Temperature field measurement of a burning aluminum droplet

IF 5.8 2区工程技术 Q2 ENERGY & FUELS

Combustion and Flame Pub Date : 2025-04-23 DOI:10.1016/j.combustflame.2025.114163

Hugo Keck , Christian Chauveau , Guillaume Legros , Stany Gallier , Fabien Halter

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引用次数: 0

Abstract

In a diffusive combustion regime, an aluminum droplet undergoing combustion forms an oxide cloud that surrounds the burning droplet. Thorough characterization of this cloud is crucial to the validation of the subsequent modeling. This paper makes a significant contribution to the field by providing an experimental procedure to resolve the spatial temperature profile within the oxide cloud. An electrodynamic levitator is used to observe the self-sustained combustion of aluminum particles with a radius of

35 μ m

in atmospheric air, with negligible convective effects. The levitating device is coupled to an optical apparatus that allows for a light extinction method, thereby enabling the determination of size and concentration profiles of the nanometric alumina droplets, as introduced in previous works. The data from the previous study are employed in conjunction with a modulated absorption–emission (MAE) technique to ascertain a temperature profile that does not rely on the grey-body assumption. This technique is further enhanced by an optimization method to account for gaseous phase emissions, which typically hinder conventional temperature evaluation. Consequently, a spatially resolved temperature profile of the oxide cloud surrounding the burning droplet is obtained. Close to the surface of the droplet, a temperature of 2580 K is assessed. Then, a maximum temperature of about 3615 K is measured. As an additional outcome, gaseous emission profiles are obtained for three wavelengths and exhibit a notable correlation with a simulated gaseous suboxide concentration profile. The results presented in this work demonstrate a relatively high degree of consistency with expected temperatures.

Novelty and Significance Statement

This work presents a novel experimental method to obtain an unique temperature profile surrounding an isolated aluminum droplet in combustion. In conjunction with previous work, a non-intrusive, complete, and instantaneous characterization of the oxide smoke is now made possible, with the addition of the temperature profile to the known alumina particle size and concentration profiles. This comprehensive data set is presented for a fundamental case of a single levitating particle. The incorporation of the temperature profile provides an incomparable insight into alumina condensation processes and a detailed reference case for simulation purposes. The results presented in this work document the intricate condensation process of nanoparticles and highlight the limitations of current simulation methods.

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燃烧铝液滴的温度场测量

在扩散燃烧状态下，铝液滴在燃烧过程中形成围绕燃烧液滴的氧化云。彻底描述该云对于验证后续建模至关重要。本文通过提供一个实验程序来解决氧化云内的空间温度分布，对该领域做出了重大贡献。采用电动悬浮器对半径为35μm的铝颗粒在大气中自燃进行了实验研究，实验中对流效应可以忽略不计。悬浮装置与光学装置耦合，该光学装置允许光消法，从而能够确定纳米氧化铝液滴的大小和浓度分布，如先前工作中所介绍的那样。先前研究的数据与调制吸收-发射（MAE）技术结合使用，以确定不依赖于灰体假设的温度分布。该技术通过一种优化方法进一步增强，以考虑气相发射，这通常阻碍传统的温度评估。因此，得到了燃烧液滴周围氧化云的空间分辨温度分布。在液滴表面附近，温度为2580k。然后测得最高温度约为3615k。作为一个额外的结果，获得了三个波长的气体发射剖面，并与模拟的气态亚氧化物浓度剖面表现出显著的相关性。在这项工作中提出的结果表明了与预期温度的相对高度的一致性。新颖性和意义声明本工作提出了一种新的实验方法，以获得在燃烧中孤立铝液滴周围的独特温度分布。结合之前的工作，现在可以对氧化烟雾进行非侵入式的、完整的、即时的表征，并将温度曲线添加到已知的氧化铝粒度和浓度曲线中。这一综合数据集提出了一个基本的情况下，一个单一的悬浮粒子。结合温度分布提供了一个无与伦比的洞察氧化铝冷凝过程和详细的参考案例模拟的目的。本研究的结果揭示了纳米颗粒的复杂凝聚过程，并指出了当前模拟方法的局限性。

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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来源期刊

Combustion and Flame 工程技术-工程：化工

CiteScore

9.50

自引率

20.50%

发文量

631

审稿时长

3.8 months

期刊介绍： The mission of the journal is to publish high quality work from experimental, theoretical, and computational investigations on the fundamentals of combustion phenomena and closely allied matters. While submissions in all pertinent areas are welcomed, past and recent focus of the journal has been on: Development and validation of reaction kinetics, reduction of reaction mechanisms and modeling of combustion systems, including: Conventional, alternative and surrogate fuels; Pollutants; Particulate and aerosol formation and abatement; Heterogeneous processes. Experimental, theoretical, and computational studies of laminar and turbulent combustion phenomena, including: Premixed and non-premixed flames; Ignition and extinction phenomena; Flame propagation; Flame structure; Instabilities and swirl; Flame spread; Multi-phase reactants. Advances in diagnostic and computational methods in combustion, including: Measurement and simulation of scalar and vector properties; Novel techniques; State-of-the art applications. Fundamental investigations of combustion technologies and systems, including: Internal combustion engines; Gas turbines; Small- and large-scale stationary combustion and power generation; Catalytic combustion; Combustion synthesis; Combustion under extreme conditions; New concepts.