基于图像测速的波浪破碎两相速度场测量方案探讨

针对波浪破碎试验中气泡区速度与水体速度无法同时测量的难题,基于实验室条件,搭建了粒子图像测速（PIV）和气泡图像测速（BIV）系统,采用声学多普勒测速仪（ADV）对PIV测量精度和不同场景下BIV测量精度进行了细致的验证,并设计多种试验方案以期实现BIV与PIV的同步耦合测量。试验结果表明,7W激光+后置灯的优化照明方案,其耦合测量的气泡区速度代表参数与标准BIV照明方案的结果误差小于5%,且耦合测量的气泡区下方水质点的速度曲线与标准PIV测量结果吻合,表明该改进方案满足PIV与BIV耦合测量的条件。本文实现的PIV与BIV耦合测量有利于优化测量和分析工作,减小破碎波浪重复生成的影响,有利于提高测量精度,为大范围波浪破碎速度场的快速测量提供了新的方案。     

青海省化隆县柏木峡地区找矿前景探析

青海省化隆县柏木峡地区构造及岩浆岩发育,根据在该区实施的1∶2.5万水系沉积物测量结果,各元素异常套合好,同时在异常区见有金矿化点及铅矿化点,认为该区成矿条件优越,找矿前景较好。     

2004年苏门答腊地震前后海面高趋势的变化

利用苏门答腊附近海域T/P、Jason-1测高卫星近20年的海面高连续观测资料,分别计算了该区域(80°E~105°E,5°S~20°N)在2004年苏门答腊大地震前后的海面高变化趋势,并与该区域对应时间段GRACE重力卫星反演的地表质量迁移结果进行比较。研究结果表明,由卫星测高观测资料估算的震区地震前后海平面趋势的变化与卫星重力反演结果基本一致。由于卫星测高沿轨观测具有高精度、高时空分辨率的特性,卫星测高资料估算的海平面趋势变化可以更为准确地反映震区海平面变化的局部特征。还对该区域震后形变特征进行了初步分析。     

Tests of new in-situ seabed acoustic measurement system in Qingdao

A new in-situ seabed acoustic measurement system is developed for direct in-situ measurement of sediment geoacoustic properties （compressional wave velocity and attenuation）. The new in-situ system consists of two parts： the deck control unit and the underwater measurement unit. The underwater measurement unit emits sonic waves that propagate through the seafloor sediment, receives the returning signals, and transmits them to the deck control unit for waveform display and analysis. The entire operation is controlled and monitored in real time by the deck control unit on the research vessel and can provide recording of full waveforms to determine the sound velocity and attenuation. This paper outlines the design of the system, the measurement process, and demonstrates its application in tests carded out on seabed sediment off the Qingdao coast, China. The test results show that the system performed well and rapidly provided accurate in-situ acoustic velocity and attenuation estimates of the seafloor sediment.     

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Study on deformation law of circular foundation under combined loading

The foundations of some ocean engineering structures are built to withstand not only the vertical gravity load V, but also the horizontal load H induced by sea waves and current. The horizontal load includes the concentrated force load, the moment load M, and the torque load T termed also as combined loading. It is of academic and engineering significance to study the deformation law of submarine seabed due to combined loading. On the basis of the three-dimensional elastic mechanics solution of circular foundation, numerical methods are used to analyze the deformation law of submarine soil under circular foundation with six degrees of freedom. The finite element analysis results give the elastic deformation law of soil in three dimensional spaces, modify the theoretical elasticity solution, and presents nonlinear soil deformation mechanism under the circular foundation with six degrees of freedom.