后向欧拉和曲克-尼克索姆技术在变饱和流动问题有限元模型数值解中的应用

M. S. Islam
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引用次数: 6

摘要

模拟水在可变饱和多孔介质中的流动在科学和工程的许多分支中是重要的。含水量与水导率和土水压力之间的高度非线性关系导致非常陡峭的湿润锋导致数值问题。这些问题包括在模拟水渗入非常干燥的多孔介质时效率低下,以及在陡峭的湿润锋附近的数值振荡。建立了变饱和流动系统数值模拟的一维有限元公式。一阶反欧拉隐式和二阶曲克式?在基于皮卡德和牛顿迭代技术的公式中,采用Nicolson时间离散格式作为求解策略。用五个算例分析了两种方法的数值性能,并着重分析了影响两种方法收敛性和效率的不同因素。第一个测试用例处理渗入土壤柱的尖锐湿气锋。它显示了提供质量保守性的能力。在第二个测试用例中不开发饱和条件。干初始条件和陡湿润锋的涉及是第三例的主要数值复杂性。第四个测试用例是水从地表快速入渗,随后由于动态边界条件,水在一段时间内重新分布。最后一个一维测试用例涉及流到具有可变初始条件的层状土壤中。数值结果表明,曲柄?对于层状土问题,Nicolson格式与完全隐式后向欧拉格式相比效率较低,但对于其他均质土情况具有相同的精度。
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CONSEQUENCE OF BACKWARD EULER AND CRANK-NICOLSOM TECHNIQUES IN THE FINITE ELEMENT MODEL FOR THE NUMERICAL SOLUTION OF VARIABLY SATURATED FLOW PROBLEMS
Modeling water flow in variably saturated, porous media is important in many branches of science and engineering. Highly nonlinear relationships between water content and hydraulic conductivity and soil-water pressure result in very steep wetting fronts causing numerical problems. These include poor efficiency when modeling water infiltration into very dry porous media, and numerical oscillation near a steep wetting front. A one-dimensional finite element formulation is developed for the numerical simulation of variably saturated flow systems. First order backward Euler implicit and second order Crank?Nicolson time discretization schemes are adopted as a solution strategy in this formulation based on Picard and Newton iterative techniques. Five examples are used to investigate the numerical performance of two approaches and the different factors are highlighted that can affect their convergence and efficiency. The first test case deals with sharp moisture front that infiltrates into the soil column. It shows the capability of providing a mass-conservative behavior. Saturated conditions are not developed in the second test case. Involving of dry initial condition and steep wetting front are the main numerical complexity of the third test example. Fourth test case is a rapid infiltration of water from the surface, followed by a period of redistribution of the water due to the dynamic boundary condition. The last one-dimensional test case involves flow into a layered soil with variable initial conditions. The numerical results indicate that the Crank?Nicolson scheme is inefficient compared to fully implicit backward Euler scheme for the layered soil problem but offers same accuracy for the other homogeneous soil cases.
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