Microstructure characterization of SS308LSi components manufactured by GTAW-based additive manufacturing: shaped metal deposition using pulsed current arc

Yilmaz, Oğuzhan; Ugla, Adnan A.

doi:10.1007/s00170-016-9053-y

Cited by 81 publications

(33 citation statements)

References 23 publications

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“…WAAM can directly fabricate fully-dense metallic large 3-D near-net-shape components with a much higher deposition rate, than most other metal additive manufacture processes [5,6], the highest rate so far being of 9.5 kg/h [7]. The WAAM process has successfully produced large-scale parts in stainless steel [8], Inconel ® [9], titanium [10], aluminium [11] and tungsten [12]. Furthermore, functionally graded structures of refractory metals have also been deposited using WAAM [13].…”

Section: Introductionmentioning

confidence: 99%

Grain refinement in an unalloyed tantalum structure by combining Wire+Arc additive manufacturing and vertical cold rolling

Marinelli

Martina

Ganguly

et al. 2020

Additive Manufacturing

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Components manufactured via Wire + Arc Additive Manufacturing are usually characterised by large columnar grains. This can be mitigated by introducing in-process cold-rolling; in fact, the associated local plastic deformation leads to a reduction of distortion and residual stresses, and to microstructural refinement. In this research, interpass rolling was applied with a load of 50 kN to a tantalum linear structure to assess its effectiveness in changing the grain structure from columnar to equiaxed, as well as in refining the grain size. An average grain size of 650 µm has been obtained after five cycles of inter-pass rolling and deposition. When the deformed layer was reheated during the subsequent deposition, recrystallisation occurred, leading to the growth of new strain-free finer equiaxed grains. The depth of the refined region has been characterised and correlated to the hardness profile developed after rolling. A reduction of porosity was also registered. Furthermore, a random texture was formed after rolling, which should result in isotropic mechanical properties. Wire + Arc Additive Manufacturing process demonstrated the ability to deposit sound refractory metal components and the possibility to improve the microstructure when coupled with cold inter-pass rolling.

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Section: Introductionmentioning

confidence: 99%

Grain refinement in an unalloyed tantalum structure by combining Wire+Arc additive manufacturing and vertical cold rolling

Marinelli

Martina

Ganguly

et al. 2020

Additive Manufacturing

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“…This makes it possible to ignite the arc independently of the filler material supply by means of highfrequency or drawn arc ignition, which facilitates a stable, spatter-free starting process. TIG hot wire processes are mainly used in the additive production of highly reactive materials such as high-alloyed steels as well as titanium and nickelbased alloys [22][23][24][25][26][27][28][29][30]. However, a striking disadvantage of processes with a non-melting electrode is that the torch is set vertically with a lateral hot wire feeding system.…”

Section: Introductionmentioning

confidence: 99%

Development of a novel TIG hot-wire process for wire and arc additive manufacturing

et al. 2020

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The presented work deals with the development of a novel TIG hot-wire process for the additive manufacturing of metallic components, which, in contrast to previous arc processes, enables a significant increase in melting performance with simultaneously reduced heat input. This is achieved by means of an upstream resistance heating of the wire between two contact points within the hot wire feeding system. The torch, hot wire feeder and gas nozzle are designed in such a way that a constant bead geometry can be guaranteed regardless of the machining direction. On the one hand, this can improve the dimensional accuracy; on the other hand, an increase in productivity is achieved through a significant reduction of process times. Essential parts of the work include the simulation-supported development of the processing system, the design and implementation of an innovative process control system and the testing of the new technology.

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“…Previous studies on WAAM of stainless steel report the use of Gas Tungsten Arc Welding (TIG) for 308LSi steel, Cold Metal Transfer (CMT) for 240 steel [4], CMT and automated TIG welding (Top TIG) for stainless steel with the aim of optimizing deposition rate [5] and deposition strategies for any material [6]. An attempt to reach high productivity has been reported by Yuehai Feng [7] using double wire plasma arc in comparison with single wire with good results Queguineur, A. et al analyse the potential of additive manufacturing for large components using the CMT process and the consequences on the manufacturing time for austenitic stainless steel parts used in naval construction [8].…”

Section: Introductionmentioning

confidence: 99%

Tandem metal inert gas process for high productivity wire arc additive manufacturing in stainless steel

Martina

Ding

Williams

et al. 2019

Additive Manufacturing

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This study investigates the feasibility of achieving high deposition rate using wire + arc additive manufacturing in stainless steel to reduce lead time and cost of manufacturing. The pulse MIG welding technique with a tandem torch was used for depositing martensitic stainless steel 17-4 PH. The mechanical and metallurgical properties of the manufactured component were analysed to evaluate the limitations and the extent to which the rate of deposition reaches a maximum without any failure or defect being evident in the manufactured component. Deposition rate of 9.5 kg/hr was achieved. The hardness was matched for the as deposited condition.

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Microstructure characterization of SS308LSi components manufactured by GTAW-based additive manufacturing: shaped metal deposition using pulsed current arc

Cited by 81 publications

References 23 publications

Grain refinement in an unalloyed tantalum structure by combining Wire+Arc additive manufacturing and vertical cold rolling

Grain refinement in an unalloyed tantalum structure by combining Wire+Arc additive manufacturing and vertical cold rolling

Development of a novel TIG hot-wire process for wire and arc additive manufacturing

Tandem metal inert gas process for high productivity wire arc additive manufacturing in stainless steel

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