基于分布式光纤传感技术的流速测量方法研究

简要介绍了分布式光纤传感技术的流速测量方法的主要仪器设备。在研究加热光纤与流水之间传热过程的基础上,推导了流速与光纤稳定温升、加热功率等参数之间的基于分布式光纤传感技术的流速测量方法的理论方程。设计了模型试验,对不同流速与加热功率下,光纤温升情况进行了试验研究。在试验数据分析的基础上,研究了静水与流水中光纤温升情况,结果表明：所有温升曲线都可以分为上升和稳定两个阶段,流水中的光纤温升明显低于静水中的光纤温升,两者的差值随着功率及流速的不同而不同。加热功率越大,两者温差越大;流速越大,温差越大。研究了加热功率对静水中光纤温升的影响,通过分析发现：静水中的光纤稳定温升与加热功率之间存在着良好的线性关系。重点分析了在一定功率下,流速与光纤稳定温升之间的关系,结果表明光纤稳定温升与水流速度呈非直线的反比关系。最后,对该方法进行了讨论,提出了下一步研究建议。     

青海省煤炭资源概况及潜力分析

青海省煤炭资源相对比较贫乏,且分布不均衡,总体勘查程度较低。煤炭资源潜力评价结果显示,青海煤炭预测资源量为344.46亿t,总量占全国比值相对较少,已查明资源储量为45.84亿t,查明率是13.26%,查明程度很低。根据对资源量赋存深度、成煤时代、煤质类型及地域分布的分析,认为全省煤炭煤种优势明显,产地相对集中,找矿潜力很大。根据青海省经济发展规划,以煤炭资源开发利用为基础的煤化工产业将成为青海省又一重要经济支柱,因此应加大地质勘查投入,着力提高全省的煤炭地质勘查程度,为青海省经济可持续发展提供资源保障。     

声学法深海热液速度场测量重建算法研究

介绍了利用声学法测量深海热液速度场的基本原理.利用往返飞渡时间差与流场速度的关系,应用反问题求解技术重建测量区域的速度场.应用最小二乘法对两种典型的热液口速度场模型进行了仿真重建,分析了换能器数量、实验测量误差以及换能器的布放对重建结果的影响,并对重建结果进行了流量分析.仿真重建的绝对误差、相对误差以及流量分析结果表明...     

皖南地区区域地球化学特征及成矿潜力的地球化学预测

根据皖南地区1:20万区域化探资料,计算了区内元素的背景值、区域浓集系数、总体变化系数等参数,阐明了区内元素含量空间分布与成矿元素共生组合特征。使用区域浓集系数及变化系数两个参数,对皖南地区32种元素的成矿潜力进行排序,在目前安徽省地质勘查主攻矿种中,皖南地区的成矿潜力依次为金(银)-钨-钼-铜-铀-锌-铅。同时根据地球化学块体理论和方法,预测了区内金、银资源量,分别为金474t、银16117t,显示出较大的找矿潜力。     

VTI介质转换波速度分析方法研究及应用

速度分析是转换波处理的核心问题之一,采用单平方根方程对具有垂直对称轴的横向各向同性(VTI)介质进行速度分析,使得转换波的处理不依赖于纵波的数据,既简化了转换波处理流程,又消除了由于纵波处理不精确所带来的传递误差。通过理论分析和数值计算,总结并设计了一套求取VTI介质转换波动校正参数的方法和处理流程,总结出了采用双参数扫描法获得较高分辨率和精度所需满足的必要条件。通过批处理和交互结合的方式对实际资料进行处理,取得了较好的处理效果,证明了该方法及软件的正确性。     

山东省地下水资源及其潜力评价

通过对山东省水文地质条件、地下水赋存特征、地下水开采现状及其动态特征进行系统研究的基础上,计算评价了全省地下水天然补给资源量、可开采资源量、开采程度和剩余可开采资源量。论述了地下水开采资源潜力的计算评价原则和判别标志,确定了全省主要的地下水资源潜力分布区。     

长条状粗颗粒在垂直管路中最小输送速度试验研究

随着陆地金属资源的日益枯竭,深海矿产资源已经成为各国的重要战略目标。在深海采矿过程中,海底锰结核的形状除了圆球状,还有长条状等,颗粒形状对固液两相流管道输送特性具有很大影响。基于固液两相流垂直管道提升输送试验系统,探究不同工况下长条状颗粒在垂直上升流中最小输送速度的变化规律及特性,并得到了长条状群体颗粒最小输送速度计算公式。结果表明:长条状颗粒在垂直管道中上升过程中,颗粒中心轴与输送方向趋向于垂直,使颗粒在管道截面的投影面积最大化;长条状单颗粒的最小输送速度随着颗粒长径比增大而减小;在不同长径比工况下,随着管段颗粒平均浓度减小,长条状群体颗粒的最小输送速度均增大,且随着长径比增大,群最小输送速度减小。     

A mixing-length model for predicting vertical velocity distribution in flows through emergent vegetation

Abstract

The vertical profiles of streamwise velocities are computed on flood plains vegetated with trees. The calculations were made based on a newly developed one-dimensional model, taking into account the relevant forces acting on the volumetric element surrounding the considered vegetation elements. A modified mixing length concept was used in the model. An important by-product of the model is the method for evaluating the friction velocities, and consequently bed shear stresses, in a vegetated channel. The model results were compared with the relevant experimental results obtained in a laboratory flume in which flood plains were covered by simulated vegetation.     

新疆东天山二红洼岩体岩浆演化特征与成矿潜力分析

二红洼岩体位于康古尔-黄山韧性剪切带东段,主要由含长二辉橄榄岩、橄榄辉长岩、辉长苏长岩和淡色辉长岩组成。岩石相对富集LREE,亏损高场强元素（Nb、Ta、Ti）。岩体原生岩浆为普通拉斑玄武岩（MgO=7.3%）。通过对元素地球化学和Nd、Sr、Pb同位素体系研究证明,岩浆源区以软流圈物质为主,混入了少量富集岩石圈地幔组分,岩浆遭受了约5%上地壳物质的混染。与同岩带典型含矿岩体对比研究表明,岩体在岩石组合、原生岩浆性质、同化混染程度等方面存在显著差异,这些因素可能制约了成矿潜力。     

Preliminary 3–D geological model of the Kalgoorlie region,Yilgarn Craton,Western Australia,based on deep seismic‐reflection and potential‐field data

The granite‐greenstone terranes of the Eastern Goldfields Province, Yilgarn Craton, Western Australia, are a major Australian and world gold and nickel source. The Kalgoorlie region, in particular, hosts several world‐class gold deposits. To attempt to understand why these deposits occur where they do, it is important to understand the crustal architecture in the region and how the major mineral systems operate in this architecture. One way to understand these relationships is to develop a detailed 3–D geological model for the region. The best method to map the 3–D geometry of major geological structures is by acquisition and interpretation of seismic‐reflection profiles. To contribute to this aim, a grid of deep seismic‐reflection traverses was acquired in 1999 to examine the 3–D geometry of the region in an area including the Kalgoorlie mineral region and mineral fields to the north and west. This grid was tied to the 1991 regional deep seismic traverse and 1997 high‐resolution seismic profiles in the same region. The grid covers an area measuring approximately 50 km wide by 50 km long and extended to a depth of approximately 50 km (below the base of the crust in this region). The resulting 3–D geological model was further constrained by both surface geological data and geophysical interpretations, with the seismic interpretations themselves also constrained by gravity and magnetic modelling. The 3–D model was used to investigate the geometric relationships between the major faults and shear zones in the area, the relationship between the granite‐greenstone succession and the basement, and the spatial relationships between the greenstones and the granites. Interpretation of the grid of seismic lines and construction of the 3–D geological model confirmed the existence of the detachment surface and led to the recognition that the granite‐greenstone contact usually occurs at a much shallower level than the detachment. Also, west‐dipping faults in the vicinity of the Golden Mile, including the Abattoir Shear through to Boulder‐Lefroy Fault, appear to be more important than previously thought in controlling the structure of that area. An antiformal thrust stack occurs beneath a triangle zone centred on the Golden Mile. The Black Flag Group was deposited in a probable extensional setting, and late extension was also probably more important than previously thought. The granite‐gneiss domes were uplifted by the formation of antiformal thrust stacks at depth beneath them.