{"title":"利用卤化化合物的阻燃剂重量分析法抑制爆燃","authors":"R. K. Singh, A. Dahake, A. V. Singh","doi":"10.1007/s00193-024-01175-4","DOIUrl":null,"url":null,"abstract":"<p>The current study numerically evaluates the detonation inhibition effects of a range of halogenated compounds on hydrogen-air gaseous detonations. The halogenated compounds investigated in this research encompass halogen acids (HI, HBr, HCl, HF), halomethanes (<span>\\(\\hbox {CH}_{{3}}\\hbox {I}\\)</span>, <span>\\(\\hbox {CH}_{{3}}\\hbox {Br}\\)</span>, <span>\\(\\hbox {CH}_{{3}}\\hbox {Cl}\\)</span>, <span>\\(\\hbox {CH}_{{3}}\\hbox {F}\\)</span>), haloethenes (<span>\\(\\hbox {C}_{{2}}\\hbox {H}_{{3}}\\hbox {I}\\)</span>, <span>\\(\\hbox {C}_{{2}}\\hbox {H}_{{3}}\\hbox {Br}\\)</span>, <span>\\(\\hbox {C}_{{2}}\\hbox {H}_{{3}}\\hbox {Cl}\\)</span>, <span>\\(\\hbox {C}_{{2}}\\hbox {H}_{{3}}\\hbox {F}\\)</span>), haloethanes (<span>\\(\\hbox {C}_{{2}}\\hbox {H}_{{5}}\\hbox {I}\\)</span>, <span>\\(\\hbox {C}_{{2}}\\hbox {H}_{{5}}\\hbox {Br}\\)</span>, <span>\\(\\hbox {C}_{{2}}\\hbox {H}_{{5}}\\hbox {Cl}\\)</span>, <span>\\(\\hbox {C}_{{2}}\\hbox {H}_{{5}}\\hbox {F}\\)</span>), and complex halogenated compounds (<span>\\(\\hbox {CF}_{{3}}\\hbox {I}\\)</span>, <span>\\(\\hbox {CF}_{{3}}\\hbox {Br}\\)</span>, <span>\\(\\hbox {CF}_{{3}}\\hbox {Cl}\\)</span>, <span>\\(\\hbox {CF}_{4}\\)</span>). The study employs a one-dimensional ZND model with detailed chemical kinetics to examine the impact on detonation propagation by adding these halogenated compounds to hydrogen-air mixtures. The effectiveness of these inhibitors is evaluated based on their capacity to increase the induction length, the amount of inhibitor needed to attenuate a detonation wave, and their influence on the detonability of the gaseous mixture under both lean and rich conditions. The results indicate that several halogenated compounds exhibit superior inhibition properties compared to Halon 1301 (<span>\\(\\hbox {CF}_{{3}}\\hbox {Br}\\)</span>). Specifically, <span>\\(\\hbox {C}_{{2}}\\hbox {H}_{{5}}\\hbox {Br}\\)</span> leads to the most significant increase in the induction length, with HBr and <span>\\(\\hbox {C}_{{2}}\\hbox {H}_{{5}}\\hbox {I}\\)</span> following closely, particularly at 20,000 ppmv concentration levels. However, it is worth noting that the inhibition efficiency also varies depending on the concentration of the inhibitor added to the gaseous <span>\\(\\hbox {H}_{{2}}\\)</span>-air mixture. Moreover, based on retardant weight analysis, fluorinated compounds were found to be the most effective inhibitors, followed by chlorinated, brominated, and iodinated compounds across all categories of halogenated inhibitors.</p>","PeriodicalId":775,"journal":{"name":"Shock Waves","volume":null,"pages":null},"PeriodicalIF":1.7000,"publicationDate":"2024-05-13","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Detonation inhibition using retardant weight analysis for halogenated compounds\",\"authors\":\"R. K. Singh, A. Dahake, A. V. Singh\",\"doi\":\"10.1007/s00193-024-01175-4\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p>The current study numerically evaluates the detonation inhibition effects of a range of halogenated compounds on hydrogen-air gaseous detonations. The halogenated compounds investigated in this research encompass halogen acids (HI, HBr, HCl, HF), halomethanes (<span>\\\\(\\\\hbox {CH}_{{3}}\\\\hbox {I}\\\\)</span>, <span>\\\\(\\\\hbox {CH}_{{3}}\\\\hbox {Br}\\\\)</span>, <span>\\\\(\\\\hbox {CH}_{{3}}\\\\hbox {Cl}\\\\)</span>, <span>\\\\(\\\\hbox {CH}_{{3}}\\\\hbox {F}\\\\)</span>), haloethenes (<span>\\\\(\\\\hbox {C}_{{2}}\\\\hbox {H}_{{3}}\\\\hbox {I}\\\\)</span>, <span>\\\\(\\\\hbox {C}_{{2}}\\\\hbox {H}_{{3}}\\\\hbox {Br}\\\\)</span>, <span>\\\\(\\\\hbox {C}_{{2}}\\\\hbox {H}_{{3}}\\\\hbox {Cl}\\\\)</span>, <span>\\\\(\\\\hbox {C}_{{2}}\\\\hbox {H}_{{3}}\\\\hbox {F}\\\\)</span>), haloethanes (<span>\\\\(\\\\hbox {C}_{{2}}\\\\hbox {H}_{{5}}\\\\hbox {I}\\\\)</span>, <span>\\\\(\\\\hbox {C}_{{2}}\\\\hbox {H}_{{5}}\\\\hbox {Br}\\\\)</span>, <span>\\\\(\\\\hbox {C}_{{2}}\\\\hbox {H}_{{5}}\\\\hbox {Cl}\\\\)</span>, <span>\\\\(\\\\hbox {C}_{{2}}\\\\hbox {H}_{{5}}\\\\hbox {F}\\\\)</span>), and complex halogenated compounds (<span>\\\\(\\\\hbox {CF}_{{3}}\\\\hbox {I}\\\\)</span>, <span>\\\\(\\\\hbox {CF}_{{3}}\\\\hbox {Br}\\\\)</span>, <span>\\\\(\\\\hbox {CF}_{{3}}\\\\hbox {Cl}\\\\)</span>, <span>\\\\(\\\\hbox {CF}_{4}\\\\)</span>). The study employs a one-dimensional ZND model with detailed chemical kinetics to examine the impact on detonation propagation by adding these halogenated compounds to hydrogen-air mixtures. The effectiveness of these inhibitors is evaluated based on their capacity to increase the induction length, the amount of inhibitor needed to attenuate a detonation wave, and their influence on the detonability of the gaseous mixture under both lean and rich conditions. The results indicate that several halogenated compounds exhibit superior inhibition properties compared to Halon 1301 (<span>\\\\(\\\\hbox {CF}_{{3}}\\\\hbox {Br}\\\\)</span>). Specifically, <span>\\\\(\\\\hbox {C}_{{2}}\\\\hbox {H}_{{5}}\\\\hbox {Br}\\\\)</span> leads to the most significant increase in the induction length, with HBr and <span>\\\\(\\\\hbox {C}_{{2}}\\\\hbox {H}_{{5}}\\\\hbox {I}\\\\)</span> following closely, particularly at 20,000 ppmv concentration levels. However, it is worth noting that the inhibition efficiency also varies depending on the concentration of the inhibitor added to the gaseous <span>\\\\(\\\\hbox {H}_{{2}}\\\\)</span>-air mixture. Moreover, based on retardant weight analysis, fluorinated compounds were found to be the most effective inhibitors, followed by chlorinated, brominated, and iodinated compounds across all categories of halogenated inhibitors.</p>\",\"PeriodicalId\":775,\"journal\":{\"name\":\"Shock Waves\",\"volume\":null,\"pages\":null},\"PeriodicalIF\":1.7000,\"publicationDate\":\"2024-05-13\",\"publicationTypes\":\"Journal Article\",\"fieldsOfStudy\":null,\"isOpenAccess\":false,\"openAccessPdf\":\"\",\"citationCount\":\"0\",\"resultStr\":null,\"platform\":\"Semanticscholar\",\"paperid\":null,\"PeriodicalName\":\"Shock Waves\",\"FirstCategoryId\":\"5\",\"ListUrlMain\":\"https://doi.org/10.1007/s00193-024-01175-4\",\"RegionNum\":4,\"RegionCategory\":\"工程技术\",\"ArticlePicture\":[],\"TitleCN\":null,\"AbstractTextCN\":null,\"PMCID\":null,\"EPubDate\":\"\",\"PubModel\":\"\",\"JCR\":\"Q3\",\"JCRName\":\"MECHANICS\",\"Score\":null,\"Total\":0}","platform":"Semanticscholar","paperid":null,"PeriodicalName":"Shock Waves","FirstCategoryId":"5","ListUrlMain":"https://doi.org/10.1007/s00193-024-01175-4","RegionNum":4,"RegionCategory":"工程技术","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q3","JCRName":"MECHANICS","Score":null,"Total":0}
Detonation inhibition using retardant weight analysis for halogenated compounds
The current study numerically evaluates the detonation inhibition effects of a range of halogenated compounds on hydrogen-air gaseous detonations. The halogenated compounds investigated in this research encompass halogen acids (HI, HBr, HCl, HF), halomethanes (\(\hbox {CH}_{{3}}\hbox {I}\), \(\hbox {CH}_{{3}}\hbox {Br}\), \(\hbox {CH}_{{3}}\hbox {Cl}\), \(\hbox {CH}_{{3}}\hbox {F}\)), haloethenes (\(\hbox {C}_{{2}}\hbox {H}_{{3}}\hbox {I}\), \(\hbox {C}_{{2}}\hbox {H}_{{3}}\hbox {Br}\), \(\hbox {C}_{{2}}\hbox {H}_{{3}}\hbox {Cl}\), \(\hbox {C}_{{2}}\hbox {H}_{{3}}\hbox {F}\)), haloethanes (\(\hbox {C}_{{2}}\hbox {H}_{{5}}\hbox {I}\), \(\hbox {C}_{{2}}\hbox {H}_{{5}}\hbox {Br}\), \(\hbox {C}_{{2}}\hbox {H}_{{5}}\hbox {Cl}\), \(\hbox {C}_{{2}}\hbox {H}_{{5}}\hbox {F}\)), and complex halogenated compounds (\(\hbox {CF}_{{3}}\hbox {I}\), \(\hbox {CF}_{{3}}\hbox {Br}\), \(\hbox {CF}_{{3}}\hbox {Cl}\), \(\hbox {CF}_{4}\)). The study employs a one-dimensional ZND model with detailed chemical kinetics to examine the impact on detonation propagation by adding these halogenated compounds to hydrogen-air mixtures. The effectiveness of these inhibitors is evaluated based on their capacity to increase the induction length, the amount of inhibitor needed to attenuate a detonation wave, and their influence on the detonability of the gaseous mixture under both lean and rich conditions. The results indicate that several halogenated compounds exhibit superior inhibition properties compared to Halon 1301 (\(\hbox {CF}_{{3}}\hbox {Br}\)). Specifically, \(\hbox {C}_{{2}}\hbox {H}_{{5}}\hbox {Br}\) leads to the most significant increase in the induction length, with HBr and \(\hbox {C}_{{2}}\hbox {H}_{{5}}\hbox {I}\) following closely, particularly at 20,000 ppmv concentration levels. However, it is worth noting that the inhibition efficiency also varies depending on the concentration of the inhibitor added to the gaseous \(\hbox {H}_{{2}}\)-air mixture. Moreover, based on retardant weight analysis, fluorinated compounds were found to be the most effective inhibitors, followed by chlorinated, brominated, and iodinated compounds across all categories of halogenated inhibitors.
期刊介绍:
Shock Waves provides a forum for presenting and discussing new results in all fields where shock and detonation phenomena play a role. The journal addresses physicists, engineers and applied mathematicians working on theoretical, experimental or numerical issues, including diagnostics and flow visualization.
The research fields considered include, but are not limited to, aero- and gas dynamics, acoustics, physical chemistry, condensed matter and plasmas, with applications encompassing materials sciences, space sciences, geosciences, life sciences and medicine.
Of particular interest are contributions which provide insights into fundamental aspects of the techniques that are relevant to more than one specific research community.
The journal publishes scholarly research papers, invited review articles and short notes, as well as comments on papers already published in this journal. Occasionally concise meeting reports of interest to the Shock Waves community are published.