Temperature evolution of laser-ignited micrometric iron particles: A comprehensive experimental data set and numerical assessment of laser heating impact

Leon C. Thijs , Daoguan Ning , Yuriy S. Shoshin , Thijs Hazenberg , XiaoCheng Mi , Jeroen A. van Oijen , Philip de Goey
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Abstract

This study examines the effects of laser heating on the ignition and critical combustion characteristics, such as temperature and burn time, of individual iron particles. It provides time-dependent temperature profiles of laser-ignited particles across a broad spectrum of particle size distributions and oxygen concentrations obtained from experiments, which are a useful database for further development and validation of iron particle combustion models. The herein reported datasets significantly complement those existing in the literature. In the current study, the raw data are thoroughly re-evaluated using refined approaches. For the experimental canonical configuration of single iron particle combustion, an ignition system based on laser heating provides several advantages in overcoming temperature field uncertainties and facilitating controlled environments for optical diagnostics. Despite the inherent uncertainties in laser heating, associated with non-uniform intensity profiles and particle size variations, this study addresses the critical question of how these uncertainties affect in situ measurements of particle temperature and time to reach peak temperature. This study, conducted using a numerical model, reveals a dependence of the particle temperature after laser heating on particle size. However, this dependence does not significantly impact the key parameters of iron-particle combustion, such as the maximum temperature and burn time of the laser-ignited iron particle. The study also presents a comparison between the simulated particle temperature histories and those derived from two-color pyrometry measurements for a wide range of particle size distributions and oxygen concentrations. Notably, by implementing a laser-heating sub-model into an iron particle combustion model, assuming external-diffusion-limited oxidation only up to stoichiometric FeO, the temperature evolution up to the maximum temperature is reasonably captured for a wide range of particle sizes (20–53μm) and oxygen volumetric fractions (14–21 vol% O2 mixed with N2). However, with increasing oxygen concentration, the external-diffusion limited model significantly overestimates the heating rate and subsequently the maximum particle temperature.

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激光点燃的微米级铁颗粒的温度演变:综合实验数据集和激光加热影响的数值评估
本研究探讨了激光加热对单个铁颗粒的点火和临界燃烧特性(如温度和燃烧时间)的影响。它提供了从实验中获得的激光点燃颗粒在广泛的粒度分布和氧气浓度范围内随时间变化的温度曲线,是进一步开发和验证铁颗粒燃烧模型的有用数据库。本文报告的数据集极大地补充了现有文献中的数据集。在当前的研究中,使用改进的方法对原始数据进行了彻底的重新评估。对于单个铁粒子燃烧的典型实验配置,基于激光加热的点火系统在克服温度场不确定性和促进光学诊断的受控环境方面具有多项优势。尽管激光加热存在固有的不确定性,与不均匀的强度曲线和颗粒尺寸变化有关,但本研究解决了一个关键问题,即这些不确定性如何影响颗粒温度的现场测量和达到峰值温度的时间。这项使用数值模型进行的研究揭示了激光加热后颗粒温度与颗粒大小的关系。然而,这种依赖性并不会对铁粒子燃烧的关键参数(如激光点燃铁粒子的最高温度和燃烧时间)产生重大影响。该研究还比较了模拟颗粒温度历史与双色高温计测量得出的颗粒温度历史,后者适用于各种颗粒尺寸分布和氧气浓度。值得注意的是,通过在铁粒子燃烧模型中实施激光加热子模型,假定外部扩散限制的氧化作用只达到化学计量的氧化铁,在粒子尺寸(20-53μm)和氧气体积分数(14-21 vol% O2 与 N2 混合)范围很宽的情况下,可以合理地捕捉到最高温度的温度演变。然而,随着氧气浓度的增加,外部扩散受限模型明显高估了加热速率,进而高估了颗粒的最高温度。
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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