[1] 李庆钊,王可,梅晓凝,等. 微米级铝粉的爆炸特性及其反应机理研究[J].工程热物理学报,2017,38(1): 219-225. LI Qingzhao, WANG Ke, MEI Xiaoning,et al. Explosion characteristics and reaction mechanism of micron aluminium powder [J]. Journal of Engineering Thermophysics, 2017, 38 (1): 219-225. [2] ZHANG Hongming, CHEN Xianfeng, ZHANG Ying, et al. Effects of particle size on flame structures through corn starch dust explosions [J]. Journal of Loss Prevention in the Process Industries, 2017,50: 7-14. [3] 秦涧, 谭迎新, 尉存娟. 水平管道内铝粉爆炸特性的试验研究[J]. 中国安全科学学报, 2011, 21(4): 66-70. QIN Jian, TAN Yingxin, WEI Cunjuan. Experimental study on explosion characteristics of aluminium powder in horizontal pipeline [J]. China Safety Science Journal, 2011, 21 (4): 66-70. [4] ADDAI E K, GABEL D, KRAUSE U. Experimental investigation on the minimum ignition temperature of hybrid mixtures of dusts and gases or solvents[J]. Journal of Hazardous Materials, 2016, 301: 314-326. [5] 陈晓坤,张自军,王秋红,等. 20 L近球形容器中微米级铝粉的爆炸特性[J].爆炸与冲击,2018,38(5): 1 130-1 136. CHEN Xiaokun, ZHANG Zijun, WANG Qiuhong, et al. Explosion characteristics of micron aluminum powder in 20 L near spherical vessel [J]. Explosion and Impact, 2018,38 (5): 1 130-1 136. [6] JANÈS A, VIGNES A, DUFAUD O, et al. Experimental investigation of the influence of inert solids on ignition sensitivity of organic powders[J]. Process Safety and Environmental Protection, 2014, 92(4): 311-323. [7] DASTIDAR A G, AMYOTTE P R, PEGG M J. Factors influencing the suppression of coal dust explosions [J]. Fuel, 1997, 76(7): 663-670. [8] UBR V, KOZIOLOVÁ E, SIVÁK L, et al. Polymer inhibitors of ABC transporter overcoming multidrug resistance: synthesis, characterization and in vitro evaluation[J]. Journal of Controlled Release, 2015, 213(1):e107-e108. [9] 雷伟刚,毕海普,王凯全.弯管内铝粉二次爆炸及抑爆试验研究[J].中国安全科学学报,2017,27(11): 43-48. LEI Weigang, BI Haipu, WANG Kaiquan. Experimental study on secondary explosion of aluminum powder in elbow pipeline and its suppression[J]. China Safety Science Journal, 2017,27(11): 43-48. [10] MAY D C, BERARD D L. Fires and explosions associated with aluminum dust from finishing operations[J]. Journal of Hazardous Materials, 1987, 17(1): 81-88. [11] LI Gang, YANG Hongxia, YUAN Chunmiao, et al. A catastrophic aluminium-alloy dust explosion in China[J]. Journal of Loss Prevention in the Process Industries, 2016, 39: 121-130. [12] 屈姣,邓军,王秋红.密闭球形空间内超细铝粉爆炸特性研究[J].中国安全科学学报, 2019,29(7): 51-57. QU Jiao, DENG Jun, WANG Qiuhong. Study on explosion characteristics of ultrafine aluminum powder in a closed spherical space [J]. China Safety Science Journal, 2019,29(7): 51-57. [13] MYERS T J. Reducing aluminum dust explosion hazards: case study of dust inerting in an aluminum buffing operation[J]. Journal of Hazardous Materials, 2008, 159(1): 72-80. [14] MARMO L, PICCININI N, DANZI E. Small magnitude explosion of aluminium powder in an abatement plant: a telling case[J]. Process Safety and Environmental Protection, 2015, 98: 221-230. [15] 丁大玉,浦以康,袁生学,等.铝粉爆炸特性的实验研究[J].爆炸与冲击,1993,13(1): 32-40. DING Dayu, PU Yikang, YUAN Shengxue, et al. Experimental study on explosion characteristics of aluminium powder [J].Explosion and Impact, 1993,13(1): 32-40. [16] 陈成,胡双启,范裕如,等.铝粉的爆炸特性研究[J].化工中间体,2013,10(1): 36-38. CHEN Cheng, HU Shuangqi, FAN Yuru, et al. Study on the explosion characteristics of aluminum powder[J].Chemical Intermediate,2013,10(1): 36-38. [17] 丁小勇,谭迎新,秦涧,等.垂直哈特曼管与水平管道中铝粉爆炸特性[J].消防科学与技术,2012,31(6): 561-563. DING Xiaoyong, TAN Yingxin, QIN Jian, et al. Explosion characteristics of aluminum powder in vertical Hartmann tube and horizontal pipeline[J].Fire Science and Technology,2012,31(6): 561-563. [18] 李文霞,林柏泉,魏吴晋,等.纳米级别铝粉粉尘爆炸的实验研究[J].中国矿业大学学报,2010,39(4): 475-479. LI Wenxia, LIN Baiquan, WEI Wujin, et al. Experimental study on nano-scale aluminum powder dust explosion[J].Journal of China University of Mining & Technology,2010,39(4): 475-479. [19] MORRIS M D. Factorial sampling plans for preliminary computational experiments[J]. Technometrics,1991,33(2):161-174. |