Characterizing Turbulence at a Forest Edge: Comparing Sub-filter Scale Turbulence Models in Simulations of Flow over a Canopy

arXiv - PHYS - Fluid Dynamics Pub Date : 2024-09-09 DOI:arxiv-2409.06047

Dorianis M. Perez, Jesse M. Canfield, Rodman R. Linn, Kevin Speer

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Abstract

In wildfires, atmospheric turbulence plays a major role in the transfer of turbulent kinetic energy. Understanding how turbulence feeds back into a dynamical system is important, down to the varying small scales of fuel structures (i.e. pine needles, grass). Large eddy simulations (LES) are a common way of numerically representing turbulence. The Smagorinsky model (1963) serves as one of the most studied sub-grid scale representations in LES. In this investigation, the Smagorinsky model was implemented in HIGRAD/FIRETEC, LANL's coupled fire-atmosphere model. The Smagorinsky turbulent kinetic energy (TKE) was compared to FIRETEC's 1.5-order TKE eddy-viscosity subgrid-scale model, known as the Linn turbulence model. This was done in simulations of flow over flat terrain with a homogeneous, cuboidal canopy in the center of the domain. Examinations of the modeled vertical TKE profile and turbulent statistics at the leading edge, and throughout the canopy, show that the Smagorinsky model provides comparable results to that of the original closure model posed in FIRETEC.

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描述森林边缘的湍流：在模拟树冠上的水流时比较亚过滤器尺度的湍流模型

在野火中，大气湍流在湍流动能的传递中扮演着重要角色。了解湍流如何反馈到动力系统非常重要，甚至包括燃料结构（如松针、草）的不同小尺度。大涡流模拟（LES）是数值表示湍流的常用方法。Smagorinsky 模型（1963 年）是 LES 中研究最多的子网格尺度表示方法之一。在本次研究中，Smagorinsky 模型在 HIGRAD/FIRETEC（LANL 的火灾-大气耦合模型）中得到了应用。将 Smagorinsky 湍流动能（TKE）与 FIRETEC 的 1.5 阶 TKE 涡粘度子网格模型（即 Linn 湍流模型）进行了比较。这是通过模拟在平坦地形上的流动进行的，该地形的中心是一个均匀的立方体冠层。对模型的垂直 TKE 剖面和前缘以及整个冠层的湍流统计进行的检验表明，斯马戈林斯基模型提供的结果与 FIRETEC 中原始闭合模型的结果相当。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - PHYS - Fluid Dynamics

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