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片层石墨尺寸对片层石墨/Al复合材料的强度和热导率的影响
Effect of Graphite Flake Size on the Strength and Thermal Conductivity of Graphite Flakes/Al Composites

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刘晓云 1   王文广 2   王东 2   肖伯律 2   倪丁瑞 2   陈礼清 3   马宗义 2 *  
文摘 采用粉末冶金法制备了名义尺寸为150、300、500 μm的片层石墨(graphite flakes, G_f)增强铝基(50%G_r/Al,体积分数)复合材料,得到密度均接近理论密度的致密复合材料坯锭。片层石墨与铝合金基体结合紧密,界面处无裂纹、孔洞等缺陷。片层石墨的(001)G_f基面与复合材料坯锭的圆周方向(坯锭的xy平面)基本平行,但受粉末冶金工艺的影响,较小片层石墨的(001G_f基面与坯锭的xy平面略有偏差。随着片层石墨的尺寸增大,偏差逐渐减少。复合材料的强度随着片层石墨尺寸增加逐渐降低。150 μm片层石墨复合材料的弯曲强度为82 MPa,当片层石墨尺寸增至500 μm时,强度降低至39 MPa。片层石墨强度较低,裂纹容易沿片层石墨的层间扩展,随着片层石墨尺寸增大,这一现象更加明显,容易在断口中观察到片层石墨剥离的现象。复合材料xy平面的热导率随片层石墨尺寸增大而增加,最高可达604 W/(m.K),与尺寸较小的片层石墨相比提高63%。300、500 μm片层石墨复合材料的界面换热系数略低于理论值,但150 μm片层石墨复合材料的界面换热系数明显小于理论值。除了片层石墨的尺寸,其形状、分布和内部缺陷等对复合材料的热导率也有一定的影响。
其他语种文摘 Graphite flakes reinforced Al matrix composites (Gf/AI) with low density, good machining property and high thermal conductivity are considered an excellent heat sink materials used in electronic industry. When the composites are manufactured by liquid method such as liquid infiltration, it is easy to achieve a high thermal conductivity composite. However, the Al_4C_3 phase would be formed in the composite, which will decrease the corrosion properties of the composites. The powder metallurgy technique could avoid the formation of the Al_4C_3 phase. In this work, three seized graphite flakes (150,300, 500 μm) were used to investigate the effect of the graphite flake size on the strength and thermal conductivity of G_f/AI alloy composites. The 50%G_f/AI alloy (volume fraction) composites were fabricated by the powder metallurgy technique. The density of all the three G_f/AI alloy composites were similar to the theoretical density. The graphite flakes had a well bonding with Al alloy matrix without cracks and pores. The (001)G_f basal plane of the graphite flakes were almost parallel to the circular plane (xy plane) of the composites ingot. However, for the small graphite flakes, their (001)G_f basal plane was not well parallel to the xy plane of the composite ingot due to the powder metallurgy process. For the large graphite flakes, they exhibited a good orientation in the xy plane of the composite ingot. The strength of the G_f/AI alloy composites decreased with the increase of the graphite flake size. For the 150 μm graphite flake, the bending strength of the G_f/AI alloy composite was 82 MPa. However, for the 500 μm graphite flake, the bending strength of the composite decreased to 39 MPa.Due to the low strength between the layers of the graphite flake, the cracks were prone to expand in the graphite flake. As the size of the graphite flake increased, this phenomenon became more obviously. It is easy to observe that the graphite flakes peeled off on the fracture surfaces. When the size of the graphite flake increased from 150 μm to 500 μm, the thermal conductivity increased by 63 %. The highest thermal conductivity was 604 W/(m.K). The interfacial thermal conductance (h_c) of the composites were calculated by the Maxwell-Garnett type effective medium approximation model. The h_c of 300 and 500 μm graphite flake G_f/AI alloy composites were slightly lower than the theoretical value (calculated by the acoustic mismatch model). However, the h_c of the 150 μm graphite flake G_f/AI alloy composite was lower than that of the theoretical value. Besides the size of the graphite flakes,the shape, distribution and defect of the graphite flakes also influenced the thermal conductivity of the composites.
来源 金属学报 ,2017,53(7):869-878 【核心库】
DOI 10.11900/0412.1961.2017.00015
关键词 片层石墨 ; 铝基复合材料 ; 热导率 ; 力学性能
地址

1. 东北大学, 轧制技术及连轧自动化国家重点实验室;;沈阳材料科学国家(联合)实验室, 沈阳, 110819  

2. 中国科学院金属研究所, 沈阳材料科学国家(联合)实验室, 沈阳, 110016  

3. 东北大学, 轧制技术及连轧自动化国家重点实验室, 沈阳, 110819

语种 中文
文献类型 研究性论文
ISSN 0412-1961
学科 金属学与金属工艺
基金 国家自然科学基金
文献收藏号 CSCD:6015440

参考文献 共 26 共2页

1.  Sidhu S S. Metal matrix composites for thermal management: A review. Crit. Rev. Solid State Mater. Sci,2016,41:132 CSCD被引 7    
2.  Mathias J D. Architectural optimization for microelectronic packaging. Appl. Therm. Eng,2009,29:2391 CSCD被引 4    
3.  Rawal S P. Metal-matrix composites for space applications. JOM,2001,53(4):14 CSCD被引 70    
4.  夏杨. 热管理材料的研究进展. 材料导报,2008,22(1):4 CSCD被引 1    
5.  Xue C. Enhanced thermal transfer and bending strength of SiC/Al composite with controlled interfacial reaction. Mater. Des,2014,53:74 CSCD被引 13    
6.  Liu X Y. Effect of nanometer TiC coated diamond on the strength and thermal conductivity of diamond/Al composites. Mater. Chem. Phys,2016,182:256 CSCD被引 7    
7.  Yoshida K. Thermal properties of diamond/copper composite material. Microelectron. Reliab,2004,44:303 CSCD被引 75    
8.  Fu H T. Synthesis by vacuum infiltration,microstructure, and thermo- physical properties of graphite-aluminum composite. Adv. Eng. Mater,2016,18:1609 CSCD被引 1    
9.  Zhou S X. Modeling the in-plane thermal conductivity of a graphite/polymer composite sheet with a very high content of natural flake graphite. Carbon,2012,50:5052 CSCD被引 7    
10.  Li W J. Preparation of graphite flakes/Al with preferred orientation and high thermal conductivity by squeeze casting. Carbon,2015,95:545 CSCD被引 22    
11.  Kurita H. Interfacial microstructure of graphite flake reinforced aluminum matrix composites fabricated via hot pressing. Composites, A,2015,73:125 CSCD被引 4    
12.  Prieto R. Thermal conductivity of graphite flakes- SiC particles/metal composites. Composites, A,2011,42:1970 CSCD被引 12    
13.  Yang Y W. Interfacial characteristic,thermal conductivity, and modeling of graphite flakes/Si/Al composites fabricated by vacuum gas pressure infiltration. J. Mater. Res,2016,31:1723 CSCD被引 1    
14.  Prieto R. Fabrication and properties of graphite flakes/metal composites for thermal management applications. Scr. Mater,2008,59:11 CSCD被引 28    
15.  Chen J K. Thermal properties of aluminum- graphite composites by powder metallurgy. Composites, B,2013,44:698 CSCD被引 26    
16.  Wang D. Friction stir welding of SiC_p/ 2009A1 composite plate. Mater. Des,2013,47:243 CSCD被引 12    
17.  Huang Y. Graphite film/aluminum laminate composites with ultrahigh thermal conductivity for thermal management applications. Mater. Des,2016,90:508 CSCD被引 10    
18.  Zhou C. In-plane thermal enhancement behaviors of Al matrix composites with oriented graphite flake alignment. Composites, B,2015,70:256 CSCD被引 10    
19.  Wang D. Evolution of the Microstructure and Strength in the Nugget Zone of Friction Stir Welded SiCp/Al-Cu-Mg Composite. J. Mater. Sci. Technol,2014,30:54 CSCD被引 14    
20.  Xue C. Thermal conductivity and mechanical properties of flake graphite/Al composite with a SiC nano- layer on graphite surface. Mater. Des,2016,108:250 CSCD被引 19    
引证文献 3

1 刘晓云 热循环对片层石墨/铝复合材料的强度和热导率的影响 复合材料学报,2021,38(4):1192-1199
CSCD被引 0 次

2 刘园 高效热管理用鳞片石墨/铝复合材料的研究进展 功能材料,2022,53(1):01025
CSCD被引 0 次

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