Effect of Heat Treatment on the Intermetallic Compounds and Mechanical Properties of Explosive Weld Interface of three Al 5083, Al 1050 and St 1515 Layers
محورهای موضوعی : Journal of Environmental Friendly MaterialsBakhtiari H 1 , Mokhtariniya F 2 , Khanzadeh M. R 3 , Farvizi M 4
1 - Institute of Materials and Energy, Meshkin Dasht, Iran
2 - Faculty of Materials Engineering, Bandarabbas Branch, Islamic Azad University, Bandarabbas, Iran
3 - Center for Advanced Engineering Research, Majlesi Branch, Islamic Azad University, Isfahan, Iran
4 - Institute of Materials and Energy, Meshkin Dasht, Iran
کلید واژه:
چکیده مقاله :
In this research, the effect of heat treatment on the microstructure and mechanical properties of intermetallic compounds of welding joint interface of three explosive layers of 5083 and 1050 aluminum as flying and intermediary plates and AISI steel sheet as the base plate has been discussed and investigated. To show the effect of temperature and time, the welded samples with stand-off distance of 6, 8, and 10mm and the explosive load of 2.41 were placed on heat treatment in the constant temperature of 315°C and 450°C within a furnace protected by Argon gas for six hours. Laboratory investigations have been conducted by the use of photomicroscope, scanning electronic microscopy, and microhardness assessing tests. Metal compounds of the interface were specified by the use of EDS analysis. In the considered samples before heat treatments, the interface of the joint has been converted from the short wavy state into the vertical wavy state by the increase of stand-off distance from 6 mm to 10 mm, and the average diameter of intermetallic layers has been increased in a range from 0.1±1.89 micrometer to 0.07± 3.13 micrometer as well. Also, microhardness has been decreased by the increase of intermetallic compounds from 266 Vickers in the sample with a stand-off distance of 10 mm to 205 Vickers in the sample with a stand-off distance of 8mm in the steel section. The performance of treatment in temperatures of 315°C and 450°C for six hours has been led to increasing the diameter of the intermetallic compounds layer.
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