Experimental and LES Studies of Propane–air Premixed Gases in Pipelines Containing Mixed Obstacles

IF 1.1 4区工程技术 Q4 MECHANICS

Journal of Applied Fluid Mechanics Pub Date : 2024-07-03 DOI:10.47176/jafm.17.9.2550

Y. Wu, J. Gao, Y. Han, B. Ai, X. Shao, B. Guo, B. Hao

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Abstract

This study investigated the effect of a mixed obstacle layout on the deflagration mechanism of propane–air premixed gases. Most previous studies focused on a single type of obstacle, changing the shape and number of the obstacles to observe the effect on the flame deflagration characteristics. However, in real explosion accident sites, obstacles are often a mixture of different types. Little literature exists on the deflagration characteristics of hybrid barriers in semi-confined spaces. In this paper, the deflagration characteristics of propane-air premixed gas with a mixed structure of hurdles and square obstacles was studied. First, the effectiveness of numerical simulations was demonstrated by comparing experimental and large eddy simulation (LES) results for the flame dynamics with a single flat plate obstacle. Based on this, the flame behavior for different layouts of square obstacles in a mixed obstacle configuration was further simulated using the large eddy simulation method, focusing on the flame behavior, overpressure characteristics, and flow field structure in the vicinity of the obstacle. The results showed that a mixed obstacle promoted flame evolution more than a single obstacle when the square obstacle was within a critical distance from the ignition source location at the same moment in time. When the flame front crossed the first hurdle-type obstacle, the flame pattern spread in a “cat’s paw” pattern to the unburned portion of the tube. In addition, the increased distance of the square obstacle from the ignition source did not allow the peak overpressure and the peak rate of overpressure rise to show a positive feedback mechanism. Finally, the strength of the vorticity in the flow field was positively correlated with the distance of the square obstacle from the ignition source. The results of study provide theoretical for the prevention of explosions.

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含混合障碍物管道中丙烷-空气预混合气体的实验和 LES 研究

本研究探讨了混合障碍物布局对丙烷-空气预混合气体爆燃机制的影响。以往的研究大多集中在单一类型的障碍物上，通过改变障碍物的形状和数量来观察其对火焰爆燃特性的影响。然而，在实际爆炸事故现场，障碍物往往是不同类型的混合体。有关半封闭空间中混合障碍物爆燃特性的文献很少。本文研究了具有跨栏和方形障碍物混合结构的丙烷-空气预混合气体的爆燃特性。首先，通过比较单个平板障碍物的火焰动力学实验结果和大涡模拟（LES）结果，证明了数值模拟的有效性。在此基础上，使用大涡模拟方法进一步模拟了混合障碍物配置中不同方形障碍物布局的火焰行为，重点研究了障碍物附近的火焰行为、过压特性和流场结构。结果表明，当方形障碍物与点火源位置在同一时刻的临界距离内时，混合障碍物比单一障碍物更能促进火焰的演化。当火焰前锋越过第一个障碍物时，火焰形态以 "猫爪 "形态向管子的未燃烧部分蔓延。此外，方形障碍物与点火源的距离增大，使得峰值超压和峰值超压上升率无法呈现正反馈机制。最后，流场中的涡度强度与方形障碍物离点火源的距离呈正相关。研究结果为预防爆炸提供了理论依据。

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

Journal of Applied Fluid Mechanics THERMODYNAMICS-MECHANICS

CiteScore

2.00

自引率

20.00%

发文量

138

审稿时长

>12 weeks

期刊介绍： The Journal of Applied Fluid Mechanics (JAFM) is an international, peer-reviewed journal which covers a wide range of theoretical, numerical and experimental aspects in fluid mechanics. The emphasis is on the applications in different engineering fields rather than on pure mathematical or physical aspects in fluid mechanics. Although many high quality journals pertaining to different aspects of fluid mechanics presently exist, research in the field is rapidly escalating. The motivation for this new fluid mechanics journal is driven by the following points: (1) there is a need to have an e-journal accessible to all fluid mechanics researchers, (2) scientists from third- world countries need a venue that does not incur publication costs, (3) quality papers deserve rapid and fast publication through an efficient peer review process, and (4) an outlet is needed for rapid dissemination of fluid mechanics conferences held in Asian countries. Pertaining to this latter point, there presently exist some excellent conferences devoted to the promotion of fluid mechanics in the region such as the Asian Congress of Fluid Mechanics which began in 1980 and nominally takes place in one of the Asian countries every two years. We hope that the proposed journal provides and additional impetus for promoting applied fluids research and associated activities in this continent. The journal is under the umbrella of the Physics Society of Iran with the collaboration of Isfahan University of Technology (IUT) .