掘进工作面传热特性及热害治理研究
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摘要
世界能源消费结构中,化石能源依然占据主导地位。随着对能源需求的增长,煤矿的开采深度在不断增加,热害矿井数量也越来越多。在高温高湿环境下工作,不仅损害工人的身体健康,降低劳动生产率,而且影响安全生产,对人的伤害大都不可逆转。目前,热害已严重制约了煤矿的发展,成为继瓦斯、火、水、矿压、粉尘之后的第六大灾害。因此,深入研究深井热害问题已成为世界煤炭开采的一项技术发展重点。本文以煤矿热害最为严重的作业点之一——掘进工作面为研究对象,对其换热特性和热害治理进行了实验和数值模拟研究,获得了掘进工作面换热计算关联式;从气候、地温和热源等方面对深部矿井的热害规律进行了系统的研究,推导出冷负荷计算式,提出热害治理的系统设计方案,开发出新型半封闭式矿用局部制冷降温系统。主要研究内容及结论如下:
(1)掘进工作面传热研究根据高温矿井掘进工作面的通风和换热特点,对换热特性进行了实验研究和数值模拟分析,数值模拟结果和实验结果吻合较好。在数值模拟和实验研究基础上,得到了掘进工作面换热特性影响因素的具体关联式。为结合实际应用,将掘进面迎头、围岩及风流看作一个整体,对840个组合分别进行数值模拟,并对实验数据进行回归分析,得出了传热系数关系式。
(2)深部高温矿井热害规律研究
对深部高温矿井热害规律进行研究,得出了地面和井下的温度、相对湿度和气压变化曲线非常相似且同步变化,一般区域矿井地面气候参数对井下气候参数有着显著影响。对于深部高温矿井较远地区,因特殊的开拓条件、进风路线比较长和深度较大等原因,井下气温受地面气温的影响较小,热害出现的主要原因是由地温造成。
推导了井下钻孔测地温的原理及巷道调热圈厚度的计算方法。随着矿井开采深度的增加,岩石的原始岩温也在增加。由于地质断层的作用,地温变化有个明显急剧增加的过程。研究确定了地温类型,恒温带的温度和深度,对矿井沿途各种热源散热量进行了定量分析,得出了沿通风线路中各种热源散热量所占的比例。
(3)热害治理研究
对高温矿井掘进工作面的热害治理进行了较深入的研究,推导了冷负荷计算式,计算了掘进工作面热源的散热量,确定了掘进面制冷负荷,针对掘进工作面设计出降温系统方案,开发出相应装备。实践表明系统运行稳定可靠、制冷效果好。通过PLC对系统进行控制,并可实现多种保护功能。测试结果显示,掘进工作面从迎头到离迎头100m范围内,干球温度平均降低5.6℃,湿球温度平均降低8.5℃,相对湿度平均降低20%,达到了设计要求。掘进工作面热害治理系统是比较成功的,可作为类似高温矿井热害治理的示范矿井,具有推广意义。
In the world energy consumption structure, fossil energy still remains the dominantposition. With the growth of energy demand and mining depth, the number of mineswith heat hazard is increasing. It has severely constrained the development of coalmines. Currently, mine heat hazard has become the sixth coal mine disaster followingroof, gas, fire, dust and water. Therefore, further study of heat hazard has become atechnical focal point of the development of coal mining. The high temperature andhumid environment not only harm workers’ health irreversibly, but also reduce laborproductivity. The thesis takes the driving face which is one of the hottest work place asthe study object. According to the study of heat transfer characteristics and mine heatharm control, we can get the heat transfer relationship of driving face. Furthermore,systematic study is done about the law of heat harm in deep mine on the climate,geothermal and heat resources and the calculation formula of cooling load is deduced.Then it puts forward the system design for the specific coal mine and develops theworld’s first semi-closed mine cooling system. Data analysis shows that the coolingeffect is good and meets the design requirements.The thesis’s main research contentsand conclusions are as follows:
(1)Study on heat transfer in driving face.
According to the ventilation and heat transfer characteristics of driving face in hotmine, and on the basis of theoretical analysis of general parameters in engineeringpractice, the heat transfer characteristics are investigated by ANSYS numericalsimulation and the ratio of1:3similar experiment, the number of numerical simulationand experimental study are respectively840and280group. Through the comparison,simulation and experiment results have high degree of coincidence both on range ofvalue and variation tendency. Then the concrete forms of heat transfer coefficientcorrelation are made through regression analysis of numerical simulation results andexperimental results. Similarly, in order to combine with practical application, thisthesis sees the driving face head-on, wall rock and airflow as a whole, conductsnumerical simulation on840combinations respectively, does regression analysis of theexperimental data and gets the correlation of heat transfer coefficient.
(2)Research on the law of heat harm in deep and hot mine
Based on the law of heat harm in deep and hot mine, the change curve of temperature, relative humidity and air pressure between the ground and underground isvery similar and synchronous. Generally, the climate parameters on the ground haveremarkable effect on climate parameters under the mine. For the distant areas ofdeep-high temperature mine, because of special conditions of development, long airwayand other reasons, the climate on the ground has a little impact on the coal mine. Theheat damage is mainly caused by high temperature of the geothermal.
Geothermal downhole drilling test theory and calculation method of thickness ofheat-adjusting layer are deduced. With the increase of the depth of coal bed, the originalrock temperature is still increasing. As the role of geological faults, the geothermaltemperature has significantly increased dramatically in the process. The thesis hasstudied and confirmed the type of geothermal, temperature and depth of constanttemperature zone. Through quantitative analysis in the heat dissipating of various heatsources along airway, the proportion of heat dissipating of various heat sources isobtained.
(3)Research on heat-harm control
Through the deep study of heat-harm control in high temperature driving face, thecalculation formula of refrigerating capacity is deduced. The heat dissipating capacity ofheat source in driving face is calculated, and the cooling system has been designed andinstalled. The practice shows that the system is stable and reliable, and also has goodcooling effect and meets the design requirements absolutely. Through the PLC tocontrol the system, it can realize many kinds of protection function. Within the100mfrom the heading face, the temperature reduction range of dry bulb mean temperatureaverage is5.6℃, and the maximum is7.5℃.The wet bulb mean temperature is8.5℃,and the maximum is11℃, and the fall scope of the relative humidity is20%on average.YongChuan coal mine local refrigeration cooling system is successful, which verifiesthe rationality of the experiment and the theory in this paper. The refrigeration coolingsystem can be used as a demonstration of mine heat harm control, and it is worthy ofbeing used widely.
(1)掘进工作面传热研究根据高温矿井掘进工作面的通风和换热特点,对换热特性进行了实验研究和数值模拟分析,数值模拟结果和实验结果吻合较好。在数值模拟和实验研究基础上,得到了掘进工作面换热特性影响因素的具体关联式。为结合实际应用,将掘进面迎头、围岩及风流看作一个整体,对840个组合分别进行数值模拟,并对实验数据进行回归分析,得出了传热系数关系式。
(2)深部高温矿井热害规律研究
对深部高温矿井热害规律进行研究,得出了地面和井下的温度、相对湿度和气压变化曲线非常相似且同步变化,一般区域矿井地面气候参数对井下气候参数有着显著影响。对于深部高温矿井较远地区,因特殊的开拓条件、进风路线比较长和深度较大等原因,井下气温受地面气温的影响较小,热害出现的主要原因是由地温造成。
推导了井下钻孔测地温的原理及巷道调热圈厚度的计算方法。随着矿井开采深度的增加,岩石的原始岩温也在增加。由于地质断层的作用,地温变化有个明显急剧增加的过程。研究确定了地温类型,恒温带的温度和深度,对矿井沿途各种热源散热量进行了定量分析,得出了沿通风线路中各种热源散热量所占的比例。
(3)热害治理研究
对高温矿井掘进工作面的热害治理进行了较深入的研究,推导了冷负荷计算式,计算了掘进工作面热源的散热量,确定了掘进面制冷负荷,针对掘进工作面设计出降温系统方案,开发出相应装备。实践表明系统运行稳定可靠、制冷效果好。通过PLC对系统进行控制,并可实现多种保护功能。测试结果显示,掘进工作面从迎头到离迎头100m范围内,干球温度平均降低5.6℃,湿球温度平均降低8.5℃,相对湿度平均降低20%,达到了设计要求。掘进工作面热害治理系统是比较成功的,可作为类似高温矿井热害治理的示范矿井,具有推广意义。
In the world energy consumption structure, fossil energy still remains the dominantposition. With the growth of energy demand and mining depth, the number of mineswith heat hazard is increasing. It has severely constrained the development of coalmines. Currently, mine heat hazard has become the sixth coal mine disaster followingroof, gas, fire, dust and water. Therefore, further study of heat hazard has become atechnical focal point of the development of coal mining. The high temperature andhumid environment not only harm workers’ health irreversibly, but also reduce laborproductivity. The thesis takes the driving face which is one of the hottest work place asthe study object. According to the study of heat transfer characteristics and mine heatharm control, we can get the heat transfer relationship of driving face. Furthermore,systematic study is done about the law of heat harm in deep mine on the climate,geothermal and heat resources and the calculation formula of cooling load is deduced.Then it puts forward the system design for the specific coal mine and develops theworld’s first semi-closed mine cooling system. Data analysis shows that the coolingeffect is good and meets the design requirements.The thesis’s main research contentsand conclusions are as follows:
(1)Study on heat transfer in driving face.
According to the ventilation and heat transfer characteristics of driving face in hotmine, and on the basis of theoretical analysis of general parameters in engineeringpractice, the heat transfer characteristics are investigated by ANSYS numericalsimulation and the ratio of1:3similar experiment, the number of numerical simulationand experimental study are respectively840and280group. Through the comparison,simulation and experiment results have high degree of coincidence both on range ofvalue and variation tendency. Then the concrete forms of heat transfer coefficientcorrelation are made through regression analysis of numerical simulation results andexperimental results. Similarly, in order to combine with practical application, thisthesis sees the driving face head-on, wall rock and airflow as a whole, conductsnumerical simulation on840combinations respectively, does regression analysis of theexperimental data and gets the correlation of heat transfer coefficient.
(2)Research on the law of heat harm in deep and hot mine
Based on the law of heat harm in deep and hot mine, the change curve of temperature, relative humidity and air pressure between the ground and underground isvery similar and synchronous. Generally, the climate parameters on the ground haveremarkable effect on climate parameters under the mine. For the distant areas ofdeep-high temperature mine, because of special conditions of development, long airwayand other reasons, the climate on the ground has a little impact on the coal mine. Theheat damage is mainly caused by high temperature of the geothermal.
Geothermal downhole drilling test theory and calculation method of thickness ofheat-adjusting layer are deduced. With the increase of the depth of coal bed, the originalrock temperature is still increasing. As the role of geological faults, the geothermaltemperature has significantly increased dramatically in the process. The thesis hasstudied and confirmed the type of geothermal, temperature and depth of constanttemperature zone. Through quantitative analysis in the heat dissipating of various heatsources along airway, the proportion of heat dissipating of various heat sources isobtained.
(3)Research on heat-harm control
Through the deep study of heat-harm control in high temperature driving face, thecalculation formula of refrigerating capacity is deduced. The heat dissipating capacity ofheat source in driving face is calculated, and the cooling system has been designed andinstalled. The practice shows that the system is stable and reliable, and also has goodcooling effect and meets the design requirements absolutely. Through the PLC tocontrol the system, it can realize many kinds of protection function. Within the100mfrom the heading face, the temperature reduction range of dry bulb mean temperatureaverage is5.6℃, and the maximum is7.5℃.The wet bulb mean temperature is8.5℃,and the maximum is11℃, and the fall scope of the relative humidity is20%on average.YongChuan coal mine local refrigeration cooling system is successful, which verifiesthe rationality of the experiment and the theory in this paper. The refrigeration coolingsystem can be used as a demonstration of mine heat harm control, and it is worthy ofbeing used widely.
引文
[1] http://www.bp.com/bodycopyarticle.do?categoryId=1&contentId=7052055,StatisticalReview of World Energy2012.
[2]濮洪九.在中国煤炭学会2013年工作会上的讲话.
[3]谢和平,周宏伟,薛东杰等.煤炭深部开采与极限开采深度的研究与思考[J].煤炭学报,37(4),2012年4月:535-542.
[4]窦林名.深部开采冲击矿压防治研究[J].矿山压力与顶板管理,1003-5923(2003)S3-0058-03,2003NOS3:58.
[5]冀贞文,孙春江,姜福兴.波兰煤矿冲击地压防治技术现状及分析[J].煤炭科学技术,2008年1月第36卷第1期,13.
[6]毛节华,许惠龙.中国煤炭资源分布现状与远景预测[J].煤田地质,第三期,1999年6月:3.
[7]彭淑萍.深部煤炭资源赋存规律与开发地质评价研究现状及今后发展趋势[J].煤,第17卷第2期,总第100期,2008年2月:4.
[8]国家安全生产监督管理总局.煤矿安全规程[S].煤炭工业出版社,2010:21.
[9]国家安全生产监督管理总局.煤矿作业场所职业危害防治规定[S].煤炭工业出版社,2010.07:15.
[10]国务院.矿山安全条例[S].1982.02.
[11]杨德源,扬天鸿.矿井热环境及其控制[M].冶金工业出版社,2009.05:7-8.
[12] Malcolm J. McPherson. Subsurface Ventilation and Environmental Engineering [M].Kluwer Academic Publishers,1993.01.31:17-39,18-2,15-7-52,15-3-4,2-13.
[13]苗素军,辛嵩,彭蓬,等.矿井降温系统优选决策理论研究与应用[J].煤炭学报,2010,35(4):613-618.
[14]姬建虎.热害矿井围岩散热研究[C].第五届全国煤矿工业生产一线青年技术创新文集,煤炭工业出版社,2010.10:544.
[15]张国枢,谭允祯,陈开岩.通风安全学[M].中国矿业大学出版社,2000年7月第一版,2003.01:173,174,164,111,118-120.
[16]陈平.采用压气供冷的新型矿井集中空调系统[J].矿业安全与环保,2004,31(3):1-4.
[17]岑衍强,胡春胜,侯祺棕.井巷围岩与风流间不稳定换热系数的探讨[J].阜新矿业学院学报,第6卷第3期,1987年9月:107-112.
[18] A.H.舍尔巴尼,黄翰文译.矿井降温指南[M].煤炭工业出版社,1982年2月第一版,118-125.
[19] Goch, D.S, Patterson, H.S.Heat flow into tunnels. J.Chem.Metall. Min.Soc. S.Afr.41,1940:117–121.
[20] Gibson, K.L.Computer simulation of climate in mine airways. Ph.D.Thesis, University ofNottingham, UK,1976.
[21] McPherson, M.J. The analysis and simulation of heat flow into underground airways. Int.J. Min. Geol. Eng.4,1986:165–196.
[22] Voss, J. Mine Climate in Mechanised Drivages and Its Determination by AdvancedCalculation. Methane, Climate, Ventilation in the Coalminesof the European Communities,Vol.1. Colliery Guardian,1980:285–305.
[23] Voss, J. Prediction of climate in production workings. Gluckauf107,1971:412–418.
[24] Middleton, J.N. Computer simulation of the climate in underground production areas.Ph.D. Thesis, University of Nottingham, UK,1979.
[25] Longson, I., Tuck, M.A. The computer simulation of mine climate on a longwall coal face.In: P. Mousset-Jones, ed, Proceedings of2nd U.S. Mine Ventilation Symposium,A.A.Balkema, Rotterdam,1985:439–448.
[26] Gupta, M.L. Panigrahi,D.C., Banerjee, S.P. Heat flow studies in longwall faces inIndia. In: R. Bhaskar, ed., Proceedings of6th U.S. Mine Ventilation Symposium, SME,Littleton, CO,1993:421–427.
[27]岛田庄平等,掘进工作面局部通风降温的实验研究,《资源与素材》, No12,1990:725-729.
[28] Kertikov, V. Air temperature and humidity in dead-end headings with auxiliary ventilation.Proceedings of6th International Mine Ventilation Congress, SMME, Littleton, CO, USA,1997:269–276.
[29] Ross, A.J., Tuck, M.A., Stokes, M.R., Lowndes, I.S. Computer simulation of climaticconditions in rapid development drivages. In: Ramani R.V., ed., Proceedingsof6thInternational Mine Ventilation Congress, SME, Littleton, CO,1997:283–288.
[30] Ian S. Lowndesa,Amanda J. Crossley,Zhi-Yuan Yang. The ventilation and climatemodelling of rapid development tunnel drivages[J]. Tunnelling and Underground SpaceTechnology19(2004):139–150.
[31] I.S. Lowndes a, Z.Y. Yang a, S. Jobling b, C. Yates b. A parametric analysis of a tunnelclimatic prediction and planning model[J]. Tunnelling and Underground SpaceTechnology21(2006):520–532.
[32] D.M. Hargreaves,I.S. Lowndes. The computational modeling of the ventilation flowswithin a rapid development drivage [J]. Tunnelling and Underground Space Technology:22(2007)150–160.
[33] M. Onder, S. Sarac, E. Cevik. The influence of ventilation variables on the volume rate ofairflow delivered to the face of long drivages[J]. Tunnelling and Underground SpaceTechnology21(2006)568–574.
[34]秦跃平,秦凤华,徐国锋.制冷降温掘进工作面风温预测及需冷量计算[J].煤炭学报,第23卷第6期,1998年12月:611-615.
[35]李孜军,吴超,周勃.独头工作面通风降温新方法及效果分析[J].金属矿山,总第307期,2002年1月:51-53.
[36]吴超,王坪龙.一种用于金属矿山独头掘进面通风降温的新设施[J].中国矿业,l998年第7卷第2期:83-86.
[37]龙腾腾.高温独头巷道射流通风热环境数值模拟及热害控制技术研究[D].中南大学硕士学位论文,2008.
[38]王海桥,施式亮,刘荣华等.独头巷道附壁射流通风流场数值模拟研究[J].煤炭学报,第29期第4卷,2004年8月:425-428.
[39]王海桥,施式亮,刘荣华等.独头巷道射流通风流场CFD模拟研究[J].中国安全科学学报,13(1),2003年1月:68-71.
[40]王海桥.掘进工作面射流通风流场研究[J].煤炭学报,24(5),1999年10月:498-501.
[41]王福成,栗昌才,王英敏等.附壁射流通风工业试验研究[J].中国矿业,第23期,1996年1月:73-76.
[42]李刚,杨敏,黄儒钦.隧道施工环境中有限空间附壁射流的试验研究[J].西南交通大学学报,35(2),2000年4月:137-140.
[43]郭志武.隧道施工通风压入式风管管口射流射程计算方法探讨[J].隧道建设,23(5),2003年10月:42-45.
[44]汤民波.掘进工作面压入式通风风流流场数值模拟研究[D],江西理工大学硕士学位论文,2013.
[45]吴强,秦跃平,郭亮等.掘进工作面围岩散热的有限元计算[J].中国安全科学学报,第12卷第6期,2002年12月:33-36.
[46]宋桂梅,张朝昌.高温矿井独头掘进面降温技术研究与方案对比[J].矿业安全与环保.2006年2月,第33卷第1期:43-45.
[47]孟凡英,车广路.基于CFD技术的掘进巷道温度场模拟[J].中国科技信息,第24期,2009年:58-59.
[48]龙腾腾,周科平,陈庆发等.基于PMV指标的掘进巷道通风效果的数值模拟[J].安全与环境学报,第8卷第3期,2008年6月:122-125.
[49]周西华,王继仁,梁栋.掘进巷道风流温度场分布规律的研究[J].辽宁工程技术大学学报,第22卷第1期,2003年2月:1-3.
[50]周西华,王继仁,单亚飞,王树刚,粱栋.掘进巷道风流温度分布规律的数值模拟[J].中国安全科学学报,第12卷第2期,2002年4月:19-23.
[51]向立平,王汉青.压入式局部通风掘进巷道内热环境数值模拟研究[J].矿业工程研究,第24卷第4期,2009年12月:71-74.
[52]吴强,秦跃平,翟明华,张金峰.掘进巷道双风筒降温措施的研究[J].煤炭学报,第27卷第5期,2002年10月:499-502.
[53]高建良.巷道断面与风筒断面形状对局部通风工作面热环境模拟结果的影响[J].焦作工学院学报(自然科学版),第23卷,第1期,2004年1月:1-6.
[54]李艳波,黄寿元,李刚等.抽出式局部通风掘进面热环境数值模拟研究[J].中州煤炭,总第189期,2011年第9期:12-14.
[55]张艳利.局部通风掘进工作面换热系数计算方法研究[D].焦作,河南理工大学,2010:7-9.
[56]董志勇.射流力学[M].科学出版社,2005.03:5,33.
[57] Matin H. Heat and mass transfer between impinging gas jets and solid surface[M],Hartnett J P. Advances in heat transfer,1977,13:1-60.
[58] Goldstein RJ,Franchett ME. Heat transfer from a flat surface to an oblique impingingjet[J]. Trans ASME J Heat Transger,1988,110:84.
[59] Button BL,Jambunathan K. Impingemeng heat transfer-a bibliography1976-1985[J].Prev heat mass transfer,1989(15):149.
[60] Viskanta R. Heat transfer to impinging isothermal gas and flame jets[J]. Experimentthermal and fluid science,1993(6):111-134.
[61]徐惊雷,徐忠,肖敏,黄淑娟.冲击射流的研究概述[J].力学与实践,1999(21):8-16.
[62] N.Zuckerman, N.Lior. Jet impingement heat transfer:phusics,correlation and numericalmodeling[J]. Advance in heat transfer,2006(39):556-624.
[63] Awaru Deepti Dutt. Experimental study of impingment heat transfer at small jet to targetsurface distances[D]. Department of Mechanical and Industrial Engineering,NortheasternUniversity,Boston, Massachusetts,2010.05:1-50.
[64] B.Sagot, G.Antonini, A.Christgen, F.Buron. Jet impingement heat transfer on a flat plateat a constant wall temperature[J]. International Journal of Thermal Sciences,47(2008):1610-1619.
[65] M.Behnia,S.Parneix, Y.Shabany,P.A.Durbin. Numerical Study of turbulent heat transfer inconfined and unconfined imping jets[J]. International journal of heat and fluid flow,1999(20):1-9.
[66] Yongmann M.Chung, kai H.Luo. Unsteady heat transfer analysis of an impinging jet[J].Journal of heat transfer,2002.12(124):1039-1048.
[67] Peter R.Robertson, B.S. The design and validation of an impinging jet test facility[D].Graduate Faculty,Baylor University,2005.12.
[68]谭蕾,张靖周,杨卫华.半封闭肋话通道射流冲击换热特性的数值计算与实验验证[J].航空学报,Vol.29(5),2008,09:1105-1110.
[69]王明波,王瑞和.采用不同湍流模型对半封闭狭缝湍流冲击射流的数值模拟[J].中国石油大学学报,Vol34(4),2010.08:75-78.
[70]王明波,王瑞和.受限湍流冲击射流的数值模拟[J].石油钻探技术,Vol36(2),2008.03:7-9.
[71]陈庆光,徐忠,张永建.两种差分格式和两种湍流模型在轴对称冲击射流数值计算中的比较[J].空气动力学报,Vol21(1),2003.03:82-88.
[72]陈庆光,徐忠,张永建.用改进的RNG模式数值模拟湍流冲击射流数流动[J].西安交通大学学报,Vol.36(9),2002.09:916-920.
[73]张永恒,周勇,王良璧.原形冲击射流床热性能的实验研究[J].热科学与技术,Vol.5(1),2006.03:38-43.
[74]牛珏,温治,王俊升.圆形喷口紊流冲击射流流动与传热过程数值模拟[J].冶金能源,Vol.26(1),2007.06:16-20.
[75]许坤梅,张平.半封闭圆管冲击射流湍流换热数值模拟[J].北京理工大学学报,23(5),2003.10:540-544.
[76]张泽远,张靖周,杨卫华.半封闭通道射流冲击换热特性的实验[J].航空动力学报,21(4),2006.8:626-629.
[77]徐惊雷,徐忠,张堃元等.冲击高度对半封闭紊流冲击射流流场影响的实验研究[J].实验力学,15(5),2000.12:465-471.
[78]姬建虎.热害矿井围岩散热研究[C].第五届全国煤矿工业生产一线青年技术创新文集,煤炭工业出版社,2010.10:544.
[79]王海桥.掘进工作面射流通风流场研究[J].煤炭学报,1999,24(5):498-501.
[80]贾力,方肇洪,钱兴华.高等传热学[M].高等教育出版社,2003年3月第一版:119-121.
[81]吴望一.流体力学(上册).北京大学出版社,第一版,2004年10月:7,12.
[82]陶文铨.数值传热学[M].西安交通大学出版社,第二版,2001年5月:5.
[83]庄礼贤,尹协远,马晖扬.流体力学[M].中国科学技术大学出版社,第二版,2009年7月:407-408,429.
[84]丁祖荣.流体力学(中册),高等教育出版社,第一版,2003年12月:87.
[85] Realizable k-ε Model, ANSYS13.0/FLUENT/Theory Guide/4. Turbulence/4.3.Standard, RNG, and Realizable k-ε Models//4.3.3. Realizable k-ε Model.
[86]杨世铭,陶文铨.传热学[M].第四版,北京:高等教育出版社,2007:7,237,248-249,60,259-261.
[87] MT164-2007,煤矿用涂覆布正压风筒[S].2007:2.
[88]王丰.相似理论及其在传热学中的应用[M].高等教育出版社,1990年6月:155.
[89]杨强生,浦保荣.高等传热学[M].第二版,上海交通大学出版社,2001年7月:227.
[90]邓聚龙.灰色系统基本方法[M].武汉:华中科技大学出版社,1987.
[91]邓聚龙.灰色系统控制[M].武汉:华中科技大学出版社,1993.
[92]易德生,郭萍.灰色理论与方法[M].石油工业出版社,1992.
[93]中国科学院地质研究所地热组,矿山地热研究及矿山地温类型划分[D].地热研究论文集,科学出版社,1978.11:45-65.
[94]邓效.改进的矿山地温类型划分[J].地质科学,第一期,1990.01:81-86.
[95]煤矿矿井采矿设计手册编写组.煤矿矿井采矿设计手册[M].下册,煤炭工业出版社,1984.04:818.
[96]张荣立,何国伟,李铎.采矿工程设计手册[M].下册,煤炭工业出版社,2008.10:3628-3645.
[97]余恒昌,邓孝,陈碧琬.矿山地热与热害治理[M].煤炭工业出版社出版,1991.7:281,357.
[98]曾丹苓,敖越,张新铭,刘朝.工程热力学[M].第3版,北京:高等教育出版社,2006.5:46,185.
[99]沈维道,童均耕.工程热力学[M].第4版,北京:高等教育出版社,2010.9:44.
[100]姬建虎,黄华良,张习军等.永川煤矿-600米水平开采安全技术研究[R].2008.12:59-99.
[101]黄华良,文光才,姬建虎等.永川煤矿-700m水平地温防治技术研究[R].2011.11.
[102]董天禄,华小龙,姚国琦等.离心式/螺杆式制冷机组的应用[M].机械工业出版社,2002.01:228,219,239.
[103]余建祖.换热器原理与设计[M].北京航空航天大学出版社,第一版.2006.01:131,116-118.
[104]常用物质物性计算和查询平台. http://www.ap1700.com.
[105]吴业正,朱瑞琪,曹小林等.制冷原理及设备[M].第3版,西安交通大学出版社,2011.07:30,214-215,182-185.
[106] GB151-1999.管壳式换热器[S],北京:中国标准出版社,2000.12:127,22-23,18,126-129,138-142,73-74.
[107]刘巍,邓方义等.冷换设备工艺计算手册[M].中国石化出版社,2008.07:5,86.
[108]钱颂文.换热器设计手册[M],第1版,化学工业出版社,2002.08:1-5,56,179-189,142,66-67,136-137,157,25,115.
[109] GB/T9123.1-2000.平面、突面钢制管法兰盖[S],北京:中国标准出版社,2005.02:2.
[110]吴业正.小型制冷装置设计指导[M],机械工业出版社,1999.06:117-118.
[111]兰州石油机械研究所.换热器[M],中国石化出版社,2013.01:1763,1777-1779,1272-1275,573,1288-1290,1311-1312.
[112] JB/T7659.2-2011.氟代烃类制冷装置用辅助设备[S],第2部分,管壳式水冷冷凝器,机械工业出版社,2012.05:2.
[113]文向南.圆柱形容器封头选择[J],石油化工设备,第28卷第4期,1997.08.
[114]郑津洋,董其伍,桑芝富.过程设备设计[M].第三版,化学工业出版社,2013.01:127.
[115] GB/T25198-2010.压力容器封头[S],北京:中国标准出版社,2011.01:3.
[116]廖强,朱峋,辛明道.水平三维肋管管外凝结换热实验与分析(I实验研究)[J].工程热物理学报,2004.01:103.
[117]彦启森,石文星,田长青.空气调节用制冷技术[M],第四版,中国建筑工业出版社,2010.07.01:90-97.
[118]彦启森,申江,石文星.制冷技术及其应用[M],中国建筑工业出版社,2006.06:198.
[119]孔绍康.多头螺旋盘管发生器换热特性研究[D],大连理工大学硕士学位论文,2013.05:2.
[120]来逢逢. R134a螺旋管内沸腾传热模拟研究[D],山东大学硕士学位论文,2006.05.18:1.
[121]孙宗保. R134a螺旋管内沸腾换热特性研究[D],山东大学硕士学位论文,2007.05.14:2.
[122]窦鹏程. R134a在卧式螺旋管内单相流动和过冷流动沸腾换热特性研究[D],山东大学硕士学位论文,2012.05.20:2.
[123]陈文文. R134a在卧式螺旋管内的沸腾换热特性与临界热流密度特性研究[D],山东大学硕士学位论文,2010.05.20:3.
[124]邵莉. R134a在卧式螺旋管内的两相流动与传热特性研究[D],山东大学博士学位论文,2009.04.11:1-2.
[125]陈常念.卧式螺旋管内临界热流密度特性及其流体模化方法研究[D],山东大学博士学位论文,2010.10.10:3.
[126]廖全.三维微肋螺旋管内的两相流动与沸腾传热[D],重庆大学硕士学位论文,2002.5:5-6.
[127]崔文智.三维微肋螺旋管内流动沸腾传热与流型[D],重庆大学博士学位论文,2003.10:4-5.
[128]王志国.螺旋管气液两相流数值模拟[D],中国石油大学硕士学位论文,2007.4:1.
[129]朱建国,仇性启.螺旋管技术研究[J],热能工程工业加热,33(1),2004年:13.
[130]王林,崔廷,孙翠霞等.微型螺旋管蒸发器的沸腾换热与阻力特性实验研究[J],节能,总第287期,2006年第6期:4.
[131]邵莉,许之初,韩吉田等.卧式螺旋管内R134a沸腾两相传热特性实验研究[J],中国电机工程学报,第31卷第8期,2011年3月15日:62.
[132]李隆键,崔文智,辛明道.螺旋管内单相及沸腾的强化换热与阻力特性实验[J].核动力工程,第26卷第1期,2005.02:6.
[133]马义伟.空冷器设计及应用[M].哈尔滨工业大学出版社,第一版,1998.12:75.
[2]濮洪九.在中国煤炭学会2013年工作会上的讲话.
[3]谢和平,周宏伟,薛东杰等.煤炭深部开采与极限开采深度的研究与思考[J].煤炭学报,37(4),2012年4月:535-542.
[4]窦林名.深部开采冲击矿压防治研究[J].矿山压力与顶板管理,1003-5923(2003)S3-0058-03,2003NOS3:58.
[5]冀贞文,孙春江,姜福兴.波兰煤矿冲击地压防治技术现状及分析[J].煤炭科学技术,2008年1月第36卷第1期,13.
[6]毛节华,许惠龙.中国煤炭资源分布现状与远景预测[J].煤田地质,第三期,1999年6月:3.
[7]彭淑萍.深部煤炭资源赋存规律与开发地质评价研究现状及今后发展趋势[J].煤,第17卷第2期,总第100期,2008年2月:4.
[8]国家安全生产监督管理总局.煤矿安全规程[S].煤炭工业出版社,2010:21.
[9]国家安全生产监督管理总局.煤矿作业场所职业危害防治规定[S].煤炭工业出版社,2010.07:15.
[10]国务院.矿山安全条例[S].1982.02.
[11]杨德源,扬天鸿.矿井热环境及其控制[M].冶金工业出版社,2009.05:7-8.
[12] Malcolm J. McPherson. Subsurface Ventilation and Environmental Engineering [M].Kluwer Academic Publishers,1993.01.31:17-39,18-2,15-7-52,15-3-4,2-13.
[13]苗素军,辛嵩,彭蓬,等.矿井降温系统优选决策理论研究与应用[J].煤炭学报,2010,35(4):613-618.
[14]姬建虎.热害矿井围岩散热研究[C].第五届全国煤矿工业生产一线青年技术创新文集,煤炭工业出版社,2010.10:544.
[15]张国枢,谭允祯,陈开岩.通风安全学[M].中国矿业大学出版社,2000年7月第一版,2003.01:173,174,164,111,118-120.
[16]陈平.采用压气供冷的新型矿井集中空调系统[J].矿业安全与环保,2004,31(3):1-4.
[17]岑衍强,胡春胜,侯祺棕.井巷围岩与风流间不稳定换热系数的探讨[J].阜新矿业学院学报,第6卷第3期,1987年9月:107-112.
[18] A.H.舍尔巴尼,黄翰文译.矿井降温指南[M].煤炭工业出版社,1982年2月第一版,118-125.
[19] Goch, D.S, Patterson, H.S.Heat flow into tunnels. J.Chem.Metall. Min.Soc. S.Afr.41,1940:117–121.
[20] Gibson, K.L.Computer simulation of climate in mine airways. Ph.D.Thesis, University ofNottingham, UK,1976.
[21] McPherson, M.J. The analysis and simulation of heat flow into underground airways. Int.J. Min. Geol. Eng.4,1986:165–196.
[22] Voss, J. Mine Climate in Mechanised Drivages and Its Determination by AdvancedCalculation. Methane, Climate, Ventilation in the Coalminesof the European Communities,Vol.1. Colliery Guardian,1980:285–305.
[23] Voss, J. Prediction of climate in production workings. Gluckauf107,1971:412–418.
[24] Middleton, J.N. Computer simulation of the climate in underground production areas.Ph.D. Thesis, University of Nottingham, UK,1979.
[25] Longson, I., Tuck, M.A. The computer simulation of mine climate on a longwall coal face.In: P. Mousset-Jones, ed, Proceedings of2nd U.S. Mine Ventilation Symposium,A.A.Balkema, Rotterdam,1985:439–448.
[26] Gupta, M.L. Panigrahi,D.C., Banerjee, S.P. Heat flow studies in longwall faces inIndia. In: R. Bhaskar, ed., Proceedings of6th U.S. Mine Ventilation Symposium, SME,Littleton, CO,1993:421–427.
[27]岛田庄平等,掘进工作面局部通风降温的实验研究,《资源与素材》, No12,1990:725-729.
[28] Kertikov, V. Air temperature and humidity in dead-end headings with auxiliary ventilation.Proceedings of6th International Mine Ventilation Congress, SMME, Littleton, CO, USA,1997:269–276.
[29] Ross, A.J., Tuck, M.A., Stokes, M.R., Lowndes, I.S. Computer simulation of climaticconditions in rapid development drivages. In: Ramani R.V., ed., Proceedingsof6thInternational Mine Ventilation Congress, SME, Littleton, CO,1997:283–288.
[30] Ian S. Lowndesa,Amanda J. Crossley,Zhi-Yuan Yang. The ventilation and climatemodelling of rapid development tunnel drivages[J]. Tunnelling and Underground SpaceTechnology19(2004):139–150.
[31] I.S. Lowndes a, Z.Y. Yang a, S. Jobling b, C. Yates b. A parametric analysis of a tunnelclimatic prediction and planning model[J]. Tunnelling and Underground SpaceTechnology21(2006):520–532.
[32] D.M. Hargreaves,I.S. Lowndes. The computational modeling of the ventilation flowswithin a rapid development drivage [J]. Tunnelling and Underground Space Technology:22(2007)150–160.
[33] M. Onder, S. Sarac, E. Cevik. The influence of ventilation variables on the volume rate ofairflow delivered to the face of long drivages[J]. Tunnelling and Underground SpaceTechnology21(2006)568–574.
[34]秦跃平,秦凤华,徐国锋.制冷降温掘进工作面风温预测及需冷量计算[J].煤炭学报,第23卷第6期,1998年12月:611-615.
[35]李孜军,吴超,周勃.独头工作面通风降温新方法及效果分析[J].金属矿山,总第307期,2002年1月:51-53.
[36]吴超,王坪龙.一种用于金属矿山独头掘进面通风降温的新设施[J].中国矿业,l998年第7卷第2期:83-86.
[37]龙腾腾.高温独头巷道射流通风热环境数值模拟及热害控制技术研究[D].中南大学硕士学位论文,2008.
[38]王海桥,施式亮,刘荣华等.独头巷道附壁射流通风流场数值模拟研究[J].煤炭学报,第29期第4卷,2004年8月:425-428.
[39]王海桥,施式亮,刘荣华等.独头巷道射流通风流场CFD模拟研究[J].中国安全科学学报,13(1),2003年1月:68-71.
[40]王海桥.掘进工作面射流通风流场研究[J].煤炭学报,24(5),1999年10月:498-501.
[41]王福成,栗昌才,王英敏等.附壁射流通风工业试验研究[J].中国矿业,第23期,1996年1月:73-76.
[42]李刚,杨敏,黄儒钦.隧道施工环境中有限空间附壁射流的试验研究[J].西南交通大学学报,35(2),2000年4月:137-140.
[43]郭志武.隧道施工通风压入式风管管口射流射程计算方法探讨[J].隧道建设,23(5),2003年10月:42-45.
[44]汤民波.掘进工作面压入式通风风流流场数值模拟研究[D],江西理工大学硕士学位论文,2013.
[45]吴强,秦跃平,郭亮等.掘进工作面围岩散热的有限元计算[J].中国安全科学学报,第12卷第6期,2002年12月:33-36.
[46]宋桂梅,张朝昌.高温矿井独头掘进面降温技术研究与方案对比[J].矿业安全与环保.2006年2月,第33卷第1期:43-45.
[47]孟凡英,车广路.基于CFD技术的掘进巷道温度场模拟[J].中国科技信息,第24期,2009年:58-59.
[48]龙腾腾,周科平,陈庆发等.基于PMV指标的掘进巷道通风效果的数值模拟[J].安全与环境学报,第8卷第3期,2008年6月:122-125.
[49]周西华,王继仁,梁栋.掘进巷道风流温度场分布规律的研究[J].辽宁工程技术大学学报,第22卷第1期,2003年2月:1-3.
[50]周西华,王继仁,单亚飞,王树刚,粱栋.掘进巷道风流温度分布规律的数值模拟[J].中国安全科学学报,第12卷第2期,2002年4月:19-23.
[51]向立平,王汉青.压入式局部通风掘进巷道内热环境数值模拟研究[J].矿业工程研究,第24卷第4期,2009年12月:71-74.
[52]吴强,秦跃平,翟明华,张金峰.掘进巷道双风筒降温措施的研究[J].煤炭学报,第27卷第5期,2002年10月:499-502.
[53]高建良.巷道断面与风筒断面形状对局部通风工作面热环境模拟结果的影响[J].焦作工学院学报(自然科学版),第23卷,第1期,2004年1月:1-6.
[54]李艳波,黄寿元,李刚等.抽出式局部通风掘进面热环境数值模拟研究[J].中州煤炭,总第189期,2011年第9期:12-14.
[55]张艳利.局部通风掘进工作面换热系数计算方法研究[D].焦作,河南理工大学,2010:7-9.
[56]董志勇.射流力学[M].科学出版社,2005.03:5,33.
[57] Matin H. Heat and mass transfer between impinging gas jets and solid surface[M],Hartnett J P. Advances in heat transfer,1977,13:1-60.
[58] Goldstein RJ,Franchett ME. Heat transfer from a flat surface to an oblique impingingjet[J]. Trans ASME J Heat Transger,1988,110:84.
[59] Button BL,Jambunathan K. Impingemeng heat transfer-a bibliography1976-1985[J].Prev heat mass transfer,1989(15):149.
[60] Viskanta R. Heat transfer to impinging isothermal gas and flame jets[J]. Experimentthermal and fluid science,1993(6):111-134.
[61]徐惊雷,徐忠,肖敏,黄淑娟.冲击射流的研究概述[J].力学与实践,1999(21):8-16.
[62] N.Zuckerman, N.Lior. Jet impingement heat transfer:phusics,correlation and numericalmodeling[J]. Advance in heat transfer,2006(39):556-624.
[63] Awaru Deepti Dutt. Experimental study of impingment heat transfer at small jet to targetsurface distances[D]. Department of Mechanical and Industrial Engineering,NortheasternUniversity,Boston, Massachusetts,2010.05:1-50.
[64] B.Sagot, G.Antonini, A.Christgen, F.Buron. Jet impingement heat transfer on a flat plateat a constant wall temperature[J]. International Journal of Thermal Sciences,47(2008):1610-1619.
[65] M.Behnia,S.Parneix, Y.Shabany,P.A.Durbin. Numerical Study of turbulent heat transfer inconfined and unconfined imping jets[J]. International journal of heat and fluid flow,1999(20):1-9.
[66] Yongmann M.Chung, kai H.Luo. Unsteady heat transfer analysis of an impinging jet[J].Journal of heat transfer,2002.12(124):1039-1048.
[67] Peter R.Robertson, B.S. The design and validation of an impinging jet test facility[D].Graduate Faculty,Baylor University,2005.12.
[68]谭蕾,张靖周,杨卫华.半封闭肋话通道射流冲击换热特性的数值计算与实验验证[J].航空学报,Vol.29(5),2008,09:1105-1110.
[69]王明波,王瑞和.采用不同湍流模型对半封闭狭缝湍流冲击射流的数值模拟[J].中国石油大学学报,Vol34(4),2010.08:75-78.
[70]王明波,王瑞和.受限湍流冲击射流的数值模拟[J].石油钻探技术,Vol36(2),2008.03:7-9.
[71]陈庆光,徐忠,张永建.两种差分格式和两种湍流模型在轴对称冲击射流数值计算中的比较[J].空气动力学报,Vol21(1),2003.03:82-88.
[72]陈庆光,徐忠,张永建.用改进的RNG模式数值模拟湍流冲击射流数流动[J].西安交通大学学报,Vol.36(9),2002.09:916-920.
[73]张永恒,周勇,王良璧.原形冲击射流床热性能的实验研究[J].热科学与技术,Vol.5(1),2006.03:38-43.
[74]牛珏,温治,王俊升.圆形喷口紊流冲击射流流动与传热过程数值模拟[J].冶金能源,Vol.26(1),2007.06:16-20.
[75]许坤梅,张平.半封闭圆管冲击射流湍流换热数值模拟[J].北京理工大学学报,23(5),2003.10:540-544.
[76]张泽远,张靖周,杨卫华.半封闭通道射流冲击换热特性的实验[J].航空动力学报,21(4),2006.8:626-629.
[77]徐惊雷,徐忠,张堃元等.冲击高度对半封闭紊流冲击射流流场影响的实验研究[J].实验力学,15(5),2000.12:465-471.
[78]姬建虎.热害矿井围岩散热研究[C].第五届全国煤矿工业生产一线青年技术创新文集,煤炭工业出版社,2010.10:544.
[79]王海桥.掘进工作面射流通风流场研究[J].煤炭学报,1999,24(5):498-501.
[80]贾力,方肇洪,钱兴华.高等传热学[M].高等教育出版社,2003年3月第一版:119-121.
[81]吴望一.流体力学(上册).北京大学出版社,第一版,2004年10月:7,12.
[82]陶文铨.数值传热学[M].西安交通大学出版社,第二版,2001年5月:5.
[83]庄礼贤,尹协远,马晖扬.流体力学[M].中国科学技术大学出版社,第二版,2009年7月:407-408,429.
[84]丁祖荣.流体力学(中册),高等教育出版社,第一版,2003年12月:87.
[85] Realizable k-ε Model, ANSYS13.0/FLUENT/Theory Guide/4. Turbulence/4.3.Standard, RNG, and Realizable k-ε Models//4.3.3. Realizable k-ε Model.
[86]杨世铭,陶文铨.传热学[M].第四版,北京:高等教育出版社,2007:7,237,248-249,60,259-261.
[87] MT164-2007,煤矿用涂覆布正压风筒[S].2007:2.
[88]王丰.相似理论及其在传热学中的应用[M].高等教育出版社,1990年6月:155.
[89]杨强生,浦保荣.高等传热学[M].第二版,上海交通大学出版社,2001年7月:227.
[90]邓聚龙.灰色系统基本方法[M].武汉:华中科技大学出版社,1987.
[91]邓聚龙.灰色系统控制[M].武汉:华中科技大学出版社,1993.
[92]易德生,郭萍.灰色理论与方法[M].石油工业出版社,1992.
[93]中国科学院地质研究所地热组,矿山地热研究及矿山地温类型划分[D].地热研究论文集,科学出版社,1978.11:45-65.
[94]邓效.改进的矿山地温类型划分[J].地质科学,第一期,1990.01:81-86.
[95]煤矿矿井采矿设计手册编写组.煤矿矿井采矿设计手册[M].下册,煤炭工业出版社,1984.04:818.
[96]张荣立,何国伟,李铎.采矿工程设计手册[M].下册,煤炭工业出版社,2008.10:3628-3645.
[97]余恒昌,邓孝,陈碧琬.矿山地热与热害治理[M].煤炭工业出版社出版,1991.7:281,357.
[98]曾丹苓,敖越,张新铭,刘朝.工程热力学[M].第3版,北京:高等教育出版社,2006.5:46,185.
[99]沈维道,童均耕.工程热力学[M].第4版,北京:高等教育出版社,2010.9:44.
[100]姬建虎,黄华良,张习军等.永川煤矿-600米水平开采安全技术研究[R].2008.12:59-99.
[101]黄华良,文光才,姬建虎等.永川煤矿-700m水平地温防治技术研究[R].2011.11.
[102]董天禄,华小龙,姚国琦等.离心式/螺杆式制冷机组的应用[M].机械工业出版社,2002.01:228,219,239.
[103]余建祖.换热器原理与设计[M].北京航空航天大学出版社,第一版.2006.01:131,116-118.
[104]常用物质物性计算和查询平台. http://www.ap1700.com.
[105]吴业正,朱瑞琪,曹小林等.制冷原理及设备[M].第3版,西安交通大学出版社,2011.07:30,214-215,182-185.
[106] GB151-1999.管壳式换热器[S],北京:中国标准出版社,2000.12:127,22-23,18,126-129,138-142,73-74.
[107]刘巍,邓方义等.冷换设备工艺计算手册[M].中国石化出版社,2008.07:5,86.
[108]钱颂文.换热器设计手册[M],第1版,化学工业出版社,2002.08:1-5,56,179-189,142,66-67,136-137,157,25,115.
[109] GB/T9123.1-2000.平面、突面钢制管法兰盖[S],北京:中国标准出版社,2005.02:2.
[110]吴业正.小型制冷装置设计指导[M],机械工业出版社,1999.06:117-118.
[111]兰州石油机械研究所.换热器[M],中国石化出版社,2013.01:1763,1777-1779,1272-1275,573,1288-1290,1311-1312.
[112] JB/T7659.2-2011.氟代烃类制冷装置用辅助设备[S],第2部分,管壳式水冷冷凝器,机械工业出版社,2012.05:2.
[113]文向南.圆柱形容器封头选择[J],石油化工设备,第28卷第4期,1997.08.
[114]郑津洋,董其伍,桑芝富.过程设备设计[M].第三版,化学工业出版社,2013.01:127.
[115] GB/T25198-2010.压力容器封头[S],北京:中国标准出版社,2011.01:3.
[116]廖强,朱峋,辛明道.水平三维肋管管外凝结换热实验与分析(I实验研究)[J].工程热物理学报,2004.01:103.
[117]彦启森,石文星,田长青.空气调节用制冷技术[M],第四版,中国建筑工业出版社,2010.07.01:90-97.
[118]彦启森,申江,石文星.制冷技术及其应用[M],中国建筑工业出版社,2006.06:198.
[119]孔绍康.多头螺旋盘管发生器换热特性研究[D],大连理工大学硕士学位论文,2013.05:2.
[120]来逢逢. R134a螺旋管内沸腾传热模拟研究[D],山东大学硕士学位论文,2006.05.18:1.
[121]孙宗保. R134a螺旋管内沸腾换热特性研究[D],山东大学硕士学位论文,2007.05.14:2.
[122]窦鹏程. R134a在卧式螺旋管内单相流动和过冷流动沸腾换热特性研究[D],山东大学硕士学位论文,2012.05.20:2.
[123]陈文文. R134a在卧式螺旋管内的沸腾换热特性与临界热流密度特性研究[D],山东大学硕士学位论文,2010.05.20:3.
[124]邵莉. R134a在卧式螺旋管内的两相流动与传热特性研究[D],山东大学博士学位论文,2009.04.11:1-2.
[125]陈常念.卧式螺旋管内临界热流密度特性及其流体模化方法研究[D],山东大学博士学位论文,2010.10.10:3.
[126]廖全.三维微肋螺旋管内的两相流动与沸腾传热[D],重庆大学硕士学位论文,2002.5:5-6.
[127]崔文智.三维微肋螺旋管内流动沸腾传热与流型[D],重庆大学博士学位论文,2003.10:4-5.
[128]王志国.螺旋管气液两相流数值模拟[D],中国石油大学硕士学位论文,2007.4:1.
[129]朱建国,仇性启.螺旋管技术研究[J],热能工程工业加热,33(1),2004年:13.
[130]王林,崔廷,孙翠霞等.微型螺旋管蒸发器的沸腾换热与阻力特性实验研究[J],节能,总第287期,2006年第6期:4.
[131]邵莉,许之初,韩吉田等.卧式螺旋管内R134a沸腾两相传热特性实验研究[J],中国电机工程学报,第31卷第8期,2011年3月15日:62.
[132]李隆键,崔文智,辛明道.螺旋管内单相及沸腾的强化换热与阻力特性实验[J].核动力工程,第26卷第1期,2005.02:6.
[133]马义伟.空冷器设计及应用[M].哈尔滨工业大学出版社,第一版,1998.12:75.