3D-printing for Aerospace : Fatigue Behaviour of Additively Manufactured Titanium

Kahlin, Magnus

doi:10.3384/diss.diva-178726

Cited by 2 publications

(2 citation statements)

References 47 publications

(72 reference statements)

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“…The life assessment of AM fatigue-critical aerospace parts has been addressed in [47]: Finite Element Analyses (FEA) results were used in the iterative design process to determine the life of a typical aerospace joint in titanium Ti-6Al-4V under cyclic loadings. The same alloy was analysed in [48] to achieve sufficient confidence and knowledge for predicting fatigue life and crack growth propagations. Airbus investigated the feasibility of replicating critical structural joints in titanium [49,50].…”

Section: Scope Of the Activitymentioning

confidence: 99%

Design and Qualification of an Additively Manufactured Manifold for Aircraft Landing Gears Applications

Arena¹,

Ambrogiani²,

Raiola³

et al. 2023

Aerospace

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The continuous pursuit of reducing weight and optimizing manufacturing processes is increasingly demanded in transportation vehicles, particularly in the aerospace field. In this context, additive manufacturing (AM) represents a well-known technique suitable for re-engineering traditional systems, minimizing the product’s weight/volume and print time. The present research activity allowed for the exploration of the feasibility to replicate a conventional hydraulic manifold already certified for defence application with a lightweight and more compact issue through typical stringent aeronautical qualification steps. Computational modelling with lab test efforts made it possible to assess the compliance of the device with airworthiness certification requirements, giving a special focus to the fulfilment of structural requirements. In particular, the fatigue life characterization is still a crucial point to be well investigated in aeronautical components dfAM (designed for additive manufacturing) to demonstrate the maturity of the technology in the certification scenario. The new AM-driven design offers a more than 40 per cent weight reduction.

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Section: Scope Of the Activitymentioning

confidence: 99%

Design and Qualification of an Additively Manufactured Manifold for Aircraft Landing Gears Applications

Arena¹,

Ambrogiani²,

Raiola³

et al. 2023

Aerospace

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“…High cycle fatigue is regarded as one of the major causes of turbine failures in military aircraft [45]. To avoid mechanical failure in an aeroengine, it is crucial to investigate the effect of fatigue crack initiation (FCI) and short crack growth (SCG) in the aeroengine spare parts produced with the use of additively manufactured aluminium alloys materials [118]. In WAAM techniques, process parameters (such as voltage, wire feed speed, current, inter-pass temperature, and shielding gas flow), material composition, environmental conditions (such as gas contamination) [77], and many other factors can significantly influence oxidation effects.…”

Section: Challenges Facing the Application Of Waam In Aerospace And A...mentioning

confidence: 99%

Wire arc additive manufacturing of aluminium alloys for aerospace and automotive applications: A review

Omiyale

Olugbade

Abioye

et al. 2022

Materials Science and Technology

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Wire arc additive manufacturing (WAAM) is suitable for printing medium-to-large complex parts with structural integrity while reducing material wastage, and lead time, improving the quality and customized design for functional components. Aluminium alloys are one of the most commonly used metallic materials in manufacturing parts for aerospace and automotive applications due to their lightweight, excellent strength, and corrosion resistance properties. Aluminium alloys have been employed in the WAAM process to produce parts for the aerospace and automotive industries. In this paper, various research works associated with the application of WAAM of aluminium alloys for aerospace and automotive industries, their metallurgical characteristics, and mechanical properties have been reviewed and discussed in detail to identify the research gap and future research directions. This paper is patterned to provide a comprehensive review of WAAM of aluminium alloys for the production of parts in the aerospace and automotive industries. Abbreviations: AM: Additive manufacturing; Al: Aluminium; Bi: Bismuth; BIW: Body in white; CNC: Computer numerical machines; CMT: Cold metal transfer; CNN: Convolutional neural networks; CL: Curved layer; DE-GMAAM: Double-electrode gas metal arc additive manufacturing; DWAAM: Double wire arc additive manufacturing; DMD: Direct metal deposition; DMLS: Direct metal laser sintering; DED-arc: Directed energy deposition arc; 3D: Three-dimensional; EAC: Environmentally assisted cracking; EBM: Electron beam melting; FCI: Fatigue crack initiation; Fe: Iron; GTAW: Gas tungsten arc welding; GMAW: Gas metal arc welding; HE: Hydrogen embrittlement; HAZ: Heat-affected zone; HWAAM: Hot wire arc additive manufacturing; IISCC: Irradiation induced stress corrosion cracking; Li: Lithium; Mg: Magnesium; Mn: Manganese; Ni: Nickel; OL: Online cooling; Pb: Lead; PAW: Plasma arc welding; RS: Robotic system; SCC: Stress corrosion cracking; SLM: Selective laser melting; SCG: Short crack growth; SLC: Super light car; Si: Silicon; Ti: Titanium; Zr: Zirconium

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3D-printing for Aerospace : Fatigue Behaviour of Additively Manufactured Titanium

Cited by 2 publications

References 47 publications

Design and Qualification of an Additively Manufactured Manifold for Aircraft Landing Gears Applications

Design and Qualification of an Additively Manufactured Manifold for Aircraft Landing Gears Applications

Wire arc additive manufacturing of aluminium alloys for aerospace and automotive applications: A review

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