TY - JOUR
T1 - Digital Twin-enabled Collaborative Data Management for Metal Additive Manufacturing Systems
AU - Liu, Chao
AU - Le Roux, Léopold
AU - Körner, Carolin
AU - Tabaste, Olivier
AU - Lacan, Franck
AU - Bigot, Samuel
N1 - Funding Information:
This research was performed within the project Additive Manufacturing using Metal Pilot Line (MANUELA), which received funding from the European Union's Horizon2020 research and innovation programme under grant agreement No 820774. The authors would like to thank Mr. Emil Johansson, Dr. Benjamin Bircher, Dr. Vaclav Pejchal and Dr. Zhuoer Chen for their support in developing the data model and the MANUELA system architecture, and Mr. Daniel Gage for coordinating the experiments.
Publisher Copyright:
© 2020 The Society of Manufacturing Engineers
PY - 2022/1
Y1 - 2022/1
N2 - Metal Additive Manufacturing (AM) has been attracting a continuously increasing attention due to its great advantages compared to traditional subtractive manufacturing in terms of higher design flexibility, shorter development time, lower tooling cost, and fewer production wastes. However, the lack of process robustness, stability and repeatability caused by the unsolved complex relationships between material properties, product design, process parameters, process signatures, post AM processes and product quality has significantly impeded its broad acceptance in the industry. To facilitate efficient implementation of advanced data analytics in metal AM, which would support the development of intelligent process monitoring, control and optimisation, this paper proposes a novel Digital Twin (DT)-enabled collaborative data management framework for metal AM systems, where a Cloud DT communicates with distributed Edge DTs in different product lifecycle stages. A metal AM product data model that contains a comprehensive list of specific product lifecycle data is developed to support the collaborative data management. The feasibility and advantages of the proposed framework are validated through the practical implementation in a distributed metal AM system developed in the project MANUELA. A representative application scenario of cloud-based and deep learning-enabled metal AM layer defect analysis is also presented. The proposed DT-enabled collaborative data management has shown great potential in enhancing fundamental understanding of metal AM processes, developing simulation and prediction models, reducing development times and costs, and improving product quality and production efficiency.
AB - Metal Additive Manufacturing (AM) has been attracting a continuously increasing attention due to its great advantages compared to traditional subtractive manufacturing in terms of higher design flexibility, shorter development time, lower tooling cost, and fewer production wastes. However, the lack of process robustness, stability and repeatability caused by the unsolved complex relationships between material properties, product design, process parameters, process signatures, post AM processes and product quality has significantly impeded its broad acceptance in the industry. To facilitate efficient implementation of advanced data analytics in metal AM, which would support the development of intelligent process monitoring, control and optimisation, this paper proposes a novel Digital Twin (DT)-enabled collaborative data management framework for metal AM systems, where a Cloud DT communicates with distributed Edge DTs in different product lifecycle stages. A metal AM product data model that contains a comprehensive list of specific product lifecycle data is developed to support the collaborative data management. The feasibility and advantages of the proposed framework are validated through the practical implementation in a distributed metal AM system developed in the project MANUELA. A representative application scenario of cloud-based and deep learning-enabled metal AM layer defect analysis is also presented. The proposed DT-enabled collaborative data management has shown great potential in enhancing fundamental understanding of metal AM processes, developing simulation and prediction models, reducing development times and costs, and improving product quality and production efficiency.
KW - data management
KW - data model
KW - Digital Twin
KW - machine learning
KW - Metal Additive Manufacturing
KW - product lifecycle management
UR - http://www.scopus.com/inward/record.url?scp=85085297137&partnerID=8YFLogxK
U2 - 10.1016/j.jmsy.2020.05.010
DO - 10.1016/j.jmsy.2020.05.010
M3 - Journal article
AN - SCOPUS:85085297137
SN - 0278-6125
VL - 62
SP - 857
EP - 874
JO - Journal of Manufacturing Systems
JF - Journal of Manufacturing Systems
ER -