TY - GEN
T1 - Particle scale numerical modelling of heat transfer and melt pool dynamics in selective laser melting
AU - Li, Erlei
AU - Zou, Ruiping
AU - Yu, Aibing
AU - Zhou, Zongyan
N1 - Publisher Copyright:
Copyright © COMPLAS 2019.
PY - 2019
Y1 - 2019
N2 - Selective laser melting (SLM), with the advantages in producing complex geometry, is becoming one of the most promising additive manufacturing (AM) technologies [1]. In order to understand the multiple physical phenomena which is crucial for successful manufacturing during SLM process, different computational models that are less expensive but challenging compared with experiments and real-time monitor technologies have been developed in the past years. In order to investigate particle scale thermal-physical phenomena in SLM process, a three-dimensional model considering Fresnel reflection is developed to and the volume of fluid approach is used to track melting and solidification phenomena. Numerical results show that the melt track is broken into several regions to minimize surface energy because of surface tension. The molten liquid tends to flow outwards from the laser spot caused by Marangoni effects. The solidified surface of multiple particle diameter powders is much rougher compared with powder bed with layer thickness of one particle diameter. The developed model provides a comprehensive understanding about physical phenomena during SLM process.
AB - Selective laser melting (SLM), with the advantages in producing complex geometry, is becoming one of the most promising additive manufacturing (AM) technologies [1]. In order to understand the multiple physical phenomena which is crucial for successful manufacturing during SLM process, different computational models that are less expensive but challenging compared with experiments and real-time monitor technologies have been developed in the past years. In order to investigate particle scale thermal-physical phenomena in SLM process, a three-dimensional model considering Fresnel reflection is developed to and the volume of fluid approach is used to track melting and solidification phenomena. Numerical results show that the melt track is broken into several regions to minimize surface energy because of surface tension. The molten liquid tends to flow outwards from the laser spot caused by Marangoni effects. The solidified surface of multiple particle diameter powders is much rougher compared with powder bed with layer thickness of one particle diameter. The developed model provides a comprehensive understanding about physical phenomena during SLM process.
KW - Additive Manufacturing
KW - Fresnel Reflection
KW - Powder Scale Modelling
KW - Selective Laser Melting
KW - Thermal Multiphase Flow and Solidification
UR - https://www.scopus.com/pages/publications/85102043431
M3 - 会议稿件
AN - SCOPUS:85102043431
T3 - 2nd International Conference on Simulation for Additive Manufacturing, Sim-AM 2019
SP - 309
EP - 315
BT - 2nd International Conference on Simulation for Additive Manufacturing, Sim-AM 2019
A2 - Auricchio, Ferdinando
A2 - Rank, E.
A2 - Steinmann, P.
A2 - Kollmannsberger, S.
A2 - Morganti, Simone
PB - International Center for Numerical Methods in Engineering
T2 - 2nd International Conference on Simulation for Additive Manufacturing, Sim-AM 2019
Y2 - 11 September 2019 through 13 September 2019
ER -