高速圆射流中典型非球形颗粒的扩散特性

黄文仕; 吴玉新; 冯乐乐; 张缦; 张扬

doi:10.16511/j.cnki.qhdxxb.2020.25.015

清华大学学报（自然科学版） >

2020 , Vol. 60 >Issue 6: 485 - 492

DOI: https://doi.org/10.16511/j.cnki.qhdxxb.2020.25.015

专题：能源领域中的多相流动基础及应用

高速圆射流中典型非球形颗粒的扩散特性

黄文仕 ,
吴玉新 ,
冯乐乐 ,
张缦 ,
张扬

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清华大学能源与动力工程系, 热科学与动力工程教育部重点实验室, 北京 100084

收稿日期: 2019-09-23

网络出版日期: 2020-04-27

基金资助

国家自然科学基金资助项目（51761125011）；国家质检总局科技项目（2017QK178-02）

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Dispersion characteristics of typical non-spherical particles in a high-speed round jet

HUANG Wenshi ,
WU Yuxin ,
FENG Lele ,
ZHANG Man ,
ZHANG Yang

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Key Laboratory for Thermal Science and Power Engineering of Ministry of Education, Department of Energy and Power Engineering, Tsinghua University, Beijing 100084, China

Received date: 2019-09-23

Online published: 2020-04-27

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摘要

低氧稀释（moderate and intense low-oxygen dilution，MILD）燃烧具有传热均匀、NO_x污染物排放低的特点。新一代MILD煤粉燃烧技术主要通过高速射流引起强烈的湍流混合来实现。其中，煤颗粒在高速射流中的扩散行为非常关键。目前对球形颗粒在气固射流中扩散行为的研究已非常深入，然而化石燃料属于典型的非球形颗粒，其在射流中的扩散行为与球形颗粒具有一定的差异，该类非球形颗粒在高速射流下的扩散特性值得进一步研究。为此，该文采用玻璃珠、玻璃渣和煤粉等颗粒开展了宽Re范围下的高速两相圆射流实验，通过激光Doppler相位分析技术（phase-Doppler anemometry，PDA）获取并分析了颗粒的质量浓度、速度及湍动能分布随球形度、粒径以及射流速度的变化规律。结果表明：非球形颗粒在射流中的质量浓度、速度、湍动能分布与粒径较小的球形颗粒具有一定相似性，但其扩散行为不能仅通过Stokes数进行定量表征，除曳力之外，升力对非球形颗粒扩散也具有一定影响；与球形颗粒相比，非球形颗粒的扩散更为显著，其主要原因是其径向湍动能显著增强所致；射流速度的增加促进了颗粒的剪切层集聚和径向扩散，对非球形颗粒的促进作用更强。

关键词： 气固两相流; 高速射流; 颗粒扩散; 球形度

本文引用格式

黄文仕 , 吴玉新 , 冯乐乐 , 张缦 , 张扬 . 高速圆射流中典型非球形颗粒的扩散特性[J]. 清华大学学报（自然科学版）, 2020 , 60(6) : 485 -492 . DOI: 10.16511/j.cnki.qhdxxb.2020.25.015

Abstract

Moderate and intense low-oxygen dilution (MILD) combustion is appealing due to its uniform heat flux profile and low NO_x emissions. The new generation of MILD coal combustion burners use high-speed jets with strong turbulent mixing. The dispersion of the coal particles in the high-speed jet is a key issue in such systems. There are many studies of the dispersion of spherical particles in particle-laden jets in the literature. However, the dispersion of fossil fuel particles, which are typically not spherical, differs from that of spherical particles, so the dispersion characteristics of these non-spherical particles in high-speed jets still deserves further study. This study used glass beads, glass powder and pulverized coal as the solid phase in a high-speed two-phase round jet for a wide range of Reynolds numbers. The particle concentrations, velocities and turbulent kinetic energy distributions were measured for various particle sphericities, sizes and jet velocities using laser phase-Doppler anemometry (PDA). The results show that the concentration, velocity and turbulent kinetic energy distribution characteristics of non-spherical particles are similar to those of smaller spherical particles. However, the non-spherical particle dispersion cannot be accurately characterized by just the Stokes number since the lift can strongly affect the particle dispersion. Non-spherical particles are more easily dispersed than spherical particles, mainly due to a significant increase in the radial turbulent kinetic energy. Increasing the jet velocity promotes the shear layer growth and radial dispersion of the particles and more strongly influences the non-spherical particle dispersion than the particle size or sphericity.

Key words： particle-laden flow; high-speed jet; particle dispersion; sphericity

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