Recent Advances in the Laser Forming Process: A Review

Safari, Mehdi; Sousa, Ricardo J. Alves de; Joudaki, Jalal

doi:10.3390/met10111472

Cited by 31 publications

(19 citation statements)

References 133 publications

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“…Hahn and Tekkaya [7] addressed both the numerics and experiments regarding the use of Vaporizing Foil Actuators (VFA) as an innovative and extremely fast sheet-metal forming methodology. Laser forming technology received attention from Safari et al in the works [8] and [9], the former as a state-of-art review in the field. The hydroforming process for the manufacture of complex shapes, such as metallic bellows, was performed by Safari et al [10].…”

Section: Contributionsmentioning

confidence: 99%

Numerical and Experimental Advances in Innovative Manufacturing Processes

Sousa

Safari

2021

Metals

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Section: Contributionsmentioning

confidence: 99%

Numerical and Experimental Advances in Innovative Manufacturing Processes

Sousa

Safari

2021

Metals

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“…Xiao et al [ 10 ] proposed an electrically assisted electromagnetic-forming process and improved the forming limit of 7075 aluminum alloy by nearly 40% compared to the conventional electromagnetic-forming method. As a high efficiency and flexibility heating source, the laser has gained more attention in the field of forming, as well as in many other fields [ 11 ]. Laser-assisted forming processes possess a superior ability to overcome the bottleneck of low-formability materials, reducing the load capacity of forming facilities, as well as realizing property-controlled forming.…”

Section: Introductionmentioning

confidence: 99%

Laser-Assisted Robotic Roller Forming of Ultrahigh-Strength Steel QP1180 with High Precision

et al. 2023

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Laser-assisted forming provides a perfect solution that overcomes the formability of low-ductility materials. In this study, laser-assisted robotic roller forming (LRRF) was applied to bend ultrahigh-strength steel sheet (a quenching and partitioning steel with a strength grade of 1180 MPa), and the effects of laser power density on the bending forces, springback, and bending radius of the final parts were investigated. The results show that LRRF is capable of reducing bending forces by 43%, and a compact profile with high precision (i.e., a springback angle smaller than 1° and a radius-to-thickness ratio of ~1.2) was finally achieved at a laser power density of 10 J/mm2. A higher forming temperature, at which a significant decrease in strength is observed, is responsible for the decrease of forming forces with a laser power density of higher than 7.5 J/mm2; another reason could be the heating-to-austenitization temperature and subsequent forming at a temperature above martensitic-transformation temperature. Forming takes place at a higher temperature with lower stresses, and unloading occurs at a relatively lower temperature with the recovery of Young’s modulus; both facilitate the reduction of springback angles. In addition, the sharp bending radius is considered to be attributed to localized deformation and large plastic strains at the heating area.

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“…13,17 The laser shock forming, based on a thermal-mechanical conversion process, have been demonstrated to be a high-throughput and flexible technique for nanostructure fabrication. [18][19][20] This noncontact and ultrahigh-strain-rate forming technology provides a promising production route for the direct and controllable formation of nanostructures. 5,21 Due to the combined performance of complex factors including ultrahigh strain rates, ultra-short time scale, size effect, and dynamic stress transfer, the high-speed forming process of nano-metals tends to generate different plastic mechanisms, mechanical responses and defect evolution behaviors compared to their bulk counterparts.…”

Section: Introductionmentioning

confidence: 99%