容器-管道气力输送中气流速度和管道直径对粉尘爆炸影响的实验研究

IF 3.6 3区 工程技术 Q2 ENGINEERING, CHEMICAL
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引用次数: 0

摘要

为确保粉末颗粒在气力输送过程中的工艺安全,我们设计了一套粉尘爆炸实验装置来模拟粉尘输送过程。该系统由高压风机提供稳定的气流,能够以可控的速度将粉尘从容器连续输送到管道。粉尘爆炸实验是在气流速度为 5、10 和 15 米/秒的条件下,通过向输送的粉尘颗粒施加 1 kJ 的点火能量而精心进行的。本研究探讨了粉尘浓度、气流速度和管道直径对爆炸特性的影响,并通过对实验结果的详细分析深入研究了这些影响的机理。结果表明,淀粉爆炸火焰在容器内经历了四个不同的阶段:火焰发展、火焰向管道延伸、淀粉颗粒剧烈燃烧以及颗粒完全燃烧。随着气流速度和管道直径的增加,火焰的拉伸效应变得更加明显。当管道内的气流速度为 15 米/秒时,颗粒燃烧加剧率和无约束排放之间达到了平衡,直径为 100 毫米的管道的最大爆炸压力为 135.56 千帕,最大压力上升率为 7.27 兆帕/秒。此外,管道入口处的火焰传播速度更高。在不同的气流速度下,管道内观察到了不同的火焰行为。与之前利用高压气体在容器内产生粉尘云进行爆炸实验的研究相比,本研究的结果突出了气流速度对粉尘爆炸的关键影响。这项研究为预防爆炸提供了关键参数,并为粉尘处理过程的安全性提供了一个案例研究。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Experimental study on the impact of airflow velocity and pipeline diameter on dust explosions in vessel-pipeline pneumatic conveying

To ensure the process safety of powder particles during pneumatic transport, a dust explosion experimental apparatus was designed to simulate the dust transport process. The system is supplied with a stable airflow by a high-pressure fan, capable of continuously transferring dust from the vessel to the pipeline at a controllable speed. Dust explosion experiments were meticulously executed by applying 1 kJ of ignition energy to the transported dust particles at airflow velocities of 5, 10, and 15 m/s. This study examines the effects of dust concentration, airflow velocity, and pipe diameter on explosion characteristics and delves into the mechanisms these effects through a detailed analysis of experimental results. The results demonstrate that the starch explosion flame progresses through four distinct stages within the vessel: flame development, flame stretching towards the pipe, intense combustion of starch particles, and complete combustion of the particles. As airflow velocity and pipe diameter increase, the stretching effect on the flame becomes more pronounced. At an airflow velocity of 15 m/s within a pipeline, a balance is struck between intensified particle combustion rates and unconstrained discharge, resulting in a maximum explosion pressure of 135.56 kPa for a 100 mm diameter pipe, with a maximum pressure rise rate of 7.27 MPa/s. Additionally, flame propagation velocity is higher at the pipe inlet. Different flame behaviors were observed inside the pipeline under varying airflow speeds. Compared to previous studies that utilized high-pressure gas to create dust clouds within vessels for explosion experiments, the results of this study underscore the crucial impact of airflow velocity on dust explosions. This research provides critical parameters for explosion prevention and presents a case study on the safety of dust handling processes.

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来源期刊
CiteScore
7.20
自引率
14.30%
发文量
226
审稿时长
52 days
期刊介绍: The broad scope of the journal is process safety. Process safety is defined as the prevention and mitigation of process-related injuries and damage arising from process incidents involving fire, explosion and toxic release. Such undesired events occur in the process industries during the use, storage, manufacture, handling, and transportation of highly hazardous chemicals.
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