高温熟料非稳态非热平衡渗流换热模型

doi:10.3969/j.issn.1000-1158.2019.03.14

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摘要回转窑卸入篦冷机的高温水泥熟料为红热半透明的多孔介质,其复杂的气固换热机理给篦冷机的工艺改进带来较大难度。针对这一问题,将高温红热颗粒等效为光学厚介质,推导了一种高温熟料颗粒间传导与辐射综合换热系数,基于渗流力学与传热学理论,建立了考虑高温熟料颗粒间热辐射效应的水泥熟料非稳态非热平衡渗流换热模型。通过对所建模型进行求解,得到了料层内熟料温度与气体温度的分布规律,比较了不同区域冷却速率的差异,获得了辐射传热因素对料层温度分布的影响。

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	王美琪
	陈恩利
	郭文武
	刘鹏飞
	戚壮
	侯爽

关键词 ：计量学, 渗流换热, 水泥熟料, 篦冷机, 多孔介质, 热辐射

Abstract：The high temperature cement clinker can be regarded as glowing red and translucent porous media when it is discharged from rotary kiln to grate cooler. It brings greater difficulty to technology improvement of grate cooler since the gas-solid heat transfer mechanism is complex. According to the problem, the glowing red particle can be equivalent to optically thick medium, then an integrated heat transfer coefficient is derived for high temperature clinker particle when heat conducting and thermal radiating. Based on the seepage mechanics and heat transfer theory, an unsteady seepage heat transfer model with thermal non-equilibrium of cement clinker is built which considering the heat radiation effect between the high temperature clinker particle. By solving the model, the distribution of clinker temperature and gas temperature inside the material layer are obtained, at the same time, the difference of cooling rates in different regions are compared to gain the impact of radiation heat transfer factor on the material layer temperature distribution.

Key words： metrology seepage heat transfer;cement clinker grate cooler porous media thermal radiation

收稿日期: 2018-01-02 发布日期: 2019-04-19

PACS:

TB941

基金资助:国家重点研发计划(2017YFC0704003);国家自然科学基金(51641609);河北省高等学校科学技术研究(BJ2016047,BJ2017001);河北省教育厅青年基金(QN2016182)

通讯作者: 王美琪 E-mail: wangmeiqi@stdu.edu.cn

作者简介: 王美琪(1988-),河北唐山人,石家庄铁道大学讲师,博士,研究方向为多孔介质传热传质、非线性动力学。Email:wangmeiqi@stdu.edu.cn

引用本文:

王美琪,陈恩利,郭文武,刘鹏飞,戚壮,侯爽. 高温熟料非稳态非热平衡渗流换热模型[J]. 计量学报, 2019, 40(3): 432-439.
WANG Mei-qi,CHEN En-li,GUO Wen-wu,LIU Peng-fei,QI Zhuang,HOU Shuang. Seepage Heat Transfer Model with Thermal Non-equilibrium of High Temperature Clinker. Acta Metrologica Sinica, 2019, 40(3): 432-439.

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［1］Afkhami B, Akbarian B, Beheshti A N, et al. Energy consumption assessment in a cement production plant［J］. Sustainable Energy Technologies and Assessments, 2015, 10:84-89.
［2］卢小丰, 原遵东, 董伟, 等. 应用高温固定点校准精密光电高温计［J］. 计量学报, 2017, 38(5): 584-588.
Lu X F, Yuan Z D, Dong W, et al. Calibrating pyrometers with high temperature fixed points［J］. Acta Metrologica Sinca, 2017,38(5):584-588.
［3］王烨, 杨立. 高温管道内流体流量及温度识别研究［J］. 计量学报, 2017,38(4): 477-480.
Wang Y, Yang L. Research on identification of flow rate and temperature in the high temperature pipeline［J］. Acta Metrologica Sinca,2017,38(4): 477-480.
［4］Locher G, Klein H. Mathematical models for the cement clinker burning process, Part4. Grate cooler［J］. ZKG-International,2002,22(6):46-57.
［5］Touil D, Belabed H F, Frances C, et al. Heat exchange modeling of a grate clinker cooler and entropy production analysis［J］. International Journal of Heat and Technology, 2005,23(1):61-68.
［6］Mujumdar K S, Ganesh K V, Kulkarni S B, et al. Rotary cement kiln simulator (RoCKS): Integrated modeling of pre-heater, calciner, kiln and clinker cooler［J］. Chemical Engineering Science, 2007,62(9):2590-2607.
［7］冯绍航, 徐德龙, 李辉, 等. 篦冷机中气固两相换热过程的模拟研究［J］. 西安建筑科技大学学报, 2007,39(2):224-234.
Feng S H, Xu D L, Li H, et al. Simulation study on heat transfer between clinker and gas of the grate cooler［J］. Journal of Xian University of Architecture and Technology, 2007,39(2):224-234.
［8］刘彬, 郝晓辰. 篦冷机熟料多通道冷却气固热交换模型研究［J］. 硅酸盐通报, 2008, 27(2): 247-253.
Liu B, Hao X C. Research on gas-solid heat exchange model of clinker grate cooler［J］. Bulletin of the Chinese Ceramic Society,2008,27(2):247-253.
［9］刘彬,刘永记,刘浩然,等. 基于改进遗传爬山算法的篦冷机熟料换热二次风温故障诊断［J］. 计量学报, 2018,39(5):651-658.
Liu B, Liu Y J, Liu H R, et al. Fault Diagnosis of Secondary Air Temperature of Grate Cooler Cement
Clinker Heat Transfer Based on Improved Genetic Hill Climbing Algorithm［J］. Acta Metrologica Sinica, 2018,39(5):651-658.

［10］郑坤灿, 温治, 刘训良, 等. 高温散料气-固换热过程通用数学模型的研究［J］. 冶金能源,2010,29(2):27-30.
Zheng K C, Wen Z, Liu X L, et al. Investigating the general mathematics model of gas-solid heat transfer in the cooling process of high temperature clinker and sintered material［J］. Energy for Metallurgical Industry,2010,29(2):27-30.
［11］闻岩, 王佳顺, 岳海龙, 等. 篦冷机熟料多孔介质直管等效换热模型［J］. 化工学报,2014,65(9):3434-3440.
Wen Y, Wang J S, Yue H L, et al. Equivalent straight pipe heat transfer model of cement clinker porous media in grate cooler［J］. Journal of Chemical Industry and Engineering,2014, 65(9):3434-3440.
［12］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.
Yin H C, Zhu Y S, Li D F. Numerical simulation and study of clinker cooler based on coupling of gas-solid heat transfer［J］. Journal of Thermal Science and Technology,2012,11(3):229-233.
［13］Wang M Q, Liu B, Wen Y, et al. Seepage Heat Transfer Between Clinker and Cooling Air with Variable Properties in Grate Cooler［J］.Heat Transfer Research,2017,48(3): 263-281.
［14］罗峰, 欧阳小龙, 高诚,等. 空气与高温烧结水泥颗粒球间气固换热规律研究［J］. 工程热物理学报,2012, 33(9):1580-1584.
Luo F, Ouyang X L, Gao C, et al. Investigation on heat transfer between air and sintered cement ball of high temperature［J］. Journal of Engineering Thermophysics,2012,33(9):1580-1584.
［15］Mukhopadhyay S, Layek G C. Effects of thermal radiation and variable fluid viscosity on free convective flow and heat transfer past a porous stretching surface［J］. International Journal of Heat and Mass Transfer,2008,51:2167-2178.
［16］Magyari E, Pantokratoras A. Note on the effect of thermal radiation in the linearized Rosseland approximation on the heat transfer characteristics of various boundary layer flows［J］. International Communications in Heat and Mass Transfer, 2011,38: 554-556.
［17］闻岩, 李斌, 王佳顺, 等. 水泥熟料堆积体等效导热系数模型与实验研究［J］. 硅酸盐通报, 2014,33(7):1589-1593.
Wen Y, Li B, Wang J S, et al. Model and experimental study of equivalent thermal conductivity for cement clinker accumulation body［J］.Bulletin of the Chinese Ceramic Society,2014, 33(7):1589-1593.
［18］孔祥言. 高等渗流力学［M］. 合肥: 中国科学技术大学出版社, 1999: 22-23.

［19］Dehghan M, Valipour M S, Keshmiri A, et al. On the thermally developing forced convection through a porous material under the local thermal non-equilibrium condition: an analytical study［J］. International Journal of Heat and Mass Transfer,2016,92:815-823.
［20］冯绍航. 篦式冷却机的换热理论研究［D］. 西安: 西安建筑科技大学,2004.

［21］胡道和, 徐德龙, 蔡玉良. 气固过程工程学及其在水泥工业中的应用［M］. 武汉: 武汉理工大学出版社,2003:132-133.

［22］姜培学, 司广树, 任泽霈. 粘性耗散及变物性对多孔介质中对流换热的影响研究［J］. 工程热物理学报,2000,21(5):590-594.
Jiang P X, Si G S, Ren Z P. Numerical investigation on the effects of viscous dissipation and variable thermophysical properties on forced convection heat transfer in porous media［J］. Journal of Engineering Thermophysics,2000,21(5):590-594.
［23］屠传经, 沈珞婵, 胡亚才. 高温传热学［M］. 杭州:浙江大学出版社,1997:20-21.