Beyond the toolpath: Site-specific melt pool size control enables printing of extra-toolpath geometry in Laser Wire-Based directed energy deposition

Brian T. Gibson; Bradley S. Richardson; Tayler W. Sundermann; Lonnie J. Love

doi:10.3390/app9204355

Beyond the toolpath: Site-specific melt pool size control enables printing of extra-toolpath geometry in Laser Wire-Based directed energy deposition

Brian T. Gibson, Bradley S. Richardson, Tayler W. Sundermann, Lonnie J. Love

Manufacturing Robotics and Control

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

18 Scopus citations

Abstract

A variety of techniques have been utilized in metal additive manufacturing (AM) for melt pool size management, including modeling and feed-forward approaches. In a few cases, closed-loop control has been demonstrated. In this research, closed-loop melt pool size control for large-scale, laser wire-based directed energy deposition is demonstrated with a novel modification, i.e., site-specific changes to the controller setpoint were commanded at trigger points, the locations of which were generated by the projection of a secondary geometry onto the primary three-dimensional (3D) printed component geometry. The present work shows that, through this technique, it is possible to print a specific geometry that occurs beyond the actual toolpath of the print head. This is denoted as extra-toolpath geometry and is fundamentally different from other methods of generating component features in metal AM. A proof-of-principle experiment is presented in which a complex oak leaf geometry was embossed on an otherwise ordinary double-bead wall made from Ti-6Al-4V. The process is introduced and characterized primarily from a controls perspective with reports on the performance of the control system, the melt pool size response, and the resulting geometry. The implications of this capability, which extend beyond localized control of bead geometry to the potential mitigations of defects and functional grading of component properties, are discussed.

Original language	English
Article number	4355
Journal	Applied Sciences (Switzerland)
Volume	9
Issue number	20
DOIs	https://doi.org/10.3390/app9204355
State	Published - Oct 1 2019

Funding

The authors would like to acknowledge the contributions of the extended Oak Ridge National Laboratory and GKN Aerospace teams, particularly those of Brian Post, Alex Roschli, Michael Borish, and Abigail Barnes of ORNL and John Potter, Emma Vetland, Chad Henry, Aaron Thornton, Ronnie Wilson, and Chris Allison of GKN Aerospace, along with Yashwanth Bandari of the EWI Buffalo Manufacturing Works. This research was funded by the U.S. Department of Energy, Office of Energy Efficiency and Renewable Energy, Advanced Manufacturing Office in partnership with GKN Aerospace. This manuscript has been authored by UT-Battelle, LLC under contract no. DE-AC05-00OR22725 with the U.S. Department of Energy. The United States government retains and the publisher, by accepting the article for publication, acknowledges that the United States government retains a non-exclusive, paid-up, irrevocable, worldwide license to publish or reproduce the published form of this manuscript, or allow others to do so, for United States government purposes. The Department of Energy will provide public access to these results of federally sponsored research in accordance with the DOE public access plan (http://energy.gov/downloads/doe-public-access-plan).

Keywords

3D printing
Additive manufacturing
Closed-loop control
Directed energy deposition
Lasers
Melt pool size
Metal
Site-specific
Titanium

Access to Document

10.3390/app9204355

Cite this

@article{03a1a004552644eb9840c969df8355ca,

title = "Beyond the toolpath: Site-specific melt pool size control enables printing of extra-toolpath geometry in Laser Wire-Based directed energy deposition",

abstract = "A variety of techniques have been utilized in metal additive manufacturing (AM) for melt pool size management, including modeling and feed-forward approaches. In a few cases, closed-loop control has been demonstrated. In this research, closed-loop melt pool size control for large-scale, laser wire-based directed energy deposition is demonstrated with a novel modification, i.e., site-specific changes to the controller setpoint were commanded at trigger points, the locations of which were generated by the projection of a secondary geometry onto the primary three-dimensional (3D) printed component geometry. The present work shows that, through this technique, it is possible to print a specific geometry that occurs beyond the actual toolpath of the print head. This is denoted as extra-toolpath geometry and is fundamentally different from other methods of generating component features in metal AM. A proof-of-principle experiment is presented in which a complex oak leaf geometry was embossed on an otherwise ordinary double-bead wall made from Ti-6Al-4V. The process is introduced and characterized primarily from a controls perspective with reports on the performance of the control system, the melt pool size response, and the resulting geometry. The implications of this capability, which extend beyond localized control of bead geometry to the potential mitigations of defects and functional grading of component properties, are discussed.",

keywords = "3D printing, Additive manufacturing, Closed-loop control, Directed energy deposition, Lasers, Melt pool size, Metal, Site-specific, Titanium",

author = "Gibson, {Brian T.} and Richardson, {Bradley S.} and Sundermann, {Tayler W.} and Love, {Lonnie J.}",

note = "Publisher Copyright: {\textcopyright} 2019 by the authors.",

year = "2019",

month = oct,

day = "1",

doi = "10.3390/app9204355",

language = "English",

volume = "9",

journal = "Applied Sciences (Switzerland)",

issn = "2076-3417",

publisher = "MDPI",

number = "20",

}

TY - JOUR

T1 - Beyond the toolpath

T2 - Site-specific melt pool size control enables printing of extra-toolpath geometry in Laser Wire-Based directed energy deposition

AU - Gibson, Brian T.

AU - Richardson, Bradley S.

AU - Sundermann, Tayler W.

AU - Love, Lonnie J.

PY - 2019/10/1

Y1 - 2019/10/1

N2 - A variety of techniques have been utilized in metal additive manufacturing (AM) for melt pool size management, including modeling and feed-forward approaches. In a few cases, closed-loop control has been demonstrated. In this research, closed-loop melt pool size control for large-scale, laser wire-based directed energy deposition is demonstrated with a novel modification, i.e., site-specific changes to the controller setpoint were commanded at trigger points, the locations of which were generated by the projection of a secondary geometry onto the primary three-dimensional (3D) printed component geometry. The present work shows that, through this technique, it is possible to print a specific geometry that occurs beyond the actual toolpath of the print head. This is denoted as extra-toolpath geometry and is fundamentally different from other methods of generating component features in metal AM. A proof-of-principle experiment is presented in which a complex oak leaf geometry was embossed on an otherwise ordinary double-bead wall made from Ti-6Al-4V. The process is introduced and characterized primarily from a controls perspective with reports on the performance of the control system, the melt pool size response, and the resulting geometry. The implications of this capability, which extend beyond localized control of bead geometry to the potential mitigations of defects and functional grading of component properties, are discussed.

AB - A variety of techniques have been utilized in metal additive manufacturing (AM) for melt pool size management, including modeling and feed-forward approaches. In a few cases, closed-loop control has been demonstrated. In this research, closed-loop melt pool size control for large-scale, laser wire-based directed energy deposition is demonstrated with a novel modification, i.e., site-specific changes to the controller setpoint were commanded at trigger points, the locations of which were generated by the projection of a secondary geometry onto the primary three-dimensional (3D) printed component geometry. The present work shows that, through this technique, it is possible to print a specific geometry that occurs beyond the actual toolpath of the print head. This is denoted as extra-toolpath geometry and is fundamentally different from other methods of generating component features in metal AM. A proof-of-principle experiment is presented in which a complex oak leaf geometry was embossed on an otherwise ordinary double-bead wall made from Ti-6Al-4V. The process is introduced and characterized primarily from a controls perspective with reports on the performance of the control system, the melt pool size response, and the resulting geometry. The implications of this capability, which extend beyond localized control of bead geometry to the potential mitigations of defects and functional grading of component properties, are discussed.

KW - 3D printing

KW - Additive manufacturing

KW - Closed-loop control

KW - Directed energy deposition

KW - Lasers

KW - Melt pool size

KW - Metal

KW - Site-specific

KW - Titanium

UR - http://www.scopus.com/inward/record.url?scp=85074174072&partnerID=8YFLogxK

U2 - 10.3390/app9204355

DO - 10.3390/app9204355

M3 - Article

AN - SCOPUS:85074174072

SN - 2076-3417

VL - 9

JO - Applied Sciences (Switzerland)

JF - Applied Sciences (Switzerland)

IS - 20

M1 - 4355

ER -

Beyond the toolpath: Site-specific melt pool size control enables printing of extra-toolpath geometry in Laser Wire-Based directed energy deposition

Abstract

Funding

Keywords

Access to Document

Other files and links

Fingerprint

Cite this