纳米碳管对泡沫炭的超临界发泡行为及其力学性能的影响机制

无机材料学报, 2011, 26(10): 1020-1024. doi: 10.3724/SP.J.1077.2011.01020

纳米碳管对泡沫炭的超临界发泡行为及其力学性能的影响机制

2. 2. 上海理工大学材料科学与工程学院, 上海200093)

(1. State Key Laboratory of Chemical Engineering, Key Laboratory for Specially Functional Polymers and Related Technology of Ministry of Education, East China University of Science and Technology, Shanghai 200237, China

2. 2. University of Shanghai for Science and Technology, School of Material Science and Engneering, Shanghai 200093, China)

基金项目: 中央高校基本科研业务费专项基金(WA1014016) 国家自然科学基金(50730003, 50672025, 20806024, 51002051) 国家863重点项目(2008AA062302) 国家科技支撑计划项目(2009BAE72B04)

关键词：泡沫炭 , carbon nanotube , supercritical foaming

Effect Mechanisms of Carbon Nanotubes on the Supercritical Foaming Behaviors and Mechanical Performance of Carbon Foam

BAO Ying , WANG Chun-Xiao , ZHAN Liang , WANG Yan-Li , YANG Guang-Zhi , YANG Jun-He , LING Li-Cheng

Keywords： carbon foam , 纳米碳管 , 超临界发泡

采用超声波?磁力搅拌的方法, 实现了纳米碳管(CNTs)在中间相沥青(MP)中的均匀分散, 并考察了CNTs对泡沫炭的超临界发泡行为及其压缩强度的影响. 研究结果表明: 在超临界发泡过程中, 处于过饱和状态的甲苯将优先在CNTs/MP固-液界面处成核, 进而不断扩散、聚集、膨胀和发泡, 导致泡沫炭孔结构的均一性得以提高; 当在中间相沥青中均匀分散3.5wt%的CNTs后, 所制泡沫炭的压缩强度由3.2MPa提高到4.7MPa, 升高了46.9%; CNTs良好的导热性能降低了基体碳在石墨化过程中的热应力差异, 使得微裂纹的数量减少, 并且其一维纳米结构使得石墨化泡沫炭的孔壁和韧带结构得以增强.

Carbon nanotubes (CNTs) were dispersed uniformly into mesophase pitch (MP) by the co-dispersion of ultrasonic and magnetic force stirring. Effects of CNTs on the supercritical foaming behaviors and mechanical performance of carbon foams were investigated. The results indicate that cell nuclei will form firstly at the CNT/MP interface in the supercritical foaming process, and then diffuse, aggregate, expanse and foam. CNTs can improve the homogenicity of pore structure due to the uniform dispersed CNT/MP interface. When MP is mixed with 3.5wt% CNTs, the compressive strength of graphitized foam increases from 3.2MPa to 4.7 MPa. In the graphitization process, the heat-stress different of carbon will decrease due to the high thermal conductivity of CNTs, leading to the decrease of the amount of microcracks. Meanwhile, the one-dimensional structure of CNTs reinforces the mechanical strength of pore walls and ligaments.

参考文献

[1]

Hammel E, Tang X, Trampert M, et al. Carbon nanofibers for composite applications. Carbon, 2004, 42(5/6):1153-1158.

[2] Ge M, Shen Z M, Chi W D, et al. Anisotropy of mesophase pitch-derived carbon foams. Carbon, 2007, 45(1): 141-145.

[3] Wang M X, Wang C Y, Li T Q, et al. Preparation of mesophase-pitch-based carbon foams at low pressures. Carbon, 2008, 46(1): 84-91.

[4] Li S Z, Song Y Z, Song Y, et al. Carbon foams with high compressive strength derived from mixtures of mesocarbon microbeads and mesophase pitch. Carbon, 2007, 45(10): 2092-2097.

[5] Liu M X, Gan L H, Zhao F Q, et al. Carbon foams prepared by an oil-in-water emulsion method. Carbon, 2007, 45(13): 2710-2712.

[6] LI Juan，WANG Can, ZHAN Liang, ZHANG Rui，et al. Effect of Pre-oxidation on the Pore Structure and Foaming Mechanisms of Mesophase Pitch Based Carbon Foam. J. Inorg. Mater., 2009, 24(2): 315-319.

[7] Li J, Wang C, Zhan L, et al. Carbon foams prepared by supercritical foaming method. Carbon, 2009, 47(4):1204-1206.

[8] Lafdi K, Mesalhy O, Elgafy A. Graphite foams infiltrated with phase change materials as alternative materials for space and terrestrial thermal energy storage applications. Carbon, 2008, 46(1): 159-168.

[9] Gallego N C, Burchell T D, Kellt J W. Irradiation effects on graphite foam. Carbon, 2006, 44(8)-: 618-628.

[10] Beechem T, Lafdi K, Elgafy A. Bubble growth mechanism in carbon foams. Carbon, 2005, 43(5): 1055-1064.

[11] Beechem T, Lafdi K. Novel high strength graphitic foams. Carbon, 2006, 44(8): 1548-1559.

[12] Leroy C M, Carn F, Backov R, et al. Multiwalled-carbon- nanotube-based carbon foams. Carbon, 2007, 45(11): 2317-2320.

[13] Li J, Wang C, Zhan L, et al. Carbon foams prepared by supercritical toluene. Journal of Porous Materials, 2010, 17(6): 685-691.

上一张下一张

计量

下载量()
访问量()

作者相关

文章评分

您的评分：
1

0%
2

0%
3

0%
4

0%
5

0%

材料期刊网