Precipitation Kinetics of AA6082: An Experimental and Numerical Investigation
Publikation: Beiträge in Zeitschriften › Konferenzaufsätze in Fachzeitschriften › Forschung › begutachtet
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Precipitation Kinetics of AA6082: An Experimental and Numerical Investigation. / Herrnring, Jan; Kashaev, Nikolai; Klusemann, Benjamin.
in: Materials Science Forum, Jahrgang 941, 12.2018, S. 1411-1417.Publikation: Beiträge in Zeitschriften › Konferenzaufsätze in Fachzeitschriften › Forschung › begutachtet
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TY - JOUR
T1 - Precipitation Kinetics of AA6082: An Experimental and Numerical Investigation
AU - Herrnring, Jan
AU - Kashaev, Nikolai
AU - Klusemann, Benjamin
N1 - Print: 978-3-0357-1208-7. ebook: 978-3-0357-3208-5. Titel: THERMEC 2018
PY - 2018/12
Y1 - 2018/12
N2 - The development of simulation tools for bridging different scales are essential for understanding complex joining processes. For precipitation hardening, the Kampmann-Wagner numerical model (KWN) is an important method to account for non-isothermal second phase precipitation. This model allows to describe nucleation, growth and coarsening of precipitation hardened aluminum alloys based on a size distribution for every phase which produces precipitations. In particular, this work investigates the performance of a KWN model by [1-3] for Al-Mg-Si-alloys. The model is compared against experimental data from isothermal heat treatments taken partially from [2]. Additionally, the model is used for investigation of the precipitation kinetics for a laser beam welding process, illustrating the time-dependent development of the different parameters related to the precipitation kinetics and the resulting yield strength.
AB - The development of simulation tools for bridging different scales are essential for understanding complex joining processes. For precipitation hardening, the Kampmann-Wagner numerical model (KWN) is an important method to account for non-isothermal second phase precipitation. This model allows to describe nucleation, growth and coarsening of precipitation hardened aluminum alloys based on a size distribution for every phase which produces precipitations. In particular, this work investigates the performance of a KWN model by [1-3] for Al-Mg-Si-alloys. The model is compared against experimental data from isothermal heat treatments taken partially from [2]. Additionally, the model is used for investigation of the precipitation kinetics for a laser beam welding process, illustrating the time-dependent development of the different parameters related to the precipitation kinetics and the resulting yield strength.
KW - Engineering
KW - Precipitation kinetics
KW - Kampmann-Wagner numerical model
KW - Heat treatment
KW - Laser beam welding
KW - AA6082
KW - simulation
U2 - 10.4028/www.scientific.net/MSF.941.1411
DO - 10.4028/www.scientific.net/MSF.941.1411
M3 - Conference article in journal
VL - 941
SP - 1411
EP - 1417
JO - Materials Science Forum
JF - Materials Science Forum
SN - 0255-5476
T2 - International Conference on PROCESSING & MANUFACTURING OF ADVANCED MATERIALS - THERMEC 2018
Y2 - 8 July 2018 through 13 July 2018
ER -