剪刀撑水泥砂浆网薄层加固砌体墙体拟静力试验

主拉应力破坏是砌体结构在地震荷载作用下最常见的一种破坏形式,剪刀撑水泥砂浆网薄层加固法就是针对砌体结构抵抗主拉应力不足的一种加固方法。为了考察该方法加固砌体墙体的受力性能及加固效果,对6片砂浆强度不同、加固方法不同的墙体试件进行了拟静力试验。试验结果表明：剪刀撑水泥砂浆网薄层加固法能够明显提高砌体墙体的抗剪承载力;该方法更适合于加固砂浆强度较低的砌体墙体;采用该方法加固后的砌体墙体破坏形式以剪切滑移破坏为主;加固面层能够与原有墙体较好地共同工作。目前剪刀撑水泥砂浆网薄层加固法是一个崭新的课题,该拟静力试验给出的试验分析结果和建议可供相关研究和加固工程设计参考。     

局部火灾场钢框架结构等效楼面活荷载分析

通过对火灾场钢结构框架梁极限抗弯、抗剪承载力的分析,提出采用等效楼面活荷载来描述火灾场对结构极限承载力的削弱,建立了火灾场等效楼面活荷载的计算公式,通过具体算例分析了厚涂型不同保护层厚度的框架钢梁极限抗弯、抗剪承载力及等效楼面活荷载的变化规律。分析结果表明,采用等效楼面活荷载可以直观地描述火灾场对结构构件极限承载能力的削弱,使火灾场钢结构受力分析变得简单、清晰。     

既有锈蚀RC梁剩余抗剪承载力试验

为了准确评估锈蚀RC梁的剩余抗剪承载力,在对6根既有纵筋、箍筋锈蚀都比较严重的混凝土抗弯构件进行了剩余抗剪承力试验研究的基础上,提出了锈蚀RC梁的剩余抗剪承载力计算公式.结果表明,既有锈蚀RC梁挠度曲线没有明显的开裂拐点;破坏时脆性明显,裂缝集中在某一处,间距较大,破坏荷载和屈服荷载接近,受剪破坏形态可能表现为加载点下垂直裂缝引起的破坏.所提出的既有锈蚀RC梁剩余抗剪承载力计算公式与试验结果吻合较好,可为锈蚀RC梁剩余抗剪承载力评估提供一定参考.     

侧贴碳纤维布加固连续梁非线性有限元分析

为研究不同初始荷载作用下侧贴碳纤维布及侧贴预应力碳纤维布加固钢筋混凝土连续梁的加固效果,采用有限元分析软件ABAQUS对其进行数值模拟,并将有限元分析结果与试验结果对比。有限元分析表明：钢筋混凝土连续梁的加固效果受初始荷载的影响,初始荷载越小,加固效果越好;对纵向侧贴碳纤维布施加预应力,能够大幅提高钢筋混凝土连续梁的抗弯承载力,与未加固梁相比其抗弯承载力提高了65%以上;有限元计算结果与试验结果的荷载-挠度曲线吻合较好,两者的抗弯承载力相差不超过10%。所得结果可以为类似加固设计和试验提供参考。     

基于强度折减法的海底隧道强震破坏机理

将强度折减法引入强震作用下的海底隧道衬砌结构安全稳定性研究,利用FLAC3D软件建立了海底隧道-岩土体-海水相互作用的强度折减法数值模型,综合考虑海底隧道衬砌在强震作用下的位移、剪应变增量和塑性区变化,确定了海底隧道衬砌局部破坏的极限平衡状态和整体破坏的极限平衡状态,分析了海底隧道衬砌在强震作用下的破坏机理。结果表明:海底隧道衬砌在水平地震波的作用下,主要是围岩变形导致隧道衬砌破坏;隧道衬砌破坏位置发生在右侧侧墙中部,破坏形式为剪切破坏;隧道衬砌局部破坏的极限安全系数为1.47,整体破坏的极限安全系数为1.8,2种安全系数的极限状态可对应结构设计中的正常使用极限状态和承载力极限状态。研究成果可为海底隧道衬砌设计提供理论依据。     

钢板夹芯砼组合板斜截面抗剪分析

本文以试验现象和结果为依据,对钢板夹心混凝土组合构件,剪切破坏机理进行研究,提出了一整套组合构件斜截面抗剪强度分析方法,并从Ｂｒｅｅｓｌｅｒ强度准则出发,导出了厚板斜截面简化的强度破坏准则,与试验结果对比,表明本文的方法是可靠的。     

U型BFRP箍筋试件受剪试验分析

针对U型箍筋抗剪试验缺乏强度折减实践依据的问题,设计15个配有BFRP箍筋的C30混凝土U型试件。在BFRP箍筋两侧用套筒将其锚固,弯折成U型,箍筋两端采用穿心千斤顶施加荷载,逐渐加载至BFRP箍筋破坏。通过分析试验数据,建立试件受力模型,可知弯折部位锚固长度对BFRP箍筋强度折减有较大影响,最大折减为原强度的65%;随着锚固长度的增加,BFRP箍筋强度呈线性增加至某个定值;最后推导出U型BFRP箍筋强度折减公式。     

非金筋材海水集料混凝土梁正截面承载力分析与试验研究

对非金筋材海水集料混凝土梁正截面承载力设计方法进行了研究,基于刚度控制和蠕变特性分析了梁构件的受弯性能,提出非金筋材海水集料混凝土梁的设计建议以及其极限弯矩、开裂弯矩的建议计算公式。制作4根6 m长的碳-玻纤维筋海水集料混凝土梁,采用两点加载的方式进行弯曲试验,研究了非金筋材海水集料混凝土梁的破坏形式及受弯变形性能,测定了梁构件的开裂荷载和极限荷载值,结果表明设计建议合理,方法具有适用性,承载力计算值与试验结果吻合较好。     

珠海关后广场地下工程抗浮爆扩桩抗拔承载力的试验研究

本文根据珠海关后广场抗浮爆护桩抗拔试验结果,简要分析了饱和软土中大直径爆扩桩的抗拔受力特性和单桩的抗拔机理。与一般摩摩擦桩相比,爆扩桩的抗浮承载力除了由桩与土的摩擦力提供外,还有底部扩大头与其上部土层的作用力提供,而该力由扩大头上部土层的极限承载力来控制,通过加大头部可以大大提高桩的抗拔力。因此,采用爆扩桩作为工程的抗浮方案可大大减少工程量、节省工期、降低工程造价。本文为今后指导同类型桩的设计、施     

不卸载时侧贴碳纤维布加固连续梁试验研究

为研究不同初始荷载作用下侧贴碳纤维布加固连续梁的受力与变形特性,以及初始荷载对加固效果的影响,对4根钢筋混凝土两跨连续梁（其中1根为未加固连续梁,其余3根为在不同初始荷载下侧贴碳纤维布加固连续梁）进行了试验研究。结果表明：侧贴碳纤维布加固连续梁不仅能提高加固梁的承载力,提高幅度达16%以上;还能提高加固梁的刚度,减少其挠度和裂缝宽度;加固效果受初始荷载影响,初始荷载越小,加固效果越好。     

Response of masonry systems against blast loading

In this paper eight successive experimental blast tests with an increasing TNT equivalent charge weights ranging from 0.56 kg to 17.78 kg were conducted on unreinforced, ferrocemented overlay masonry and confined masonry walls. The pressure-time history caused by the blast was recorded by pressure sensors installed on the test specimen. The resulting damage pattern was observed during each test. Weak zones in the three systems of masonry were identified. Scaled distances for different damage levels in the three masonry systems were experimentally obtained. The results provide a basis for determining the response of each masonry system against blast loading. Consequently, efficiency of ferrocemented overlay ma-sonry and confined masonry was found established in mitigation against blast loads.     

多轴向织物层合板层间剪切强度有限元分析与实验研究

用VIMP工艺制备了UD、0/45/-45、0/45/90/-45三种多轴向织物增强,四种厚度的GFRP层合板试样,采用短梁剪切实验考察了层间剪切强度和破坏模式。建立了GFRP层合板短梁剪切试样有限元模型,计算了内部层间剪应力分布。结合计算和实验结果分析表明层合板存在由宽度方向层间剪应力变化导致的自由边缘效应,含偏轴铺层的层合板更容易发生边缘开裂破坏。厚度相同时0/45/-45多轴向织物增强层合板的层间剪切强度最高。短梁剪切强度测试存在尺寸效应,随着厚度的增加,强度下降,样品波动系数增大。     

Development of cost effective personnel armour through structural hybridization

The objective of the present study is to develop cost effective thermoplastic hybrid laminate using Dyneema® HB50 and Tensylon®HSBD 30A through structural hybridization method. Laminates having 20 mm thickness were fabricated and subjected to 7.62 × 39 mm mild steel core projectile with an impact velocity of 730 ± 10 ms⁻¹. Parameters such as energy absorption, back face deformation and rate of back face deformation were measured as a function of hybridization ratio. It was observed that hybrid laminate with 50:50 ratio (w/w) of Tensylon® and Dyneema® with Tensylon® as front face showed 200% more energy absorption when compared to 100% Tensylon® laminate and showed equal energy absorption as that of expensive 100% Dyneema® laminate. Moreover, hybrid laminate with TD50:50 ratio showed 40% lower in terms of final back face deformation than Dyneema® laminate. Rate of back face deformation was also found to be slow for hybrid laminate as compared to Dyneema® laminate. Dynamic mechanical analysis showed that, Tensylon® laminate has got higher stiffness and lower damping factor than Dyneema® and hybrid laminates. The interface between Tensylon® and Dyneema® layers was found to be separating during the penetration process due to the poor interfacial bonding. Failure behaviour of laminates for different hybridization ratios were studied by sectioning the impacted laminates. It was observed that, the Tensylon® laminate has undergone shear cutting of fibers as major failure mode whereas the hybrid laminate showed shear cutting followed by tensile stretching, fiber pull out and delamination. These inputs are highly useful for body armour applications to design cost effective armour with enhanced performance.     

An interface shear damage model of chromium coating/steel substrate under thermal erosion load

The Cr-plated coating inside a gun barrel can effectively improve the barrel's erosion resistance and thus increase the service life.However,due to the cyclic thermal load caused by high-temperature gun-powder,micro-element damage tends to occur within the Cr coating/steel substrate interface,leading to a gradual deterioration in macro-mechanical properties for the material in the related region.In order to mimic this cyclic thermal load and,thereby,study the thermal erosion behavior of the Cr coating on the barrel's inner wall,a laser emitter is utilized in the current study.With the help of in-situ tensile test and finite element simulation results,a shear stress distribution law of the Cr coating/steel substrate and a change law of the interface ultimate shear strength are identified.Studies have shown that the Cr coating/steel substrate interface's ultimate shear strength has a significant weakening effect due to increasing temperature.In this study,the interfacial ultimate shear strength decreases from 2.57 GPa(no erosion)to 1.02 GPa(laser power is 160 W).The data from this experiment is employed to establish a Cr coating/steel substrate interface shear damage model.And this model is used to predict the flaking process of Cr coating by finite element method.The simulation results show that the increase of coating crack spacing and coating thickness will increase the service life of gun barrel.     

Low velocity impact studies of E-glass/epoxy composite laminates at different thicknesses and temperatures

Low velocity impact experiments were carried out on E-glass/epoxy composite laminates having varying thicknesses at sub zero and elevated temperatures using hemi spherical steel impactor of 16 mm diameter with impact energies in the rage of 50–150 J. The performance of the laminates was assessed in terms of energy absorption, maximum displacement, peak force and failure behaviour. Results indicated that the effect of temperature on energy absorption of the laminate is negligible although the laminates are embrittling at sub zero temperatures. However it has influence on failure behaviour and displacement. Peak force has increased linearly with increase in laminate thickness from 5 to 10 mm. However it got reduced by 25% when temperature was increased from −20 °C to 100 °C. Based on experimental results, laminate perforation energies were predicted using curve fitting equations. Statistical analysis was carried out using Taguchi method to identify the global effects of various parameters on laminate performance and confirmed that the laminate thickness has significant influence as compared to temperature, for the studied range.     

Texture evaluation in AZ31/AZ31 multilayer and AZ31/AA5068 laminar composite during accumulative roll bonding

This article presents the texture development of magnesium AZ31 alloy in the accumulative roll bonded (ARB) AZ31/AZ31 multilayer and AZ31/AA5086 laminate composite. The comparative study demonstrates that the texture evolution in AZ31 in a multilayer system is strongly influenced by the interfaces. A typical basal texture of AZ31 has been observed in AZ31/AZ31 multilayer with texture intensity increased with the rolling deformation. Presence of AZ31/AA5086 interface in the laminate composite leads to a tilted basal texture along the rolling direction (RD) in AZ31 alloy. The texture intensity of composite increased initially with rolling reduction and weakened at the higher rolling strain. Weakening of texture in AZ31 during the laminate processing at higher strain has been attributed to the development of wavy interfaces in AZ31/AA5086 laminate.     

内压作用下复合材料修复裂纹管道的失效分析

为准确评估在内压作用下纤维复合材料修复含裂纹管道的有效性及失效压力,建立复合材料修复后裂纹管道的失效数值模型。该数值模型通过扩展有限元法模拟管道裂纹的扩展,利用cohesive单元模拟胶层的脱粘失效,复合材料的失效通过最大应力失效准则进行判定。通过静水压爆裂试验对所提失效数值模型进行验证,实验结果与数值计算结果具有较好的一致性。失效数值分析结果表明:当内压增大至一定值后,未修复管道的初始裂纹沿轴向及壁厚方向逐渐扩展,进而使得管道内壁单元扩展成真实裂纹,此时真实裂纹贯穿整个壁厚方向,即认为裂纹管道发生爆裂失效,爆裂失效压力随初始裂纹半长呈指数形式下降。复合材料修复裂纹管道的不同修复工况呈现相同的失效模式:在单调递增的内压作用下,管道内表面首先出现黏结裂纹,而后其外表面裂纹张开趋势急剧上升,使得复合材料层应力急剧上升,达到极限强度而失效。且对于不同的初始裂纹尺寸,存在对应的复合材料缠绕层数临界值。     

复合材料结构传热分析的新的高阶热层合理论研究

提出了新的高阶热层合理论及相应的有限元模型．新的高阶热层合理论比作者最初提出的一阶热层合理论［１］前进了一大步,它有效克服了一阶热层合理论中存在的计算缺陷．大量数值算例表明了高阶热层合理论的精确有效性．算例还对铺设角和纵厚比对层合板温度场的影响进行了分析,并得到了一些有意义的结论．