Liang Zhu , Bingyou Jiang , Jie Wang , Yifan Wang , Hanyi Lin , Jie Wu , Yang Zhao
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引用次数: 0
摘要
为提高煤矿可吸入粉尘分离器的分离效率,设计了一种护套流虚拟冲击分离器。通过数值模拟,得到了在喷嘴与大颗粒收集室间距(S)、大颗粒收集室宽度(D)和护套流角度(θ)等不同结构参数影响下,分离器中可吸入粉尘的分离规律。实验结果与模拟结果的最大差异仅为 4.72%。结果表明,随着 S 的增大,分离器在各粒度点的分离效率不断提高。当θ增大时,分离效率曲线的整体变化较小。利用响应面方法获得了参数优化方案。研究成果为改进煤矿可吸入粉尘分离器结构提供了参考,进一步推动了可吸入粉尘精确监测技术的发展。
Study on the separation efficiency of sheath flow respirable dust virtual impact separator under the influence of multiple parameters
To improve the separation efficiency of respirable dust separator in coal mine, a sheath flow virtual impact separator was designed. Through numerical simulation, the separation law of respirable dust in separator under the effect of various structural parameters, such as the spacing between nozzle and large-particle collection chamber (S), the width of the large-particle collection chamber (D), and sheath flow angle (θ), was obtained. The maximum difference between the results of experiment and simulation is only 4.72 %. The results show that the separation efficiency of separator at each particle size point increases continuously with the increase of S. When D increases, the deviation degree of the separation efficiency curve from the BMRC curve decreases and then increases. When θ increases, the overall change of separation efficiency curve is small. The parameter optimization scheme was obtained using response surface methodology. The research results provide reference for improving the structure of respirable dust separator in coal mine, and further promote the development of accurate monitoring technology for respirable dust.
期刊介绍:
The Process Safety and Environmental Protection (PSEP) journal is a leading international publication that focuses on the publication of high-quality, original research papers in the field of engineering, specifically those related to the safety of industrial processes and environmental protection. The journal encourages submissions that present new developments in safety and environmental aspects, particularly those that show how research findings can be applied in process engineering design and practice.
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