Online Real-Time Quality Monitoring in Additive Manufacturing Processes Using Heterogeneous Sensors-Reference-Cited by-同舟云学术

Online Real-Time Quality Monitoring in Additive Manufacturing Processes Using Heterogeneous Sensors

Published:2015-09-09 Issue:6 Volume:137 Page:
ISSN:1087-1357
Container-title:Journal of Manufacturing Science and Engineering
language:en
Short-container-title:

Author:

Rao Prahalad K.¹,Liu Jia (Peter)²,Roberson David³,Kong Zhenyu (James)⁴,Williams Christopher⁵

Affiliation:

1. Department of Systems Science and Industrial Engineering, State University of New York at Binghamton, Binghamton, NY 13702

2. Grado Department of Industrial and Systems Engineering, Virginia Polytechnic Institute and State University, Blacksburg, VA 24061

3. Grado Department of Industrial and Systems Engineering, Virginia Polytechnic Institute and State University, Blacksburg, VA 24061

4. Grado Department of Industrial and Systems Engineering, Virginia Polytechnic Institute and State University, Blacksburg, VA 24061 e-mail:

5. Department of Mechanical Engineering, Virginia Polytechnic Institute and State University, Blacksburg, VA 24061

Abstract

The objective of this work is to identify failure modes and detect the onset of process anomalies in additive manufacturing (AM) processes, specifically focusing on fused filament fabrication (FFF). We accomplish this objective using advanced Bayesian nonparametric analysis of in situ heterogeneous sensor data. Experiments are conducted on a desktop FFF machine instrumented with a heterogeneous sensor array including thermocouples, accelerometers, an infrared (IR) temperature sensor, and a real-time miniature video borescope. FFF process failures are detected online using the nonparametric Bayesian Dirichlet process (DP) mixture model and evidence theory (ET) based on the experimentally acquired sensor data. This sensor data-driven defect detection approach facilitates real-time identification and correction of FFF process drifts with an accuracy and precision approaching 85% (average F-score). In comparison, the F-score from existing approaches, such as probabilistic neural networks (PNN), naïve Bayesian clustering, support vector machines (SVM), and quadratic discriminant analysis (QDA), was in the range of 55–75%.

Publisher

ASME International

Subject

Industrial and Manufacturing Engineering,Computer Science Applications,Mechanical Engineering,Control and Systems Engineering

Link

http://asmedigitalcollection.asme.org/manufacturingscience/article-pdf/doi/10.1115/1.4029823/6266728/manu_137_06_061007.pdf

Reference56 articles.

1. Bourell, D., Beaman, J., Leu, M., and Rosen, D., 2009, “A Brief History of Additive Manufacturing and the Roadmap for Additive Manufacturing: Looking Back and Looking Ahead,” U.S.–Turkey Workshop on Rapid Technologies, pp. 5–11.

2. Progress in Additive Manufacturing and Rapid Prototyping;CIRP Ann.-Manuf. Technol.,1998

3. Rapid Manufacturing and Rapid Tooling With Layer Manufacturing (LM) Technologies, State of the Art and Future Perspectives;CIRP Ann.-Manuf. Technol.,2003

4. A Review of Melt Extrusion Additive Manufacturing Processes: I. Process Design and Modeling;Rapid Prototyping J.,2014

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