INDUSTRIAL IMPLEMENTATION OF HYBRID MANUFACTURING FOR REPAIR
Abstract
The shift towards circular, sustainable fabrication is becoming an urgent challenge for the manufacturing industry. As relatively new technologies, such as additive and hybrid manufacturing gain more trust of the industry, the repair possibilities also get a new extension. Components deemed as nonreworkable or too expensive to repair with specialized personnel and technology, can be brought back to their original geometries and initial or even enhanced mechanical characteristics, within hours, instead of days, using the hybrid repair approach. The increasing number of research projects developed for various materials and industries, such as aerospace, automotive, tooling, underline its potential to reduce time, cost of repair, and extend the lifetime of components. Even if the results are promising, companies still doubt the reliability of the process, as the technology readiness level is not yet explored for this approach. To respond to the industrial reluctance, this article aims to highlight the latest capabilities and challenges of hybrid repair, followed by the definition of a roadmap of implementation, extended with an industrial case study from the semiconductor equipment industry.
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W.Grzesik, A. Ruszaj, Hybrid Manufacturing Processes, Physical Fundamentals, Modelling and Rational Applications, Springer UK, Ser. Advanced Manufacturing, ISBN 978-3-030-77106-5
ASTM F3187-16: Standard Guide for Directed Energy Deposition of Metals, last update on 27.12.2016, as of www.astm.org
T.Cobbs, L.Brewer, J.L.Crandall, Optomec Webinar: How 3D printing saves time and lowers costs: DED for repair of industrial components, available on optomec.com (2019)
A.Saboori et.al. Application of DED-Based Additive Manufacturing in Repair, Appl.Sci. 9, 3316, 2019
Wang, Z.-K.; Ye, H.-Q.; Xu, D.-S.; Huang, S.-Y. Laser repairing surface crack of Ni-based superalloy components. Trans. Nonferrous Met. Soc. China, 11, 572–575, 2011
Zhu, S.; Chen,W.; Zhan, X.; Ding, L.; Zhou, J. Parameter optimisation of laser cladding repair for an Invar alloy mould. Proc. Inst. Mech. Eng. Part B:J. Eng. Manuf. [CrossRef] 2018
Yu, J.-H.; Choi, Y.-S.; Shim, D.-S.; Park, S.-H. Repairing casting part using laser assisted additive metal-layer deposition and its mechanical
properties. Opt. Laser Technol., 106, 87–93, 2018
Onuike, B.; Bandyopadhyay, A. Additive manufacturing in repair: Influence of processing parameters on properties of Inconel 718. Mater. Lett. 252, 256–259. [CrossRef], 2019
Kattire, P.; Paul, S.; Singh, R.; Yan,W. Experimental characterization of laser cladding of CPM 9V on H13 tool steel for die repair applications. J. Manuf. Process., 20, 492–499. [CrossRef], 2015
J.D. Hamilton, S.Sorondo, B.Li, H.Qui, Mechanical behaviour of bimetallic stainless steel and gray cast iron repairs via directed energy deposition additive manufacturing, Journal of Manufacturing Processes
:1197-1207, 2023
H.Rajaei et.al Microstructural and Tribological Evaluation of Brake Disc Refurbishing Using Fe- Based Coating via Directed Energy Deposition,
MDPI Metals, 12 (3), 2022
X.Zhang et.al, A Hybrid Process Integrating Reverse Engineering Pre-Repair Processing, Additive Manufacturing and Material Testing for Component Remanufacturing, MDPI Materials 12, 1961, 2019
M.Perini, P.Bosetti, N.Balc, Additive manufacturing for repairing: from damage identification and modeling to DLD, Rapid Prototyping Journal, 26/5929-940, Emerald Publishing Limited (ISSN 1355-
, 2020
M.Liu et.al, A review of the anomalies in DED Processes & Potential solutions – Part Quality & Defects, Procedia Manufacturing of the 49th SME North American Manufacturing Research Conference (NAMRC 49, 2021), Volume 53, pgs. 507-518, 2021
K.Nyamuchiwa et.al, Recent Progress in Hybrid Additive Manufacturing of Metallic Materials, Applied Sciences 13(14) :8383, 2023
ISO/ASTM 52920:2023 Additive manufacturing — Qualification principles — Requirements for industrial additive manufacturing
processes and production sites, avaialble as of 25.09.2023 on https://www.iso.org/standard/76911.html
M.P.Masterton et.al, Algorithmic detection and categorization of partially attached particles in AM structures: a non-destructive method for the certification of lattice implants, Rapid Prototyping Journal, 29/7, 2023
Y.Xiao, et.al, Restoration of pure copper motor commutator for aviation by laser powder deposition, Journal of Materials Research and Technology 23:5796-5806, 2023
M.Liu et.al, Multi-indicator evaluation and material selection of hybrid additive-subtractive manufacturing to repair automobile panel dies and
molds, The International Journal of Advanced Manufacturing Technologies, 127: 1675-1690, 2023
P.Kahhal, Y-K.Jo, S-H Park, Recent Progress in Remanufacturing Technologies using Metal Additive Manufacturing Processes and Surface Treatment, International Journal of Precision Engineering and
Manufacturing - Green Technology, ISSN 2198-0810, 2023
A Muniappan et. Al, Investigation of wire EDM control variables on kerf width for Al6063/SiC/Al2 O3 composite by response surface methodology IOP Conf. Ser.: Mater. Sci. Eng. 402 012152, 2018
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