余热利用集热器性能的实验研究与数值计算

doi:10.11949/j.issn.0438-1157.20171001

化工学报 ›› 2018, Vol. 69 ›› Issue (5): 1946-1955.DOI: 10.11949/j.issn.0438-1157.20171001

余热利用集热器性能的实验研究与数值计算

杜文静¹, 孙会民², 程林²

1. 山东大学能源与动力工程学院, 山东济南 250061;
2. 山东大学热科学与工程研究中心, 山东济南 250061

收稿日期:2017-07-28 修回日期:2017-10-13 出版日期:2018-05-05 发布日期:2018-05-05
通讯作者: 程林
基金资助:
山东省自然科学基金面上项目（ZR2016EEM44）。

Experimental research and numerical analysis of heat collector performance for waste heat recovery

DU Wenjing¹, SUN Huimin², CHENG Lin²

1. School of Energy and Power Engineering, Shandong University, Jinan 250061, Shandong, China;
2. Center of Thermal Science and Technology, Shandong University, Jinan 250061, Shandong, China

Received:2017-07-28 Revised:2017-10-13 Online:2018-05-05 Published:2018-05-05
Supported by:
supported by the Natural Science Foundation of Shandong Province(ZR2016EEM44).

摘要/Abstract

摘要：

以回转窑表面余热回收用集热器为研究对象，采用实验研究和数值计算方法，分析了集热器的流动和传热特性及其在线运行规律。实验中选取了一种辐射型和两种耦合型结构的集热器进行研究，分析了出口水温、出口压力和工质流量的变化对集热器性能的影响，总结了三种结构类型的集热器在换热量上的变化规律。采用Matlab软件编程进行数值求解，将数值计算结果与实验结果对比，验证了数值计算的准确性。数值分析了入口空气温度、入口空气流速和窑体温度变化时对应的集热器内熵增、火积耗散以及有效度的变化规律。相关计算结果为集热器的优化设计和在线运行参数的选择提供了数据支持。

关键词: 集热器, 余热利用, 传热, 实验验证, 数值分析

Abstract:

The research object is a novel heat collector installed on the surface of the rotary kiln, which is used for waste heat recovery from the kiln. The experimental and numerical calculation methods are used to analyze the flow and heat transfer characteristics of this equipment. In the process of experimental research, one radiant type heat collector and two coupled type heat collectors are investigated to study the influence between the variation of outlet water temperature, outlet pressure and flow mass on the performance of the collector. Numerical calculations are also performed to obtain working performances of the heat collector using Matlab software. Both numerical and experimental results are compared to verify the accuracy of numerical calculations. The changes of the inlet air temperature, inlet air flow rate and kiln body temperature are numerically analyzed. Related results provide data support for the optimization design of the collector and the selection of the online operating parameters.

Key words: heat collector, waste heat recovery, heat transfer, experimental validation, numerical analysis

中图分类号:

TK-9

杜文静, 孙会民, 程林. 余热利用集热器性能的实验研究与数值计算[J]. 化工学报, 2018, 69(5): 1946-1955.

DU Wenjing, SUN Huimin, CHENG Lin. Experimental research and numerical analysis of heat collector performance for waste heat recovery[J]. CIESC Journal, 2018, 69(5): 1946-1955.

参考文献 25

[1]	MEENA P, RITTIDECH S. Waste heat collector by closed-loop oscillating heat pipe with check valve from pottery kilns for energy thrift[J]. American Journal of Engineering and Applied Sciences, 2008, 1(2):126-130.
[2]	KARAMARKOVI? V, MARAŠEVI? M, KARAMARKOVI? R, et al. Recuperator for waste heat collector from rotary kilns[J]. Appl. Therm. Eng., 2013, 54(2):470-480.
[3]	CAPUTO A C, PELAGAGGE P M, SALINI P. Performance modeling of radiant heat collector exchangers for rotary kilns[J]. Appl. Therm. Eng., 2011, 31(14/15):2578-2589.
[4]	SÖ?ÜT Z, OKTAY Z, KARAKOÇ H. Mathematical modeling of heat collector from a rotary kiln[J]. Appl. Therm. Eng., 2010, 30(8/9):817-825.
[5]	顾永敏, 戴苏明.水泥回转窑余热热水系统的设计[J]. 能源研究与利用, 2009, (6):32-35. GU Y M, DAI S M. Design of the waste heat water system for cement rotary kilns[J]. Energy Research & Utilization, 2009, (6):32-35.
[6]	马爽. 对流式鳍片管结构的回转窑余热回收装置的设计[J]. 余热锅炉, 2014, (1):1-4. MA S. The design of fin-tubed waste heat recovery equipment on the rotary kilns[J]. Waste Heat Boiler, 2014, (1):1-4.
[7]	杨大哲, 黄新元, 薛立志, 等. H型鳍片管的传热与流动特性试验研究[J]. 锅炉制造, 2008, (6):14-17. YANG D Z, HUANG X Y, XUE L Z, et al. The experimental study on the characteristics of heat transfer and flow of H-type finned tube[J]. Boiler Manufacturing, 2008, (6):14-17.
[8]	曹辉, 王龙江, 张嘉, 等. 回转窑筒体表面余热回收利用系统:202470783-U[P]. 2012-10-03. CAO H, WANG L J, ZHANG J, et al. The waste heat recovery and utilization system on rotary kilns surfaces:202470783-U[P]. 2012-10-03.
[9]	王建立, 宋纪元, 周文祥, 等. 一种改善回转窑筒体热回收中工作条件的装置:202709710-U[P]. 2013-01-30. WANG J L, SONG J Y, ZHOU W X, et al. A heat recovery device for improving the operational conditions of the rotary kilns:202709710-U[P]. 2013-01-30.
[10]	吴新江. 一种水泥回转窑废热回收机构:204730675-U[P]. 2015-10-28. WU X J. A device which recover the waste heat on rotary kilns:204730675-U[P]. 2015-10-28.
[11]	袁国才, 王文棚, 黄鑫, 等. 一种回转窑余热回收发电装置:204271952-U[P]. 2015-04-15. YUAN G C, WANG W P, HUANG X, et al. A waste heat power generation system for rotary kilns:204271952-U[P]. 2015-04-15.
[12]	LYNN PRICE A H H L. Analysis of energy-efficiency opportunities for the cement industry in Shandong Province, China:a case study of 16 cement plants[J]. Energy, 2010, 35(8):3461-3473.
[13]	ENGIN T, ARI V. Energy auditing and recovery for dry type cement rotary kiln systems-a case study[J]. Energy Conversion and Management, 2005, 46(4):551-562.
[14]	董梅. 回转窑筒体表面辐射热回收技术研究[D]. 北京:北京建筑大学, 2014. DONG M. Study on heat recovery technology of rotary kiln tube body surface radiation[D]. Beijing:Beijing University of Civil Engineering and Architecture, 2014
[15]	程林, 杜文静. 正六边形水泥回转窑表面热量回收装置:103123219A[P]. 2013-05-29. CHENG L, DU W J. The orthohexagonal heat recovery devices on rotary kilns:103123219A[P]. 2013-05-29
[16]	杨世铭, 陶文铨. 传热学[M]. 4版. 北京:高等教育出版社, 2006:197. YANG S M, TAO W Q. Heat Transfer[M]. 4th ed. Beijing:Higher Education Press, 2006:197.
[17]	杜广生. 工程流体力学[M]. 北京:中国电力出版社, 2007:241. DU G S. Engineering Fluid Mechanics[M]. Beijing:China Electric Power Engineering Press, 2007:241.
[18]	华绍增. 实用流体阻力手册[M]. 北京:国防工业出版社, 1985:660. HUA S Z. Practical Fluid Resistance Manual[M]. Beijing:National Defense Industry Press, 1985:660.
[19]	沈维道, 童钧耕. 工程热力学[M]. 4版. 北京:高等教育出版社, 2007. SHEN W D, TONG J G. Engineering Thermodynamics[M]. 4th ed.Beijing:Higher Education Press, 2007.
[20]	董源, 过增元. 非平衡热力学中传热过程熵产表达式的修正[J]. 物理学报, 2012, (3):97-101. DONG Y, GUO Z Y. The modification of entropy production by heat conduction in non-equilibrium thermodynamics[J]. Acta Physica Sinica, 2012, (3):97-101.
[21]	王怡飞, 陈群. 换热器组性能与火积耗散及其热阻的关系研究[J]. 工程热物理学报, 2014, 35(6):1189-1193. WANG Y F, CHEN Q. Analyses of heat exchanger group performance, entransy dissipation and entransy-dissipation-based thermal resistance[J]. Journal of Engineering Thermophysics, 2014, 35(6):1189-1193.
[22]	郭江峰, 许明田, 程林. 换热量和换热面积给定时的火积耗散最小原则[J]. 科学通报, 2010, (32):3141-3146. GUO J F, XU M T, CHENG L. The entransy dissipation minimization principle under given heat duty and heat transfer area conditions[J]. Chinese Sci. Bull., 2010, (32):3141-3146.
[23]	许明田, 程林, 郭江峰. 火积耗散理论在换热器设计中的应用[J]. 工程热物理学报, 2009, 30(12):2090-2092. XU M T, CHENG L, GUO J F. An application of entransy dissipation theory to heat exchanger design[J]. Journal of Engineering Thermophysics, 2009, 30(12):2090-2092.
[24]	李雪芳, 郭江峰, 许明田, 等. 换热器优化设计的最小火积耗散方法[J]. 科学通报, 2011, 56(11):869-873. LI X F, GUO J F, XU M T, et al. Entransy dissipation minimization for optimization of heat exchanger design[J]. Chinese Sci. Bull., 2011, 56(11):869-873.
[25]	史美中, 王中铮. 热交换器原理与设计[M]. 5版. 南京:东南大学出版社, 2014. SHI M Z, WANG Z Z. Principle and Design of Heat Exchanger[M]. 5th ed. Nanjing:Southeast University Press, 2014.

余热利用集热器性能的实验研究与数值计算

Experimental research and numerical analysis of heat collector performance for waste heat recovery

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