水射流破碎南海含水合物沉积物数值模拟研究

为研究高压水射流切割、破碎南海天然气水合物储层的过程,采用著名的LS—DYNA显示动力分析有限元程序,对淹没状态下,水射流破碎海底含水合物沉积物过程进行数值模拟研究,研究了不同射流速度对高压水射流作用下含水合物沉积物破碎效果的影响规律。随着射流速度的增大,冲蚀深度逐渐增大,两者呈线性递增关系。含水合物沉积物冲蚀体积是轴向冲蚀与径向冲蚀共同作用的结果,射流速度越大,对含水合物沉积物的轴向与径向冲蚀作用增强,加大了含水合物沉积物冲蚀体积递增速率。     

有机蒙脱石层间微结构的分子模拟

采用分子动力学模拟方法,对舍烷基长链阳离子表面活性剂改性有机蒙脱石的层间域内分子环境及烷基长链排列状况进行模拟研究,并考察改性剂负载量与层间域含水量的改变对烷基链排列方式和活动性以及表面活性剂离子中N,C原子的分布状况的影响.1.0倍阳离子交换容量改性的有机蒙脱石在含少量水的情况下(干态),N,C原子均呈双层分布,表明烷基长链为双层平卧排列.含水量的提高(湿态)会导致烷基链从双层分布向在层闻域内均匀分布转变.2.0倍阳离子交换容量改性的有机蒙脱石在舍少量水的情况下(干态),烷基链呈双层倾斜分布于层间域内,烷基链的头部靠近四面体片层.含水量的提高(湿态)对烷基链在层间域内分布状态影响有限,但会导致烷基链整体向层间域中心平面移动,水分子优先占据靠近四面体片层的位置.     

基于GMS的三维TOUGH2模型及模拟

GMS和TOUGH2均是应用广泛的地下流动系统数值模拟软件,其中,GMS界面友好,功能强大;而TOUGH2虽具有强大的数值计算能力,但缺乏友好的可视化前后处理界面。本文借助GMS强大的前处理能力,基于概念模型建立了三维复杂模型,把GMS/MODFLOW三维数值模型(包括网格数据、岩性数据、初始和边界数据等)转化为TOUGH2数值模型进行数值计算。通过两个计算实例(含水层水平没有起伏和有起伏)对比分析了GMS/MODFLOW和TOUGH2计算结果的差异。结果显示,该方法可以快速地建立刻画复杂地质条件的TOUGH2模型,计算结果与GMS/MODFLOW差异很小,说明两个软件均有很高的可信度;同时,该方法发挥了两个软件各自的优势,为进行更为复杂的多相流动数值模拟提供了可行性。     

地基土沉降对复合地基影响的三维数值模拟

通过对复合地基在正常使用条件下和地基土沉降后的三维数值模拟,研究了复合地基由地下水位下降引起的地基土沉陷后的沉降、桩体摩阻力分布和桩身轴力分布的变化。分析表明：随着地基土沉降的增加,加固桩体和基础的沉降加大,中性点位置逐渐下降,桩身轴力有所增大;在加强桩中,中心桩的中性点最低,边桩次之,角桩最高;随着地基土沉降的增加,各桩中性点位置差异逐渐减小,桩体上部负摩阻力作用的桩身长度更长,负摩阻力值逐渐增大。     

基于相似模拟和地质力学模型试验的突出装置研制及应用

国内外学者对煤与瓦斯突出过程及机制进行了大量的研究,但使用的均是型煤试验,很少涉及地质构造对突出的影响,而且数据监测均未深入到煤体内部。基于相似模拟试验思想和地质力学模型试验新思路,在实验室搭建了综合考虑地应力、瓦斯压力及煤体结构的大型石门揭煤的煤与瓦斯突出试验平台。该试验平台包括试验箱体和反力架、液压加载系统、密封系统、试验监测系统;设计了线充气和面充气系统,用来模拟煤层的瓦斯赋存差异。同时,利用该试验平台进行了石门揭构造软煤的相似模拟试验,研究了石门揭构造软煤过程中煤岩应力和位移的变化规律,以及突出过程中煤层内瓦斯压力和声发射的变化规律。结果表明,在巷道开挖过程中,掘进工作面前方存在明显的应力集中,且越靠近构造软煤应力集中现象越明显;突出发生的瞬间,在突出点附近的位移产生了突变;在突出发生前,声发射信号有一次降低;掘进工作面前方煤岩体应力释放,煤体裂隙增大,为瓦斯的快速放散提供了条件。     

层状云的雨滴谱分档数值模拟研究

通过建立雨滴分档模式,结合部分观测资料,对中国北方常见的三类典型层状云系:强锋面抬升层状云系、气旋尺度辐合层状云系及弱锋面抬升层状云系的云中水成物总比含水量、降水强度及地面雨滴谱进行了数值模拟,并与观测值进行了比较分析。结果表明,雨滴分档模式较一般使用的单参数Marshall-Palmer（M-P）分布的参数化模式更能反映雨滴的自然演变特征。     

Estimation of Hourly Solar Radiation at the Surface under Cloudless Conditions on the Tibetan Plateau Using a Simple Radiation Model

In this study,the clear sky hourly global and net solar irradiances at the surface determined using SUNFLUX,a simple parameterization scheme,for three stations(Gaize,Naqu,and Lhasa) on the Tibetan Plateau were evaluated against observation data.Our modeled results agree well with observations.The correlation coefficients between modeled and observed values were > 0.99 for all three stations.The relative error of modeled results,in average was < 7%,and the root-mean-square variance was < 27 W m 2.The solar irradiances in the radiation model were slightly overestimated compared with observation data;there were at least two likely causes.First,the radiative effects of aerosols were not included in the radiation model.Second,solar irradiances determined by thermopile pyranometers include a thermal offset error that causes solar radiation to be slightly underestimated.The solar radiation absorbed by the ozone and water vapor was estimated.The results show that monthly mean solar radiation absorbed by the ozone is < 2% of the global solar radiation(< 14 W m 2).Solar radiation absorbed by water vapor is stronger in summer than in winter.The maximum amount of monthly mean solar radiation absorbed by water vapor can be up to 13% of the global solar radiation(95 W m 2).This indicates that water vapor measurements with high precision are very important for precise determination of solar radiation.     

登陆北上台风暴雨突发性增强的一种机制研究

采用一个三维混合模式对1992年8月30日至9月2日一次登陆北上台风暴雨过程进行了模拟。模式可以较准确地预报出与地面倒槽相一致的地面降水位置及降水量值。模拟的台风云系结构与卫星云图比较表明,外围云场与实例云况吻合很好,验证了本模式模拟卫星云图的能力,对卫星云图预报有实际意义;暴雨突然增幅的直接原因是高层冰云与低层供水云的突然北移重叠造成的。受地面倒槽附近强烈辐合抬升的动力作用,各相态云系的分布与垂直运动紧密相关;辐合线右侧的东南低空急流为降水的增幅及维持提供水汽来源;云的相变潜热非绝热加热作用对暴雨的增幅及维持具有正反馈作用,它对暴雨维持具有积极贡献。     

城市中水体布局对大气环境的影响

城市下垫面状况在很大程度上决定城市大气物理环境的特征。在城市区域增加湿地等自然地表有利于城市的减温增湿,促使局地流场发生变化,改善局地微气象条件以及大气物理环境。城市规划大气物理环境多尺度数值模拟系统为城市规划大气物理环境定量评估提供了有效的模拟工具。利用该系统中的城市尺度模式模拟了水体布局为集中型和分散型,水体面积占有率分别为4%、8%、12%和16%条件下,城市大气温度、湿度、风速、城市大气扩散条件的变化及其对城市大气环境的影响,利用北京市城市水体气象观测数据,分析了水体周边和商业区、交通区温、湿度的差异,并对模式模拟结果进行了验证,揭示了城市水体布局对城市大气物理环境影响的可能机制。模拟和观测结果显示,城市水体布局会对城市微气象环境产生一定影响。无论分散型或集中型布局,城市水体面积的增加,都在一定程度上使城市气温降低、湿度增加、平均风速增大。比较而言,分散型水体布局对城市区域微气象环境的影响更为显著。     

SIMULATION OF BOUNDARY LAYER EFFECTS ON A HEAVY RAINFALL EVENT CAUSED BY A MESOSCALE CONVECTIVE SYSTEM OVER THE YELLOW RIVER MIDSTREAM AREA

A heavy rainfall event caused by a mesoscale convective system (MCS), which occurred over the Yellow River midstream area during 7–9 July 2016, was analyzed using observational, high-resolution satellite, NCEP/NCAR reanalysis, and numerical simulation data. This heavy rainfall event was caused by one mesoscale convective complex (MCC) and five MCSs successively. The MCC rainstorm occurred when southwesterly winds strengthened into a jet. The MCS rainstorms occurred when low-level wind fields weakened, but their easterly components in the lower and boundary layers increased continuously. Numerical analysis revealed that there were obvious differences between the MCC and MCS rainstorms, including their three-dimensional airflow structure, disturbances in wind fields and vapor distributions, and characteristics of energy conversion and propagation. Formation of the MCC was related to southerly conveyed water vapor and energy to the north, with obvious water vapor exchange between the free atmosphere and the boundary layer. Continuous regeneration and development of the MCSs mainly relied on maintenance of an upward extension of a positive water vapor disturbance. The MCC rainstorm was triggered by large range of convergent ascending motion caused by a southerly jet, and easterly disturbance within the boundary layer. While a southerly fluctuation and easterly disturbance in the boundary layer were important triggers of the MCS rainstorms. Maintenance and development of the MCC and MCSs were linked to secondary circulation, resulting from convergence of Ekman non-equilibrium flow in the boundary layer. Both intensity and motion of the convergence centers in MCC and MCS cases were different. Clearly, sub-synoptic scale systems in the middle troposphere played a leading role in determining precipitation distribution during this event. Although mesoscale systems triggered by the sub-synoptic scale system induced the heavy rainfall, small-scale disturbances within the boundary layer determined its intensity and location.