Please wait a minute...
Shopping Cart Email List Chinese
Advanced Search Fig/Tab
Frontiers in Energy

ISSN 2095-1701

ISSN 2095-1698(Online)

CN 11-6017/TK

Postal Subscription Code 80-972

2018 Impact Factor: 1.701

Featured Articles  |  Most Downloaded  |  Most Reading
Online Submission Subscribe to Our RSS Content Feed
Front Energ Power Eng Chin    2009, Vol. 3 Issue (2) : 226-232    https://doi.org/10.1007/s11708-009-0022-0
RESEARCH ARTICLE
A new heat transfer correlation for supercritical fluids
Yanhua YANG, Xu CHENG(), Shanfang HUANG
School of Nuclear Science and Engineering, Shanghai Jiao Tong University, Shanghai 200240, China
 Download: PDF(232 KB)   HTML
 Export: BibTeX | EndNote | Reference Manager | ProCite | RefWorks
Abstract

A new method of heat transfer prediction in supercritical fluids is presented. Emphasis is put on the simplicity of the correlation structure and its explicit coupling with physical phenomena. Assessment of qualitative behaviour of heat transfer is conducted based on existing test data and experience gathered from open literature. Based on phenomenological analysis and test data evaluation, a single dimensionless number, the acceleration number, is introduced to correct the deviation of heat transfer from its conventional behaviour, which is predicted by the Dittus-Boelter equation. The new correlation structure excludes direct dependence of heat transfer coefficient on wall surface temperature and eliminates possible numerical convergence. The uncertainty analysis of test data provides information about the sources and the levels of uncertainties of various parameters and is highly required for the selection of both the dimensionless parameters implemented into the heat transfer correlation and the test data for the development and validation of new correlations. Comparison of various heat transfer correlations with the selected test data shows that the new correlation agrees better with the test data than other correlations selected from the open literature.
Keywords super critical fluids      heat transfer      circular tubes      prediction method     
Corresponding Author(s): CHENG Xu,Email:chengxu@sjtu.edu.cn   
Issue Date: 05 June 2009
 Cite this article:   
Yanhua YANG,Xu CHENG,Shanfang HUANG. A new heat transfer correlation for supercritical fluids[J]. Front Energ Power Eng Chin, 2009, 3(2): 226-232.
 URL:  
https://academic.hep.com.cn/fie/EN/10.1007/s11708-009-0022-0
https://academic.hep.com.cn/fie/EN/Y2009/V3/I2/226
1 Bishop A A, Sandberg L O, Tong L S. Forced convection heat transfer to water at near critical temperatures and supercritical pressures. WCAP-2056-P, Part-III-B , 1964
2 Swenson H S, Caever J R, Kakarala C R. Heat transfer to supercritical water in smooth-bore tube. Journal of Heat Transfer , 1965, 87(4): 477-484
3 Krasnoshchekov E A, Protopopov V S. Experimental study of heat exchange in carbon dioxide in the supercritical range at high temperature drops, Teplofizika Vysokikh Temperatur , 1966, 4(3): 389-398
4 Yamagata K, Nishikawa K, Hasegawa S, . Forced convection heat transfer to supercritical water flowing in tubes. International Journal of Heat and Mass Transfer , 1972, 15(12): 2575-2593
doi: 10.1016/0017-9310(72)90148-2
5 Griem H. Untersuchungen zur thermohydraulik innenberippter verdampferrohre. . Technical University of Munich , 1995
6 Cheng Xu, Schulenberg T. Heat transfer at supercritical pressures—literature review and application to an HPLWR. Wissenschaftliche Berichte (Tech. Report) FZKA 6609, Forschungszentrum Karlsruhe , Mai, 2001
7 Pioro I L, Duffey R B. Experimental heat transfer in supercritical water flowing inside channels. Nuclear Engineering and Design , 2005, 235(22): 2407-2430
doi: 10.1016/j.nucengdes.2005.05.034
8 Jackson J D. Semi-empirical model of turbulent convective heat transfer to fluids at supercritical pressure. Procceding of 16th International Conference on Nuclear Engineering , ICONE16, Orlando, Florida, USA, 2008, Paper No. 48914
9 Kuang B, Zhang Y Q, Cheng X. A new, wide-ranged heat transfer correlation of water at supercritical pressures in vertical upward ducts. The 7th International Topical Meeting on Nuclear Reactor Thermal Hydraulics, Operation and Safety (NUTHOS-7) , Seoul, Korea, 2008, Paper No. 189
10 Herkenrath H, M?rk-M?rkenstein P, Jung U, . Forced convection Heat transfer to water at the pressure range from 140 to 250 bar, EUR 3658d, EURATOM , 1967
11 Koshizuka S, Takano N, Oka Y. Numerical analysis of deterioration phenomena in heat transfer to supercritical water. International Journal of Heat and Mass Transfer , 1995, 38(16): 3077-3084
doi: 10.1016/0017-9310(95)00008-W
12 Jackson J D, Hall W B. Influences of buoyancy on heat transfer to fluids in vertical tubes under turbulent conditions. In: Turbulent Forced Convection in Channels and Bundles , Vol.2, New York: Hemisphere Publishing Corporation, 1979, 613-640
13 Jackson J D. HTFS design report No. 34 – Heat transfer to supercritical pressure fluids, Part 1 – Summary of design recommendation and equations. AERE-R8157, 1975
[1] Yanxing ZHAO, Maoqiong GONG, Haocheng WANG, Hao GUO, Xueqiang DONG. Development of mobile miniature natural gas liquefiers[J]. Front. Energy, 2020, 14(4): 667-682.
[2] Bojie WANG, Wen WANG, Chao QI, Yiwu KUANG, Jiawei XU. Simulation of performance of intermediate fluid vaporizer under wide operation conditions[J]. Front. Energy, 2020, 14(3): 452-462.
[3] Shaozhi ZHANG, Xiao NIU, Yang LI, Guangming CHEN, Xiangguo XU. Numerical simulation and experimental research on heat transfer and flow resistance characteristics of asymmetric plate heat exchangers[J]. Front. Energy, 2020, 14(2): 267-282.
[4] R. LALITHA NARAYANA, V. RAMACHANDRA RAJU. Experimental study on performance of passive and active solar stills in Indian coastal climatic condition[J]. Front. Energy, 2020, 14(1): 105-113.
[5] Yang YU, Guoliang AN, Liwei WANG. Major applications of heat pipe and its advances coupled with sorption system: a review[J]. Front. Energy, 2019, 13(1): 172-184.
[6] Xiao-Hu YANG, Jing LIU. Liquid metal enabled combinatorial heat transfer science: toward unconventional extreme cooling[J]. Front. Energy, 2018, 12(2): 259-275.
[7] Vishal TALARI, Prakhar BEHAR, Yi LU, Evan HARYADI, Dong LIU. Leidenfrost drops on micro/nanostructured surfaces[J]. Front. Energy, 2018, 12(1): 22-42.
[8] Jie GUO,Danmei XIE,Hengliang ZHANG,Wei JIANG,Yan ZHOU. Effect of heat transfer coefficient of steam turbine rotor on thermal stress field under off-design condition[J]. Front. Energy, 2016, 10(1): 57-64.
[9] Anil Singh YADAV,J. L. BHAGORIA. Heat transfer and fluid flow analysis of an artificially roughened solar air heater: a CFD based investigation[J]. Front. Energy, 2014, 8(2): 201-211.
[10] Foued CHABANE,Nesrine HATRAF,Noureddine MOUMMI. Experimental study of heat transfer coefficient with rectangular baffle fin of solar air heater[J]. Front. Energy, 2014, 8(2): 160-172.
[11] Manli LUO, Jing LIU. Experimental investigation of liquid metal alloy based mini-channel heat exchanger for high power electronic devices[J]. Front Energ, 2013, 7(4): 479-486.
[12] Qingqing SHEN, Wensheng LIN, Anzhong GU, Yonglin JU. A simplified model of direct-contact heat transfer in desalination system utilizing LNG cold energy[J]. Front Energ, 2012, 6(2): 122-128.
[13] Jing HUANG, Yuwen ZHANG, J. K. CHEN, Mo YANG. Ultrafast solid-liquid-vapor phase change of a thin gold film irradiated by femtosecond laser pulses and pulse trains[J]. Front Energ, 2012, 6(1): 1-11.
[14] Jinying YIN, Linhua LIU. Analysis of the radiation heat transfer process of phase change for a liquid droplet radiator in space power systems[J]. Front Energ Power Eng Chin, 2011, 5(2): 166-173.
[15] C Y ZHAO, D ZHOU, Z G WU. Heat transfer of phase change materials (PCMs) in porous materials[J]. Front Energ, 2011, 5(2): 174-180.
Viewed
Full text


Abstract

Cited
  Shared   
  Discussed