水泥熟料堆积体渗流换热的管道等效模型研究
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摘要
本文将管道流动换热理论与多孔介质达西渗流理论结合,建立了具有多孔介质特性的熟料颗粒堆积体渗流换热的等效管道换热物理模型,推导了熟料颗粒堆积体的多孔介质参数与等效管道参数的对应关系,并通过数值仿真计算,给出了等效管道模型的管直径、管内气体流速、管数量随熟料颗粒直径与熟料单元体孔隙率的变化曲线,为堆积颗粒多孔介质的简化提供了理论方法与等效数据。
Based on the combination of porous media's Darcy seepage theory and the pipe's flow heat transfer theory,the seepage and heat transfer process of clinker particles accumulation body that with porous media characteristic can be equivalent to the heat transfer model of pipe. Then the congruent relationship between the porous media parameters and the equivalent pipe parameters is structured. By numerical simulation,the pipe diameter,gas velocity inside the pipe as well as the pipe number of the equivalent pipe model is calculated. With the changing curve of clinker particles diameter and the clinker unit body porosity,the theoretical method and equivalent data are provided for the simplification of the accumulation particles porous media.
Based on the combination of porous media's Darcy seepage theory and the pipe's flow heat transfer theory,the seepage and heat transfer process of clinker particles accumulation body that with porous media characteristic can be equivalent to the heat transfer model of pipe. Then the congruent relationship between the porous media parameters and the equivalent pipe parameters is structured. By numerical simulation,the pipe diameter,gas velocity inside the pipe as well as the pipe number of the equivalent pipe model is calculated. With the changing curve of clinker particles diameter and the clinker unit body porosity,the theoretical method and equivalent data are provided for the simplification of the accumulation particles porous media.
引文
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[8]陈强,杨静宇,董涛,等.微管道换热器多孔介质模型分析及应用[J].机械工程学报,2004,40(4):108-113.
[9]赵军,戴传山,刘启梁.多孔介质层内同轴管式井下换热器的相似解[J].太阳能学报,2000,21(3):274-278.
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[11]王荣华,章青,夏晓舟.含裂隙饱和多孔介质流-固耦合的扩展有限元分析[J].岩土力学,2017,38(5):1-9.
[12]孔祥言.高等渗流力学[M].合肥:中国科学技术大学出版社,2010:30-31.
[13]田兴旺,王平,徐士鸣.颗粒堆积多孔介质内幂律流体的流动阻力特性[J].哈尔滨工业大学学报,2017,49(1):126-132.
[2]尹洪超,朱元师,李德付.基于耦合气固传热篦冷机的数值模拟与研究[J].热科学与技术,2012,11(3):229-233.
[3]李德付.水泥回转窑和篦冷机内气固两相流及换热过程的数值研究[D].大连:大连理工大学,2013.
[4]刘彬,岳海龙,闻岩.基于变长度单元的水泥熟料渗流换热模型研究[J].燕山大学学报,2013,37(3):234-239.
[5]WANG M Q,LIU B,WEN Y,et al.Numerical simulation and analytical characterization of heat transfer between cement clinker and air in grate cooler[J].Journal of Chemical Engineering of Japan,2016,49(1):10-15.
[6]张少方,杨泽亮.管内单相对流强化换热及阻力特性的实验研究[J].节能,1997(8):14-17.
[7]杨茉,周方,赵婷,等.管内变密度流体流动与换热的充分发展与解析解[J].工程热物理学报,2008,29(7):1199-1201.
[8]陈强,杨静宇,董涛,等.微管道换热器多孔介质模型分析及应用[J].机械工程学报,2004,40(4):108-113.
[9]赵军,戴传山,刘启梁.多孔介质层内同轴管式井下换热器的相似解[J].太阳能学报,2000,21(3):274-278.
[10]邓斌,李欣,陶文铨.多孔介质模型在管壳式换热器数值模拟中的应用[J].工程热物理学报,2004,25(S1):167-169.
[11]王荣华,章青,夏晓舟.含裂隙饱和多孔介质流-固耦合的扩展有限元分析[J].岩土力学,2017,38(5):1-9.
[12]孔祥言.高等渗流力学[M].合肥:中国科学技术大学出版社,2010:30-31.
[13]田兴旺,王平,徐士鸣.颗粒堆积多孔介质内幂律流体的流动阻力特性[J].哈尔滨工业大学学报,2017,49(1):126-132.
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