[1] HAMMITT J K, CAMM F, CONNELL P S, et al. Future emission scenarios for chemicals that may deplete stratospheric ozone[J]. Nature, 1987, 330: 711-716. [2] MORRISETTE P M. The evolution of policy responses to stratospheric ozone depletion[J]. Natural Resources Journal, 1989, 29(3): 793-820. [3] PARSON E A, GREENE O. The complex chemistry of the international ozone agreements[J]. Environment: Science and Policy for Sustainable Development, 1995, 37(2): 16-35. [4] LINTERIS G T, KATTA V R, TAKAHASHI F. Experimental and numerical evaluation of metallic compounds for suppressing cup-burner flames[J]. Combustion and Flame, 2004, 138(1/2): 78-96. [5] HIRST R, BOOTH K. Measurement of flame-extinguishing concentrations[J]. Fire Technology, 1977, 5: 296-315. [6] TAKAHASHI F, LINTERIS G T, KATTA V R. Extinguishment mechanisms of coflow diffusion flames in a cup-burner apparatus[J]. Proceedings of the Combustion Institute, 2007, 31(2): 2 721-2 729. [7] SENECAL J A. Flame extinguishing in the cup-burner by inert gases[J]. Fire Safety Journal, 2005, 40(6): 579-591. [8] 杜建科. 杯式燃烧器法灭火浓度测试技术研究进展[C]. 2013中国消防协会科学技术年会论文集,2013:330-332. [9] NFPA 2001-2018, Standard on clean agent fire extinguishing systems[S]. [10] ISO 14520-1:2015(E), Gaseous fire-extinguishing systems-physical properties and system design-Part 1:general requirements[S]. [11] CREITZ E C. Inhibition of diffusion flames by methyl bromide and trifluoromethyl bromide applied to the fuel and oxygen sides of the reaction zone[J]. Journal of Research of the National Bureau of Standards. Section A, Physics and Chemistry, 1961, 64(4): 389-396. [12] 陈涛,傅学成,黄鑫. 基于cup-burner的超细粉体灭火性能研究[C]. 2012中国消防协会科学技术年会论文集(上),2012:295-299. [13] 付海雁. 基于杯式燃烧器的超细干粉灭火剂灭火性能研究[D]. 南京:南京理工大学, 2015. FU Haiyan. Study on fire suppression performance of superfine powder extinguishing agent based on cup-burner[D]. Nanjing: Nanjing University of Science and Technology, 2015. [14] ZHANG Tianwei, LIU Hao, HAN Zhiyue, et al. Active substances study in fire extinguishing by water mist with potassium salt additives based on thermoanalysis and thermodynamics[J]. Applied Thermal Engineering, 2017, 122: 429-438. [15] 李杰. 科学知识图谱原理及应用:VOSviewer和CitNetExplorer 初学者指南[M].北京:高等教育出版社,2018:2. LI Jie. Principle and applications of mapping knowledge domains a Beginner's guide to VOSviewer and CitNetExplorer [M].Beijing: Higher Education Press,2018:2. [16] 李杰,李生才,冯长根.《安全与环境学报》2007—2017年文献计量分析[J]. 安全与环境学报, 2019, 19(3):1 092-1 100. LI Jie, LI Shengcai, FENG Changgen. Bibliometric analysis of the articles published in the Journal of Safety and Environment from 2007 to 2017 [J]. Journal of Safety and Environment, 2019, 19(3): 1 092-1 100. [17] 冯长根,李杰,陈伟炯. 2008—2017年国际安全科学研究产出分析[J]. 安全与环境学报,2018,18(4):1 629-1 633. FENG Changgen, LI Jie, CHEN Weijiong. Publication outputs of the safety research around the world during the period of 2008-2017 [J]. Journal of Safety and Environment, 2018, 18(4): 1 629-1 633. [18] 马丹,裴玉龙,田昆.基于文献计量分析的行人交通安全研究综述[J].中国安全科学学报,2020,30(8):101-108. MA Dan, PEI Yulong, TIAN Kun. Literature review of pedestrian traffic safety research based on bibliometric analysis [J]. China Safety Science Journal, 2020,30(8):101-108. [19] DANVILA-DEL-VALLE I, ESTÉVEZ-MENDOZA C, LARA F J. Human resources training: a bibliometric analysis[J]. Journal of Business Research, 2019, 101: 627-636. [20] ZEGERS E J P, WILLIAMS B A, FISHER E M, et al. Suppression of nonpremixed flames by fluorinated ethanes and propanes[J]. Combustion and Flame, 2000, 121(3): 471-487. [21] BANKS R E, CLARKE E K, JOHNSON E P, et al. Comparative life-cycle assessment of the impacts associated with fire extinguishants HFC-227ea and IG-541[J]. Process Safety and Environmental Protection, 1998, 76(3): 229-238. [22] LIANG Tianshui, LI Runwan, LI Jing, et al. Extinguishment of hydrocarbon pool fires by ultrafine water mist with ammonium/amidogen compound in an improved cup burner[J]. Fire and Materials, 2018, 42(8): 889-896. [23] CHEN Xianfeng, FAN Ao, YUAN Bihe, et al. Renewable biomass gel reinforced core-shell dry water material as novel fire extinguishing agent[J]. Journal of Loss Prevention in the Process Industries, 2019, 59: 14-22. [24] WANG, Xingyu, WU Rui, CHENG Lu, et al. Suppression of propane cup-burner flame with HFO-1336mzz (Z) and its thermal stability study[J]. Thermochimica Acta, 2020, 683: 178463. [25] DZIKOWSKI P. A bibliometric analysis of born global firms[J]. Journal of Business Research, 2018, 85: 281-294. [26] ZHENG Tianlong, WANG Juan, WANG Qunhui, et al. A bibliometric analysis of micro/nano-bubble related research: current trends, present application, and future prospects[J]. Scientometrics, 2016, 109(1):53-71. [27] CONG Beihua, LIAO Guangxuan. Mechanisms of suppressing cup-burner flame with water vapor[J]. Science in China Series E: Technological Sciences, 2008, 51(8): 1222-1231. [28] PAPAS P, FLEMING J W, SHEINSON R S. Extinction of non-premixed methane-and propane-air counterflow flames inhibited with CF4, CF3H and CF3Br[J]. Symposium (International) on Combustion, 1996, 26(1): 1405-1411. [29] HAN Zhiyue, GONG Li, DU Zhiming, et al. A novel environmental-friendly gel dry-water extinguishant containing additives with efficient combustion suppression efficiency[J]. Fire Technology, 2020,56: 2365-2385. [30] ZHANG Tianwei, HAN Zhiyue, DU Zhiming, et al. Application of thermal mechanism to evaluate the effectiveness of the extinguishment of CH4/air cup-burner flame by water mist with additives[J]. Hydrogen Energy, 2016, 41(33): 15 078-15 088. [31] SHEINSON R S, PENNER-HAHN J E, INDRITZ D. The physical and chemical action of fire suppressants[J]. Fire Safety Journal, 1989, 15:437-450. |