| METALS AND METAL MATRIX COMPOSITES |
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| Optimization of Heat Treatment Process of Al-Si-Cu-Mg Cast Alloy Based on CALPHAD Calculation |
| ZHANG Mingshan1, TIAN Yaqiang1, ZHENG Xiaoping1, ZHANG Yuan1, WANG Junsheng2,3,*, CHEN Liansheng1,*
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1 Key Laboratory of the Ministry of Education for Modern Metallurgy Technology, North China University of Science and Technology, Tangshan 063210, Hebei, China
2 School of Materials Science and Engineering, Beijing Institute of Technology, Beijing 100081, China
3 Advanced Research Institute of Multidisciplinary Science, Beijing Institute of Technology, Beijing 100081, China |
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Abstract The optimization of heat treatment process parameters plays an important role in the regulation of microstructure and properties of Al-Si-Cu-Mg cast alloy. In this work, the heat treatment process parameters of Al-Si-Cu-Mg cast alloy were optimized by the combination of thermodynamic calculation and experiment. The results of thermodynamic calculation and differential scanning calorimetry (DSC) show that the formation temperature of low melting point eutectic Al2Cu phase is 501 ℃, and the calculation of thermodynamic software dynamics module shows that Si, Mg and Cu elements reach homogenization diffusion within 5 h at 495 ℃. With the increase of solution temperature and time, eutectic Si gradually fragments, spheroidizes and coarsens. In addition, the microhardness is affected by the degree of solution heat treatment and the morphology of eutectic Si. During the solution heat treatment, the microhardness first increases and then decreases with the increase of solution temperature and time. When the solution temperature is 495 ℃ and the solution time is 12 h, the microhardness reaches the maximum value of (70.8±1.0)HV, and the Feret diameter of spherical eutectic Si is 2.8 μm. When the alloy is aged at 170 ℃, the microhardness of alloy increases gradually, and reaches the peak aging when the aging time is 5 h, and the microhardness reaches (119.0±5.7)HV.
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Published: 25 November 2023
Online: 2023-11-21
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| Fund:Natural Science Foundation of Hebei Province, China (E2022209059,E2020209153 ), and Science and Technology Project of Tangshan(22130217G). |
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1 Lombardi A, Mu W, Ravindran C, et al. Materials Characterization, 2018, 141, 328.
2 Shi Q, Huo Y, Berman T, et al. Scripta Materialia, 2021, 190, 97.
3 Dash M, Makhlouf M. Journal of Light Metals, 2001, 1(4), 251.
4 Cheng W, Liu C Y, Huang H F, et al. Materials Characterization, 2021, 178, 111278.
5 Lados D A, Apelian D, Wang L. Metallurgical and Materials Transactions B, 2011, 42(1), 171.
6 Lin Y C, Luo S C, Huang J, et al. Materials Science and Engineering: A, 2018, 725, 530.
7 Li D Z. Acta Metallurgica Sinica, 2018, 54(2), 129 (in Chinese).
李殿中. 金属学报, 2018, 54(2), 129.
8 Sun W, Xue W, Zhang Y, et al. International Journal of Pavement Research and Technology, 2017, 11(2), 195.
9 Xie J X, Su Y J, Xue D Z, et al. Acta Metallurgica Sinica, 2021, 57(11), 1343 (in Chinese).
谢建新, 宿彦京, 薛德祯, 等. 金属学报, 2021, 57(11), 1343.
10 Ågren J. Current Opinion in Solid State and Materials Science, 1996, 1(3), 355.
11 Jung J G, Cho Y H, Lee J M, et al. Computer Coupling of Phase Diagrams and Thermochemistry, 2019, 64, 236.
12 Zhang M S, Liu K L, Han J Q, et al. Materials Today Communications, 2021, 26, 102055.
13 Hernandez-Sandoval J, Garza-Elizondo G H, Samuel A M, et al. Mate-rials & Design, 2014, 58, 89.
14 Tillová E, Chalupová M, Hurtalová L, et al. Acta Metallurgica Slovaca, 2013, 3, 196.
15 Gao Y X, Yi J Z, Lee P D, et al. Acta Materialia, 2004, 52, 5435.
16 Beroual S, Boumerzoug Z, Paillard B, et al. Journal of Alloys and Compounds, 2019, 784, 1026.
17 Zhao Y Z, Pan F S, P J. The Chjnese JournaI of Nonferrous Metals, 2010, 20(6), 1069 (in Chinese).
赵亚忠, 潘复生, 彭建. 中国有色金属学报, 2010, 20(6), 1069.
18 Li D X, Han M X, Zhang J, et al. Materials Reports, 2021, 35(9), 9003 (in Chinese).
李道秀, 韩梦霞, 张将, 等. 材料导报, 2021, 35(9), 9003.
19 Basavakumar K G, Mukunda P G, Chakraborty M. Materials Characte-rization, 2008, 59(3), 283.
20 Lin Y C, Luo S C, Huang J, et al. Materials Science & Engineering, A, 2018, 725, 530.
21 Vandersluis E, Ravindran C. Journal of Alloys and Compounds, 2020, 838, 155577.
22 Eduardo Spinelli J, Garcia A. Journal of Materials Science: Materials in Electronics, 2014, 25(1), 478.
23 Costa T A, Dias M, Gomes L G, et al. Journal of Alloys and Compounds, 2016, 683, 485.
24 Yang R X, Liu Z Y, Ying P Y, et al. Transactions of Nonferrous Metals Society of China, 2016, 26(5), 1183.
25 Wang Y Q, Deng T Q, Chen Q, et al. Foundry Technology, 2010, 31(10), 1303 (in Chinese).
王元庆, 邓天泉, 陈强, 等. 铸造技术, 2010, 31(10), 1303.
26 Li R X, Li C X, Li R D. Foundry, 2006(10), 1015 (in Chinese).
李润霞, 李晨曦, 李荣德. 铸造, 2006(10), 1015. |
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