Short beam shear properties and failure modes of the wood-based X-type lattice sandwich structure

A wood-based X-type lattice sandwich structure was manufactured by insertion-glue method.The birch was used as core,and Oriented Strand Board was used as panel of the sandwich structure.The short beam shear properties and the failure modes of the wood-based X-type lattice sandwich structure with different core direction(vertical and parallel),unit specification(120 mm×60 mm and 60 mm×60 mm),core size(50 mm and 60 mm),and drilling depth(9 mm and 12 mm)were investigated by a short beam shear test and the establishment of a theoretical model to study the equivalent shear modulus and deflection response of the X-type lattice sandwich structure.Results from the short beam shear test and the theoretical model showed that the failure modes of the wood-based X-type lattice sandwich structure were mainly the wrinkling and crushing of the panels under three-point bending load.The experimental values of deflection response of various type specimens were higher than the theoretical values of them.For the core direction of parallel,the smaller the unit specification is,the shorter the core size is,and the deeper the drilling depth is,the greater the short beam shear properties of the wood-based X-type lattice sandwich structure is.

Effect of gravel on rock failure in glutenite reservoirs under different confining pressures

Due to the existence of gravel,glutenite is heterogeneous and different from fine-grained rocks such as sandstone and shale in structure.To fully understand the effect of gravel on failure mode in glutenite,we performed triaxial compression tests on different glutenites.The results indicate that failure modes of glutenite are complex due to the existence of gravel.Under different confining pressures,three failure modes were observed.The first failure mode,a tensile failure under uniaxial compression,produces multiple tortuous longitudinal cracks.In this failure mode,the interaction between gravels provides the lateral tensile stress for rock splitting.The second failure mode occurs under low and medium confining pressure and produces a crack band composed of micro-cracks around gravels.This failure mode conforms to the Mohr-Coulomb criterion and is generated by shear failure.In this failure mode,shear dilatancy and shear compaction may occur under different confining pressures to produce different crack band types.In the second failure mode,gravel-induced stress concentration produces masses of initial micro-cracks for shear cracking,and gravels deflect the fracture surfaces.As a result,the fracture is characterized by crack bands that are far broader than in fine-grained rocks.The third failure mode requires high confining pressure and produces disconnected cracks around gravels without apparent crack bands.In this failure mode,the gravel rarely breaks,indicating that the formation of these fractures is related to the deformation of the matrix.The third failure mode requires lower confining pressure in glutenite with weak cement and matrix support.Generally,unlike fine-grained rocks,the failure mode of glutenite is not only controlled by confining pressure but also by the gravel.The failure of glutenite is characterized by producing cracks around gravels.These cracks are produced by different mechanisms and distributed in different manners under different confining pressures to form different fracture patterns.Therefore,understanding the rock microstructure and formation stress state is essential in guiding glutenite reservoir development.

Failure Modes of Lead Free Solder Bumps Formed by Induction Spontaneous Heating Reflow

The shear failure modes and respective failure mechanism of Sn3.5Ag and Sn3.0Ag0.5Cu lead-free solder bumping on Au/Ni/Cu metallization formed by induction spontaneous heating reflow process have been investigated through the shear test after aging at 120℃ for 0, 1, 4, 9 and 16 d. Different typical shear failure behaviors have been found in the loading curves （shear force vs displacement）. From the results of interracial morphology analysis of the fracture surfaces and cross-sections, two main typical failure modes have been identified. The probabilities of the failure modes occurrence are inconsistent when the joints were aged for different times. The evolution of the brittle NiaSn4 and Cu-Ni-Au-Sn layers and the grains coarsening of the solder bulk are the basic reasons for the change of shear failure modes.

Shear behavior of intact granite under thermo-mechanical coupling and three-dimensional morphology of shear-formed fractures

The shear failure of intact rock under thermo-mechanical(TM)coupling conditions is common,such as in enhanced geothermal mining and deep mine construction.Under the effect of a continuous engineering disturbance,shear-formed fractures are prone to secondary instability,posing a severe threat to deep engineering.Although numerous studies regarding three-dimensional(3D)morphologies of fracture surfaces have been conducted,the understanding of shear-formed fractures under TM coupling conditions is limited.In this study,direct shear tests of intact granite under various TM coupling conditions were conducted,followed by 3D laser scanning tests of shear-formed fractures.Test results demonstrated that the peak shear strength of intact granite is positively correlated with the normal stress,whereas it is negatively correlated with the temperature.The internal friction angle and cohesion of intact granite significantly decrease with an increase in the temperature.The anisotropy,roughness value,and height of the asperities on the fracture surfaces are reduced as the normal stress increases,whereas their variation trends are the opposite as the temperature increases.The macroscopic failure mode of intact granite under TM coupling conditions is dominated by mixed tensileeshear and shear failures.As the normal stress increases,intragranular fractures are developed ranging from a local to a global distribution,and the macroscopic failure mode of intact granite changes from mixed tensileeshear to shear failure.Finally,3D morphological characteristics of the asperities on the shear-formed fracture surfaces were analyzed,and a quadrangular pyramid conceptual model representing these asperities was proposed and sufficiently verified.

Impact of Compaction Mode on Strength Properties of Sustainable Asphalt Concrete

Various modes of compacting the asphalt concrete mixture can create mechanically different behaviour of the prepared specimens and can alter its sustainability.An attempt has been made in the present assessment to prepare asphalt concrete specimens by implementation of three modes of compaction,the gyratory,the roller,and the Marshall hammer.The specimens were prepared at the target bulk density of Marshall method at optimum asphalt content.Extra specimens were prepared at 0.5%asphalt below and above the optimum.Core specimens have been obtained from the roller compacted slab samples.The specimens were tested for the Marshall stiffness,tensile,and shear strength.It was observed that at optimum asphalt content,the indirect tensile strength declines by(18.8 and 70.5)%for gyratory and roller compacted specimens respectively as compared with hammer compacted specimens.At optimum asphalt content,the shear strength declines by(70.5 and 82.2)%while Marshall stiffness declines by(10.2 and 44.8)%for hammer and roller compacted specimens as compared with that of gyratory compacted specimen.Specimens prepared by gyratory compaction are less susceptible to the change in the testing temperature as compared with other modes of compaction.It is recommended to consider the mode of compaction to suit the required design property of sustainable asphalt concrete mixture.

聚丙烯纤维增强橡胶砂固结不排水剪切试验

鉴于橡胶砂作为回填材料时承载力低和变形量大的问题,采用加入聚丙烯纤维(PPF)的方法提高橡胶砂的力学性能,提出了聚丙烯纤维增强橡胶砂的半干拌式制备方法,通过48组聚丙烯纤维增强橡胶砂、普通橡胶砂和纯砂试样的固结不排水剪切试验,探究了聚丙烯纤维掺量和橡胶掺量等参数对聚丙烯纤维增强橡胶砂主要力学变形特征参数的影响.结果表明:聚丙烯纤维对橡胶砂弹性模量的影响较小;聚丙烯纤维增强橡胶砂具有先剪缩后剪胀破坏的特征,其偏应力与轴向应变关系为应变硬化型;聚丙烯纤维可有效提高橡胶砂的内摩擦角和黏聚力;聚丙烯纤维增强橡胶砂破坏偏应力的提升效果十分显著,最高可提高3倍.

型钢混凝土T形截面剪力墙基于性能的变形限值研究

为更好地评估T形截面型钢混凝土(steel reinforced concrete,SRC)剪力墙变形性能,采用ABAQUS有限元软件对按照规范设计的324个T形截面SRC剪力墙构件的破坏形态和变形性能进行研究,根据收集的试验数据分析构件的破坏形态,提出T形截面SRC剪力墙的破坏形态划分准则;以构件的各材料应变极限值为准则来判别构件的性能状态,考虑轴压比、剪跨比、弯剪比、腹板暗柱配钢率、暗柱纵筋配筋率及箍筋暗柱特征值对构件变形性能的影响。对不同性能状态变形限值和参数进行线性回归分析,得到不同破坏类型下各性能状态位移角限值计算式;按规范ASCE 41修正各性能状态变形限值的失效概率,得到具有15%、20%、35%失效概率保证的各性能状态变形限值取值表。研究表明:剪跨比、轴压比对构件各性能状态位移角限值影响较大,暗柱腹板配钢率、纵筋配筋率及箍筋特征值对构件位移角限值影响相对较小,但能提高其延性。按规范ASCE 41修正后的位移角限值取值较为合理且有一定的安全储备。为T形截面SRC剪力墙基于性能的抗震设计与性能评估提供参考。

基于性能的含可更换耗能梁段高强钢框筒结构抗震性能研究

含可更换耗能梁段的高强钢框筒结构(HSS-SFT-RSL)结合了耗能梁段耗能强、钢框筒抗侧刚度大、高强钢承载力高等优点,是一种抗震性能优良的结构体系.传统设计方法需要进行复杂的迭代和计算才能使结构达到预期性能目标,且无法较为准确地控制结构的塑性发展顺序和破坏模式,本文采用课题组提出的基于性能的塑性设计方法(PBPD)各设计一个30层HSS-SFT-RSL算例和含可更换剪切型耗能梁段的普通钢框筒结构(CS-SFT-RSL)算例,通过静力和动力弹塑性分析对比两算例的抗震性能.结果表明:采用PBPD法设计的两算例具有相似的顶点侧移角和破坏模式,HSS-SFT-RSL算例抗侧刚度略低,但极限承载力更高;在罕遇水准地震下,两算例各层耗能梁段均能参与耗能,层间侧移角沿结构高度分布均匀,避免了薄弱层,残余层间变形较小,有利于耗能梁段更换和结构震后功能的快速恢复.

PBL抗剪传力钢筋连接接头受拉力学性能试验

装配式混凝土构件间钢筋的连接是其适用性和经济性的关键环节,针对国内工程常用的灌浆套筒和约束浆锚钢筋连接技术存在施工难度大、效率低、质量不易检验等问题,本文提出了PBL-穿孔钢筋连接接头、PBL-穿孔钢管连接接头和PBL-U形钢筋连接接头3种钢筋连接接头,实现预制混凝土单元间钢筋应力的传递,具有施工简便、质量易保证、成本低等优势。对这3种钢筋接头进行了6组参数共18个钢筋接头试件的拉伸性能试验,研究了新型接头试件的破坏模式、承载力和变形能力等,得到各参数对新型接头拉伸强度的影响规律,并对不同接头的受拉力学性能进行对比分析。研究结果表明:3种钢筋连接接头能够实现钢筋应力的有效传递,验证了新型钢筋连接接头的可行性。

RC梁柱节点抗剪机理及承载力计算方法综述

对国内外关于框架结构中梁柱节点抗震性能研究成果进行总结归纳,分析了加载过程中节点的破坏形态及其抗剪机理,总结了典型的梁柱节点抗剪承载力计算模型,并基于各国规范对比了现有的抗剪承载力计算模型的适用性。对比了美国规范ACI 318-19、欧洲规范EC2的抗剪承载力计算的差异,指出了《混凝土结构设计规范》(GB 50010—2010)(2015年版)建议的梁柱节点抗剪承载力计算结果相对保守。建议适量增加节点核心区配箍率,从而提高钢筋与核心区混凝土的粘结性能,减少纵筋的粘结滑移现象。

不锈钢槽式预埋组件受剪性能研究

为研究不锈钢槽式预埋组件在剪力作用下的破坏模式和承载性能,完成了3组9个带混凝土基材的不锈钢槽式预埋组件试件的受剪试验。试验结果表明,平行受剪工况下破坏模式为齿牙剪切破坏,垂直受剪工况下破坏模式为混凝土边缘破坏及槽道卷边受弯破坏。在试验的基础上,通过ABAQUS软件建立了有限元分析模型,并验证了模型的准确性。通过数值分析研究了齿牙尺寸、混凝土强度、边缘距离、锚件中心线间距及预埋槽道有效埋深等参数对极限承载力的影响。结果表明,平行受剪工况下,平齿型槽道的齿牙数量、宽度及厚度的增加均可提高极限承载力,齿牙高度对极限承载力影响较小;垂直受剪工况下,平齿型和燕尾型槽道的混凝土强度及边缘距离的增加均可提高极限承载力,而锚件中心线间距的增加则使极限承载力降低,预埋槽道有效深度对极限承载力影响较小。给出了不同破坏模式下的受剪承载力计算公式,通过试验结果与有限元模拟结果的对比,验证了承载力计算公式的有效性。

直接剪切下页岩的各向异性破坏特征和强度预测模型

了解页岩剪切破坏特性对页岩气储层改造和井壁稳定性控制具有重要意义。然而,由于页岩本身的各向异性属性,页岩的剪切破坏行为复杂。本文对6种不同层理倾角(0°、30°、60°、90°、120°和150°)的立方体页岩进行了系统的直接剪切破坏测试,详细分析了在层理弱面影响下页岩的剪切应力–剪切位移、抗剪强度、剪切模量和破坏模式的各向异性特征。结果表明:页岩的剪切破坏表现为典型的非线性渐进破坏特征;页岩平均抗剪强度和剪切模量随层理倾角的增加均呈现“M”型变化趋势;在90°~180°的层理倾角区间,平均抗剪强度的极值差明显大于0°~90°区间,而剪切模量近似关于90°呈对称变化;当层理倾角从0°变化到180°时,页岩剪切各向异性行为呈现非对称演化规律。在层理倾角和直接剪切荷载作用下,页岩的破坏模式有3类:层理倾角为0°时,沿层理面剪切滑移破坏;层理倾角为30°、60°和90°时,表现为穿透层理和基质的剪切滑移破坏;其他倾角下呈现穿透层理和基质的剪切滑移与沿层理的拉伸劈裂相结合的复合破坏。基于试验结果和组构张量,构建了一个可考虑页岩本征各向异性和剪应力诱导各向异性影响的直接剪切破坏准则,其理论预测值与试验结果的平均偏差率低于3%,能够定量表征黏聚力和摩擦系数的各向异性程度,合理评估页岩直接剪切强度对外加法向应力的敏感性,可推广应用于理论表征所有层状岩土材料的直接剪切强度。

石英砂岩三轴剪切力学特性及裂隙面形态特征

为研究3维压剪应力状态下岩质边坡中完整岩石的剪切损伤破坏特征,采用RockTop-50HT全应力多场耦合三轴试验系统,对成分简单、结构均质及饱和完整的细粒石英砂岩进行16组不同围压的三轴剪切试验,获得相应的三轴剪切应力-应变曲线和含有原岩屑碎片的剪切破坏裂隙面,分析三轴剪切应力作用下石英砂岩的非线性强度变化特征,探究石英砂岩的三轴剪切破坏模式和裂隙结构面形态粗糙特征。基于德洛内(delaunay)点云离散算法重构石英砂岩破坏裂隙结构面,分析剪切破坏结构面的潜在接触部分随着表面有效倾角门槛值的变化特征。结果表明:1)随着围压逐渐增大,石英砂岩的三轴剪切破坏模式先由脆性破坏转变为塑性破坏,再逐渐转变为塑形流动破坏;2)石英砂岩的三轴剪切强度随着围压的递增呈现出明显的非线性变化特征,可用幂函数描述,并采用摩尔-库仑准则(Mohr-Coulomb)对石英砂岩的三轴剪切强度进行分段线性拟合,可知随着围压的增大,黏聚力逐渐增大,内摩擦角逐渐减小;3)剪切破坏裂隙面3维粗糙特征可用传统的Grasselli模型评估,其非线θ_(max)^(*)性拟合参数和粗糙度参数c能充分描述三轴剪切破坏裂隙的粗糙度特征。研究成果对岩石在复杂应力状态下的三轴剪切强度评价、岩石工程中边坡的稳定性分析和支护设计方案优化具有重要意义。

拉-压变轴力下小剪跨比RC剪力墙受剪试验研究

近年来,高层建筑中底部剪力墙因受拉,处于拉-压变轴力和水平荷载耦合受力的问题得到了广泛的关注。为了研究拉-压变轴力下小剪跨比钢筋混凝土(RC)剪力墙的受剪性能,该文完成了3个剪跨比为1.0的RC剪力墙在拉-压变轴力下的往复受剪试验,研究参数为拉-压变轴力变化幅值和加载路径。结果表明:不同加载路径下RC墙均在压剪方向发生剪压破坏,压剪方向极限位移角为1.2%~1.4%;拉-压变轴力变化幅值改变墙体拉剪和压剪承载力,加载路径对墙体的拉剪强度有一定的影响,但对压剪强度影响很小;拉-压变轴力下剪力墙的滞回曲线呈现明显不对称现象,拉-压变轴力的变化幅值对滞回曲线的形状影响较小,但加载路径改变滞回曲线的形状;拉-压变轴力的变化幅值将增加剪力墙拉剪与压剪刚度的差别,在双肢墙结构中可能导致更多的剪力从受拉墙体转移到受压墙体;基于OpenSees建立了可准确模拟拉-压变轴力下RC剪力墙受剪行为的有限元模型。

端板攻丝高强度螺栓连接受力性能试验研究

对10.9S级M16、M20高强度螺栓和Q345B端板攻丝连接与传统高强度螺栓连接受力性能进行试验对比,研究了其在单向受拉、单向受剪以及拉-剪复合受力状态下的破坏形态、受力机理和极限承载能力。试验结果表明:单向受拉时,极限承载能力和变形与传统连接方式基本一致;单向受剪时,即使是厚径比为0.8的M20螺栓,仍可实现栓杆剪断,而端板攻丝孔内牙体无明显变形破坏且攻丝连接件形式早期滑移量明显较小;拉-剪复合受力时,随着拉剪比从0.58增大到1.73,破坏形态由剪切破坏转变为受拉破坏。因此,为确保端板攻丝牙体无明显破坏,应考虑螺栓与板厚的合理设计,建议M20螺栓在单向受拉和拉-剪复合受力时厚径比不小于0.9d,3种受力状态下高强度螺栓端板攻丝连接方式的承载力与传统连接方式基本一致。试验结果分析可为工程设计提供参考依据。

循环荷载下饱和黄土的剪切特性与破坏模式

饱和黄土的破坏模式和剪切特性是分析黄土地基及其构筑物地震变形的基础,为了揭示循环荷载下黄土独特的强度衰减和变形劣化规律,本文开展了饱和黄土不排水动三轴试验,控制初始剪应力(q_(s))和循环剪应力(q_(c)),研究了不同初始应力状态下饱和黄土的动强度、孔压发展规律及破坏模式。试验结果表明:当q_(s)<q_(c)时,重塑和原状黄土试样表现为循环迁移型破坏,当q_(s)≥q_(c)时,重塑黄土试样表现为流动型破坏,而原状黄土试样则表现为塑性应变累积型破坏;黄土试样的循环应力比(R_(CS))、循环阻力比(R_(CR,10))随着初始剪应力比(R_(SS))的增大呈先增大后减小的趋势;循环迁移型和塑性应变累积型破坏在循环加载的初始阶段孔压上升迅速,孔压增长曲线分别呈“风琴”状和“喇叭”状,而流动型破坏的初始阶段孔压增长速率较慢,当到达某一振次后孔压突然增长,孔压增长曲线呈“镰刀”状。基于初始阶段孔压发展指标(K_(1-2))与初始应力状态(q_(s)/q_(c))提出了图表法,可用于预测循环荷载下饱和黄土的破坏模式。

带混合连接的装配式混凝土剪力墙抗震性能研究

基于完成的带水平连接的装配式混凝土剪力墙(precast concrete shear walls with horizontal connection,PCSW-HC)试验研究,提出了一种带混合连接的装配式混凝土剪力墙(precast concrete shear walls with hybrid connection,PCSW-HVC),其中,水平连接采用高强螺栓的“强”连接方式,竖向连接采用钢剪切键(steel shear key,SSK)的“弱”连接方式。首先,结合已完成的试验,建立带水平连接的装配式混凝土剪力墙的数值模型,通过对比试验与数值分析结果,验证了材料本构关系的选取、各部件相互作用关系设置的正确性。进一步,采用同样的建模方法,建立带混合连接的装配式混凝土剪力墙的数值模型。分析了不同竖缝型式和增设钢剪切键对带混合连接的装配式混凝土剪力墙抗震性能的影响,揭示了其损伤失效模式。结果表明:单片剪力墙模块分割成较小尺寸模块拼装后,抗侧刚度有一定程度的减小,但刚度退化更缓慢,剪力墙墙板损伤更小,具有更好的变形能力;在剪力墙模块之间的竖缝中增设钢剪切键后,提高抗侧刚度的同时还可以改善其刚度退化行为,与不带钢剪切键模型相比,单片剪力墙(Single模型)和竖向滑动双片剪力墙(Sliding模型)峰值割线刚度分别提高了14.9%和11.4%;带混合连接的装配式混凝土剪力墙的损伤失效模式为“钢剪切键塑性屈服-墙板模块底部损伤-墙板模块破坏”,实现了钢剪切键塑性屈服耗能与墙板塑性损伤转移的“双功能”控制。

新型耗能连接正交胶合木剪力墙抗侧力性能试验

为研究基于软钢屈服与橡胶剪切变形双重耗能机制新型连接的正交胶合木剪力墙抗侧力性能,考虑顶部竖向荷载、墙体高宽比、耗能连接件可更换性等因素,对6榀2.4m高足尺试件进行了单调及低周往复加载试验,并与普通金属连接正交胶合木墙体进行对比试验,获取并分析了剪力墙的破坏过程、力学性能参数及各项因素对抗侧力性能的影响规律。结果表明:新型耗能连接正交胶合木剪力墙在侧向力下的损伤主要集中在耗能连接的软钢耗能段屈服断裂与耗能橡胶脱胶破坏,墙体板材与自攻螺钉未见损伤;增大顶部竖向荷载可有效提升墙体的抗侧力性能,而增大高宽比主要可增加墙体的变形能力与延性;与普通金属连接墙体相比,耗能连接墙体的最大承载力相近,但延性提升26%,耗能能力提升38%,最大层间位移角可达1/23,且在原位替换耗能连接修复的墙体与原墙体的抗侧力性能相近,表明新型耗能连接正交胶合木剪力墙具有较好抗震性能,可实现强震后连接可更换、结构可修复的设计目标。

腹板开洞型抗剪连接件力学性能有限元分析

为了提高全装配式混凝土梁柱-钢支撑的受剪性能,提出一种腹板开洞型抗剪连接件。以腹板截面分配方式为参数,设计2个试件进行往复加载试验,研究其力学性能。采用ABAQUS软件进行有限元分析校正,并设计16个分别考虑混凝土强度、腹板宽度高度和2组腹板组合形式影响的有限元模型进行模拟分析,进而探究各参数对抗剪连接件受剪性能的影响。结果表明:两试件破坏形态基本一致,首先混凝土梁侧面产生斜向裂缝,并向梁正面发展,随后抗剪腹板处出现裂缝,最终在多次循环往复加载下,混凝土被压溃。两滞回曲线走势基本相同,主要包括弹性、弹塑性和破坏3个阶段。提高混凝土强度能有效提高连接件剪切承载能力;腹板截面面积一定时,截面尺寸为15 mm×32 mm的连接件极限承载能力最大;同时改变2组腹板尺寸,截面组合尺寸为18 mm×40 mm和6 mm×40 mm的组合形式抗剪性最好。

可拆卸抗剪连接件抗剪性能研究进展

在组合梁结构中,可拆卸抗剪连接件起到承担钢梁和混凝土板之间剪力传递的作用。在组合梁破坏或达到服役期后,通过更换可拆卸抗剪连接件可实现快速恢复结构正常使用功能。可拆卸抗剪连接件是未来组合桥梁和建筑实现可持续发展的一种有力途径。对可拆卸抗剪连接件的类型、破坏模式、抗剪承载力、刚度和延性进行了综述,并提出了目前可拆卸抗剪连接件存在的问题,最后对未来可拆卸抗剪连接件研究进行了展望。