插入圆柱状丝网管对单相对流传热的强化

doi:10.3969/j.issn.0438-1157.2014.08.015

摘要/Abstract

摘要： 提出在传热管内插入圆柱状丝网管调控流场进而强化传热的方法。通过在管内同心插入圆柱状丝网管，将流通截面分成中心区和环隙区，流体流经丝网入口处时受到阻力较大，大部分流体流向环隙区，使得速度场受到调控。环隙区与中心区内冷热流体掺混，强化传热。为验证这一思想搭建强制对流换热实验台，以去离子水为工质，Reynolds数为2392～20175，热通量为50.18～282.88 kW·m^-2。通过对局部、平均Nusselt数及摩擦压降数据的研究，结果表明：同光管传热相比，插入丝网管后平均Nusselt数提高，传热强化系数为1.21～1.84，且最大强化系数发生在过渡流内。入口段强化效果明显，局部传热强化系数最高可达到2.64。而强化传热的同时摩擦压降增大6.1～10.6倍。同时对该结构的传热强化机理进行分析：流场受到丝网管的调控作用，进而强化传热。

关键词: 丝网管, 流场调控, 对流, 传热, 实验验证

Abstract: A method was proposed to enhance the single phase convective heat transfer. A stainless mesh cylinder was inserted into the tube concentrically to divide its cross section into an annular region and a central region. As the fluid passes the mesh cylinder, most of it enters the annular region because of resistance, modulating the flow field. Hot fluid in the annular region and cold fluid in the central region mix with each other more intensely through the mesh surface, enhancing the heat transfer. The heat transfer and pressure drop characteristics in the vertical upward flow with inserted mesh cylinder were investigated experimentally to validate the method. The mean and local Nusselt numbers and pressure drop data were obtained from the mesh cylinder tube and a smooth tube with water as the working fluid. The Reynolds numbers cover the range of 2392-20175 and the heat flux is in the range of 50.18-282.88 kW·m^-2. The experimental results from the smooth tube are validated by using the well known equations in literature. Inserting a mesh cylinder increases the heat transfer and pressure drop considerably compared with the smooth tube. The heat transfer enhancement factors range from 1.21 to 1.84. In the entrance region or thermal developing region, the heat transfer enhancement factor is up to 2.64. Meanwhile, the pressure drop is 6.1-10.6 times larger than that of the smooth tube.

Key words: mesh cylinder, flow field modulation, convection, heat transfer, experimental validation

中图分类号:

TK124

邢峰, 谢剑, 徐进良. 插入圆柱状丝网管对单相对流传热的强化[J]. 化工学报, 2014, 65(8): 2954-2962.

XING Feng, XIE Jian, XU Jinliang. Single phase convective heat transfer enhanced by inserted mesh cylinder[J]. CIESC Journal, 2014, 65(8): 2954-2962.

参考文献 30

[1]	Lin Zhimin (林志敏). The characteristics of secondary flow and heat transfer enhancement in circular tube with twisted tape or vortex generators [D]. Lanzhou: Lanzhou Jiaotong University, 2011
[2]	Liu S, Sakr M. A comprehensive review on passive heat transfer enhancements in pipe exchangers [J]. Renewable and Sustainable Energy Reviews, 2013, 19: 64-81
[3]	Dewan A, Mahanta P, Raju K S, Kumar P S. Review of passive heat transfer augmentation techniques//Proceedings of the Institution of Mechanical Engineers [C]. 2004: 509-527
[4]	Gou Feng (苟峰). Investigation of heat transfer enhancement for twisted-tape inserts in tubes [D]. Beijing: China Institute of Atomic Energy, 2002
[5]	Zhang Lin (张琳), Qian Hongwei (钱红卫), Xuan Yimin (宣益民), Yu Xiumin (俞秀民). 3D numerical simulation of fluid flow and heat transfer in self-rotating twisted-tape-inserted-tube [J]. Journal of Chemical Industry and Engineering (China) (化工学报), 2005, 56 (9): 1633-1638
[6]	Wang Yangjun (王杨君), Deng Xianhe (邓先和). Numerical simulation of flow and heat transfer in a tube inserted with twisted-leaves [J]. Journal of Chemical Industry and Engineering (China) (化工学报), 2007, 58 (10): 2455-2461
[7]	Akhavan-Behabadi M A, Kumar R, Mohammadpour A, Jamali-Asthiani M. Effect of twisted tape insert on heat transfer and pressure drop in horizontal evaporators for the flow of R-134a [J]. International Journal of Refrigeration, 2009, 32: 922-930
[8]	Hejazi V, Akhavan-Behabadi M A, Afshari A. Experimental investigation of twisted tape inserts performance on condensation heat transfer enhancement and pressure drop [J]. International Communications in Heat and Mass Transfer, 2010, 37: 1376-1387
[9]	Bharadwaj P, Khondge A D, Date A W. Heat transfer and pressure drop in a spirally grooved tube with twisted tape insert [J]. International Journal of Heat and Mass Transfer, 2009, 52: 1938-1944
[10]	Guo Jian, Fan Aiwu, Zhang Xiaoyu, Liu Wei. A numerical study on heat transfer and friction factor characteristics of laminar flow in a circular tube fitted with center-cleared twisted tape [J]. International Journal of Thermal Sciences, 2011, 50: 1263-1270
[11]	Yu Xiumin (俞秀民), Yu Tianlan (俞天兰), Peng Deqi (彭德其), Jiang Shaoqing (蒋少青), Luo Jiankang (罗健康). Twisted strip with oblique teeth to efficiently remove fouling and enhance heat transfer at low flowing velocity [J]. Journal of Chemical Industry and Engineering (China) (化工学报), 2005, 56 (4): 744-747
[12]	Gunes S, Ozceyhan V, Buyukalaca O. The experimental investigation of heat transfer and pressure drop in a tube with coiled wire inserts placed separately from the tube wall [J]. Applied Thermal Engineering, 2010, 30: 1719-1725
[13]	Garcia A, Vicente P G, Viedma A. Experimental study of heat transfer enhancement with wire coil inserts in laminar-transition-turbulent regimes at different Prandtl numbers [J]. International Journal of Heat and Mass Transfer, 2005, 48: 4640-4651
[14]	Saeedinia M, Akhavan-Behabadi M A, Nasr M. Experimental study on heat transfer and pressure drop of nanofluid flow in a horizontal coiled wire inserted tube under constant heat flux [J]. Experimental Thermal and Fluid Science, 2012, 36: 158-168
[15]	Luo Lincong (罗林聪), Zhang Guanmin (张冠敏), Tian Maocheng (田茂诚), Tang Yufeng (唐玉峰), Pan Jihong (潘继红). Heat transfer characteristics of subcooled flow boiling in vertical annuli with wire coil inserts [J]. CIESC Journal (化工学报), 2012, 63 (10): 3086-3093
[16]	Eiamsaard S, Rattanawong S, Promvonge P. Turbulent convection in round tube equipped with propeller type swirl generators [J]. International Communications in Heat and Mass Transfer, 2009, 36: 357-364
[17]	Yang C S, Jeng D Z, Yang Y J, Chen H R, Gau C. Experimental study of pre-swirl flow effect on the heat transfer process in the entry region of a convergent pipe [J]. Experimental Thermal and Fluid Science, 2011, 35: 73-81
[18]	Promvonge P, Eiamsaard S. Heat transfer and turbulent flow friction in a circular tube fitted with conical-nozzle turbulators [J]. International Communications in Heat and Mass Transfer, 2007, 34: 72-82
[19]	Naphon P, Nuchjapo M, Kurujareon J. Tube side heat transfer coefficient and friction factor characteristics of horizontal tubes with helical rib [J]. Energy Conversion and Management, 2006, 47: 3031-3044
[20]	Tang Xinyi (唐新宜), Zhu Dongsheng (朱冬生), Chen Hong (陈宏). Vertical flow and heat transfer characteristics in rectangular channel with trapezoidal tab [J]. CIESC Journal (化工学报), 2012, 63 (1): 71-83
[21]	Gao Xiang (高翔), Luo Zhongyang (骆仲泱), Zhou Jinsong (周劲松), Ni Mingjiang (倪明江), Cen Kefa (岑可法). Heat transfer enhancement characteristics of non-decaying swirl flow due to spiral fin [J]. Journal of Chemical Industry and Engineering (China) (化工学报), 2003, 54 (9): 1205-1208
[22]	Liu Chunjiang (刘春江), Liu Hui (刘辉), Lu Hanbing (陆寒冰), Yuan Xigang (袁希钢). Heat transfer enhancement in round tube with cross over disk: experiment and simulation [J]. Journal of Chemical Industry and Engineering (China) (化工学报), 2008, 59 (2): 301-308
[23]	Huang Zhifeng (黄志锋), Liu Wei (刘伟), Yang Kun (杨昆). Study on heat transfer performance for tube inserted with ring porous and its field synergy analysis [J]. Journal of Engineering Thermophysics (工程热物理学报), 2009, 30 (5): 844-846
[24]	Yang Junlan (杨俊兰), Ma Yitai (马一太). Analysis of heat transfer enhancement performance and its application in tube inserts [J]. Power Engineering (动力工程), 2004, 24 (3): 388-392
[25]	Wu Jinxing (吴金星), Wang Haifeng (王海峰), Wang Baodong (王保东). Analysis on the performance of enhanced heat transfer structure inside tube [J]. Energy Conservation Technology (节能技术), 2006, 24 (136): 150-153
[26]	Armour J C, Cannon J N. Fluid flow through woven screens [J]. AIChE Journal, 1968, 14: 415-420
[27]	Bas H, Ozceyhan V. Heat transfer enhancement in a tube with twisted tape inserts placed separately from the tube wall [J]. Experimental Thermal and Fluid Science, 2012, 41: 51-58
[28]	Kline S J, McClintock F A. Describing uncertainties in single sample experiments [J]. Mechanical Engineering, 1953, 75 (1): 3-8
[29]	Gnielinski V. New equations for heat and mass transfer in turbulent pipe and channel flow [J]. Int. Chem. Eng., 1976, 16: 359-368
[30]	Fan J F, Ding W K, Zhang J F, He Y L, Tao W Q. A performance evaluation plot of enhanced heat transfer techniques oriented for energy-saving [J]. International Journal of Heat and Mass Transfer, 2009, 52: 33-44