| METALS AND METAL MATRIX COMPOSITES |
|
|
|
|
|
| Microstructure, Mechanical Properties and Wear Resistance Performance of TiCp/7075 Matrix Composite by Vacuum Stirring |
| LIU Jingfu1, QI Li1, LI Guanglong2, QU Yingdong2
|
1 College of Materials Science and Engineering, Liaoning Technical University, Fuxin 123000, China
2 College of Materials Science and Engineering, Shenyang University of Technology, Shenyang 110000, China |
|
|
|
|
Abstract TiCp/7075 composites were prepared by vacuum assisted stirring casting. Phase analysis and microstructure observation of the composite were carried out by XRD and SEM. The mechanical properties and wear resistance of the composite were studied. The investigation shows that the TiC particles are evenly distributed in the 7075 aluminum alloy, and the grain size of as cast 7075 aluminum alloy are significantly refined. TiC particles make the grains shape of the matrix alloy change from 200 μm dendrites to 100 μm equiaxed shape. The Brinell hardness and tensile strength of the composites are 163HBW and 362 MPa, respectively, which are 20.7% and 20.3% higher than that of the matrix. Strengthening mechanism of the composites is fine grain and particle load share mechanism. The wear resistance of the matrix can be improved effectively by addition of TiC particles. Under 10 N load, the wear loss of the composites is 2.9 mg, which is 54.7% lower than the matrix. During the process of wear test, the exposed TiC particles preferentially contact with the wear-resistant material, reducing the effective contact area between the composites and the wear-resistant material, and improving the wear resistance of the composites.
|
|
Published: 23 March 2021
|
|
|
| Fund:National Natural Science Foundation of China (51574167), the Natural Science Foundation of Liaoning (201602356). |
| About author:: Jingfu Liu received his B.E. degree in corrosion from University of Science and Technology Beijing in 1996 and received his Ph.D. degree in materials processing engineering from Shenyang University of Technology in 2008. His research interests are new forming technology and corrosion mechanism of non-ferrous alloys. |
|
|
1 Dong G, Zhao C, Peng Y, et al. Chinese Journal of Mechanical Enginee-ring,2015,28(3),580.
2 Liu T, Su R M, Qu Y D, et al. Chinese Journal of Materials Research,2018,32(4),25(in Chinese).
刘桐,苏睿明,曲迎东,等.材料研究学报,2018,32(4),25.
3 Kumar S, Balasubramanian V. Wear,2008,264,1026.
4 Rao K V S, Govindaraju. Materials Today Proceedings,2017,4(10),11096.
5 Pazhouhanfar Y, Eghbali B. Materials Science & Engineering A,2018,710,172.
6 Kumar K S A, Murigendrappa S M, Kumar H. Journal of Materials Research,2019,34(7),1.
7 Losch K, Schuff S, Balle F, et al. Journal of Microscopy,2019,273(2),1.
8 George J, Janardhanan S, Sijo T M. Advanced Materials Research,2015,1119,533.
9 Huang L J, Geng L, Peng H X. Progress in Materials Science,2015,71,93.
10 Wang J T, Xie L, Luo K Y, et al. Surface and Coatings Technology,2018,349,725.
11 Roohollah R, Farshad A. International Journal of Materials Research,2018,109(6),545.
12 Huang G, Hou W, Shen Y. Materials Characterization,2018,138,26.
13 Yang H, Me Y. Acta Materiae Compositae Sinica,2018,35(4),927(in Chinese).
杨慧,么娆.复合材料学报,2018,35(4),927.
14 Saravanan C, Subramanian K, Anandakrishnan V, et al. Industrial Lubrication and Tribology,2018,70(6),1066.
15 Sijo M T, Jayadevan K R. Procedia Technology,2016,24,379.
16 Canakci A, Varol T. Powder Technology,2014,268,72.
17 Bai P C, Dai X J, Zhao C W, et al. Acta Materiae Compositae Sinica,2008,25(1),88(in Chinese).
白朴存,代雄杰,赵春旺,等.复合材料学报,2008,25(1),88.
18 Fang G, Yu Z, Tan Z, et al. Acta Metallurgica Sinica,2014,27(5),839.
19 Liang Y F, Dong S Q, Li G H. Rare Metal Materials and Engineering,2013,42(7),1377(in Chinese).
梁艳峰,董晟全,李高宏.稀有金属材料与工程,2013,42(7),1377.
20 Shangguan D, Ahuja S, Stefanescu D M. Metallurgical Transactions A,1992,23(2),669.
21 Shen P, Wang Y, Ren L, et al. Applied Surface Science,2015,355(15),930.
22 Qiu F, Tong H T, Shen P, et al. Acta Metallurgica Sinica,2019,55(1),91(in Chinese).
邱丰,佟昊天,沈平,等.金属学报,2019,55(1),91.
23 Kennedy A R,Weston D P, Jones M I. Materials Science and Engineering A,2001,316,32.
24 Singh M, Mondal D P, Modi O P, et al. Wear,2002,253,357.
25 Mabuchi M, Higashi K. Acta Materialia,1996,44(11),4611.
26 Zhang G F, Tan Y Q, Zhang B, et al. Materials Science Forum,2009,626,219.
27 Huang K, Jiang R P, Li X Q, et al. Journal of Materials Engineering,2019,47(12),78.
黄凯,蒋日鹏,李晓谦,等.材料工程,2019,47(12),78.
28 Kumar V, Gautam R K, Tyagi R. Composite Interfaces,2016,23,6. |
|
|
|
渝公网安备50019002502923号 © Editorial Office of Materials Reports.
2021, Vol. 35 
