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潜热型功能热流体的制备及其传热和流动特性研究进展 被引量:13

Research on preparation, heat transfer and flow characteristics of latent functionally thermal fluid
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摘要 介绍了我们近年来对潜热型功能热流体制备、流动和强化换热特性的研究.潜热型功能热流体换热能力比普通流体强,其强化换热的物理机制为:相变颗粒为分布内热源或热汇,相变颗粒的存在改变了流体的温度分布;自研潜热型功能热流体可看成牛顿流体,摩擦阻力系数符合64/Re关系,粘度约是水的5.57倍,优于国内外文献中报道的同类材料的粘度.由于存在相变,相同换热量下泵耗比水小,实际应用的经济性和可行性较好. Our recent research on the preparation, heat and flow characteristics of latent functionally thermal fluid (LFTF) is introduced. The results show that: compared with conventional heat transfer fluid, LFTF is of higher heat transfer and transportation ability. The mechanism for that is the function of micro phase change material particles is the same as distributed internal heat sources or sinks; the LFTF developed by us can be considered as Newtonian liquid from its rbeological characteristics; the friction factor of the LFTF conforms to the rule of 64/Re and its viscosity is about 5.57 times of that of water, which is much lower than those reported in the literature; for given heat transportation quantity, due to phase change, the pump consumption for the LFTF decrease greatly compared with water; the LFTF has good application feasibility.
作者 张寅平 王馨 陈斌娇 徐慧 杨睿
机构地区 清华大学建筑技术科学系 清华大学化学工程系
出处 《高技术通讯》 CAS CSCD 北大核心 2006年第5期485-491,共7页 Chinese High Technology Letters
基金 国家自然科学基金(50436020,50076020)、973计划(G2000026309)、教育部优秀青年教师资助计划(教人司[2001]39号)、北京市科技计划(H021820040620)资助项目.
关键词 潜热型功能热流体 相变 热物性 流动阻力 换热强化 latent functionally thermal fluid (LFTF), phase change, thermal performance, flow resistance, heat transfer enhancement
分类号 TK124 [动力工程及工程热物理—工程热物理] TD722 [矿业工程—矿井通风与安全]
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  • 1张寅平,胡先旭,郝磬,王馨.Convective heat transfer enhancement of laminar flow of latent functionally thermal fluid in a circular tube with constant heat flux: internal heat source model and its application[J].Science China(Technological Sciences),2003,46(2):131-140. 被引量:10
  • 2Xie Chunbo,Ind Eng Chem Res,1992年,31卷,3期,727页
  • 3Kasza K E, Chen M M. Improvement of the performance of solar energy or waste heat utilization systems by using phase-change slurry as an enhanced heat-transfer storage fluid. Journal of Solar Energy Engineering, 1985, 107:229-236.
  • 4Charunyakorn P,Sengupta S, Roy S K. Forced convection heat transfer in microencapsulated phase change material slurries:Flow in circular ducts. Int J Heat Transfer, 1991, 34(3): 819-833.
  • 5Inaba H, Sato K. Fundamental study on latent cold heat energy storage by means of direct-contact-freezing between oil droplets and cold water solution. Journal of Heat Transfer-Transactions of the ASME, 1996, 118:799-802.
  • 6Inaba H, Morita S. Flow and cold heat-storage characteristics of phase-change emulsion in a coiled double-tube heat-exchanger.Journal of Heat Transfer-Transactions of the ASME, 1995, 117(2): 440-446.
  • 7Inada H, Sato K A. Measurement of interfacial tension between tetradecane and ethylene glycol water solution by means of the pendant drop method. Fluid Phase Equilibria, 1996, 125:159-168.
  • 8Inaba H, Sato K. Latent cold heat energy storage characteristics by means of direct-contact-freezing between oil droplets and cold water solution. Int J Heat Mass Transfer, 1997, 40 (13):3189-3200.
  • 9He B, Mari G. Fredrik setterwall, paraffin waxes and their binary mixture as phase change materials(PCMs) for cool storage in district cooling system. IEA Annex 10, Phase Change Materials and Chemical Reaction for Thermal Energy Storage First Workshop, 16-17 April 1998, Adana, Turkey, 45-56.
  • 10Inaba H. New challenge in advanced thermal energy transportation using functionally thermal fluids. Int J Therm Sci, 2000,39:991-1003.

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高技术通讯
2006年 第5期

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