall critical loads several times greater than the local critical load, there is no danger of elastic instability, but the deflections under dynamic lateral loads of less than 1 per cent of the axial load may reach such huge values that there is a serious danger of localized plastic collapse. It is also shown that moment frames having thin-walled columns such as those fabricated out of cold formed steel are extremely vulnerable to moderate seismic excitations.