The effect of hold-melt time of micro-regime precipitation size and hardness in Al-Cu alloy

W. Suprapto, Y. Irawan, S. Suparman, Muhammad Rafi Amrullah, Pratama Auliasyah, Aditya Rafi Ramdhani
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引用次数: 1

Abstract

This study aims to control the characterization and mechanical properties of smelting Al-Cu Alloy through Hold-Melt Time. This research uses aluminum scrap and copper wire scrap to produce quality as-cast ingots, clean the environment, and increase waste utilization. Copper melting point of 1083 °C is immersed in molten aluminum at a temperature of 900 °C for 10–30 minutes causing copper to dissolve in aluminum due to smelting events based on diffusion phenomena. Parameters of temperature and immersion time of copper in molten aluminum in this study are expressed by hold-melt time. In the copper aluminum alloy trade, commonly called Duralumin, it is commonly used for impact loads and is heat-treatable. Resistance to cryogenic temperatures, in the future Duralumin has the potential to replace stainless steel. This study used an electric resistance furnace with the specifications for smelting aluminum 3 kg, electric power 2.5–3.0 kW, electric voltage 220 Volts, maximum temperature 1000 °C. It had been conducted an experiment where copper had been melted under its melting point in duralumin ingot casting. In this study, copper pieces were soaked in liquid aluminum with temperature of 900 °C. After 10–30 minutes of holding melt, the soaked copper became Al-Cu alloys and was called molten Duralumin. After the molten duralumin had been cleaned from dross, it was poured into ingot casting. From specific weight test, more soaking time of the copper in liquid aluminum caused specific weight of ingot duralumin increase from 47.08 % to 57.56 % and its hardness increase from 93 to 113 BHN. This study contributes on melting energy saving and improves the characteristic and hardness of ingot aluminum type 2xxx
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保温时间对Al-Cu合金微态析出尺寸和硬度的影响
本研究旨在通过保温时间控制铝铜合金的表征和力学性能。本研究利用废铝、废铜线生产优质铸锭,清洁环境,提高废弃物利用率。铜熔点为1083℃,在900℃的铝液中浸泡10-30分钟,由于基于扩散现象的熔炼事件,导致铜溶解在铝中。本研究中铜在铝液中的温度和浸泡时间参数用保温时间表示。在铜铝合金行业中,通常称为硬铝,它通常用于冲击载荷,并且可以热处理。耐低温,在未来硬铝有可能取代不锈钢。本研究使用的电阻炉规格为熔炼铝3kg,电功率2.5-3.0 kW,电压220伏,最高温度1000℃。在硬铝铸锭中对铜进行了熔点以下的熔炼试验。在本研究中,铜片浸泡在温度为900℃的铝液中。保温10-30分钟后,浸过的铜就变成了Al-Cu合金,称为熔融硬铝。熔化的硬铝从杂质中清除后,倒入铸锭中。比重试验结果表明,随着铜在铝液中浸泡时间的延长,铸锭的比重由47.08%提高到57.56%,硬度由93提高到113 BHN。本研究有助于降低熔炼能耗,提高2xxx型铝锭的特性和硬度
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来源期刊
EUREKA: Physics and Engineering
EUREKA: Physics and Engineering Engineering-Engineering (all)
CiteScore
1.90
自引率
0.00%
发文量
78
审稿时长
12 weeks
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