Three-dimensional Numerical Study on Thermal Performance of a Super Large Natural Draft Cooling Tower of 220m Height 被引量：5

Three-dimensional Numerical Study on Thermal Performance of a Super Large Natural Draft Cooling Tower of 220m Height

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摘要 Based on the heat and mass transfer theory and the characteristics of general-purpose software FLUENT, a three-dimensional numerical simulation platform, composed of lots of user defined functions(UDF), has been developed to simulate the thermal performance of natural draft wet cooling towers(NDWCTs). After validation, this platform is used to analyse thermal performances of a 220m high super large cooling tower designed for inland nuclear plant under different operational conditions. Variations of outlet temperature of the cooling tower caused by changes of water flow rates, inlet water temperatures are investigated. Effects of optimization through non-uniform water distributions on outlet water temperature are discussed, and the influences on the flow field inside the cooling tower are analyzed in detail. It is found that the outlet water temperature will increase as the water flow rate increases, but the air flow rate will decrease. The outlet water temperature will decrease 0.095K and 0.205K, respectively, if two non-uniform water distribution approaches are applied. Based on the heat and mass transfer theory and the characteristics of general-purpose software FLUENT, a three-dimensional numerical simulation platform, composed of lots of user defined functions（UDF）, has been developed to simulate the thermal performance of natural draft wet cooling towers（NDWCTs）. After validation, this platform is used to analyse thermal performances of a 220m high super large cooling tower designed for inland nuclear plant under different operational conditions. Variations of outlet temperature of the cooling tower caused by changes of water flow rates, inlet water temperatures are investigated. Effects of optimization through non-uniform water distributions on outlet water temperature are discussed, and the influences on the flow field inside the cooling tower are analyzed in detail. It is found that the outlet water temperature will increase as the water flow rate increases, but the air flow rate will decrease. The outlet water temperature will decrease 0.095K and 0.205K, respectively, if two non-uniform water distribution approaches are applied.

作者 JIN Tai ZHANG Li LUO Kun FAN Jianren

机构地区 State Key Laboratory of Clean Energy Utilization (Zhejiang University) Hunan Electric Power Design Institute

出处《Journal of Thermal Science》 SCIE EI CAS CSCD 2013年第3期234-241,共8页 热科学学报（英文版）

基金 the National Natural Science Foundation of China (No. 51176170) Foundation for the Author of National Excellent Doctoral Dissertation of PR China (2007B4) are gratefully acknowledged

关键词 Super LARGE Natural Draft WET Cooling TOWER THREE-DIMENSIONAL Numerical Simulation Thermal Performance NON-UNIFORM Water Distribution Super Large Natural Draft Wet Cooling Tower Three-dimensional Numerical Simulation Thermal Performance Non-uniform Water Distribution

分类号 TM623.4 [电气工程—电力系统及自动化]

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参考文献2

1周兰欣,蒋波.横向风对湿式冷却塔热力特性影响数值研究[J].汽轮机技术,2009,51(3):165-168. 被引量：18
2叶奇蓁.中国核电发展战略研究[J].电网与清洁能源,2010,26(1):3-8. 被引量：52

二级参考文献5

1J.C.Kloppers,D.G.Kroger.Loss coefficient correlation for wetcooling tower fills[J].Applied Thermal Engineering,2003,23(17):2201 -2211.
2J.C.Kloppers.A critical evaluation and refinement of the performance of wet-cooling towers[D].South Africa:University of Stellenbosch,2003.
3A1-Waked R,Behnia M.CFD simulation of wet cooling towers[J].Applied Thermal Engineering,2006,26(4):382 -395.
4N.Williamson,S.Armfieid,M.Behnia.Numerical simulation of flow in a natural draft wet cooling tower-the effect of radial thermo fluid fields[J].Applied Thermal Engineering,2008,28 (2):178-189.
5FLUENT:User's Guide,Fluent Inc,2003..< http ://www. fluent.com >.

共引文献68

1王祥高,秦松梅,顾运厅.广西核电建设概况[J].广西物理,2010,31(2):36-38.
2郑水华,金台,罗坤,唐磊,易超,樊建人.逆流式自然通风冷却塔热力性能的三维数值模拟[J].中南大学学报（自然科学版）,2013,44(9):3898-3903. 被引量：6
3唐磊,刘自力,易超.电厂逆流式自然通风冷却塔热力性能研究进展[J].现代电力,2010,27(6):35-40. 被引量：2
4潘雯瑞,任建兴,翁建华.燃煤机组湿式冷却塔淋水填料结构与特性分析[J].上海电力学院学报,2011,27(1):9-13. 被引量：2
5周丽芳.中国核电发展浅析[J].经济研究导刊,2011(7):200-201. 被引量：5
6田佳树,王闯.核电——绿色经济的希望[J].核安全,2010,9(2):1-10. 被引量：1
7江才俊,佘靖策,白光谱.核电站高中能管道断管影响探讨[J].电网与清洁能源,2011,27(6):65-70. 被引量：1
8姜巍,高卫东.低碳压力下中国核电产业发展及铀资源保障[J].长江流域资源与环境,2011,20(8):938-943. 被引量：18
9余国瑞,孙健,茅晓晨,陆福敏,王晓岚.核电领域电器安全保护设备校准方法[J].上海计量测试,2011,38(5):21-24.
10曾宪平,潘雯瑞,翁建华,任建兴.火电厂循环水冷却塔冷却性能的实验研究[J].汽轮机技术,2011,53(5):365-368. 被引量：9

同被引文献38

1周兰欣,蒋波,陈素敏.自然通风湿式冷却塔热力特性数值模拟[J].水利学报,2009,39(2):208-213. 被引量：41
2谷芳,刘春江,袁希钢,余国琮.倾斜波纹板上液膜流动的CFD研究[J].化工学报,2005,56(3):462-467. 被引量：28
3LEMOUARI M, BOUMAZA M. Experimental in- vestigation of the performance characteristics of a eounterflow wet cooling tower[J]. International Jour- nal of Thermal Sciences, 2010, 49 (10) : 2049-2056.
4DONALD Z. Guidelines for selecting the proper film fill[J]. CTI Journal,2007, 28(6): 28-34.
5XIA Z Z, CHEN C J, WANG R Z. Numerical simu- lation of a closed wet cooling tower with novel design [J]. International Journal of Heat and Mass Transfer, 2011, 54(11/12): 2367-2374.
6LUCAS M, MARTINEZ P J, VIEDMA A. Experi- mental determination of drift loss from a cooling tow- er with different drift eliminators using the chemical balance method[J]. International Journal of Refrige- ration, 2012, 35(6). 1779 1788.
7KUMAR R, DHAR P L, JAIN S. Development of new wire mesh packings for improving the perform ante of zero carryover spray tower[J] Energy, 2011, 36(2) : 1362-1374.
8GROBBELAAR P J, REUTER H C R, BER- TRAND T P. Performance characteristics of a trickle fill in cross-and counter-flow configuration in a wet- cooling tower [J ]. Applied Thermal Engineering, 2013, 50(1): 475-484.
9MILOSAVLJEVIC N, HEIKKILA P. A comprehen- sive approach to cooling tower design[J]. Applied Thermal EnMneering, 2001, 21(9): 899-915.
10赵元宾,孙奉仲,王凯,高明.自然通风湿式冷却塔传热传质的三维数值分析[J].山东大学学报（工学版）,2008,38(5):36-41. 被引量：22

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1程友良,杨星辉,韩富强.正弦波形填料基底上液膜的研究及热经济性分析[J].动力工程学报,2015,35(3):230-236. 被引量：4
2周兰欣,赵笙箫.AP1000MW核电机组冷却塔结构数据的优化和研究[J].电站辅机,2017,38(1):1-4.
3SONG Jialiang,CHEN Yongdong,WU Xiaohong,RUAN Shengqi,ZHANG Zhongqing.A Novel Approach for Energy Efficiency Prediction of Various Natural Draft Wet Cooling Towers Using ANN[J].Journal of Thermal Science,2021,30(3):859-868.
4张政清,王明勇,张德英,陈瑞,何锁盈,高明.超大型湿式冷却塔干湿混合雨区正交优化研究[J].中国电机工程学报,2022,42(22):8224-8231. 被引量：2
5余志康,黄世芳,张小松,伍文聪.冷却塔冷却技术的应用与优化[J].制冷学报,2024,45(3):50-62.

二级引证文献6

1吴慧华,曹琳.能源塔波纹填料表面液膜流动过程模拟研究[J].低温建筑技术,2017,39(9):126-129. 被引量：1
2吴慧华,曹琳,吴加胜.能源塔波纹填料间气液两相热质交换模拟[J].南京理工大学学报,2018,42(1):26-32.
3刘梅,甄猛,吴正人,王松岭.矩形结构壁面上液膜流动特性的数值研究[J].中国科技论文,2019,14(1):46-50.
4吴正人,张亚萌,刘梅,李莉,杨红月.三角形壁面液膜孤立波特性的实验研究[J].动力工程学报,2020,40(8):641-645.
5龙国庆,张国罡,孙奉仲,陈学宏,邓伟鹏,张晓宇.机械通风高位收水冷却塔三维热力特性数值研究[J].中国电机工程学报,2023,43(13):5078-5085. 被引量：1
6杨繁昌,刘江,王明勇,翁培奋,张宇琪.低风阻流线型导风板对自然通风湿式冷却塔的性能影响[J].热力发电,2024,53(6):122-131.

1符松,翟志强.NUMERICAL INVESTIGATION OF THE ADVERSE EFFECT OF WIND ON THE HEAT TRANSFER PERFORMANCE OF TWO NATURAL DRAFT COOLING TOWERS IN TANDEM ARRANGEMENT[J].Acta Mechanica Sinica,2001,17(1):24-34. 被引量：2
2鲍雷,曾向东,严家.An Equation of State for Fluids by Applying the Tower-Well Potential Model[J].Journal of Harbin Institute of Technology(New Series),1995,2(4):60-66.
3Wang, Ya-Ling, Liu, Ying-Zhong, Mia, Guo-Ping.CALCULATION OF VISCOUS FLOW AROUND CIRCULAR CYLINDER WITH THREE-DIMENSIONAL NUMERICAL SIMULATION[J].Journal of Hydrodynamics,2001,13(4):83-87. 被引量：5
4Zhao Zhen-guo, Shi Jin-ling, Chen Xian-songDepartment of Cooling Water, Institute of Water Conservancy and Hydroelectric Power Research (IWHR),Beijing 100044, P. R. China.STUDY ON THE AIRFLOW RESISTANCE IN NATURAL DRAFT COOLING TOWERS[J].Journal of Hydrodynamics,1994,6(3):7-14.
5Han Ji-tian, Gong Wei-pingDept. of Power Engineering, Shandong University of Technology, Jinan 250061, P. R. ChinaShi Ming-heng, Gui Ke-tingDept. of Power Engineering, Southeast University, Nanjing 210096, P. R.China.A MATHEMATICAL MODEL FOR HEAT AND MASS TRANSFER IN UNSATURATED WET POROUS MEDIA CONSIDERING EFFECT OF CAPILLARY HYSTERESIS[J].Journal of Hydrodynamics,1998,10(4):37-44. 被引量：1
6姜中宏,胡丽丽.Phase diagram structure model of glass[J].Science China(Technological Sciences),1997,40(1):1-11. 被引量：1
7Haruzo HIDA.Irreducibility of The Igusa Tower[J].Acta Mathematica Sinica,English Series,2009,25(1):1-20.
8卢文达,顾皓中.BUCKLING OF COOLING TOWER SHELLS WITH RING-STIFFENERS[J].Applied Mathematics and Mechanics(English Edition),1989,10(7):583-592.
9JI Shun-wen,ZHU Yue-ming,QIANG Sheng,ZENG Deng-feng.FORECAST OF WATER TEMPERATURE IN RESERVOIR BASED ON ANALYTICAL SOLUTION[J].Journal of Hydrodynamics,2008,20(4):507-513. 被引量：4
10李龙元,卢文达.NONLINEAR BUCKLING ANALYSIS OF HYPERBOLIC COOLING TOWER SHELL WITH RING-STIFFENERS[J].Applied Mathematics and Mechanics(English Edition),1989,10(2):113-118.

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