Zeng Y, Himmler D, Randelzhofer P, Körner C (2020)
Publication Language: English
Publication Type: Journal article
Publication year: 2020
Book Volume: 110
Pages Range: 1589-1599
Journal Issue: 5-6
DOI: 10.1007/s00170-020-05956-w
High shear technology (HST) is an advanced melt stirring technology with the intensive shear effect and allows the production of particle-reinforced Al composites (PAMCs) with a homogeneous particle distribution. In the fabrication process, applying an appropriate mixing strategy to obtain the excellent microstructure and properties is crucial. In this work, Al3Ti/Al composites with different Al3Ti volume fractions were fabricated in situ by high shear technology at various mixing speeds. The effect of mixing speed on the microstructure and mechanical properties was investigated. The results show that the reaction rate and Al3Ti particle size increase with the increase of mixing speed. An intermediate mixing speed is appropriate for preparing the Al3Ti/Al composite with a homogeneous distribution of reinforcing particles and low porosity. A lower mixing speed leads to severe particle agglomerations, which deteriorates the ductility of Al3Ti/Al composites. A higher mixing speed results in high porosity within castings resulting from severe air entrainment, which significantly reduces mechanical properties. Young’s modulus improves with increasing the stiff Al3Ti particle content and matches well with the predicted results as well. Tensile and compression strength and hardness are enhanced due to generating the uniform distribution of reinforcing particles and the matrix grain refinement.
APA:
Zeng, Y., Himmler, D., Randelzhofer, P., & Körner, C. (2020). Processing of in situ Al3Ti/Al composites by advanced high shear technology: influence of mixing speed. International Journal of Advanced Manufacturing Technology, 110(5-6), 1589-1599. https://doi.org/10.1007/s00170-020-05956-w
MLA:
Zeng, Yan, et al. "Processing of in situ Al3Ti/Al composites by advanced high shear technology: influence of mixing speed." International Journal of Advanced Manufacturing Technology 110.5-6 (2020): 1589-1599.
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