| Posted: Jun 20, 2017 | |
Lightweight steel production breakthrough: brittle phases controlled with nanosized morphology(Nanowerk News) High-strength, lightweight steels can finally be processed on an industrial scale, thanks to a breakthrough in controlling undesired brittle stages from production, by WMG, University of Warwick (Acta Materialia, "Effect of Ni alloying on the microstructural evolution and mechanical properties of two duplex light-weight steels during different annealing temperatures: experiment and phase-field simulation"). |
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| Dr Alireza Rahnama has developed a new processing route which allows low density steel-based alloys to be produced with maximum strength, whilst remaining durable and flexible– something which has been largely impossible until now. | |
| Two lightweight steels were tested - Fe-15Mn-10Al-0.8C-5Ni and Fe-15Mn-10Al-0.8C – for their potential to achieve maximum strength and ductility. | |
| During production, two brittle phases can occur in these steels: kappa-carbide (k-carbide) and B2 intermetallic – which make the steels hard but limits their ductility, so they are difficult to roll. | |
| Through simulation and then experimentation, the WMG researchers found that at certain high annealing temperatures, these brittle phases can become much more controllable, allowing the steels to retain their ductility. | |
| Between 900°C to 1200°C, the k-carbide phase can be removed from production, and the B2 intermetallic brittle phase can become manageable – forming in a disk-like, nano-sized morphology, as opposed to a coarser product which forms at lower temperatures. | |
| Current processes for strengthening lightweight steels make them less flexible – and therefore less marketable - but thanks to Dr Rahnama’s research, this is set to be a problem of the past. | |
| The breakthrough could lead to a revolution in safer, greener, more fuel-efficient cars. | |
| Vehicles made of stronger and lighter materials are safer for drivers, emit less CO2 and consume less fuel - and more malleable steels will allow manufacturers to form car parts into desirable, streamlined shapes. | |
| Dr Rahnama comments: “Alloys with higher strength and ductility could alleviate some of these concerns by reducing weight and improving energy efficiency. Lightweight steels are one of the candidates to address these concerns. | |
| “Most metallurgical mechanisms for increasing strength lead to ductility loss, an effect referred to as the strength-ductility trade-off. This paper studies the kinetics and thermodynamics of microstructural evolution of lightweight steels through simulations and experiments and proposes a mechanism to achieve higher strength and larger ductility; a method that can be readily adopted by industry.” |
| Source: University of Warwick | |
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