A Centralized Framework for System-Level Control and Management of Additive Manufacturing Fleets

In most industrial additive manufacturing (AM) applications a set of AM machines (AM-Fleet) are used in parallel. An AM-Fleet often consists of machines from various vendors and may include different AM processes. AM processes often suffer from poor repeatability within a single build, between builds on the same machine, and from machine to machine. AM's lack of robustness is often attributed to insufficient in-process monitoring and feedback control, as well as unknown modeling dynamics, and a lack of process standards. To effectively monitor and control AM-Fleets, system-level approaches must be devised. In this work, a centralized approach is proposed for the system-level control and management of AM-Fleets. Integrating such an approach has advantages in terms of system-level intelligent decision making for AM-Fleets. Key problems that needs to be solved and the challenges for a centralized approach are discussed in this work. The architecture of the proposed framework is presented with discussions on the individual components. A discrete event model for the system-level monitoring and control of AM machines is also proposed to support the presented framework. The use of discrete event models creates an abstract representation of the AM machine that enables the supervision of the physical system. An illustrative example that demonstrates a system-level run-to-run anomaly detection case is discussed. The proposed framework will provide an analytical foundation for systematic anomaly detection, scheduling, and decision making in AM-Fleets.

[1]  Christos G. Cassandras,et al.  Introduction to Discrete Event Systems , 1999, The Kluwer International Series on Discrete Event Dynamic Systems.

[2]  J. S. Zuback,et al.  Building blocks for a digital twin of additive manufacturing , 2017 .

[3]  Charlie C. L. Wang,et al.  The status, challenges, and future of additive manufacturing in engineering , 2015, Comput. Aided Des..

[4]  Christopher J. Sutcliffe,et al.  Performance modelling and simulation of metal powder bed fusion production system , 2016 .

[5]  Dawn M. Tilbury,et al.  Production as a Service: Optimizing Utilization in Manufacturing Systems , 2016 .

[6]  Paul Witherell,et al.  Digital Solutions for Integrated and Collaborative Additive Manufacturing , 2016 .

[7]  Jia Liu,et al.  Online Real-Time Quality Monitoring in Additive Manufacturing Processes Using Heterogeneous Sensors , 2015 .

[8]  Zhuoqing Morley Mao,et al.  Categorization of Anomalies in Smart Manufacturing Systems to Support the Selection of Detection Mechanisms , 2017, IEEE Robotics and Automation Letters.

[9]  David He,et al.  A PHM Approach to Additive Manufacturing Equipment Health Monitoring, Fault Diagnosis, and Quality Control , 2014, Annual Conference of the PHM Society.

[10]  Young B. Moon,et al.  Detecting cyber-physical attacks in CyberManufacturing systems with machine learning methods , 2017, Journal of Intelligent Manufacturing.

[11]  D.M. Tilbury,et al.  An Approach for Factory-Wide Control Utilizing Virtual Metrology , 2007, IEEE Transactions on Semiconductor Manufacturing.

[12]  Yan Wang,et al.  Real-time FDM machine condition monitoring and diagnosis based on acoustic emission and hidden semi-Markov model , 2017 .

[13]  Zhuoqing Morley Mao,et al.  Production as a service: A centralized framework for small batch manufacturing , 2017, 2017 13th IEEE Conference on Automation Science and Engineering (CASE).

[14]  Dawn M. Tilbury,et al.  A software-defined framework for the integrated management of smart manufacturing systems , 2018 .

[15]  Eric Feron,et al.  Foundations of Intelligent Additive Manufacturing , 2017, ArXiv.

[16]  Yong Huang,et al.  Additive Manufacturing: Current State, Future Potential, Gaps and Needs, and Recommendations , 2015 .

[17]  Richard E. Ricker,et al.  Measurement Science Roadmap for Polymer-Based Additive Manufacturing , 2016 .

[18]  Jing Zhang,et al.  Cybersecurity risks and mitigation strategies in additive manufacturing , 2018 .

[19]  Leonardo Santana,et al.  A study of parametric calibration for low cost 3D printing: Seeking improvement in dimensional quality , 2017 .

[20]  Kira Barton,et al.  On Spatial Iterative Learning Control via 2-D Convolution: Stability Analysis and Computational Efficiency , 2016, IEEE Transactions on Control Systems Technology.

[21]  Fugee Tsung,et al.  A Statistical Transfer Learning Perspective for Modeling Shape Deviations in Additive Manufacturing , 2017, IEEE Robotics and Automation Letters.

[22]  David C. Drain Run-to-Run Control in Semiconductor Manufacturing , 2002 .

[23]  Jim Esch,et al.  Software-Defined Networking: A Comprehensive Survey , 2015, Proc. IEEE.

[24]  Dawn M. Tilbury,et al.  Anomaly detection and productivity analysis for cyber-physical systems in manufacturing , 2017, 2017 13th IEEE Conference on Automation Science and Engineering (CASE).

[25]  Omar Ahmed Mohamed,et al.  Optimization of fused deposition modeling process parameters: a review of current research and future prospects , 2015, Advances in Manufacturing.

[26]  Dawn M. Tilbury,et al.  Production as a Service: A Digital Manufacturing Framework for Optimizing Utilization , 2018, IEEE Transactions on Automation Science and Engineering.

[27]  Gert Goch,et al.  Development of an adaptive, self-learning control concept for an additive manufacturing process , 2017 .