Densification of SiCp/Al-Fe-V-Si Composites by the Wedge Rolling Method

• Published in: Materials Vol. 16; no. 12; p. 4290
• Main Authors: He, Yiqiang, Huan, Changbao, Su, Qianhang, Zuo, Lijie, Feng, Wen, Ding, Yunfei, Shang, Feng, Luo, Yi, Feng, Lichao, Wang, Yan, Gu, Hang
• Format: Journal Article
• Language: English
• Published: Switzerland MDPI AG 09.06.2023; MDPI
• Subjects: al-matrix composite; Aluminum; Aluminum alloys; Composite materials; Deformation; Deformation mechanisms; Densification; Flow velocity; Formability; Grain size; Heat transfer; High temperature; Hot pressing; Hot rolling; Iron; Mathematical analysis; Mechanical properties; microstructure; Oxide coatings; Particulate composites; Plane strain; Plastic deformation; Porosity; Porous metals; Preforming; Pressing; Silicon carbide; Simulation; Specific gravity; spray deposition; Tensile strength; Titanium alloys; True strain; wedge pressing; United States > US; microstructure; spray deposition; wedge pressing; densification; al-matrix composite
• ISSN: 1996-1944; 1996-1944
• DOI: 10.3390/ma16124290

The densification of a SiCp/Al-Fe-V-Si billet was achieved by reducing the pores and oxide film between the particles by rolling. The wedge pressing method was used to improve the formability of the composite after jet deposition. The key parameters, mechanisms, and laws of wedge compaction were studied. The results showed that the pass rate was reduced by 10 to 15 percent when using steel molds during the wedge pressing process if the distance between the two ends of the billet was about 10 mm, which was beneficial to improve the compactness and formability of the billet. The density and stress of the surface of the material were higher than those of the interior, where the distribution of density and stress tended to be uniform as the overall volume of the material shrank. During the wedge extrusion process, the material in the preforming area was thinned along the thickness direction, while the material in the main deformation area was lengthened along the length direction. Under plane strain conditions, the wedge formation of spray-deposited composites follows the plastic deformation mechanism of porous metals. The true relative density of the sheet was higher than the calculated value during the initial stamping phase, but was lower than the calculated value when the true strain exceeded 0.55. This was due to the accumulation and fragmentation of SiC particles, which made the pores difficult to remove.