摘要
综述了纳米流体强化传热特性的研究现状,着重论述了纳米流体的制备、强化传热特性和强化传热机理。最后指出了纳米流体研究中存在的局限。
出处
《科技创新导报》
2008年第33期9-10,共2页
Science and Technology Innovation Herald
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共引文献70
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1彭小飞,俞小莉,余凤芹.低浓度纳米流体比热容试验研究[J].材料科学与工程学报,2007,25(5):719-722. 被引量:7
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2周春华,尹衍升,师瑞霞,陈守刚.超细Fe_3Al粉末表面处理偶联剂的用量及其作用机理[J].化工学报,2004,55(6):998-1001. 被引量:3
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同被引文献52
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1郭顺松,骆仲泱,王涛,赵佳飞,岑可法.SiO_2纳米流体粘度研究[J].硅酸盐通报,2006,25(5):52-55. 被引量:15
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引证文献4
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1高文忠,柳建华,邬志敏,张青.液体除湿空调的传热强化研究[J].制冷学报,2010,31(3):16-20. 被引量:4
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2骆仲泱,吴越琼,胡倩,王涛,倪明江.碳纳米管-导热油纳米流体导热与流变特性研究[J].高校化学工程学报,2015,29(1):35-42. 被引量:7
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3曾远娴,肖鑫,陈梓云,李文娟,冯发达.导热油基CuO纳米流体的合成及其强化传热研究[J].化工技术与开发,2017,46(4):6-10. 被引量:2
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4王罗斌.表面活性剂对石墨烯润滑油导热性能的影响[J].水利水电施工,2024(4):89-93.
二级引证文献13
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1徐惠斌,宋新南,葛凤华,胡自成,顾锋.常见液体除湿剂池内核态沸腾换热特性[J].化工学报,2013,64(4):1211-1216. 被引量:9
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2徐惠斌,宋新南,葛凤华,胡自成,顾锋.常压下溴化锂水溶液沸腾换热特性实验研究[J].制冷学报,2013,34(3):56-59. 被引量:9
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3李宁,王俊.导热油在化工生产中的应用实践[J].化工管理,2016(9):51-51. 被引量:2
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4罗朋,白建波,李华锋,彭俊,张臻,曹飞,章国芳.基于纳米流体的光伏热联用装置及其理论分析[J].可再生能源,2016,34(5):633-638. 被引量:5
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5李小可,雷鑫宇,邹长军.超声振荡对SiC-EG纳米流体稳定性的影响[J].精细石油化工进展,2016,17(4):52-54.
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6YIN Xiang,KOU Guang-xiao,XU Ai-xiang,FU Tao,ZHU Jie.Effects of TiO2 nanoparticles on thermal conductivity of heat transfer oil[J].Journal of Central South University,2019,26(8):2129-2135. 被引量:8
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7惠庆玲,邹同华,韩晓婉,常亚飞,康博强.真空条件下压力对LiCl溶液沸腾特性的影响[J].化学工程,2020,48(6):40-44.
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8朱杰伟,周璐,张宇航,吉祝昊,马红和.一步法制备铜导热油纳米流体的导热系数与黏度[J].化学工程,2022,50(5):30-35. 被引量:1
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9张雨,铁生年,汪长安.改性纳米碳粉芒硝基纳米流体强化传热[J].材料导报,2022,36(18):44-50. 被引量:1
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2赵国昌,曹磊,宋丽萍,路天栋.纳米流体导热机理研究分析[J].沈阳航空航天大学学报,2013,30(4):7-11. 被引量:9
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3王彩霞,黄云,姚华,叶锋,杨军,丁玉龙.纳米流体研究进展[J].储能科学与技术,2017,6(1):24-34. 被引量:8
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4赵忠超,张东辉,陈育平,周根明.纳米流体强化传热实验研究进展[J].江苏科技大学学报(自然科学版),2011,25(1):44-48. 被引量:8
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