煤矿火灾防治技术的研究进展
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摘要
介绍了目前我国煤矿火灾防治的基本方法,综合论述了当前在煤矿火灾防治方面研发的维C、Na_3PO_4、煤灰稳定泡沫塑料、离子液体、阻化剂等新方法,并对不断创新提高防火技术的有效性、适应性和经济性进行了分析;展望了未来煤矿火灾防治发展的方向。
引文
[1] 罗海珠,梁运涛.煤自然发火预测预报技术的现状与展望[J].中国安全科学学报,2003,13(3):76-78.
[2] 梁运涛,罗海珠.中国煤矿火灾防治技术现状与趋势[J].煤炭学报,2008,33(2):127-133.
[3] 戚颖敏.我国煤矿火灾防治技术的现代发展与应用[J].煤,1999,8(2):1-4.
[4] 王省身,张国枢.中国煤矿火灾防治技术的现状与发展[J].火灾科学,1994,3(2):1-6.
[5] Wang HH,Dlugogorski B Z,Kennedy E M.Analysis of the Mechanism of the Low-temperature Oxidation of Coal[J].Combust.Flame,2003,134:107-117.
[6] Mao J D,Schi mmelmann A,Mastalerz M,et al.Structural Features of a Bituminous Coal and Their Changes during Low-Temperature Oxidation and Loss of Volatiles Investigated by Advanced Solid-State NMR Spectroscopy[J].Energ.Fuel,2010,24:2536-2544.
[7] Wang HH,Dlugogorski B Z,Kennedy E M.Coal Oxidation at Low Temperatures:Oxygen Consumption Oxidation Products,Reaction Mechanism and Kinetic Modeling[J].Prog.Energy Combust.Sci.,2003,29:487-513.
[8] Taraba B,Peter R,Slovak V.Calorimetric Investigation of Chemical Additives Affecting Oxidation of Coal at Low Temperatures[J].Fuel Process.Technol.,2011,92:712-715.
[9] Slovák V,Taraba B.Urea and CaCl2 as Inhibitors of Coal Lowtemperature Oxidation[J].J.Therm.Anal.Calorim.,2012,110:363-367.
[10] 梁运涛.煤炭自然发火预测预报的气体指标法[J].煤炭科学技术,2008,36(6):5-8.
[11] 高广伟.中国煤矿氮气防灭火的现状与未来[J].煤炭学报,1999,24(1):48-52.
[12] 梁运涛,汤晓君,罗海珠,等.煤层自然发火特征气体的光谱定量分析[J].光谱学与光谱分析,2011,31(9):2481-2487.
[13] 胡广扬,张淑兰.中国煤矿火灾的防治[J].中国安全科学学报,1992,2(1):11-19.
[14] 王刚.新型高分子凝胶防灭火材料在煤矿火灾防治中的应用[J].煤矿安全,2014,45(2):228-229.
[15] Wang HH,Dlugogorski BZ,KennedyEM.Coal Oxidationat Low Temperatures:Oxygen Consumption Oxidation Products,Reaction Mechanismand Kinetic Modeling[J].Prog.Energy Combust.Sci.,2003,29:487-513.
[16] Sujanti W,Zhang DK.Investigation into the Role of Inherent Inorganic Matterand Additives in Low-Temperature Oxidation of a Victorian Brown Coal[J].Combust.Sci.Technol.,2000,152:99-114.
[17] SlovákV,TarabaB.Ureaand CaCl2 as Inhibitors of Coal Low temperature Oxidation[J].J.Therm.Anal.Calorim.,2012,110:363-367.
[18] XuY,WangD,WangL,etal.Experimental Research on Inibition Performances of the Sand-suspended Colloid for Coal Spontaneous Combustion[J].SafetySci.,2012,50:822-827.
[19] ZhanJ,WangHH,SongSN,etal.Role of an Additive in Retarding Coal Oxidation at Moderate Temperatures[J].Proceed.Combust.Insti.,2011,33:2515-2522.
[20] QINBotao,DOUGuolan,D Wang.Thermal Analysis of Vitamin C Affecting Low-temperature Oxidation of Coal.J.Wuhan Uni.Tec.,2016,31(3):519-522.
[21] ZhouF,RenW,WangD,et al.Application of the three-phase foam to fight an extra ordinarily serious coal mine fire.Int J Coal Geol,2006,67:95-100.
[22] Fu-baoZ,De-mingW,Yong-jiuZ,et al.Practice of fighting fire and suppressing explosion for a super-large and highly gassy mine[J].China Univ Mining Technology,2007,17:0459-0463.
[23] El-DidamonyH,El-RahmanE,OsmanRM.Fire resistance of fired clay bricks-fly ash composite cement pastes[J].CeramInt,2012,38:201-209.
[24] VilchesLF,LeivaC,ValeJ,et al.Insulating capacity of fly ash Pastes used for passive protection against fire[J].Cem Concr Compos,2005,27:776-781.
[25] QinB,LuY,LiY,WangD.Aqueous three-phase foam supported by fly ash for coal spontaneous combustion prevention and control[J].Adv Powder Technology,2014,25:1527-1533.
[26] B Qin,YJia,Y Lu,et al.Micro fly-ash particles stabilized Pickering foams and its combustion-retardant characteristics[J].Fuel,201,15:174-180.
[27] B Qin,G Dou,Y Wang,et al.A super absorbent hydrogel–ascorbic acid composite inhibitor for the suppression of coal oxidation[J].Fuel,2017,190:129-135.
[28] GaoJ,KoshioS,IshikawaM,et al.Inter active effects of vitamin C and E supplementation on growth performance,fatty acid composition and reduction of oxidative stress injuvenile Japanese flounder Paralichthys olivaceus fed dietary oxidized fish oil[J].Aquaulture,2014,422-423:84-90.
[29] Y Tang.The Influences of Manganese and Phosphorus on the Low-Temperature Oxidation of Coal[J].Coal Preparation,2015,35(2):63-75.
[30] ZHANG W Q,JIANGSG,WANG K,etal.Study On coal spontaneous combustion characteristic structures affected by ionic liquids[J].Procedia Engineering,2011(26):480-485.
[31] WANGLY,XU YL,JIANGSG,etal.Imidazolium based ionic liquids affecting functional groups and oxidation properties of bituminous coal[J].Safety Science,2012(50):1528-1534.
[32] 王兰云,蒋曙光,吴正艳,等.离子液体抑制煤炭自燃的新设想[J].煤矿安全,2009,40(8):90-92.
[33] L Wang,YXu,S Wang,et al.Inhibiting effect of[HOEmim][BF4]and[Amim]Cl ionic liquids on the cross-linking reaction of bituminous coal[J].Inter J Min Sci Techno.,2016,26(2):353-359
[34] 张卫清,蒋曙光,吴征艳,等.离子液体对煤中氢键反应活性的影响[J].中国矿业大学学报,2013,42(2):200-205.
[35] 肖旸,钟凯琪,解萌玥,等.离子液体抑制煤自燃的程序升温试验研究[J].西安科技大学学报,2017,37(3):396-402.
[36] 李明,蒋曙光,张卫清,等.不同浓度离子液体对煤中官能团的影响[J].中国煤炭,2018,44(5):78-83.
[37] C Cui,S Jiang,W Zhang.Experimental Study on the Effect of a Thermoresponsive Secundine Inhibitor on Coal Spontaneous Combustion[J].Energy & Fuels,2017,31(12).
[38] Y Tang.Inhibition of Low-Temperature Oxidation of Bituminous Coal Using a Novel Phase-Transition Aerosol[J].Energy & Fuels,2016,30(11).
[39] SuHetao,Zhou Fubao,Qi Haining,et al.Design for thermoelectric power generation using subsurface coal fires[J].Energy,2017,140:926-940.
[2] 梁运涛,罗海珠.中国煤矿火灾防治技术现状与趋势[J].煤炭学报,2008,33(2):127-133.
[3] 戚颖敏.我国煤矿火灾防治技术的现代发展与应用[J].煤,1999,8(2):1-4.
[4] 王省身,张国枢.中国煤矿火灾防治技术的现状与发展[J].火灾科学,1994,3(2):1-6.
[5] Wang HH,Dlugogorski B Z,Kennedy E M.Analysis of the Mechanism of the Low-temperature Oxidation of Coal[J].Combust.Flame,2003,134:107-117.
[6] Mao J D,Schi mmelmann A,Mastalerz M,et al.Structural Features of a Bituminous Coal and Their Changes during Low-Temperature Oxidation and Loss of Volatiles Investigated by Advanced Solid-State NMR Spectroscopy[J].Energ.Fuel,2010,24:2536-2544.
[7] Wang HH,Dlugogorski B Z,Kennedy E M.Coal Oxidation at Low Temperatures:Oxygen Consumption Oxidation Products,Reaction Mechanism and Kinetic Modeling[J].Prog.Energy Combust.Sci.,2003,29:487-513.
[8] Taraba B,Peter R,Slovak V.Calorimetric Investigation of Chemical Additives Affecting Oxidation of Coal at Low Temperatures[J].Fuel Process.Technol.,2011,92:712-715.
[9] Slovák V,Taraba B.Urea and CaCl2 as Inhibitors of Coal Lowtemperature Oxidation[J].J.Therm.Anal.Calorim.,2012,110:363-367.
[10] 梁运涛.煤炭自然发火预测预报的气体指标法[J].煤炭科学技术,2008,36(6):5-8.
[11] 高广伟.中国煤矿氮气防灭火的现状与未来[J].煤炭学报,1999,24(1):48-52.
[12] 梁运涛,汤晓君,罗海珠,等.煤层自然发火特征气体的光谱定量分析[J].光谱学与光谱分析,2011,31(9):2481-2487.
[13] 胡广扬,张淑兰.中国煤矿火灾的防治[J].中国安全科学学报,1992,2(1):11-19.
[14] 王刚.新型高分子凝胶防灭火材料在煤矿火灾防治中的应用[J].煤矿安全,2014,45(2):228-229.
[15] Wang HH,Dlugogorski BZ,KennedyEM.Coal Oxidationat Low Temperatures:Oxygen Consumption Oxidation Products,Reaction Mechanismand Kinetic Modeling[J].Prog.Energy Combust.Sci.,2003,29:487-513.
[16] Sujanti W,Zhang DK.Investigation into the Role of Inherent Inorganic Matterand Additives in Low-Temperature Oxidation of a Victorian Brown Coal[J].Combust.Sci.Technol.,2000,152:99-114.
[17] SlovákV,TarabaB.Ureaand CaCl2 as Inhibitors of Coal Low temperature Oxidation[J].J.Therm.Anal.Calorim.,2012,110:363-367.
[18] XuY,WangD,WangL,etal.Experimental Research on Inibition Performances of the Sand-suspended Colloid for Coal Spontaneous Combustion[J].SafetySci.,2012,50:822-827.
[19] ZhanJ,WangHH,SongSN,etal.Role of an Additive in Retarding Coal Oxidation at Moderate Temperatures[J].Proceed.Combust.Insti.,2011,33:2515-2522.
[20] QINBotao,DOUGuolan,D Wang.Thermal Analysis of Vitamin C Affecting Low-temperature Oxidation of Coal.J.Wuhan Uni.Tec.,2016,31(3):519-522.
[21] ZhouF,RenW,WangD,et al.Application of the three-phase foam to fight an extra ordinarily serious coal mine fire.Int J Coal Geol,2006,67:95-100.
[22] Fu-baoZ,De-mingW,Yong-jiuZ,et al.Practice of fighting fire and suppressing explosion for a super-large and highly gassy mine[J].China Univ Mining Technology,2007,17:0459-0463.
[23] El-DidamonyH,El-RahmanE,OsmanRM.Fire resistance of fired clay bricks-fly ash composite cement pastes[J].CeramInt,2012,38:201-209.
[24] VilchesLF,LeivaC,ValeJ,et al.Insulating capacity of fly ash Pastes used for passive protection against fire[J].Cem Concr Compos,2005,27:776-781.
[25] QinB,LuY,LiY,WangD.Aqueous three-phase foam supported by fly ash for coal spontaneous combustion prevention and control[J].Adv Powder Technology,2014,25:1527-1533.
[26] B Qin,YJia,Y Lu,et al.Micro fly-ash particles stabilized Pickering foams and its combustion-retardant characteristics[J].Fuel,201,15:174-180.
[27] B Qin,G Dou,Y Wang,et al.A super absorbent hydrogel–ascorbic acid composite inhibitor for the suppression of coal oxidation[J].Fuel,2017,190:129-135.
[28] GaoJ,KoshioS,IshikawaM,et al.Inter active effects of vitamin C and E supplementation on growth performance,fatty acid composition and reduction of oxidative stress injuvenile Japanese flounder Paralichthys olivaceus fed dietary oxidized fish oil[J].Aquaulture,2014,422-423:84-90.
[29] Y Tang.The Influences of Manganese and Phosphorus on the Low-Temperature Oxidation of Coal[J].Coal Preparation,2015,35(2):63-75.
[30] ZHANG W Q,JIANGSG,WANG K,etal.Study On coal spontaneous combustion characteristic structures affected by ionic liquids[J].Procedia Engineering,2011(26):480-485.
[31] WANGLY,XU YL,JIANGSG,etal.Imidazolium based ionic liquids affecting functional groups and oxidation properties of bituminous coal[J].Safety Science,2012(50):1528-1534.
[32] 王兰云,蒋曙光,吴正艳,等.离子液体抑制煤炭自燃的新设想[J].煤矿安全,2009,40(8):90-92.
[33] L Wang,YXu,S Wang,et al.Inhibiting effect of[HOEmim][BF4]and[Amim]Cl ionic liquids on the cross-linking reaction of bituminous coal[J].Inter J Min Sci Techno.,2016,26(2):353-359
[34] 张卫清,蒋曙光,吴征艳,等.离子液体对煤中氢键反应活性的影响[J].中国矿业大学学报,2013,42(2):200-205.
[35] 肖旸,钟凯琪,解萌玥,等.离子液体抑制煤自燃的程序升温试验研究[J].西安科技大学学报,2017,37(3):396-402.
[36] 李明,蒋曙光,张卫清,等.不同浓度离子液体对煤中官能团的影响[J].中国煤炭,2018,44(5):78-83.
[37] C Cui,S Jiang,W Zhang.Experimental Study on the Effect of a Thermoresponsive Secundine Inhibitor on Coal Spontaneous Combustion[J].Energy & Fuels,2017,31(12).
[38] Y Tang.Inhibition of Low-Temperature Oxidation of Bituminous Coal Using a Novel Phase-Transition Aerosol[J].Energy & Fuels,2016,30(11).
[39] SuHetao,Zhou Fubao,Qi Haining,et al.Design for thermoelectric power generation using subsurface coal fires[J].Energy,2017,140:926-940.