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多元醇二元体系纤维复合相变材料的传热性能 被引量:5

Fiber-enhanced heat conduction of polyalcohol binary systems
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摘要 多元醇热传导系数较低,纤维复合相变材料将纤维材料与多元醇联合起来以改善多元醇的传热特性。FLUENT数值计算软件用于模拟多元醇二元体系PE/TRIS的贮热温度场。通过实验验证,模拟时建立的物理模型是可信的。模拟结果显示,插入多元醇的铜纤维可改进多元醇的传热性能,通过铜纤维传递的热量和通过容器壁传递的热量相当。为了进一步提高多元醇的热响应特性,有必要插入与底部加热板平行的铜纤维。 Polyalcohol is considered as a promising candidate of phase change material for heat storage,but it presents poor heat conduction performance.Fiber-enhanced polyalcohol binary system combines polyalcohol with copper fiber to improve its heat conduction.FLUENT software is used to simulate the temperature field of polyalcohol binary system PE/TRIS in this study,in which molar capacity of polyalcohol binary system PE/TRIS is fitted to polynomial equations.Simulation results present the same trend of temperature distribution in the fiber-enhanced polyalcohol binary system as experimental data.Therefore,the physical model for the simulation is reliable.The simulation shows that fiber planes do contribute to heat conduction.The heat flux first declines sharply with time with or without fiber planes inserted,and then becomes steady.The heat conducted through fiber planes in fiber-enhanced polyalcohol is the main heat flux and is comparable with the heat conducted through five boundary walls.The fiber-enhanced polyalcohol binary system shows quicker response to heat input than the polyalcohol binary system PE/TRIS without fiber.To perfect the temperature field,fiber planes parallel to the bottom copper board should be added to the polyalcohol heat storage system.
作者 王小伍 黄玮
出处 《化工学报》 EI CAS CSCD 北大核心 2013年第8期2839-2845,共7页 CIESC Journal
基金 国家自然科学基金项目(21106048)~~
关键词 多元醇 热传导性能 温度 强化传热 贮热 polyalcohol heat conduction performance temperature heat transfer enhancement heat storage
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参考文献18

  • 1Sturz L,Witusiewicz V T,Hecht U,Rex S.Organic alloy systems suitable for the investigation of regular binary and ternary eutectic growth[J].Journal of Crystal Growth,2004,270:273-282.
  • 2Dhanesh Chandra,Raja Chellappa,Chien Wen-Ming. Thermodynamic assessment of binary solid-state[J].Journal of Physics and Chemistry of Solids,2005,66:235-240.
  • 3Raja Chellappa,Renee Russell,Dhanesh Chandra. Thermodynamic modeling of the C(CH2OH)4-(NH2)(CH3)C(CH2OH)2 binary system[J].Computer Coupling of Phase Diagrams and Thermochemistry,2004,28:3-8.
  • 4Raja Chellappa,Dhanesh Chandra.Phase diagram calculations of organic "plastic crystal" binaries:(NH2)(CH3)C(CH2OH)2-(CH3)2C(CH2OH)2 system[J].Computer Coupling of Phase Diagrams and Thermochemistry,2003,27:133-140.
  • 5Victor Timofey Witusiewicz,Ulrike Hecht,Laszlo Sturz,Stephan Rex.Phase equilibria and eutectic growth in ternary organic system camphor-neopentylglycol-succinonitrile[J].Journal of Crystal Growth,2006,286:431-439.
  • 6Mogeritsch J P,Ludwig A,Eck S,Grasser M,McKay B J.Thermal stability of a binary non-faceted/non-faceted peritectic organic alloy at elevated temperatures[J].Scripta Materialiam,2009,60:882-885.
  • 7Feng Haiyan(冯海燕),Liu Xiaodi(刘晓地),He Shumei(何书美),Wu Kezhong(武克忠),Zhang Jianling(张建玲).Studies on solid-solid phase transition of polyols and their binary mixtures by infrared spectroscopy[J].物理化学学报,1999,15:850-855.
  • 8Zhang Zhiying,Xu Yupeng.Measurement of the thermal conductivities of 2-amino-2-methyl-1,3-propanediol(AMP), 2-amino-2-hydroxymethyl-1,3-propanediol(TRIS)and the mixture(AMP+TRIS,mole ratio 50:50)in the temperature range from 20℃ to their supermelting temperatures[J].Solar Energy,2001,71:299-303.
  • 9Suresh Divi,Raja Chellappa,Dhanesh Chandra.Heat capacity measurement of organic thermal energy storage materials[J].J.Chem.Thermodynamics,2006,38:1312-1326.
  • 10王小伍,徐海红.多元醇固——固相变机理的研究[J].物理学报,2011,60(3):130-133. 被引量:8

二级参考文献57

  • 1Kim D W. Convection and flow boiling in microgaps andporous foam coolers [ D ].Maryland: University ofMaryland . 2007.
  • 2Zhao C Y, Lu W, Tassou S A. Flow boiling heat transferin horizontal metal-foam tubes [J].Journal of HeatTransfer-I'ransactions of the ASME, 2009,131 (12):121002-1.
  • 3Chen Z Q, Cheng P, Zhao T S. An experimental study oftwo phase flow and boiling heat transfer in bi-dispersedporous channels [ J ].Int. Comm. Heat Mass Transfer ,2000, 27 (3): 293-302.
  • 4Ji X B, Xu J L. Experimental study on the two-phasepressure drop in copper foams [ J Heat and MassTransfer, 2012,48 (1): 153-164.
  • 5Topin F,Bonnet J P,Madani B,Tadrist L. Experimentalanalysis of multiphase flow in metallic foam: flow laws,heat transfer and convective boiling [ J ].Adv. Eng.Mater. , 2006, 8 (9) : 890-899.
  • 6Hu H T,Ding G L,Wei W J, Wang Z C, Wang KJ. Measurement and correlation of frictional pressure drop ofR410A/oil mixture flow boiling in a 7mm straight smoothtube [J].HVAC^R Research, 2008,14 (5); 763-781.
  • 7Wojtan L. Experimental and analytical investigation of voidfraction and heat transfer during evaporation in horizontaltubes [ D ].Lausanne: Swiss Federal Institute ofTechnology, 2004.
  • 8Moffat R J. Describing the uncertainties in experimentalresults [J].Experimental Thermal and Fluid Science,1998, 1 (1): 3-17.
  • 9Hu H T, Ding G L, Wang K J. Measurement andcorrelation of frictional two-phase pressure drop of R410A/POE oil mixture flow boiling in a 7mm straight micro-fintube [J].Applied Thermal Engineering, 2008,28 (11/12): 1272-1283.
  • 10Ergun S,Orning A A. Fluid flow through randomly packedcolumns and fluidized beds [ J ]? Industrial andEngineering Chemistry Research,1949,41 (6): 1179-1184.

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