燃料特性和放热公式在火灾-大气耦合模拟中的作用

IF 3 3区 农林科学 Q2 ECOLOGY
Kasra Shamsaei, T. Juliano, M. Roberts, Hamed Ebrahimian, N. Lareau, E. Rowell, B. Kosović
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引用次数: 1

摘要

在本研究中,我们重点研究了在耦合火-大气模拟平台中燃料床表征和火灾热量和烟雾分布对两个景观尺度火灾的影响:2018年的坎普火灾和2021年的卡尔多火灾。在耦合火-气模拟平台WRF-Fire中,燃料床表示目前仅包括地表燃料。因此,我们通过增加冠层燃料特性和热量释放来增强模型,为此开发了一种计算冠层燃料消耗产生热量的方法并在WRF-Fire中实现。此外,将当前WRF-Fire在大气中的热量和烟雾分布替换为保温的截断高斯(TG)函数,并对其效果进行了评价。案例研究的模拟火灾周长与来自NEXRAD雷达观测的半连续、高分辨率火灾周长进行了验证。此外,将两种火灾情况下的模拟羽流与NEXRAD雷达反射率观测结果进行了比较,然后利用模拟温度场和垂直速度场进行了浮力分析。结果表明,改进的燃料床和TG放热方案对风驱动营火的模拟火周影响较小,但会影响羽流驱动Caldor火的传播方向,使模拟火周与观测值匹配更好。然而,与两种火灾的观测结果相比,改进的燃料床表示以及TG热烟释放方案导致了更真实的羽流结构。浮力分析还描述了改进燃料床后更为真实的火灾温度异常和大气环流。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
The Role of Fuel Characteristics and Heat Release Formulations in Coupled Fire-Atmosphere Simulation
In this study, we focus on the effects of fuel bed representation and fire heat and smoke distribution in a coupled fire-atmosphere simulation platform for two landscape-scale fires: the 2018 Camp Fire and the 2021 Caldor Fire. The fuel bed representation in the coupled fire-atmosphere simulation platform WRF-Fire currently includes only surface fuels. Thus, we enhance the model by adding canopy fuel characteristics and heat release, for which a method to calculate the heat generated from canopy fuel consumption is developed and implemented in WRF-Fire. Furthermore, the current WRF-Fire heat and smoke distribution in the atmosphere is replaced with a heat-conserving Truncated Gaussian (TG) function and its effects are evaluated. The simulated fire perimeters of case studies are validated against semi-continuous, high-resolution fire perimeters derived from NEXRAD radar observations. Furthermore, simulated plumes of the two fire cases are compared to NEXRAD radar reflectivity observations, followed by buoyancy analysis using simulated temperature and vertical velocity fields. The results show that while the improved fuel bed and the TG heat release scheme have small effects on the simulated fire perimeters of the wind-driven Camp Fire, they affect the propagation direction of the plume-driven Caldor Fire, leading to better-matching fire perimeters with the observations. However, the improved fuel bed representation, together with the TG heat smoke release scheme, leads to a more realistic plume structure in comparison to the observations in both fires. The buoyancy analysis also depicts more realistic fire-induced temperature anomalies and atmospheric circulation when the fuel bed is improved.
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来源期刊
Fire-Switzerland
Fire-Switzerland Multiple-
CiteScore
3.10
自引率
15.60%
发文量
182
审稿时长
11 weeks
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