综放工作面支架喷雾降尘装置的选择及优化
摘要
由于综放工作面的产尘量较采用其它生产工艺的采煤工作面的产尘量要大,因此,从保护现场作业人员职业安全健康以及企业安全生产的角度考虑,必须将综放工作面的粉尘浓度控制在可容许的范围以内。本文在雾化机理研究、喷嘴喷雾粒径测量实验、现场粉尘浓度测定以及喷雾前后粉尘迁移规律模拟的基础上,提出了优化的支架喷雾降尘系统,现场应用取得了较好的降尘效果。
本文根据雾化破碎机理以及两相流体力学理论,分析得到了雾化影响参数、雾滴初始速度、雾滴在空气中的存活时间以及液滴的降尘效率。在比较多种光学测粒仪的基础上,选择Winner313系统测量不同孔径喷嘴在不同供水压力下喷雾雾场的粒径分布。通过分析比较喷嘴在不同压力下喷雾雾场的粒径分布和Ansys模拟得到的喷嘴内部及出水口速度场,建议现场应用1.5mm喷嘴、供水压力为8MPa进行喷雾。
在测定现场喷雾前后的粉尘浓度分布的基础上,分析得出了综放工作面现场的粉尘分布规律,通过对采煤机处和放煤口的粉尘迁移规律模拟,得出了采煤机工作时下风侧支架喷雾开启的位置、架数等。
在上述研究的基础上,提出了东滩煤矿1303综放工作面支架喷雾降尘系统,通过比较不同的喷雾降尘系统的布置方式及其现场应用效果,得出了最优化的支架喷雾降尘布置方式、喷雾供水压力等参数。现场应用表明,本文设计选择的最优化的支架喷雾降尘布置方式具有较好的降尘效果。
Compared with other caving faces which are not using the fully-mechanized caving method, the fully-mechanized caving face produces much larger amount of dust than others. Therefore, in consideration of mine workers' occupational safety and health, and the enterprise's safety management, we must ensure that the dust concentration in the working face is controlled under the allowable range of our regulations. On the basis of the mechanism research of nozzle spraying, the measurement of the particle size of droplet which produced by nozzle atomization, the dust examination on the working face and the simulation of dust along the whole working face, the author puts forward a optimized dust-laying system of support spraying, and it has obtained a good dust-laying effect dust-laying work.
Based on the mechanism of atomization broken and two-phase flow theory, the influent parameters of spraying, the equations for calculating the velocity of the liquid jet, the survival time of the particle in the atmosphere and the efficiency of the dust-laying by liquid droplets were obtained. Then, by comparing a number of modern laser measurement equipments, this dissertation chose Winner 313 system to measure the particle size distribution of different nozzles under different water pressure. Therefore, by comparing particle distribution of the spraying under different water pressure, and the nozzle's outlet velocity simulation get by Ansys, which is a software for mechanical simulation, a proposal of the application of 1.5mm nozzle, 8Mpa water pressure on the spot was put forward.
On the basis of the measuring of dust distribution in the working face before and after spraying, this dissertation analyzed and elicited the regulation of the dust concentration along the fully-mechanized caving face. Depend on the simulation of the dust around the shearer and drawing opening, the starting number of the support spraying system in the leeward of shearer was confirmed.
Based on this study, a support nozzle spraying system which suited the Dongtan coal mine' situation was put forward. By comparing the different arrangement of the dust-laying system, some optimal parameters, such as arrangement, water pressure, etc. were determined. By the experiment of the dust-laying efficiency on the working face, the optimized spraying system has a good efficiency in dust-laying work.
本文根据雾化破碎机理以及两相流体力学理论,分析得到了雾化影响参数、雾滴初始速度、雾滴在空气中的存活时间以及液滴的降尘效率。在比较多种光学测粒仪的基础上,选择Winner313系统测量不同孔径喷嘴在不同供水压力下喷雾雾场的粒径分布。通过分析比较喷嘴在不同压力下喷雾雾场的粒径分布和Ansys模拟得到的喷嘴内部及出水口速度场,建议现场应用1.5mm喷嘴、供水压力为8MPa进行喷雾。
在测定现场喷雾前后的粉尘浓度分布的基础上,分析得出了综放工作面现场的粉尘分布规律,通过对采煤机处和放煤口的粉尘迁移规律模拟,得出了采煤机工作时下风侧支架喷雾开启的位置、架数等。
在上述研究的基础上,提出了东滩煤矿1303综放工作面支架喷雾降尘系统,通过比较不同的喷雾降尘系统的布置方式及其现场应用效果,得出了最优化的支架喷雾降尘布置方式、喷雾供水压力等参数。现场应用表明,本文设计选择的最优化的支架喷雾降尘布置方式具有较好的降尘效果。
Compared with other caving faces which are not using the fully-mechanized caving method, the fully-mechanized caving face produces much larger amount of dust than others. Therefore, in consideration of mine workers' occupational safety and health, and the enterprise's safety management, we must ensure that the dust concentration in the working face is controlled under the allowable range of our regulations. On the basis of the mechanism research of nozzle spraying, the measurement of the particle size of droplet which produced by nozzle atomization, the dust examination on the working face and the simulation of dust along the whole working face, the author puts forward a optimized dust-laying system of support spraying, and it has obtained a good dust-laying effect dust-laying work.
Based on the mechanism of atomization broken and two-phase flow theory, the influent parameters of spraying, the equations for calculating the velocity of the liquid jet, the survival time of the particle in the atmosphere and the efficiency of the dust-laying by liquid droplets were obtained. Then, by comparing a number of modern laser measurement equipments, this dissertation chose Winner 313 system to measure the particle size distribution of different nozzles under different water pressure. Therefore, by comparing particle distribution of the spraying under different water pressure, and the nozzle's outlet velocity simulation get by Ansys, which is a software for mechanical simulation, a proposal of the application of 1.5mm nozzle, 8Mpa water pressure on the spot was put forward.
On the basis of the measuring of dust distribution in the working face before and after spraying, this dissertation analyzed and elicited the regulation of the dust concentration along the fully-mechanized caving face. Depend on the simulation of the dust around the shearer and drawing opening, the starting number of the support spraying system in the leeward of shearer was confirmed.
Based on this study, a support nozzle spraying system which suited the Dongtan coal mine' situation was put forward. By comparing the different arrangement of the dust-laying system, some optimal parameters, such as arrangement, water pressure, etc. were determined. By the experiment of the dust-laying efficiency on the working face, the optimized spraying system has a good efficiency in dust-laying work.
引文
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[32] R·C·Reid, J·M·Prausnitz and T·K·Sherwood. The Properties of Gases and Liquids[M]. New York US: McGraw Hill, 1997: 27-43.
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[37] 范宝春,叶经方.瞬态流场参数测量[M].哈尔滨:哈尔滨工程大学出版社,2005:104-305.
[38] 吕方.国内外激光粒度仪性能特点对比[J].中国非金属矿工业导刊,2005,(3):35-36.
[39] 梁国标,李新衡,王燕民.激光粒度测量的应用与前景[J].材料导报,2006,20(4):90-93.
[40] 孙昕,张贵忠,贾光明等.基于米氏散射理论的激光粒度仪的介绍[J].现代科学仪器,2004,(5):40-43.
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[2] 姜健.掘进工作面截割粉尘及其影响因素的研究[D].辽宁阜新:辽宁工程技术大学,2000.
[3] 梁冬.黑龙江七台河矿难搜救工作结束确认171人遇难[EB/OL].[2006-03-01].http://gb.chinabroadcast.cn/8606/2005/12/06/1245@808924.htm.
[4] 邓卫华.枣庄发生煤尘爆炸特大事故15人死亡12人受伤[EB/OL].[2006-03-01].http://news.xinhuanet.com/society/2006-02/24/content_4221691.htm.
[5] 孙艳玲,刘烟台,王德江.煤矿采掘引起粉尘污染与防治[J].辽宁工程技术大学学报,2002,21(4):520-522.
[6] 刘毅.综采工作面粉尘运动规律及高压喷雾除尘技术的研究[D].北京:北京科技大学,2006.
[7] 李新东,许波云,田水承.矿山粉尘防治技术[M].西安:陕西科学技术出版社,1995:77,82-100.
[8] 张延松.煤层注水湿润煤体的研究[J].煤炭学报,1995,20(6):1-7.
[9] 秦文贵,张延松.煤孔隙分布与煤层注水增量的关系[J].煤炭学报,2000,25(5):514-517.
[10] 陈沅江,吴超.注水煤层渗透性的影响因素及其改善对策[J].煤矿安全,1997,(12):15-18.
[11] 王海桥,刘荣华.综采工作面隔尘空气幕模拟实验及应用研究[J].矿业安全与环保,2000,27(2):13-15.
[12] 李晓豁.采煤机截割产尘的数学模型[J].辽宁工程技术大学学报 2002,21(6):776-779.
[13] 赵树强.采煤机参数对尘肺病及安全的影响研究[D].辽宁阜新:辽宁工程技术大学,2005.
[14] 张小良,陈建华.矿山粉尘防治技术的进展[J].矿产保护与利用,2002,(3):51-54.
[15] 谢德瑜,舒新前,郝王娟.煤尘抑尘剂的开发与研究[J].选煤技术,2004,(5):19-21.
[16] 王海桥,施式亮,刘荣华.综采工作面空气幕隔尘研究及应用[J].湘潭矿业学院学 报,1999,14(1):11-14.
[17] 宋马俊.国外煤矿粉尘控制措施的新进展[J].中国职业安全卫生管理体系认证,2003,(3):21-22.
[18] 梁扬宝,刘启荣.降低煤矿粉尘浓度的新途径[J].科技情报开发与经济,2002,12(6):124-125.
[19] 李聪.喷油嘴参数对柴油机喷雾特性影响的试验研究[D].洛阳:洛阳工学院,2003.
[20] Reitz·R·D, Bracco·F·V. Mechanism of Atomization of a Liquid Jet[J]. Phys. Fluids, 1982, 25(10): 1730-1742.
[21] 严春吉,解茂昭.气动力对空心圆柱形液体射流分裂与雾化特性的影响[J].大连海事大学学报,1998,24(2):84-88.
[22] 严春吉,解茂昭,殷佩海.粘性气体中粘性液体射流分裂与雾化机理研究[J].空气动力学学报,2004,22(4):422-426.
[23] 姚悦.高粘度流体气力雾化机理及实验研究[D].浙江杭州:浙江大学,2006.
[24] 贺文智,陈宇峰,孟庆.液体雾化机理的研究进展[J].内蒙古石油化工,1996,(3):13-16.
[25] 曹建明,马志义.喷雾中液滴破裂机理的研究[J].车用发动机,1997,(4):11-13.
[26] 李天友.压力式喷嘴雾化特性实验研究及喷雾干燥热质传递特性数值模拟[D].四川成都:四川大学,2006.
[27] 侯凌云,侯晓春.喷嘴技术手册[M].北京:中国石化出版社,2002:13-16.
[28] 武通海.高效喷雾除尘技术在掘进工作面的应用研究[D].山西太原:太原理工大学,2002.
[29] 浑宝炬,郭立稳.矿井粉尘检测与防治技术[M].北京:化学工业出版社,2005:137-149.
[30] 章熙民,任泽需,梅飞鸣等.传热学[M].北京:中国建筑工业出版社,1989:280-285.
[31] Liu Xiangsheng, Zheng Yangxin, Xie jun, et. Improved Algorithm of Relative Humidity of Coal Air[A]. In: Huang Ping, Wang Yajun, Li Shengcai, etc. eds. Progress in Safety Science and Technology: vol.Ⅵ[C]. Beijing: Science Press, 2006:1575~1578.
[32] R·C·Reid, J·M·Prausnitz and T·K·Sherwood. The Properties of Gases and Liquids[M]. New York US: McGraw Hill, 1997: 27-43.
[33] 宿凤明.超声雾化喷嘴的实验及理论研究[D].河北石家庄:河北工业大学,2002.
[34] 田春霞,仇性启,崔运静.喷嘴雾化技术进展[J].工业加热,2005,34(4):40-43.
[35] 于建文,刘晓东,黄金瑞.几种先进测量技术浅析[J].锅炉制造,2002,(3):79-80.
[36] 王德忠,黄震,张连方.激光技术在燃油喷雾测试中应用的进展[J].激光技术,1995,19(1):27-32.
[37] 范宝春,叶经方.瞬态流场参数测量[M].哈尔滨:哈尔滨工程大学出版社,2005:104-305.
[38] 吕方.国内外激光粒度仪性能特点对比[J].中国非金属矿工业导刊,2005,(3):35-36.
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