Mechanical and thermal expansion properties of SiCp/ZAlSi9Mg composites produced by centrifugal casting

Kai Wang; Tao Jiang; Zhili Huang; Hansong Xue; Dazhuang Yang; Zizong Zhu

doi:10.1007/s11595-016-1352-5

Journal of Wuhan University of Technology Materials Science Edition ›› 2016, Vol. 31 ›› Issue (1) : 197 -203. DOI: 10.1007/s11595-016-1352-5

Metallic Materials

Mechanical and thermal expansion properties of SiC_p/ZAlSi9Mg composites produced by centrifugal casting

Author information +

History +

PDF

Abstract

Centrifugal casting was applied to produce cylindrical castings using SiCp/Al composite slurry, which contained 20% SiC particles. The castings comprised a particle free zone and a particle rich zone. The amount of SiC particles had a dramatic transformation from the particle rich zone to the particle free zone, and the maximum content of SiC particles in the particle rich zone reached up to 40 vol%. The ultimate tensile strength (UTS) of the as-cast SiCp / Al composites in the particle rich zone was 143 MPa, and the fracture was caused by the desorption of SiC particles from matrix alloy. The coefficient of thermal expansion (CTE) of the SiC_p / Al composites in the range of 20 and 100 °C was determined as 16.67×10^-6 s^-1, and the experimental CTE was lower than the predicted data based on the Kerner’s model. The results show that the decrease in CTE in the case of the composites at high temperature stage can be attributed to the solute concentration of Si in Al and the plastic deformation of the matrix alloy in the composites with void architecture.

Keywords

metal-matrix composites / aluminum / thermal expansion property / mechanical property / casting

Cite this article

Download citation ▾

Kai Wang, Tao Jiang, Zhili Huang, Hansong Xue, Dazhuang Yang, Zizong Zhu. Mechanical and thermal expansion properties of SiC_p/ZAlSi9Mg composites produced by centrifugal casting. Journal of Wuhan University of Technology Materials Science Edition, 2016, 31(1): 197-203 DOI:10.1007/s11595-016-1352-5

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Lee HS, Yeo JS, Hong SH, et al. The Fabrication Process and Mechanical Properties of SiCp/Al-Si Metal Matrix Composites for Automobile Air-conditioner Compressor Pistons[J]. Journal of Materials Processing Technology, 2001, 113(1-3): 202-208.

[2]	Ortega-Celaya F, Pech-Canul M I L-, Cuevas J, et al. Microstructure and Impact Behavior of Al/SiCp Composites Fabricated by Pressureless Infiltration with Different Types of SiCp[J]. Journal of Materials Processing Technology, 2007, 183(2-3): 368-373.

[3]	Chen N, Zhang H, Gu M, et al. Effect of Thermal Cycling on the Expansion Behavior of Al/SiCp Composite[J]. Journal of Materials Processing Technology, 2009, 209(3): 1 471-1 476.

[4]	Zhang Q, Wu G, Jiang L, et al. Thermal Expansion and Dimensional Stability of Al-Si Matrix Composite Reinforced with High Content SiC[J]. Materials Chemistry and Physics, 2003, 82(3): 780-785.

[5]	Park CS, Kim CH, Kim MH, et al. The Effect of Particle Size and Volume Fraction of the Reinforced Phases on the Linear Thermal Expansion in the Al–Si–SiCp System[J]. Materials Chemistry and Physics, 2004, 88(1): 46-52.

[6]	Beffort O, Long S, Cayron C, et al. Alloying Effects on Microstructure and Mechanical Properties of High Volume Fraction SiC-particle Reinforced Al-MMCs Made by Squeeze Casting Infiltration[J]. Composites Science and Technology, 2007, 67(3-4): 737-745.

[7]	Aghajanian MK, Rocazella MA, Burke JT, et al. The Fabrication of Metal Matrix Composites by a Pressureless Infiltration Technique[J]. Journal of Materials Science, 1991, 26(2): 447-454.

[8]	Bahraini M, Minghetti T, Zoellig M, et al. Activated Pressureless Infiltration of Metal-matrix Composites with Graded Activator Content[J]. Composites Part A: Applied Science and Manufacturing, 2009, 40(10): 1 566-1 572.

[9]	Dash K, Ray BC, Chaira D. Synthesis and Characterization of Copperalumina Metal Matrix Composite by Conventional and Spark Plasma Sintering[J]. Journal of Alloys and Compounds, 2012, 516: 78-84.

[10]	Scudino S, Liu G, Prashanth KG, et al. Mechanical Properties of Albased Metal Matrix Composites Reinforced with Zr-based Glassy Particles Produced by Powder Metallurgy[J]. Acta Materialia, 2009, 57(6): 2 029-2 039.

[11]	Yue TM, Chadwick GA. Squeeze Casting of Light Alloys and Their Composites[J]. Journal of Materials Processing Technology, 1996, 58(2-3): 302-307.

[12]	Wang K, Cheng JF, Sun WJ, et al. An Approach for Increase of Reinforcement Content in Particle Rich Zone of Centrifugally Cast SiCp/Al Composites[J]. Journal of Composite Materials, 2011, 46(9): 1 021-1 027.

[13]	Hoffman M, Skirl S, Pompe W, et al. Thermal Residual Strains and Stresses in Al₂O₃/Al Composites with Interpenetrating Networks[J]. Acta Materialia, 1999, 47(2): 565-577.

[14]	Benal MM, Shivanand HK. Influence of Heat Treatment on the Coefficient of Thermal Expansion of Al (6061) Based Hybrid Composites[J]. Materials Science and Engineering: A, 2006, 435-436: 745-749.

[15]	Seo YH, Kang CG. The Effect of Applied Pressure on Particledispersion Characteristics and Mechanical Properties in Melt-stirring Squeeze-cast SiCp/Al Composites[J]. Journal of Materials Processing Technology, 1995, 55(3-4): 370-379.

[16]	Wang K, Sun W, Li B, et al. Microstructures in Centrifugal Casting of SiCp/AlSi9Mg Composites with Different Mould Rotation Speeds[J]. Journal of Wuhan University of Technology -Mater. Sci. Ed., 2011, 26(3): 504-509.

[17]	Schöbel M, Altendorfer W, Degischer HP, et al. Internal Stresses and Voids in SiC Particle Reinforced Aluminum Composites for Heat Sink Applications[J]. Composites Science and Technology, 2011, 71(5): 724-733.

[18]	Schöbel M, Degischer HP, Vaucher S, et al. Reinforcement Architectures and Thermal Fatigue in Diamond Particle-reinforced Aluminum[J]. Acta Materialia, 2010, 58(19): 6 421-6 430.

[19]	Rodríguez-Castro R, Wetherhold RC, Kelestemur MH. Microstructure and Mechanical Behavior of Functionally Graded Al A359/SiCp Composite[J]. Materials Science and Engineering: A, 2002, 323(1-2): 445-456.

[20]	Mazahery A, Shabani MO. Mechanical Properties of Squeeze-Cast A356 Composites Reinforced With B4C Particulates[J]. Journal of Materials Engineering and Performance, 2012, 21(2): 247-252.

[21]	Leggoe JW, Hu XZ, Bush MB. Crack Tip Damage Development and Crack Growth Resistance in Particulate Reinforced Metal Matrix Composites[J]. Engineering Fracture Mechanics, 1996, 53(6): 873-895.

[22]	Elomari S, Skibo MD, Sundarrajan A, et al. Thermal Expansion Behavior of Particulate Metal-matrix Composites[J]. Composites Science and Technology, 1998, 58(3-4): 369-376.

[23]	Lemieux S, Elomari S, Nemes JA, et al. Thermal Expansion of Isotropic Duralcan Metal-matrix Composites[J]. Journal of Materials Science, 1998, 33(17): 4 381-4 387.

[24]	Geiger AL, Jackson M. Low-Expansion MMCs Boost Avionics[J]. Advanced Materials and Processes, 1993, 7(136): 23-30.

[25]	Hahn TA, Armstrong RW. Internal Stress and Solid Solubility Effects on the Thermal Expansivity of Al-Si Eutectic Elloys[J]. International Journal of Thermophysics, 1988, 9(2): 179-193.

[26]	Berry CR. Effect of Internal Strains on Linear Expansion, X-ray Lattice Constant, and Density of Crystals[J]. Journal of Applied Physics, 1953, 24(5): 658-659.

[27]	Neite G, Mielke S. Thermal Expansion and Dimensional Stability of Alumina Fibre Reinforced Aluminium Alloys[J]. Materials Science and Engineering: A, 1991, 148(1): 85-92.

[28]	Elomari S, Boukhili R, San Marchi C, et al. Thermal Expansion Responses of Pressure Infiltrated SiC/Al Metal-matrix Composites[J]. Journal of Materials Science, 1997, 32(8): 2 131-2 140.

[29]	Schöbel M, Requena G, Kaminski H, et al. Residual Stresses and Void Kinetics in AISiC MMCs during Thermal Cycling[J]. Materials Science Forum, 2008, 571-572: 413-418.

[30]	Wang K, Xue HS, Zou MH, et al. Microstructural Characteristics and Properties in Centrifugal Casting of SiC_p/Zl104 Composite[J]. Transactions of Nonferrous Metals Society of China, 2009, 19(6): 1 410-1 415.