Copaifera sp.木材的物理力学特性

V. Aquino, Viliam Cardoso da Silveira, G. Degrazia, D. Buske, S. Rolim
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引用次数: 11

摘要

这项工作的目的是评估INEL(美国)实验发布地区的污染物羽流行为。INEL扩散实验由一系列测试组成,这些测试是在稳定的低风大气条件下,在平坦均匀的地形上完成的。因此,考虑到目前对稳定行星边界层(PBL)湍流模式和特征(稳定涡扩散率)的理解,采用了由WRF(天气研究和预测)和LES-PALM(大涡模拟并行化)模型组成的建模系统来描述与风曲流运动相关的扩散效应。WRF模型产生的潜在温度分布和热通量将用作LES-PALM模型的初始条件。PALM被称为大气和海洋通量的大涡模拟(LES)模型,用于并行计算机架构。LES-PALM模型产生的水平风曲流将被用作基于3D-GILTT(3D广义积分拉普拉斯变换技术)技术的离散模型的初始条件,该技术解析求解平流-扩散方程。这种积分变换技术结合了级数展开和积分。在展开中,使用了由Sturm-Liouville辅助问题确定的三角基。利用展开中使用的基的正交性特性,在变换变量的所有范围内进行积分。使用拉普拉斯变换和对角化对所得的常微分方程组进行解析求解。该建模系统产生的模拟结果与INEL实验观测到的地面中心线浓度以及其他大气扩散模型的模拟结果一致。本研究表明,由两个气象模型(WRF和LES-PALM)耦合提供的水平风场可以用于欧拉扩散模型,以正确模拟低风速稳定PBL中污染物的弯曲增强扩散。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Physical and Mechanical Characterization of Copaifera sp. Wood Specie
The aim of this work is evaluating the behaviour of the pollutant plume in the region where the INEL (USA) experiment was released. The INEL diffusion experiment consists of a test series that was accomplished in a flat and uniform terrain under stable low wind atmospheric conditions. Thusly, accounting for the current understanding of the stable planetary boundary layer (PBL) turbulence pattern and characteristics (stable eddy diffusivities), a modelling system consisting of the WRF (Weather Research and Forecasting) and LES-PALM (Large-Eddy Simulation-Parallelized) model is employed to describe the dispersive effects associated with the wind meandering movements. The potential temperature profiles and heat fluxes generated by the WRF model will be used as initial conditions to the LES-PALM model. PALM is referred as a model to Large Eddy Simulation (LES) to atmospheric and oceanic fluxes that is destined to parallel computer architectures. The horizontal wind meandering generated by LES-PALM model will be used as initial conditions to the dispersion model based in the 3D-GILTT (3D Generalized Integral Laplace Transform Technique) technique that analytically solves the advection-diffusion equation. This technique of the integral transform combines a series expansion with an integration. In the expansion a trigonometric base, determined from the Sturm-Liouville auxiliary problem, is employed. The integration is made in all range of the transformed variable, making use of the orthogonality property of the base used in the expansion. The resultant ordinary differential equations system is analytically solved using the Laplace transform and diagonalization. The simulation results, generated from this modelling system are show to agree with the observed ground-level centreline concentrations of INEL experiments and also with those of other atmospheric dispersion models. The present study shows that the horizontal wind field provided by the coupling of two meteorological models (WRF and LES-PALM) can be used in a Eulerian diffusion model to properly simulate meandering enhanced dispersion of contaminants in a low wind speed stable PBL.
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