TY - GEN
T1 - Sliding Mode Control for Melt Pool Area in Metal Laser Powder Bed Fusion Process
AU - Karagiannis, Dimitri
AU - Kontsos, Antonios
AU - Malekipour, Ehsan
AU - Gomez, Fabian Andres Gonzalez
N1 - Publisher Copyright:
© 2025 IEEE.
PY - 2025
Y1 - 2025
N2 - The laser powder bed fusion (LPBF) additive manufacturing process involves fusing powdered metals with a high powered laser moving at a high speed. As this process is governed by a complex multi-phase interaction between multiple physical domains, several models have been developed of varying complexity. This paper adopts a non-linear first order model from the literature governing the surface area of the moving melt pool created by the laser heating of the powder, as control of this state can lead to improved build quality (small melt pool hinders metal fusion, large melt pools lead to material evaporation and stress-concentrations in the final part). The model is reviewed, and a second order state space model is constructed using the error between the actual melt pool size and a desired reference value. The power supplied to the laser is used as a control input, and an exponentially stable sliding manifold is defined. A control law is defined to drive the system states to the manifold in finite time and hold it there, ensuring a desirable melt pool size throughout the duration of the build. Simulated results are presented, indicating the effectiveness of the control design using gains for slow and fast convergence.
AB - The laser powder bed fusion (LPBF) additive manufacturing process involves fusing powdered metals with a high powered laser moving at a high speed. As this process is governed by a complex multi-phase interaction between multiple physical domains, several models have been developed of varying complexity. This paper adopts a non-linear first order model from the literature governing the surface area of the moving melt pool created by the laser heating of the powder, as control of this state can lead to improved build quality (small melt pool hinders metal fusion, large melt pools lead to material evaporation and stress-concentrations in the final part). The model is reviewed, and a second order state space model is constructed using the error between the actual melt pool size and a desired reference value. The power supplied to the laser is used as a control input, and an exponentially stable sliding manifold is defined. A control law is defined to drive the system states to the manifold in finite time and hold it there, ensuring a desirable melt pool size throughout the duration of the build. Simulated results are presented, indicating the effectiveness of the control design using gains for slow and fast convergence.
UR - https://www.scopus.com/pages/publications/105017843735
UR - https://www.scopus.com/pages/publications/105017843735#tab=citedBy
U2 - 10.1109/CCTA53793.2025.11151375
DO - 10.1109/CCTA53793.2025.11151375
M3 - Conference contribution
AN - SCOPUS:105017843735
T3 - 2025 IEEE Conference on Control Technology and Applications, CCTA 2025
SP - 988
EP - 994
BT - 2025 IEEE Conference on Control Technology and Applications, CCTA 2025
A2 - Vermillion, Christopher
A2 - Olaru, Sorin
A2 - Mathieu, Johanna
A2 - Mercangoz, Mehmet
A2 - Stockar, Stephanie
A2 - Karimi, Alireza
A2 - Faulwasser, Timm
A2 - Kerrigan, Eric
A2 - Fineisen, Rolf
A2 - Gros, Sebastien
A2 - Prodan, Ionela
A2 - Edwards, Christopher
A2 - Dabbene, Fabrizio
A2 - Chapman, Airlie
A2 - Touri, Behrouz
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 9th IEEE Conference on Control Technology and Applications, CCTA 2025
Y2 - 25 August 2025 through 27 August 2025
ER -