动载下土工格栅加筋桥台挡墙承载性能分析

为研究加筋土桥台结构在顶部条基动载作用下的动力响应问题,通过MTS伺服加载系统施加循环动载,开展室内加筋桥台挡墙动载破坏试验,对比分析3种格栅长度和3类格栅型式的加筋土挡墙沉降及面板水平位移、土压力、筋材应变等参数的分布规律,揭示加筋桥台挡墙的动力承载性能。试验结果表明：在循环动载下不同格栅长度及型式的加筋桥台挡墙破坏模式存在差异,M、A、B型格栅加筋长度 1.0H（H为挡墙高）的挡墙破坏模式均为冲切剪切破坏,A、B型格栅 0.7H和 0.4H的挡墙破坏模式为局部剪切破坏。加筋桥台挡墙面板侧移随筋材长度增加依次减小,A型格栅加筋土挡墙侧移系数总体上相比B型小。桥台挡墙因加筋格栅长度及型式不同导致动土压力衰减规律差异明显,当 1.0H时M型及A型筋材竖向动土压力衰减系数沿墙高呈抛物线函数模型,当 0.7H时,A型和B型筋材竖向动土压力衰减系数沿墙高皆呈指数函数模型。     

有限空间中三维壁面紊动射流流动特性试验研究

为了研究三维壁面紊动射流前方布置的垂直挡板对时均流动特性的影响,采用粒子图像测速技术对不同雷诺数和淹没水深条件下的流速场进行了测量,统计分析了U速度剖面分布、速度半宽值变化和最大速度衰减规律。结果表明:沿射流方向具有3个明显不同的衰减区,依次划分为自由边界下的三维壁面射流区（Ⅰ区）、垂直挡板影响区（Ⅱ区）和近壁区（Ⅲ区）。在重点分析的Ⅱ区内,3个特征物理量的分布规律均与雷诺数无关;在垂直挡板影响下,速度半宽值扩展率明显加快,发展更为充分;在水深H~1.75H范围内,射孔中垂面内速度半宽值扩展率为0.043,同时0.5H的递增对射孔中心水平面内速度半宽值的分布较为敏感,其扩展率由0.205增至0.270;最大速度衰减对水深的改变并不敏感,且在Ⅱ区加速衰减,衰减指数为1.095。通过与半无限空间中三维壁面射流径向型衰减区的流动特征比较,Ⅱ区与之相似,将Ⅱ区视为提前进入径向型衰减区。     

薄壁结构砼的裂缝与处理

分析了万年闸船闸砼工程结束后薄壁砼结构墙体出现大面积贯通性裂缝的发生原因,提出了修复裂缝的工艺方案,总结了预防此类裂缝发生的有效措施。     

固壁紊流流速分布指数型公式和阻力规律——(Ⅱ)过渡区

基于相似理论中的不完全自相似假设,研究了固壁紊流流速分布的结构型式。通过对壁面紊流结构的分析,进而给出了固壁紊流包括光滑区、过渡区和粗糙区在内的统一的指数型流速分布公式和阻力规律,并用尼库拉兹的实验资料作了验证。     

土钉墙模型试验分析

通过土钉墙模型试验,研究土钉的分布对上钉墙成形整体的作用,超载对土钉墙的影响。     

上海地区饱和粉土层中土钉墙支护的工程实践

通过虹祺花苑复合式土钉墙工程实例,阐述饱和粉土层中的土钉墙支护计算原理及现场施工要点,并总结了技术要点及注意事项以资推广。     

土钉墙与压密注浆在复杂地质条件下基坑中的应用

通过上海长途客运公司恒丰路高速客运站基坑土钉支护工程实例,阐明了土钉支护在复杂地质条件下的适用性及灵活性,并提出了相应处理措施,说明了只有有效地结合其他多种施工方法,才能更好地处理复杂情况。     

Computation of solitary waves during propagation and runup on a slope

A numerical time-simulation algorithm for analysing highly nonlinear solitary waves interacting with plane gentle and steep slopes is described by employing a mixed Eulerian–Lagrangian method. The full nonlinear free surface conditions are considered here in a Lagrangian frame of reference without any analytical approximations, and thus the method is valid for very steep waves including overturning. It is found that the runup height is crucially dependent on the wave steepness and the slope of the plane. Pressures and forces exerted on impermeable walls of different inclinations (slopes) by progressive shallow water solitary waves are studied. Strong nonlinear features in the form of pronounced double peaks are visible in the time history of pressure and force signals with increasing heights of the oncoming solitary waves. The effect of nonlinearity is less pronounced as the inclination of the wall decreases with respect to the bottom surface.     

Experimental evidence for flexibility of a building foundation supported by concrete friction piles

This article explores the possibility to measure deformations of building foundations from measurements of ambient noise and strong motion recordings. The case under study is a seven-storey hotel building in Van Nuys, California. It has been instrumented by strong motion accelerographs, and has recorded several earthquakes, including the 1971 San Fernando (M_L=6.6, R=22 km), 1987 Whittier–Narrows (M_L=5.9, R=41 km), 1992 Landers (M_L=7.5, R=186 km), 1992 Big Bear (M_L=6.5, R=149 km), and 1994 Northridge (M_L=6.4, R=1.5 km) earthquake and its aftershocks (20 March: M_L=5.2, R=1.2 km; 6 December, 1994: M_L=4.3, R=11 km). It suffered minor structural damage in 1971 earthquake and extensive damage in 1994. Two detailed ambient vibration tests were performed following the Northridge earthquake, one before and the other one after the 20 March aftershock. These included measurements at a grid of points on the ground floor and in the parking lot surrounding the building, presented and analyzed in this article. The analysis shows that the foundation system, consisting of grade beams on friction piles, does not act as a “rigid body” but deforms during the passage of microtremor and therefore earthquake waves. For this geometrically and by design essentially symmetric building, the center of stiffness of the foundation system appears to have large eccentricity (this is seen both from the microtremor measurements and from the earthquake recordings). This eccentricity may have contributed to strong coupling of transverse and torsional responses, and to larger than expected torsional response, contributing to damage during the 1994 Northridge, earthquake.     

考虑桩顶冠梁效应的水泥土挡墙变形计算方法

以ｍ法为基础,建立了考虑桩顶冠梁效应的挡墙变形计算模型,给出了计算公式。工程实例表明：该方法预测挡墙变形是可行的。