CFRP加固一字形竖缝耗能预制剪力墙抗震性能研究

以一字形竖缝耗能预制剪力墙作为研究对象,设计了3个装配式剪力墙试件及1个现浇剪力墙对比试件,进行低周往复荷载试验,并对破坏墙体进行CFRP加固,再次进行拟静力试验。试件变化参数包括轴压比、混凝土强度等级及配筋率,对比分析加固前后试件滞回性能、刚度退化、承载力和耗能能力等性能。试验结果表明,与现浇剪力墙相比,一字形竖缝耗能预制剪力墙工作性能良好,阻尼器屈服耗能提高了试件整体工作性能;CFRP加固可有效抑制墙体斜裂缝的发展,对墙体承载力及耗能能力均有显著改善作用;各试件均满足剪力墙弹塑性层间位移角限值要求,延性较好;试件整体表现出良好的抗震性能。     

典型斜坡地形地震动特征分析

以云南鲁甸6.5级地震中房屋建筑破坏严重的龙头山集镇斜坡地形为例,通过地脉动测试分析得出斜坡及坡顶测点相对于坡脚参考点谱比峰值均>1,顺坡向谱比峰值大于垂直坡向谱比峰值,且谱比峰值从斜坡坡脚到坡顶逐渐增大,坡顶处约为3;顺坡向谱比峰值对应的频率为4.57～5.39 Hz,垂直坡向谱比峰值对应的频率稍高,为5.42～5.96 Hz。通过结合黏弹性边界的时域动力有限元方法分析斜坡地形在垂直入射地震动作用下的响应,数值模拟结果表明,斜坡坡顶处的位移放大作用显著,坡脚处放大作用较小;介质剪切波速对斜坡地震动的影响较明显,尤其是坡顶点处不同介质剪切波速模型位移峰值差异较大。由于斜坡地形复杂的散射效应,在斜坡及附近测点均出现明显的转换面波,坡顶点处波形转换最显著。数值模拟结果进一步验证了龙头山集镇依坡而建的房屋建筑破坏严重是由局部地形地震动放大效应与地震动差动共同作用引起的。     

坡面日出日没时角的配置关系与坡向坡度

对于给定的纬度和太阳赤纬,在水平面非极昼时的偏东（偏西）坡面上存在一对互补的坡向,以互补的两个坡向（一般临界坡向）为界,坡面日出日没时角的配置关系具有三种不同的形式。在两个一般临界坡向之间,在坡面日出日没时角的配置关系与坡度无关,或者为ω1=ωs1,ω2=ω0（偏西坡）,或者为ω1=-ω0,ω2=ωs2（偏东坡）。存在一参考坡度α0（arccos（sinφ／cosδ））,一般临界坡向之外的时角配置关系以坡度α0为界,具有不同的形式。如果坡度一定,可存在使非水平面极昼或极夜的特别临界坡向,在一般临界坡向之外,特别临界坡向前后,坡面日出日没时角的配置关系也不同。在一般临界坡向之外,如果坡向一定,可存在参考纬度φ0=arccos（｜cosδ／cosβ｜）,以及使非水平面极昼或极夜的临界坡度。以参考纬度为界,坡面日出日没时角的配置关系或者随临界坡度而变化,或者与坡度无关。     

屋盖悬挑端加固减振试验研究

大跨网架屋盖挑檐部分风致响应较大,提出附加杆件、粘弹性阻尼器及粘滞阻尼器三种加固减振方法。设计制作正置四角锥体单元空间网架足尺子结构试验模型,基于带悬挑平屋盖风压分布风洞试验数据,对三种加固足尺子结构试验模型进行不同风向角下风荷载时程的加载。分析结构风致加速度与位移响应,结果表明:附加杆件加固后网架刚度增大,加速度响应增大,位移响应减小;附加粘弹性阻尼器,结构加速度与位移响应均降低;附加粘滞阻尼器,结构加速度响应减小,位移减小效果不明显。     

灌注桩钢筋笼外部的磁异常特征研究

灌注桩中的钢筋笼在地磁场中受磁化作用而产生磁感应强度,使灌注桩附近的磁场强度发生变化.通过分析水平磁性圆柱体外部的磁异常特征,结合模型桩试验,研究了灌注桩钢筋笼外部的磁异常特征,结果表明在钢筋笼外侧钻孔中的磁异常总体上呈现"两峰夹一谷"的特征,钢筋笼中部呈宽缓的马鞍形负异常,钢筋笼底端位置对应磁异常从极小值转变为极大值的拐点.研究成果从理论上为用磁测井法检测灌注桩中钢筋笼长度奠定了基础.     

鄂尔多斯盆地陕北斜坡延长区块储层流体识别

延长油田区块位于鄂尔多斯盆地陕北斜坡东部延安单斜的中间部位,为研究天然气储层及储层中高含气分布区,2008年在延长油田区块内完成三维地震勘探344km2。本文对三维地震资料应用吸收系数、频谱分解、振幅衰减等地震属性进行流体识别试验。试验结果表明振幅衰减对含气层段异常响应相对敏感,吸收系数对高含气层段有一定反映。利用天然气储层各层段振幅衰减极大值,参考吸收系数剖面的高值层段,分析预测了三维区块含气概率高的平面分布区,2009年在预测的含气概率高分布区进行了探井验证,取得了比较理想的效果。     

Layout design of rockbolts for natural ground reinforcement

The present study addresses a layout design of rockbolts for reinforcing natural ground structures applying a special optimization method, called multiphase layout optimization. Rockbolts are used to tighten loosed natural ground, and the layout of rockbolts are determined without sufficient information about the physical properties of the ground materials. Because of this uncertainty, unexpected deformation often occurs at the excavation surface of natural ground. In that case, it is requested to determine an effective layout of the additional rockbolts promptly with respect to the actual deformation at the construction site. However, it is not easy to determine the optimal layout because of its complexity, and consequently, it has no choice but to determine the layout in an empirical way. This study introduces a numerical approach to determine an optimal layout of rockbolts with respect to arbitrarily possible deformation of natural ground. The objective is to maximize the stiffness of the overall ground structure reinforced with rockbolts. For optimization, a gradient‐based optimization scheme is applied because of its numerical efficiency. It was verified from a series of numerical examples that this method has great potential to improve the stiffness of the overall ground structure and shows a certain applicability to a practical design. Copyright © 2013 John Wiley & Sons, Ltd.     

返包式土工格栅加筋土高挡墙现场试验研究

为了研究返包式土工格栅加筋土高挡墙结构的受力、变形状态,分析其作用机理,进行了包括加筋土墙体基底应力、墙背侧向土压力、拉筋拉力和墙面水平变形等内容的现场试验,研究了加筋土墙体基底垂直应力、不同层位的拉筋拉力沿筋长的分布规律,加筋土挡墙潜在的破裂面位置,墙背侧向土压力沿墙高的分布规律以及墙面水平变形规律。测试结果表明,加筋土挡墙基底垂直土压力沿土工格栅拉筋长度方向呈非线性分布,最大值发生在拉筋中部附近,向拉筋两端方向逐渐减少;实测墙背侧向土压力沿墙高呈非线性形式分布,其值小于主动土压力;上部墙体拉筋应变沿筋长呈单峰值分布,下部墙体拉筋应变沿筋长呈双峰值分布;上部墙体潜在破裂面形状与“0.3H法”接近,而下部墙体潜在的破裂面形状与朗肯主动土压力理论接近;施工期墙面最大水平变形位置在墙高的下部,竣工后墙面最大水平变形发生在墙顶处等结论。     

Response of multilayer geosynthetic-reinforced bed resting on soft soil with stone columns

In the present study, a mechanical model has been developed to study the behavior of multilayer geosynthetic-reinforced granular fill over stone column-reinforced soft soil. The granular fill and geosynthetic reinforcement layers have been idealized by Pasternak shear layer and rough elastic membranes, respectively. The Kelvin–Voight model has been used to represent the time-dependent behavior of saturated soft soil. The stone columns are idealized by stiffer springs and assumed to be linearly elastic. The nonlinear behavior of the soft soil and granular fill is considered. The effect of consolidation of soft soil due to inclusion of the stone columns on settlement response has also been included in the model. Plane strain conditions are considered for the loading and reinforced foundation soil system. An iterative finite difference scheme is applied for obtaining the solution and results are presented in nondimensional form. It has been observed that if the soft soil is improved with stone columns, the multilayer reinforcement system is less effective as compared to single layer reinforcement to reduce the total settlement as there is considerable reduction in the total settlement due to stone column itself. Multilayer reinforcement system is effective for reducing the total settlement when stone columns are not used. However, multilayer reinforcement system is effective to transfer the stress from soil to stone column. The differential settlement is also slightly reduced due to application of multiple geosynthetic layers as compared to the single layer reinforcement system.     

Landslide Hazard Zonation using Remote Sensing and GIS: a case study of Dikrong river basin, Arunachal Pradesh, India

Landslides are among the most costly and damaging natural hazards in mountainous regions, triggered mainly under the influence of earthquakes and/or rainfall. In the present study, Landslide Hazard Zonation (LHZ) of Dikrong river basin of Arunachal Pradesh was carried out using Remote Sensing and Geographic Information System (GIS). Various thematic layers namely slope, photo-lineament buffer, thrust buffer, relative relief map, geology and land use / land cover map were generated using remote sensing data and GIS. The weighting-rating system based on the relative importance of various causative factors as derived from remotely sensed data and other thematic maps were used for the LHZ. The different classes of thematic layers were assigned the corresponding rating value as attribute information in the GIS and an “attribute map” was generated for each data layer. Each class within a thematic layer was assigned an ordinal rating from 0 to 9. Summation of these attribute maps were then multiplied by the corresponding weights to yield the Landslide Hazard Index (LHI) for each cell. Using trial and error method the weight-rating values have been re-adjusted. The LHI threshold values used were: 142, 165, 189 and 216. A LHZ map was prepared showing the five zones, namely “very low hazard”, “low hazard”, “moderate hazard”, “high hazard” and “very high hazard” by using the “slicing” operation.