寸草塔二矿注氮防灭火数值模拟研究

doi:10.16265/j.cnki.issn1003-3033.2022.S2.0103

摘要/Abstract

摘要：

为明确不同注氮条件对遗煤自燃的影响,利用矿井束管监测系统测得某工作面采空区“三带”范围,并采用Fluent模拟软件,建立该工作面采空区不同注氮条件下的自燃“三带”迁移模型,以确定最佳注氮位置、注氮温度、注氮流量,并在寸草塔二矿开展现场试验,验证该模型的科学性和有效性。结果表明:注氮出口位置距工作面30 m时,回风侧氧化带宽度最小值为25 m,注氮效果最佳;氧化带宽度随注氮流量的增加呈减小趋势,当注氮流量达到900 m³/h,对采空区氧化带范围整体控制效果较好;注氮气体温度越低,覆盖氧化带范围越广,且对采空区有一定降温效果;在该工作面开展注氮防灭火现场应用过程中,采空区氧化带最大宽度由40.4 m降低至15.2 m,氧化带最大宽度降低61.4%,防灭火效果显著。

关键词: 注氮位置, 注氮温度, 注氮流量, 防灭火, 数值模拟, 氧化带宽度

Abstract:

In order to study the effect of different nitrogen injection conditions on the spontaneous combustion of residual coal, the three zones in the goaf of a working face were measured, with the beam tube monitoring system of mines utilized. A migration model for the three zones, which featured spontaneous combustion in the goaf of the working face under different nitrogen injection conditions, was established, and Fluent simulation software was adopted. The optimal nitrogen injection location, temperature, and flow rate were determined by the model. Field experiments were carried out at the Cuncaota No.2 mine, so as to verify the scientificity and effectiveness of the model. The results show that the nitrogen injection effect is the best when the outlet of nitrogen injection is 30 m from the working face. The minimum width of the oxidized zone on the wind return side is 25 m. In addition, the width of the oxidized zone decreases as the nitrogen injection flow rate increases. The oxidized zone in the goaf is better controlled when the flow rate reaches 900 m³/h. As the nitrogen injection temperature drops, the oxidized zone covers more areas and has a cooling effect on the goaf. During the field application of nitrogen injection for fire prevention in this working face, the maximum width of the oxidized zone is reduced from 40.4 m to 15.2 m. The maximum width of the oxidized zone is reduced by 61.4%, which indicates a significant effect on fire prevention.

Key words: nitrogen injection location, nitrogen injection temperature, nitrogen injection flow rate, fire prevention, numerical simulation, width of oxidized zone

张晓旭, 罗伙根. 寸草塔二矿注氮防灭火数值模拟研究[J]. 中国安全科学学报, 2022, 32(S2): 131-135.

ZHANG Xiaoxu, LUO Huogen. Numerical simulation research on nitrogen injection for fire prevention in Cuncaota No.2 mine[J]. China Safety Science Journal, 2022, 32(S2): 131-135.

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参考文献 17

[1]	王志坚. 矿山救护指挥员[M]. 北京: 煤炭工业出版社, 2007:5-8.
[2]	王继仁, 邓存宝. 煤微观结构与组分量质差异自燃理论[J]. 煤炭学报, 2007, 32(12):1291-1 296.
	WANG Jiren, DENG Cunbao. The spontaneous combustion theory of coal microcosmic structure and component differences in quantity and quality[J]. Journal of China Coal Society, 2007, 32(12):1291-1 296.
[3]	王继仁. 煤自燃量子化学理论[M]. 北京: 科学出版社, 2007:69-81.
[4]	徐精彩, 薛韩玲, 文虎, 等. 煤氧复合热效应的影响因素分析[J]. 中国安全科学学报, 2001, 11(2):34-39.
	XU Jingcai, XUE Hanling, WEN Hu, et al. Analysis on influential factors of thermal effect in coal oxidation[J]. China Safety Science Journal, 2001, 11(2): 34-39.
[5]	刘剑, 王继仁, 孙宝铮. 煤的活化能理论研究[J]. 煤炭学报, 1999, 24(3):94-98.
	LIU Jian, WANG Jiren, SUN Baozheng. A study on the theory of activation energy of coal[J]. Journal of China Coal Society, 1999, 24(3):94-98.
[6]	王德明, 辛海会, 戚绪尧, 等. 煤自燃中的各种基元反应及相互关系:煤氧化动力学理论及应用[J]. 煤炭学报, 2014, 39(8):1 667-1 674.
	WANG Deming, XIN Haihui, QI Xuyao, et al. Mechanism and relationships of elementary reactions in spontaneous combustion of coal:the coal oxidation kinetics theory and application[J]. Journal of China Coal Society, 2014, 39(8):1 667-1 674.
[7]	朱令起, 刘聪, 王福生. 煤自燃过程中自由基变化规律特性研究[J]. 煤炭科学技术, 2016, 44(10):44-47.
	ZHU Lingqi, LIU Cong, WANG Fusheng. Study on variation law and features of free radicals in coal spontaneous combustion process[J]. Coal Science and Technology, 2016, 44(10):44-47.
[8]	JONES J C, HENDERSON K P, LITTLEFAIR J, et al. Kinetic parameters of oxidation of coals by heat-release measurement and their relevance to self-heating tests[J]. Fuel, 1998, 77(1/2):19-22. doi: 10.1016/S0016-2361(97)00155-5
[9]	BEAMISH B B, ARISOY A. Effect of mineral matter on coal self-heating rate[J]. Fuel, 2008, 87(1):125-130. doi: 10.1016/j.fuel.2007.03.049
[10]	SCHMIDT L, ELDER J, DAVIS J. Atmospheric oxidation of coal at moderate temperatures. effect of oxidation on the carbonizing properties of representative coking coals[J]. Industrial & Engineering Chemistry Research, 2003, 32(4):548-555. doi: 10.1021/ie00015a018
[11]	KAM A Y, HIXSON A N, PERLMUTTER D D. The oxidation of bituminous coal-I development of a mathematical model[J]. Chemical Engineering Science, 1976, 31(9):815-819. doi: 10.1016/0009-2509(76)80055-3
[12]	ITAY M, HILL C R, GLASSER D. A study of the low temperature oxidation of coal[J]. Fuel Processing Technology, 1989, 21(2):81-97. doi: 10.1016/0378-3820(89)90063-5
[13]	邓军, 文虎, 徐精彩. 煤自然发火预测理论及技术[M]. 西安: 陕西科学技术出版社, 2001:11.
[14]	吴玉国, 邬剑明, 张东坡, 等. 综放工作面连续注氮下采空区气体分布及“三带”变化规律[J]. 煤炭学报, 2011, 36(5):964-967.
	WU Yuguo, WU Jianming, ZHANG Dongpo, et al. Distribution law of gas and change rule of ″three zones″ in the goaf of fully mechanized top-coal caving working face under the continuous nitrogen injection[J]. Journal of China Coal Society, 2011, 36(5):964-967.
[15]	REN T X, EDWARDS J S. Three-dimensional computational fluid dynamics modelling of methane flow through permeable strata around a longwall face[J]. Mining Technology: IMM Transaction Section A, 2000, 109(1): 41-48.
[16]	李宗翔, 单龙彪, 张文君. 采空区开区注氮防灭火的数值模拟研究[J]. 湖南科技大学学报:自然科学版, 2004, 19(3):5-9.
	LI Zongxiang, SHAN Longbiao, ZHANG Wenjun. Numerical simulation study of nitrogen injection porocess for prevention and extinguishment in goaf[J]. Journal of Hunan University of Science and Technology:Natural Science Edition, 2004, 19(3):5-9.
[17]	崔传发. 采空区瓦斯抽采钻孔参数及注氮防灭火研究[J]. 工矿自动化, 2020, 46(3):12-20.
	CUI Chuanfa. Research on gas drainage drilling parameters and nitrogen injection for fire prevention in goaf[J]. Industry and Mine Automation, 2020, 46(3):12-20.

位置	散热带	氧化带	窒息带	氧化带最大宽度
进风侧	(0,41.9]	(41.9,82.3]	>82.3	40.4
工作面中部	(0,32.2]	(32.2,62.7]	>62.7
回风侧	(0,28.7]	(28.7,64.5]	>64.5

序号	模型组成	模型尺寸
1	工作面	长200 m×断面23.4 m²
2	进、回风巷	长20 m×断面21.1 m²
3	采空区	长300 m×宽200 m×高20 m