The effect of the processing parameters on the martensitic transformation of Cu-Al-Mn shape memory alloy

The influence of processing, heat-treatment and aging of Cu-(8–9) wt% Al-(7–10) wt% Mn alloy on the kinetics and temperatures of martensitic transformation was investigated by calorimetric measurements. Cu-Al-Mn alloy was prepared by continuous casting, melt-spinner and by melting in the electric ar...

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Bibliographic Details
Published in:Journal of alloys and compounds 2018-10, Vol.765, p.664-676
Main Authors: Grgurić, T. Holjevac, Manasijević, D., Kožuh, S., Ivanić, I., Anžel, I., Kosec, B., Bizjak, M., Bajsić, E. Govorčin, Balanović, Lj, Gojić, Mirko
Format: Article
Language:English
Subjects:
Activation energy
Aging (artificial)
Aging (metallurgy)
Aluminum alloys
Arc heating
Continuous cast shapes
Continuous casting
Continuous furnaces
Cooling rate
Copper
Copper base alloys
Crystal structure
Cu-based alloys
Effects
Electric arc furnaces
Heat measurement
Kinetics
Manganese base alloys
Martensite
Martensitic transformation
Martensitic transformations
Melt spinning
Parameter estimation
Process parameters
Quenching
Scanning electron microscopy
Shape
Shape memory alloys
Solution heat treatment
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Summary:The influence of processing, heat-treatment and aging of Cu-(8–9) wt% Al-(7–10) wt% Mn alloy on the kinetics and temperatures of martensitic transformation was investigated by calorimetric measurements. Cu-Al-Mn alloy was prepared by continuous casting, melt-spinner and by melting in the electric arc furnace. Alloys were further heat-treated at 900 °C for 30 min and quenched in water, as well as aged at 300 °C for 1 h. Differential Scanning Calorimetry (DSC) was performed at 3 heating/cooling cycles from −50 to 250 °C. Non-isothermal measurements were determined at five different heating/cooling rates: 5, 10, 15, 20 and 25 °C/min. Activation energy was obtained according to Ozawa and Kissinger kinetic models. Microstructure analysis of investigated systems was performed by scanning electron microscopy (SEM). Results indicate the most intensive formation of martensitic structure in the as-cast state during continuous casting, where the partially formation of needle-like and V-shape martensite was observed. After solution treatment and quenching as well as aging, completely martensitic phase occurred in continuously cast alloy. XRD analysis detected Cu2AlMn, Cu3Al and Al4Cu9 phases in quenched specimens of continuously cast Cu-Al-Mn alloy and ribbon. The highest impact of the solution treatment and aging on the shifting of the martensitic temperatures was observed for Cu-Al-Mn ribbons, while in continuously cast Cu-Al-Mn alloy heat treatment and aging induced formation of different martensitic crystal structures. Kinetic investigations showed increasing start martensitic temperatures, Ms, and wider temperature interval of martensitic transformation with higher cooling rate. The highest values of activation energy of martensitic transformation was obtained for the continuously cast Cu-Al-Mn alloy. •Cu-Al-Mn SMA by continuous casting and melt-spinner was successfully produced.•Heat-treatment of Cu-Al-Mn SMA results in formation of intensive martensite.•γ' martensite is formed by melt-spinner, β' by continuous casting (Cu3Al, Cu2AlMn).•Heat-treatment increases Ms of continuously cast SMA, and decreases in ribbon.•Cu-Al-Mn ribbon has the lowest energy of activation of martensitic transformation.
ISSN:0925-8388
1873-4669
DOI:10.1016/j.jallcom.2018.06.250