小尺度蒸发器的数值模拟及优化研究Numerical Simulation and Optimization on the Small-scale Evaporator
夏源,徐厚达,王守国,曹锋
XIA Yuan,XU Hou-da,WANG Shou-guo,CAO Feng
摘要(Abstract):
为了使差示扫描量热仪中加热炉快速的从400℃以上的高温冷却到室温,设计了一套采用小尺度蒸发器的单级制冷系统。为保证冷却过程中蒸发器内部温度场的均匀性及冷却效果,利用CFD商业软件,对该蒸发器内部流体的温度场进行数值模拟,并对蒸发器表面温度进行了试验测量。试验结果表明,蒸发器内壁面温度达到设计要求(-35℃);蒸发器整体温度分布均匀,轴向温差小于1℃;模拟结果与试验测量结果基本吻合。在此基础上进一步对该蒸发器进行了优化设计,将其内壁面改为波纹面,采用波纹面的蒸发器与加热炉的换热空间内,被冷却空气的比例增大,空气出口温度明显降低,冷却效果增强。
A refrigeration system with a small-scale evaporator for cooling the heating furnace of the Differential Scanning Calorimeter from 400℃ to ambient temperature rapidly was designed. To ensure the temperature uniformity and the cooling effect in the evaporator during the cooling process,the evaporator temperature distribution was simulated by using the CFD commercial software and measured experimentally. The temperature of the evaporator reaches the design requirements(- 35℃); The overall temperature distributes uniformly,and the axial temperature difference is less than 1℃; The results obtained by numerical simulating was in agreement with the experimental data. Further more,the optimization design was conducted by changing the inner surface of the evaporator into the wavy surface. The proportion of air to be cooled between the evaporator and the furnace increased and the outlet temperature of the air decreased obviously. The cooling effect is improved through the optimization.
关键词(KeyWords):
小尺度;蒸发器;数值模拟;试验研究;优化设计
small-scale;evaporator;numerical simulation;experiment study;optimization design
基金项目(Foundation): 国家自然科学基金资助项目(51176144);; 广东省政府和教育部合作项目(2011B090400470)
作者(Author):
夏源,徐厚达,王守国,曹锋
XIA Yuan,XU Hou-da,WANG Shou-guo,CAO Feng
参考文献(References):
- [1]汪蕊,贺小华.薄膜蒸发器内流体流动模拟[J].南京工业大学学报,2004,26(1):72-77.
- [2]王军,吴苇,罗荣,等.空调用贯流风机的内流模拟与性能研究[J].工程热物理学报,2003,24(4):592-694.
- [3]Guilherme B.Ribeiro,Jader R.Barbosa,Alvaro T Prata.Mini-channel evaporator/heat pipe assembly for a chip cooling vapor compression refrigeration system[J].International journal of refrigeration,2010,33:1402-1412.
- [4]Chen Lin,Wenjian Cai,Yanzhong Li,et al.Pressure recovery ratio in a variable cooling loads ejector-based multi-evaporator refrigeration system[J].Energy,2012,44:649-656.
- [5]Mithraratne P,Wijeysundera N E.An experimental and numerical study of the dynamic behavior of a counterflow evaporator[J].International journal of refrigeration,2001,24:554-565.
- [6]阮并璐,刘广彬,赵远扬,等.制冷系统中水平管降膜式蒸发器内部流动数值模拟[J].西安交通大学学报,2008,42(3):318-322.
- [7]张猛,周帼彦,朱冬生.降膜蒸发器的研究进展[J].流体机械,2012,40(6):82-86.
- [8]吴开荣,金苏敏.组合式热管蒸发器在污水源热泵中的应用[J].流体机械,2011,39(4):82-86.
- [9]Kakac S,Bon B.A Review of two-phase flow dynamic instabilities in tube boiling systems[J].International Journal of Heat and Mass Transfer,2007,51(3):399-433.
- [10]仲崇宝,周长茂,孔铁,等.基于Fluent的夹套式热管热交换器的数值模拟[J].石油化工设备,2012,41(2):12-14.
- [11]孙东亮,徐进良,王丽.求解两相蒸发和冷凝问题的气液相变模型[J].西安交通大学学报,2012,46(7):7-11.
- [12]孙艳,魏峰.自然循环蒸发器内流动和传热的数值模拟研究[J].流体机械,2012,40(9):76-78.
- [13]Hanfei Tuo,Pega Hrnjak.Flash gas bypass in mobile air conditioning system with R134a[J].International journal of refrigeration,2012,35:1869-1877.
- [14]Rousseau P G,Greyvenstein G P.Enhancing the impact of heat pump water heaters in the South African commercial sector[J].Energy,2000,25:51-70.
- [15]吴业正.制冷与低温技术原理[M].北京:高等教育出版社,2004,8.
- [16]陶文铨.数值模拟学(第二版)[M].西安:西安交通大学出版社,2001,5.
- [17]Pzfreezerar S V.Numberical Heat Transfer and Fluid Flow[M].New York:Mc Gra N-Hill Book Company,1987.
- [18]魏小兵,江楠,曾纪成.新型纵向流油冷却器传热性能及压降的试验研究[J].压力容器,2012,29(6):13-17.
- [19]杨世铭,陶文铨.传热学(第四版)[M].北京:高等教育出版社,2006,8.