A data-driven approach for predicting printability in metal additive manufacturing processes

William Mycroft; Mordechai Katzman; Samuel Tammas-Williams; Everth Hernandez-Nava; George Panoutsos; Iain Todd; Visakan Kadirkamanathan

doi:10.1007/s10845-020-01541-w

A data-driven approach for predicting printability in metal additive manufacturing processes

William Mycroft^*, Mordechai Katzman, Samuel Tammas-Williams, Everth Hernandez-Nava, George Panoutsos, Iain Todd, Visakan Kadirkamanathan

^*Corresponding author for this work

School of Engineering

Research output: Contribution to journal › Article › peer-review

Abstract / Description of output

Metal powder-bed fusion additive manufacturing technologies offer numerous benefits to the manufacturing industry. However, the current approach to printability analysis, determining which components are likely to build unsuccessfully, prior to manufacture, is based on ad-hoc rules and engineering experience. Consequently, to allow full exploitation of the benefits of additive manufacturing, there is a demand for a fully systematic approach to the problem. In this paper we focus on the impact of geometry in printability analysis. For the first time, we detail a machine learning framework for determining the geometric limits of printability in additive manufacturing processes. This framework consists of three main components. First, we detail how to construct strenuous test artefacts capable of pushing an additive manufacturing process to its limits. Secondly, we explain how to measure the printability of an additively manufactured test artefact. Finally, we construct a predictive model capable of estimating the printability of a given artefact before it is additively manufactured. We test all steps of our framework, and show that our predictive model approaches an estimate of the maximum performance obtainable due to inherent stochasticity in the underlying additive manufacturing process.

Original language	English
Pages (from-to)	1769-1781
Number of pages	13
Journal	Journal of Intelligent Manufacturing
Volume	31
Issue number	7
Early online date	7 Feb 2020
DOIs	https://doi.org/10.1007/s10845-020-01541-w
Publication status	Published - 1 Oct 2020

Keywords / Materials (for Non-textual outputs)

Additive manufacturing
Electron beam melting
Machine learning
Powder bed fusion
Printability analysis

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10.1007/s10845-020-01541-wLicence: Creative Commons: Attribution (CC-BY)

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title = "A data-driven approach for predicting printability in metal additive manufacturing processes",

abstract = "Metal powder-bed fusion additive manufacturing technologies offer numerous benefits to the manufacturing industry. However, the current approach to printability analysis, determining which components are likely to build unsuccessfully, prior to manufacture, is based on ad-hoc rules and engineering experience. Consequently, to allow full exploitation of the benefits of additive manufacturing, there is a demand for a fully systematic approach to the problem. In this paper we focus on the impact of geometry in printability analysis. For the first time, we detail a machine learning framework for determining the geometric limits of printability in additive manufacturing processes. This framework consists of three main components. First, we detail how to construct strenuous test artefacts capable of pushing an additive manufacturing process to its limits. Secondly, we explain how to measure the printability of an additively manufactured test artefact. Finally, we construct a predictive model capable of estimating the printability of a given artefact before it is additively manufactured. We test all steps of our framework, and show that our predictive model approaches an estimate of the maximum performance obtainable due to inherent stochasticity in the underlying additive manufacturing process.",

keywords = "Additive manufacturing, Electron beam melting, Machine learning, Powder bed fusion, Printability analysis",

author = "William Mycroft and Mordechai Katzman and Samuel Tammas-Williams and Everth Hernandez-Nava and George Panoutsos and Iain Todd and Visakan Kadirkamanathan",

note = "Funding Information: The authors would like thank the participants in the {\textquoteleft}Tailorable and Adaptive Connected Digital Additive Manufacturing{\textquoteright} (TACDAM) EPSRC and Innovate UK funded project for providing extremely useful industry-specific comments and advice. We thank the EPSRC Future Manufacturing Hub in Manufacture using Advanced Powder Processes (MAPP) for funding the CT scan through Grant EP/P006566/1. We acknowledge the Engineering and Physical Science Research Council (EPSRC) for funding the Henry Moseley X-ray Imaging Facility which has been made available through the Royce Institute for Advanced Materials through Grants (EP/F007906/1, EP/F001452/1,EP/I02249X, EP/M010619/1, EP/F028431/1, EP/M022498/1 and EP/R00661X/1). Publisher Copyright: {\textcopyright} 2020, The Author(s). Copyright: Copyright 2020 Elsevier B.V., All rights reserved.",

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doi = "10.1007/s10845-020-01541-w",

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AU - Mycroft, William

AU - Katzman, Mordechai

AU - Tammas-Williams, Samuel

AU - Hernandez-Nava, Everth

AU - Panoutsos, George

AU - Todd, Iain

AU - Kadirkamanathan, Visakan

N1 - Funding Information: The authors would like thank the participants in the ‘Tailorable and Adaptive Connected Digital Additive Manufacturing’ (TACDAM) EPSRC and Innovate UK funded project for providing extremely useful industry-specific comments and advice. We thank the EPSRC Future Manufacturing Hub in Manufacture using Advanced Powder Processes (MAPP) for funding the CT scan through Grant EP/P006566/1. We acknowledge the Engineering and Physical Science Research Council (EPSRC) for funding the Henry Moseley X-ray Imaging Facility which has been made available through the Royce Institute for Advanced Materials through Grants (EP/F007906/1, EP/F001452/1,EP/I02249X, EP/M010619/1, EP/F028431/1, EP/M022498/1 and EP/R00661X/1). Publisher Copyright: © 2020, The Author(s). Copyright: Copyright 2020 Elsevier B.V., All rights reserved.

PY - 2020/10/1

Y1 - 2020/10/1

N2 - Metal powder-bed fusion additive manufacturing technologies offer numerous benefits to the manufacturing industry. However, the current approach to printability analysis, determining which components are likely to build unsuccessfully, prior to manufacture, is based on ad-hoc rules and engineering experience. Consequently, to allow full exploitation of the benefits of additive manufacturing, there is a demand for a fully systematic approach to the problem. In this paper we focus on the impact of geometry in printability analysis. For the first time, we detail a machine learning framework for determining the geometric limits of printability in additive manufacturing processes. This framework consists of three main components. First, we detail how to construct strenuous test artefacts capable of pushing an additive manufacturing process to its limits. Secondly, we explain how to measure the printability of an additively manufactured test artefact. Finally, we construct a predictive model capable of estimating the printability of a given artefact before it is additively manufactured. We test all steps of our framework, and show that our predictive model approaches an estimate of the maximum performance obtainable due to inherent stochasticity in the underlying additive manufacturing process.

AB - Metal powder-bed fusion additive manufacturing technologies offer numerous benefits to the manufacturing industry. However, the current approach to printability analysis, determining which components are likely to build unsuccessfully, prior to manufacture, is based on ad-hoc rules and engineering experience. Consequently, to allow full exploitation of the benefits of additive manufacturing, there is a demand for a fully systematic approach to the problem. In this paper we focus on the impact of geometry in printability analysis. For the first time, we detail a machine learning framework for determining the geometric limits of printability in additive manufacturing processes. This framework consists of three main components. First, we detail how to construct strenuous test artefacts capable of pushing an additive manufacturing process to its limits. Secondly, we explain how to measure the printability of an additively manufactured test artefact. Finally, we construct a predictive model capable of estimating the printability of a given artefact before it is additively manufactured. We test all steps of our framework, and show that our predictive model approaches an estimate of the maximum performance obtainable due to inherent stochasticity in the underlying additive manufacturing process.

KW - Additive manufacturing

KW - Electron beam melting

KW - Machine learning

KW - Powder bed fusion

KW - Printability analysis

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U2 - 10.1007/s10845-020-01541-w

DO - 10.1007/s10845-020-01541-w

M3 - Article

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SN - 0956-5515

VL - 31

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EP - 1781

JO - Journal of Intelligent Manufacturing

JF - Journal of Intelligent Manufacturing

IS - 7

ER -

A data-driven approach for predicting printability in metal additive manufacturing processes

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