Thermodynamics of the Effect of Alloying of Phase Formation during Crystallization of Aluminum Matrix Composites with Exogenous Reinforcement

IF 0.6 4区 材料科学 Q4 METALLURGY & METALLURGICAL ENGINEERING Russian Journal of Non-Ferrous Metals Pub Date : 2022-12-29 DOI:10.3103/S106782122206013X
E. S. Prusov, V. A. Kechin, V. B. Deev, P. K. Shurkin
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Abstract

A thermodynamic assessment of the influence of alloying elements (Si, Mg, Cu, Ti) on the processes of phase formation during the production and liquid-phase processing of cast aluminum matrix composite materials with exogenous reinforcement (Al–SiC, Al–B4C) has been carried out. It is shown that without suppression of the formation of Al–Si–C and Al4C3 carbides in the range of carbon concentrations from 0 to 4.5 wt %, the equilibrium phase composition of composites of the Al–SiC system in the solid state at temperatures from 423 to 575ºC lies in the three-phase region (Al) + Si + Al4SiC4, and below a temperature of 423ºC, the Al4SiC4 ternary carbide is replaced by the Al8SiC7 compound. In the Al–SiC–Mg system, the crystallization of composites containing more than 0.58 wt % magnesium ends in the four-phase region (Al) + Al3Mg2 + SiC + Mg2Si. In the Al–SiC–Ti system, the end of crystallization is fixed in the three-phase region (Al) + Al3Ti + SiC. In the Al–B4C system, after suppression of the formation of the Al4C3 phase, with a deviation from the concentrations of elements that provide 10 vol % B4C, aluminum borides are formed in the direction of increasing boron, and free carbon is formed in the direction of decreasing boron. Under equilibrium conditions, with a silicon content of up to 0.67 wt %, the crystallization of the Al–B4C–Si system ends in the four-phase region (Al) + B4C + AlB12 + Al8SiC7, and at a higher silicon content, it ends in the region (Al) + Si + AlB12 + Al8SiC7. In the Al–B4C–Ti system, with a Ti content of less than 0.42 wt %, crystallization ends in the three-phase (Al) + TiB2 + B4C region.

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外源增强铝基复合材料结晶过程中合金化对相形成影响的热力学研究
对外源增强铸铝基复合材料(Al-SiC, Al-B4C)的生产和液相加工过程中合金元素(Si, Mg, Cu, Ti)对相形成过程的影响进行了热力学评价。结果表明:在0 ~ 4.5 wt %的碳浓度范围内,不抑制Al - Si - C和Al4C3碳化物的形成,在423 ~ 575℃的固相温度下,Al - sic体系复合材料的平衡相组成位于三相区(Al) + Si + Al4SiC4,在423℃以下,Al4SiC4三元碳化物被Al8SiC7化合物取代。在Al - SiC - mg体系中,含镁量大于0.58 wt %的复合材料结晶结束于四相区(Al) + Al3Mg2 + SiC + Mg2Si。在Al - SiC - ti体系中,结晶终点固定在(Al) + Al3Ti + SiC三相区。在Al-B4C体系中,抑制Al4C3相的形成后,偏离提供10 vol % B4C的元素浓度,硼的增加方向形成硼化铝,硼的减少方向形成游离碳。在平衡条件下,当硅含量达到0.67 wt %时,Al - B4C - Si体系的结晶结束于(Al) + B4C + AlB12 + Al8SiC7的四相区;当硅含量较高时,Al - B4C - Si体系的结晶结束于(Al) + Si + AlB12 + Al8SiC7的区域。在Al - B4C - Ti体系中,当Ti含量小于0.42 wt %时,结晶结束于(Al) + TiB2 + B4C三相区。
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来源期刊
Russian Journal of Non-Ferrous Metals
Russian Journal of Non-Ferrous Metals METALLURGY & METALLURGICAL ENGINEERING-
CiteScore
1.90
自引率
12.50%
发文量
59
审稿时长
3 months
期刊介绍: Russian Journal of Non-Ferrous Metals is a journal the main goal of which is to achieve new knowledge in the following topics: extraction metallurgy, hydro- and pirometallurgy, casting, plastic deformation, metallography and heat treatment, powder metallurgy and composites, self-propagating high-temperature synthesis, surface engineering and advanced protected coatings, environments, and energy capacity in non-ferrous metallurgy.
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