[1] 金龙哲.我国作业场所粉尘职业危害现状与对策分析[J]. 安全, 2020,41(1):1-6. JIN Longzhe. The occupational hazards and strategy analysis of dust exposure in workplace in China[J]. Safety & Security, 2020,41(1):1-6. [2] 张丹丹, 刘贝贝. 我国矿山职业病的统计与展望分析[J]. 能源与环保, 2017,39(9): 173-178. ZHANG Dandan, LIU Beibei. Statistics and prospect of occupational diseases of mine in China [J]. China Energy and Environmental Protection, 2017,39(9): 173-178. [3] CHEN Weihong, LIU Yuewei, WANG Haijiao, et al. Long-term exposure to silica dust and risk of total and cause-specific mortality in Chinese workers: a cohort study[J]. PLOS Medicine, 2012,9(4):e1001206. [4] 许素睿. 燃煤电厂生产性粉尘健康风险评价[J]. 中国安全科学学报, 2020,30(2): 152-157. XU Surui. Health risk assessment caused by productive dust in coal-fired power plants[J]. China Safety Science Journal, 2020,30(2): 152-157. [5] 佟瑞鹏, 程蒙召, 马晓飞, 等. 不确定性条件下煤尘职业健康损害评价方法及应用[J]. 中国安全科学学报, 2018,28(4): 139-144. TONG Ruipeng, CHENG Mengzhao, MA Xiaofei, et al. Evaluation method of coal dust occupational health damage under uncertainty condition and its application[J]. China Safety Science Journal, 2018,28(4): 139-144. [6] 肖峻峰, 许峰, 樊世星,等.大断面综掘巷道长压短抽条件下粉尘运移模拟[J]. 中国安全科学学报, 2017,27(2): 127-132. XIAO Junfeng, XU Feng, FAN Shixing, et al. Simulation of dust diffusion in fully mechanized excavation face having large cross-section under FPNA ventilation condition[J]. China Safety Science Journal, 2017,27(2): 127-132. [7] 张雪艳,李玉珍,贾宁助,等.颗粒物防护口罩适合因子的影响因素研究[J]. 中国安全科学学报, 2015,25(3): 121-125. ZHANG Xueyan, LI Yuzhen,JIA Ningzhu,et al. Research on factors affecting particulate respirator fit factor[J]. China Safety Science Journal, 2015,25(3): 121-125. [8] BERGMAN M S, HE Xinjian, JOSEPH M E, et al. Correlation of respirator fit measured on human subjects and a static advanced headform[J]. Journal of Occupational and Environmental Hygiene, 2015,12(3): 163-171. [9] 金小汉,虞天仲.防尘口罩阻尘效率试验方法的探讨[J].煤矿安全, 1998,29(2): 23-24. [10] 姚红, 丁松涛. 探讨高浓度粉尘环境下的呼吸防护[J].中国职业安全健康协会2011年学术年会论文集, 2011: 439-445. [11] 42CFR-Part84-2006, Assigned protection factors: final rule[S]. [12] EN149-2001, Respiratory protective devices-filtering half masks to protect against particles-requirement, testing, marking[S]. [13] GB2626—2006,呼吸防护用品-自吸过滤式防颗粒物呼吸器[S]. GB2626-2006, Respiratory protective equipment-filtering facepiece respirators against particulates[S]. [14] ZHU Jintuo, HE Xinjian, GUFFEY S E, et al. Performance comparison of N95 and P100 filtering facepiece respirators with presence of faceseal leakage[J]. Annals of Work Exposures and Health, 2020,64(2): 202-216. [15] MUKHAMETZANOV I T, GRINSHPUN S A, ZARIPOV S K, et al. Assessing the protection provided by facepiece filtering respirator: new model involving spherical porous layer with annular peripheral opening[J]. Aerosol and Air Quality Research, 2016,16: 2 428-2 437. [16] RENGASAMY S, EIMER B C. Nanoparticle penetration through filter media and leakage through face seal interface of N95 filtering facepiece respirators[J]. Annals of Occupational Hygiene, 2012,56(5): 568-580. [17] ISO/TS-16976-1-2015, Respiratory protective devices—human factors. part 1: metabolic rates and respiratory flow rates[S]. [18] COOPER E. A comparison of the respiratory work done against an external resistance via man and by sine-wave pump[J]. Experimental Physiology, 1960,45(2): 179-191. [19] HARUTA H, HONDA T, ENINGER R, et al. Experimental and theoretical investigation of the performance of N95 respirator filters against ultrafine aerosol particles tested at constant and cyclic flows[J]. Journal of the International Society for Respiratory Protection, 2008,25: 75-88. [20] HINDS W C. Aerosol technology: properties, behavior, and measurement of airborne particles[M]. New York: John Wiley & Sons, Inc, 1982: 182-205. |