Adaptive process control implementation of wire arc additive manufacturing for thin-walled components with overhang features

The ability to fabricate overhang structures in WAAM (wire arc additive manufacturing) is vital in ensuring that a wide variety of designs can be realised. Unlike other additive manufacturing techniques that leverage on the addition of support structures, WAAM utilises a support-free approach for ov...

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Bibliographic Details
Published inInternational journal of advanced manufacturing technology Vol. 108; no. 4; pp. 1061 - 1071
Main Authors Lam, Teng Foong, Xiong, Yi, Dharmawan, Audelia Gumarus, Foong, Shaohui, Soh, Gim Song
Format Journal Article
LanguageEnglish
Published London Springer London 01.05.2020
Springer Nature B.V
Subjects
Adaptive control
Additive manufacturing
Algorithms
CAD
CAE) and Design
Computer aided design
Computer-Aided Engineering (CAD
Engineering
Industrial and Production Engineering
Interpolation
Mechanical Engineering
Media Management
Near net shaping
Original Article
Process controls
Substrates
Turntables
Wire
Toolpath planning
Additive manufacturing
Overhang features
Process planning
Biharmonic spline interpolation
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Summary:The ability to fabricate overhang structures in WAAM (wire arc additive manufacturing) is vital in ensuring that a wide variety of designs can be realised. Unlike other additive manufacturing techniques that leverage on the addition of support structures, WAAM utilises a support-free approach for overhang fabrication to ensure components achieve a minimal buy-to-fly ratio. Currently, turntables are employed to achieve features with overhangs, but this does not scale well for large parts, in which the substrate’s position is fixed. This paper presents an alternative approach to overcome this limitation by implementing adaptive process control for the fabrication of thin-walled components with overhang features under flat-position deposition conditions. An overhang slicer algorithm was developed to generate the toolpath based on the sliced computer-aided design model and tag the toolpath with overhang angle information. A data-driven interpolation model was then used to determine the torch speed for each path segment based its overhang angle that would result in uniform layer height. A thin-walled part with a complex overhang feature that varies from 0° to 37.5° was fabricated using the proposed approach. The result is a near-net shape part, as verified using an industrial optical three-dimensional digitiser.
ISSN:0268-3768
1433-3015
DOI:10.1007/s00170-019-04737-4