Detail publikace
Influence of deposition strategy on the microstructure of volumetric WADED-fabricated AZ61 magnesium alloy components
SEIDLER, F. SLAVÍČEK, J. KOUTNÝ, D.
Anglický název
Influence of deposition strategy on the microstructure of volumetric WADED-fabricated AZ61 magnesium alloy components
Typ
Článek WoS
Jazyk
en
Originální abstrakt
This study investigates the impact of various deposition strategies on the microstructure of volumetric components fabricated from AZ61 magnesium alloy using Wire Arc Direct Energy Deposition (WADED), also referred to as Wire Arc Additive Manufacturing (WAAM). Because coarse grains can significantly reduce mechanical performance, thermal simulations were performed to identify low-cooling-rate regions associated with different deposition trajectories. Three deposition strategies were analysed: ZigZag, Spiral, and S-pattern. The simulated thermal profiles were validated by optical grain size analysis and hardness measurements. In the selected critical regions, where the largest grains are expected, the S-pattern achieved the narrowest range in grain size and hardness distribution. This trajectory also exhibited the finest microstructure in the most critical region, with the smallest average grain size. Additionally, it maintained good geometrical accuracy, indicating that it offers a promising route for producing high-quality magnesium-alloy components via WADED.
Klíčová slova anglicky
WAAM, WADED, Magnesium alloy, AZ61, Volumetric component, Grain size, Deposition strategy, Trajectory
Vydáno
2026-02-01
Nakladatel
Elsevier
Časopis
Additive Manufacturing Letters
Ročník
16
Číslo
February
Strany od–do
1–10
Počet stran
10
BIBTEX
@article{BUT200884,
author="Filip {Seidler} and Jakub {Slavíček} and Daniel {Koutný}",
title="Influence of deposition strategy on the microstructure of volumetric WADED-fabricated AZ61 magnesium alloy components",
journal="Additive Manufacturing Letters",
year="2026",
volume="16",
number="February",
pages="10",
doi="10.1016/j.addlet.2025.100348",
url="https://www.sciencedirect.com/science/article/pii/S2772369025000830"
}