A study on wire and arc additive manufacturing of low-carbon steel components: process stability, microstructural and mechanical properties

Le, Van Thao; Si, Dinh; Hoang, Quang Huy

doi:10.1007/s40430-020-02567-0

Cited by 35 publications

(9 citation statements)

References 36 publications

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“…These barriers relate, to a large extent, to the scarcity of test data on the mechanical properties and structural performance of additively manufactured materials [12,13,14]. In light of this, there has recently been a growing number of research groups investigating the microstructural and mechanical properties of different WAAM materials, including lowalloy steels [15,16,17,18,19] and various stainless steel alloys [20,21,22,23,24,25,26,27]. The aforementioned studies have revealed a degree of anisotropy in the behaviour of WAAM stainless steel material, i.e.…”

Section: Torchmentioning

confidence: 99%

Description of anisotropic material response of wire and arc additively manufactured thin-walled stainless steel elements

Hadjipantelis

Weber

Buchanan

et al. 2022

Thin-Walled Structures

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Section: Torchmentioning

confidence: 99%

Description of anisotropic material response of wire and arc additively manufactured thin-walled stainless steel elements

Hadjipantelis

Weber

Buchanan

et al. 2022

Thin-Walled Structures

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“…Essential attributes for an AM component are the resulting mechanical properties of the final product. These properties depend substantially on the thermal history of the material and relate with the microstructure, toughness, and the material [1,12,13]. For additive manufacturing, the knowledge of multilayer welding can be adapted with a few modifications.…”

Section: Introductionmentioning

confidence: 99%

Influence of the WAAM process and design aspects on residual stresses in high-strength structural steels

Wandtke¹,

Schroepfer²,

Scharf-Wildenhain

et al. 2023

Weld World

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Wire arc additive manufacturing (WAAM) enables the efficient production of weight-optimized modern engineering structures. Further increases in efficiency can be achieved by using high-strength structural steels. Commercial welding consumables for WAAM are already available on the market. Lack of knowledge and guidelines regarding welding residual stress and component safety during production and operation leads to severely limited use for industry applications. The sensitive microstructure of high-strength steels carries a high risk of cold cracking; therefore, residual stresses play a crucial role. For this reason, the influences of the material, the WAAM process, and the design on the formation of residual stresses and the risk of cold cracking are being investigated. The material used has a yield strength of over 800 MPa. This strength is adjusted via solid solution strengthening and a martensitic phase transformation. The volume expansion associated with martensite formation has a significant influence on the residual stresses. The focus of the present investigation is on the additive welding parameters and component design on their influence on hardness and residual stresses, which are analyzed by means of X-ray diffraction (XRD). Reference specimens (hollow cuboids) are welded fully automated with a systematic variation of heat control and design. Welding parameters and AM geometry are correlated with the resulting microstructure, hardness, and residual stress state. Increased heat input leads to lower tensile residual stresses which causes unfavorable microstructure and mechanical properties. The component design affects heat dissipation conditions and the intensity of restraint during welding and has a significant influence on the residual stress.

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“…Most of the previously mentioned studies have selected the process variables (e.g., the arc voltage, welding current, and wire-feed speed) based on the suggestion of the wire manufacturers for conventional welding or based on several tests, while the WADED process is very different from welding. In WADED processes, the quality and geometry of weld beads (e.g., stable and smooth shape and less spatter) notably affect the process stability and the appearance of as-fabricated components [22][23][24][25]. Therefore, this study aims to explore the relationship between the process variables {C, U, and V} and the geometrical characteristics of weld beads {BW, BH, and MPL} and identify optimal process parameters that produce weld beads with expected geometrical properties.…”

Section: Introductionmentioning

confidence: 99%

Optimization of Weld Parameters in Wire and Arc-Based Directed Energy Deposition of High Strength Low Alloy Steels

Dang

et al. 2023

Adv. technol. innov.

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This paper aims to investigate the fabrication of high strength low alloy (HSLA) steels by wire and arc-based directed energy deposition (WADED). Firstly, the relationship between the process variables (including the travel speed-V, the current-C, and the voltage-U) and the geometrical characteristics of weld beads (including the bead height (BH), bead width (BW), and melting pool length (MPL)) was investigated. Secondly, the optimal process variables were identified using the desirability approach. The results indicate that voltage-U has the highest impact on BW and MPL, meanwhile the travel speed-V is the most impacting factor on BH. The optimal variables for the WADED process of HSAL steels are V = 0.3 m/min, C = 160 A, and U = 19 V. The component fabricated with the optimal variables is fully dense without spatters and defects, confirming the efficiency of the WADED process for HSLA steels.

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A study on wire and arc additive manufacturing of low-carbon steel components: process stability, microstructural and mechanical properties

Cited by 35 publications

References 36 publications

Description of anisotropic material response of wire and arc additively manufactured thin-walled stainless steel elements

Description of anisotropic material response of wire and arc additively manufactured thin-walled stainless steel elements

Influence of the WAAM process and design aspects on residual stresses in high-strength structural steels

Optimization of Weld Parameters in Wire and Arc-Based Directed Energy Deposition of High Strength Low Alloy Steels

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