Computational Simulation of Complex Turbulent Diffusion Flames

复杂湍流扩散火焰的计算模拟

• 批准号: 0133925
• 负责人: George Kosaly
• 金额: --
• 依托单位: University of Washington
• 依托单位国家: 美国
• 项目类别: Continuing Grant
• 财政年份: 2002
• 资助国家: 美国
• 起止时间: 2002-09-01 至 2007-08-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=0133925&HistoricalAwards=false
• 关键词: Computational; Simulation; Complex; Turbulent; Diffusion

Although the principles and fundamental equations that describe turbulent combustion are known, their direct numerical solution (DNS) remains impossible for practical problems. The usual approximations are to either time average or to spatially filter the fundamental equations. The first approach involves full time averaging (Reynolds averaged Navier-Stokes equations, or RANS), while the second filters only for the smaller scales, allowing the larger scales to be resolved in space and time (Large Eddy Simulation, or LES). In either case, the semi-empirical modeling assumptions associated with the averaging process are critical, and have been the focus of much debate. These approaches have had substantial successes in the modeling of many flames, principally those dominated by boundary-layer-like flows such as free jets and shear layers, and combustion that is uninterrupted by local extinction. Most practical flames are, however, stabilized by recirculation or swirl, and exhibit extinction events, e.g., standoff from the burner. These phenomena are not well captured by the present models. To improve the modeling one must consider issues such as strongly curved streamlines, buoyancy, strongly varying density, dilatation due to heat release and its influence on the overall dynamics of the flow, and local extinction and reignition of the flame chemistry in regions of high shear rates. In this study, the bluff-body laboratory flames of the University of Sydney are used as a prototype for the study of the modeling of these phenomena. A bluff body at the base establishes a recirculation zone that stabilizes the flame. This experimental work has covered a wide range of conditions between fast chemistry and close-to-blowout behavior. These experiments therefore exhibit many of the challenging phenomena occurring in more complex, practical flames. They are, however, of a simple axisymmetric configuration and have been experimentally well characterized. Thus, these flames are excellent targets for fundamental investigations into the modeling of complex flame behavior. The following research activities are proposed: (a) DNS and theoretical work towards better understanding of (1) the mechanisms of extinction/reignition in recirculation-stabilized jet flames, and (2) the physics and stability of flames dominated by large density differences, dilatation, curved streamlines, and buoyancy; (b) investigation/evaluation of LES subgrid-scale models that incorporate the new information gained on extinction/ reignition and on fluid-mechanics issues specific to recirculating flames; and (c) comparison of LES computations with laboratory data on bluff-body stabilized jet flames to test the performance of the subgrid-scale models developed in this project.

尽管描述湍流燃烧的原理和基本方程是已知的，但它们的直接数值解（DNS）对于实际问题仍然是不可能的。 通常的近似是时间平均或空间过滤基本方程。 第一种方法涉及全时平均（雷诺平均纳维-斯托克斯方程，或 RANS），而第二种方法仅针对较小的尺度进行过滤，允许在空间和时间上解析较大的尺度（大涡模拟，或 LES）。 无论哪种情况，与平均过程相关的半经验建模假设都是至关重要的，并且一直是许多争论的焦点。 这些方法在许多火焰的建模方面取得了巨大的成功，主要是那些以边界层状流动为主的火焰，例如自由射流和剪切层，以及不受局部熄灭干扰的燃烧。 然而，大多数实际火焰通过再循环或涡流来稳定，并表现出熄灭事件，例如与燃烧器的隔离。 目前的模型并没有很好地捕捉到这些现象。 为了改进建模，必须考虑诸如强烈弯曲的流线、浮力、强烈变化的密度、由于放热引起的膨胀及其对流动整体动力学的影响，以及高剪切区域中火焰化学的局部熄灭和重新点燃等问题费率。 在这项研究中，悉尼大学的钝体实验室火焰被用作研究这些现象建模的原型。 底部的钝体建立了一个稳定火焰的再循环区。 这项实验工作涵盖了快速化学反应和接近井喷行为之间的广泛条件。 因此，这些实验展示了在更复杂、更实际的火焰中发生的许多具有挑战性的现象。 然而，它们具有简单的轴对称结构，并且已经通过实验得到了很好的表征。 因此，这些火焰是对复杂火焰行为建模进行基础研究的绝佳目标。 提议进行以下研究活动：（a）DNS和理论工作，以更好地理解（1）再循环稳定喷射火焰的熄灭/重燃机制，以及（2）由大密度差主导的火焰的物理和稳定性，膨胀、弯曲流线和浮力； (b) 调查/评估 LES 亚网格尺度模型，其中纳入了有关熄灭/重燃以及再循环火焰特有的流体力学问题的新信息； (c) 将 LES 计算与钝体稳定射流火焰的实验室数据进行比较，以测试本项目中开发的亚网格尺度模型的性能。