A benchmark of mechanical properties and operational parameters of different steel filler metals for wire arc additive manufacturing

Silva, Rafael Gomes Nunes; Vandermeiren, N.; Verlinde, Wim; Boruah, Dibakor; Motte, R. J. De; Waele, Wim De

doi:10.1007/s00170-023-11520-z

Cited by 2 publications

(1 citation statement)

References 41 publications

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“…Additive manufacturing (AM) technology has evolved steadily over the last decade to overcome the challenges and operational and financial drawbacks associated with conventional manufacturing processes. AM is a tool-less, near-net-shape production technology, based on three-dimensional (3D) model data [1]. This new type of processing has provided industries with unprecedented opportunities to produce metal components with complex free-form geometries, where such geometries are not achievable using conventional manufacturing techniques [2,3].…”

Section: Introductionmentioning

confidence: 99%

A Review on the Weldability of Additively Manufactured Aluminium Parts by Fusion and Solid-State Welding Processes

Nunes,

Faes,

De Waele

et al. 2023

Metals

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Additive manufacturing (AM) processes are playing a significant role in several industrial sectors such as construction and machine building industries, involving a wide variety of metallic materials. Among these, the AM of aluminium alloys has developed significantly over the last decade, mainly through Powder Bed Fusion (PBF) and Directed Energy Deposition (DED) processes. Despite the many advantages of AM technology, some large or complex products cannot be produced entirely without the use of conventional manufacturing and joining processes, generally for financial or operational reasons. In this way, the ability to join conventionally and additively manufactured components or parts represents a crucial step towards their future use and the consolidation of conventional and additive manufacturing technologies. Despite the growing interest in AM technologies, there is still a significant lack of information on the joining of conventionally and additively manufactured components. The present work proposes a first review of the literature evaluating the weldability of AM aluminium alloys. The focus is on the use of fusion and solid-state welding processes and analysing the achieved microstructural evolution and mechanical properties. A clear relationship is observed between the AM technology used to produce the part, and the physical principles of the joining process. In addition, the gaps in the literature are highlighted to enable focused future work.

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Section: Introductionmentioning

confidence: 99%

A Review on the Weldability of Additively Manufactured Aluminium Parts by Fusion and Solid-State Welding Processes

Nunes,

Faes,

De Waele

et al. 2023

Metals

Self Cite

View full text Add to dashboard Cite

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Welding of Additively Manufactured Aluminium Alloy Components: Challenges and Mitigation Strategies

Nunes,

Faes,

Verlinde

et al. 2024

Preprint

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Additive manufacturing (AM) has contributed to significant advances in the production of aluminium alloys, particularly through powder bed fusion (PBF) and directed energy deposition (DED) processes. However, joining of conventionally and additively manufactured components remains essential. This work focuses on the weldability of AM aluminium alloys using fusion and solid-state welding processes. The study analyses the microstructural evolution and mechanical properties, revealing a relationship between AM technology and joining process. In particular, fusion welding of PBF-LB produced aluminium alloys presented a significant limitation due to the high porosity level, especially in the weld zone near the PBF-LB base material. This region of high porosity, known as the pore belt region, has an enormous detrimental effect on the mechanical properties of the weld. This phenomenon is not observed when the welds are carried out by solid-state welding processes, which makes this group of welding processes very suitable for this type of material. On the other hand, fusion welding of aluminium alloys produced by Wire Arc Additive Manufacturing (DED-Arc or WAAM) exhibits a good stability and repeatability, analogous to conventional aluminium alloy welding practices. Rotational friction welding of DED-Arc-produced components presented an unexpected challenge. Due to the difference in ductility compared to conventionally manufactured parts, the process window for optimal process pressure was found to be very narrow and sensitive. The findings are confirmed by metallographic examination, hardness profile measurement, tensile and bend testing.

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A benchmark of mechanical properties and operational parameters of different steel filler metals for wire arc additive manufacturing

Cited by 2 publications

References 41 publications

A Review on the Weldability of Additively Manufactured Aluminium Parts by Fusion and Solid-State Welding Processes

A Review on the Weldability of Additively Manufactured Aluminium Parts by Fusion and Solid-State Welding Processes

Welding of Additively Manufactured Aluminium Alloy Components: Challenges and Mitigation Strategies

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