掺氨量对管道氨气-氢气-空气预混气体爆燃特性的影响OA
Influence of ammonia content on ammonia-hydrogen-air premixed gas duct-vented explosions
为了深入研究氨气-氢气-空气预混气体火焰在管道内外的燃烧特性,在长 2 000 mm的不锈钢管道中开设尺寸为 400 mm×70 mm的观察窗,借助高速摄影和压力传感器,测试分析了化学计量比Ф=1 的条件下掺氨量(φ)在30%~85%范围内对火焰形态和管道内外压力演化的影响.结果表明:掺氨量会显著影响管道内火焰的传播过程以及压力时程曲线.管道内火焰的传播速度随掺氨量的增加而降低,到达由二次爆炸引起的回流现象的时间也随之延长;管内距离泄爆口 400 mm处设置压力测点PS1 采集数据,各工况下管道内的压力曲线均呈现p1、p2 和p3 的三峰结构,3 个压力峰分别由泄爆口薄膜破裂、管内气体泄放以及管外二次爆炸产生的气体回流引起,p1 的大小取决于泄爆膜的抗拉强度,其幅值几乎与掺氨量无关,p2 和p3 均随着掺氨量的增加而升高,其中p3 的升高速率最大;管外距离泄爆口500 mm处设置压力测点PS2 采集数据,管外二次爆炸压力峰值(pout)随着掺氨量的增加而降低,到达pout的时间则随之延长.
Renewable energy is addressing some of the key challenges facing global society today,and zero-carbon energy systems are the fundamental way to achieve carbon neutrality.Therefore,hydrogen and ammonia have gained great attention as zero-carbon energy sources.To further study the combustion characteristics of ammonia-hydrogen-air premixed gas flame inside and outside the duct,the influence of ammonia doped amount(φ)on the flame morphology and the evolution of pressure inside and outside the duct under stoichiometric ratio was explored with the help of high-speed photography and pressure sensor in the 2 000-mm-long stainless steel duct with a 400-mm-long and 70-mm-wide observation window.The results show that φ significantly affects the pressure inside and outside the duct,and the time to reach the reverse flow phenomenon caused by the secondary explosion also increases.The pressure measuring point PS1 is set at 400 mm away from the explosion vent in the duct to collect data.The pressure curves in the duct under each working condition are presented as a three-peak structure,named p1,p2,and p3.The three pressure peaks are caused by the rupture of the explosion vent film,the gas venting in the duct,and the gas reverse generated by the secondary explosion outside the duct.The size of p1 depends on the tensile strength of the explosion venting membrane,and its amplitude is almost independent of the φ.p2 and p3 both increase with the increase of φ,and the p3 increase rate is the largest when φ is in 50%–65%.p2 changes from a single peak to a fluctuating pressure platform in the pressure curve diagram,and the time of the platform extends with the increase of φ.The pressure measurement point PS2 is set at the horizontal central axis,500mm away from the explosion vent outside the duct,to collect data.And the peak pressure of the secondary explosion outside the duct(pout)decreases with the increase of the φ,and the time to reach pout increases.This study provides a theoretical basis for the utilization of ammonia and hydrogen energy.
葛雨;汪泉;朱文艳;李瑞;冯鼎玉;徐建设;杨耀勇
安徽理工大学化工与爆破学院,安徽 淮南 232001安徽理工大学化工与爆破学院,安徽 淮南 232001||安徽理工大学安徽省新型爆炸材料与爆破技术工程研究中心,安徽 淮南 232001安徽理工大学化工与爆破学院,安徽 淮南 232001安徽理工大学化工与爆破学院,安徽 淮南 232001安徽理工大学化工与爆破学院,安徽 淮南 232001安徽理工大学化工与爆破学院,安徽 淮南 232001安徽理工大学土木建筑学院,安徽 淮南 232001
数理科学
泄爆动态压力变化超压火焰形态
explosion ventingdynamic pressure changeoverpressureflame pattern
《爆炸与冲击》 2026 (2)
119-131,13
安徽省重点研究与开发计划社会领域项目(2023g07020002)
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