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HFC134a水平二维与三维肋管外冷凝换热特性 被引量:8

Film condensation characteristics of HFC134a on enhanced horizontal tubes with two dimensional and three dimensional integral fins
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摘要 环保工质与高效冷凝管的应用对制冷行业实现节能减排意义重大,工质在强化管外膜状凝结换热特性是二者推广应用的关键。建立了水平管外膜状凝结换热试验系统,研究了HFC134a在4种二维肋管与2种三维肋管外的膜状凝结传热特性。试验管公称外径为19.05mm、有效换热长度为1000mm;试验中,通过改进的Wilson图解法获取试验管水侧对流传热系数。结果表明:HFC134a水平二维与三维肋管外冷凝传热系数分别达到同热通量下光管的11倍与19倍以上;HFC134a工质对应最佳二维肋管的肋密度在1069-1575fpm(肋每米)之间、肋高在0.7~1.5mm之间,对应最优三维肋管(与本文试验肋型相似)肋密度低于2000fpm;既有二维肋管膜状凝结换热模型需要进一步完善,肋管结构优化过程中应遵循优先提升肋密度的原则。 Design of shell-tube condenser with finned tubes with two dimensional (2D) or three dimensional (3D) fins for HFC134a needs reliable models for the film condensation, which is usually based on reliable experimental data. A new test facility was established to investigate experimentally film condensation characteristics of HFC134a on six enhanced tubes (four kinds of 2D finned tubes and two kinds of 3D finned tubes) and the reliability of existing models and the effect of fin density and fin height on film condensation of HFC134a were discussed. Equivalent outside diameter and active length of test tubes are 19.05 and 1000 mm, respectively. In the experiment, water-side convection heat transfer coefficient for all test tubes is determined by the modified Wilson plot method. The results are as follows. Condensation heat transfer coefficient (CHTC) of HFC134a on single smooth tube is a little higher (5%-8%) than that predicted by the Nusselt model; CHTC of the best 2D (or 3D)finned tubes is 11.5 (or 19) times higher than that of single smooth tube under the same heat flux; the best fin density and fin height of 2D finned tubes are in the regions of 1069--1575 fins per meter (fpm) and 0.7--1.5 mm, respectively; the best fin density of the 3D finned tubes is less than 2000 fpm; the deviations between existing models and experimental results are not acceptable, due to their bad stability or poor accuracy. More work should be done to improve the models for film condensation of HFC134a on 2D finned tubes and develop models for that on 3D finned tubes in the future. The result can be used to guide the design of shell-tube condenser with HFC134a.
作者 马志先 张吉礼 孙德兴 周浩平
机构地区 大连理工大学土木学院 哈尔滨工业大学市政环境工程学院 江苏萃隆精密铜管股份有限公司
出处 《化工学报》 EI CAS CSCD 北大核心 2014年第4期1221-1228,共8页 CIESC Journal
基金 国家自然科学基金项目(51078053) '十二五'国家科技部支撑计划项目(2011BAJ03B12-3) 中国博士后科学基金项目 中央高校基本科研业务费项目(DUT12RC(3)81)~~
关键词 凝结 传热 模型 强化管 HFC134A 水平管 condensation heat transfer film model enhanced tube HFC 134a horizontal tube
分类号 TK124 [动力工程及工程热物理—工程热物理]
作者简介 马志先(1982-),男,博士后。 联系人:张吉礼。
  • 相关文献

参考文献33

  • 1Seara J F, Uhia F J, Diz R, Dopozo A. Condensation of R-134a on horizontal integral-fin titanium tubes[J]. Applied Thermal Engineering, 2010, 30: 295-301.
  • 2Cao Desheng, Shi Lin. Handbook for refrigerant appli- cation[M]. Beijing: Press of Metallurgy Industry(冶金工业出版社), 2003.
  • 3Adamek T. Bestimmung der kondensation-grossen auf fe-ingewellten oberflachen zur auslegun aptimaler wandprofile[J]. Warme-und Stoffiibertragung, 1981, 15: 255-270.
  • 4张正国,林培森,王世平.花瓣形翅片管的开发及其纵向冲刷冷凝强化传热的研究[J].石油化工设备,1996,25(3):3-6. 被引量:3
  • 5Kumar R, Varma H K, Mohanty B, Agrawal K N., Augmentation of heat transfer during filmwise condensation of steam and R-134a over single horizontal finned tubes[J]. Int. J. Heat and Mass Transfer, 2002, 45: 201-211.
  • 6Ali H M, Briggs A. Enhanced condensation of ethylene glycol on single pin-fin tubes—effect of pin geometry [J]. Journal of Heat Transfer, 2012, 134: 1-7.
  • 7Kumar R, Gupta A, Vishvakarma S. Condensation of R-134a vapour over single horizontal integral-fin tubes: effect of fin height[J]. Int J Refrig., 2005, 28: 428-435.
  • 8Belghazi M, Bontemps A, Marvillet C. Condensation heat transfer on enhanced surface tubes: experimental results and predictive theory[J]. Journal of Heat Transfer, 2002, 124: 754-761.
  • 9Honda H, Takata N, Takamatsu H, Kim J S, Usami K. Condensation of downward flowing HFC-134a in a staggered bundle of horizontal finned tubes: effect of fin geometry. Int. J Refrig., 2002, 25: 3-10.
  • 10Cheng W Y, Wang C C. Condensation of R134a on Enhanced Tubes[J]. ASHRAE Trans., 1994, 100(2): 809-817.

二级参考文献108

  • 1刘文毅,李妩,陶文铨.替代工质R123水平强化单管外凝结换热实验研究[J].现代电力,2005,22(1):52-55. 被引量:2
  • 2张定才,刘启斌,陶文铨,何雅玲.R22在水平双侧强化管外的凝结换热[J].化工学报,2005,56(10):1865-1868. 被引量:17
  • 3刘启斌,何雅玲,张定才,陶文铨.R123在水平双侧强化管外池沸腾换热[J].化工学报,2006,57(2):251-257. 被引量:15
  • 4Marto P J. An evaluation of film condensation on horizontal integral fin tubes. Journal of Heat Transfer, 1988, 110: 1287- 1305.
  • 5Browne M W, Bansal P K. An overview of condensation heat transfer on horizontal tube bundles. Applied Thermal Engineering, 1999, 19:565- 594.
  • 6Nusselt W. Die oberflachenkondensation des wasserdampfes. Z. Vereines Deutsch.Ing., 1916, 60: 541-546, 569 -575.
  • 7Beatty K O, Katz D L. Condensation of vapours on outside of finned tubes. ChemicalEngineering Progress, 1948, 44 (1): 55-70.
  • 8Karkhu V A, Borovkov V P. Film condensation of vapour at finely-finned horizontal tubes. Heat Transfer Soviet Research, 1971 (3): 183- 191.
  • 9WuPeiyi(吴沛宜).A criterial equation for condensation heat transfer of R12 and R113 on single horizontal finned tubes[J].西安交通大学学报,1979,1(3):1-10.
  • 10Rudy T M, Webb R L. Theoretical model for condensation on horizontal integral fin tubes. AIChE Symp. Ser. , 1983 (79) : 11- 18.

共引文献33

同被引文献49

  • 1燕志鹏,刘建,张刚,张正国.R22,R410A,R407C和R134a在花瓣翅片管管束外的冷凝传热强化[J].化工进展,2011,30(S1):655-659. 被引量:4
  • 2张定才,刘启斌,陶文铨,何雅玲.R22在水平双侧强化管外的凝结换热[J].化工学报,2005,56(10):1865-1868. 被引量:17
  • 3周光辉,张定才.R134a在水平强化管外凝结换热的实验研究[J].制冷学报,2006,27(6):25-28. 被引量:10
  • 4张定才,王凯,何雅玲,陶文铨.R134a在水平双侧强化管外沸腾换热[J].化工学报,2007,58(11):2710-2714. 被引量:13
  • 5Wang W C, Yu C, Wang B X. Condensation heat transfer of a non-azeotropic binary mixture on a horizontal tube [ J]. International Journal of Heat and Mass Transfer, 1995, 38 (2) : 233 - 240.
  • 6吴沛宜.氟里昂12、113在水平肋管外冷凝放热的准则方程[J].西安交通大学学报,1979,(3):1-10.
  • 7A1-Badri A R, Gebauer T, Leipertz A, et al. Element by element prediction model of condensation heat transfer on a horizontal integral finned tube [J]. International Journal of Heat and Mass Transfer, 2013, 62:463-472.
  • 8Rose J W. An Analysis of Film Condensation on a Horizon- tal Wire-wrapped Tube [ J ]. Chemical Engineering Re- search and Decign, 2002, 80 (3): 290-294.
  • 9Xu S M, Liu Y L, Zhang L S. Performance research of self regenerated absorption heat transformer cycle using TFE-NMP as working fluids [ J ]. International Journal of Refrigeration , 2001, 24 (6) : 510 -518.
  • 10Nusselt W. Die Oberflachenkondensation Des Wass-er- dampfes [ Jl. Z. Verines Deutsch. Ing. 1916, 60: 541 - 546, 569 - 575.

引证文献8

二级引证文献11

化工学报
2014年 第4期

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