Optimization of laser bending process parameters for enhanced bending angle and residual stress control in St12 steel sheets: Experimental investigation and FEM simulation
Restricted accessResearch articleFirst published online August, 2025
Optimization of laser bending process parameters for enhanced bending angle and residual stress control in St12 steel sheets: Experimental investigation and FEM simulation
Laser bending has emerged as an efficient technique for bending sheet metals without the need for mechanical force or hard tooling. This study investigates the bending angle and residual stress in ST12 steel sheets under direct CO2 laser irradiation. Finite element simulations, experimental investigations, and statistical analysis were employed to systematically examine the influence of laser power (1600–2400 W), scanning speed (65–93 mm/s), and the number of passes (1–5) on the bending process. Seventy-five numerical simulations and a subset of 15 experiments – selected via the Central Composite Design (CCD) method – were conducted to optimize process parameters and validate the simulation model. ANOVA identified the number of passes as the most significant factor; additionally, higher scanning speeds reduced both the bending angle and residual stress, whereas increased laser power had the opposite effect. Notably, higher compressive residual stresses, resulting primarily from multiple passes, help mitigate the spring-back effect, thereby enhancing the final form accuracy of the bent sheet. Simulation outcomes, validated with a maximum error of 6.48%, were used to determine the optimal conditions (2400 W, 65 mm/s, and five passes) for achieving the desired bending performance. Overall, this research advances our understanding of laser bending phenomena and provides practical guidelines for optimizing sheet metal forming processes.
SafariMAlves de SousaRJoudakiJ. Recent advances in the laser forming process: a review. Metals2020; 10: 1472.
2.
AherVNavtharRR. A comprehensive review on laser bending of advanced materials. Lasers Manuf Mater Process2024; 11(3): 814–852.
3.
KhandaiBKGopinathM. Modelling and monitoring of scaling effects in multi-scan laser forming. Opt Laser Technol2025; 186: 112712.
4.
SafariMBabaeiAMZamzamiB, et al. Experimental investigation, statistical modeling and optimization of laser bending process of perforated sheets. Opt Laser Technol2024; 175: 110810.
5.
NikhilPKumarVArun BabuK. Selection and optimization of process parameters during multi-pass laser bending process. Opt Laser Technol2025; 184: 112406.
6.
AhemadMWPalaniIAJoshiSS. Investigation on multiple bending using laser forming of mild steel plate and its bend angle prediction. J Micromanufacturing2025; 25165984241312738.
7.
YadavRVinayGKantR. Mechanical, metallurgical and corrosion analysis of forced cooling assisted laser bending of duplex-2205. Opt Laser Technol2024; 175: 110804.
8.
SharmaYPKantRSidhuBS, et al. Mechanical behaviour of mild steel during multi-scan laser bending with forced cooling. Opt Laser Technol2024; 171: 110417.
9.
AbedinzadehRSattariMToghraieD. Experimental analysis on bending behavior of non-alloy carbon steel sheets using laser forming process. Steel Res Int2022; 93: 2200011.
10.
NathUYadavVBhadauriaSS. Effects of workpiece size on bending angle in laser forming of al 6061-T6 sheet. Mater Today Proc2024; 113: 307–313.
11.
LiuYDengDLiuJ, et al. Investigation on the bending deformation of laser peen forming with a simplified eigenstrain-based finite element model. Int J Adv Manuf Technol2024; 131: 5815–5816.
12.
NathUYadavV. Analytical modeling of temperature evolution and bend angle in laser forming of Al 6061-T6 sheets and its experimental analysis. Opt Laser Technol2022; 154: 108307.
13.
KotobiMHonarpishehM. Through-depth residual stress measurement of laser bent steel–titanium bimetal sheets. J Strain Anal Eng Des2018; 53: 130–140.
14.
KotobiMMansouriHHonarpishehM. Investigation of laser bending parameters on the residual stress and bending angle of St-Ti bimetal using FEM and neural network. Opt Laser Technol2019; 116: 265–275.
15.
YilbasBSAkhtarSS. Laser bending of metal sheet and thermal stress analysis. Opt Laser Technol2014; 61: 34–44.
16.
HuJCaoQShenH. Experimental study on edge effects in laser bending. J Laser Appl2010; 22(4): 144–149.
17.
ZahraniEGMarasiA. Modeling and optimization of laser bending parameters via response surface methodology. Proc IMechE, Part C2012; 227(7): 1577–1584.
18.
MajiKPratiharDKNathAK. Experimental investigations, modeling, and optimization of multi-scan laser forming of AISI 304 stainless steel sheet. Int J Adv Manuf Technol2016; 83(9): 1441–1455.
19.
SeyedkashiSMHAbazariHDGolloMH, et al. Characterization of laser bending of SUS304L/C11000 clad sheets. J Mech Sci Technol2019; 33(7): 3223–3230.
20.
YadavRGoyalDKKantR. A comprehensive study on the effect of line energy during laser bending of duplex stainless steel. Opt Laser Technol2022; 151: 108025.
21.
RoohiAH, et al. Effects of temperature gradient magnitude on bending angle in laser forming process of aluminum alloy sheets. J Comput Appl Res Mech Eng2015; 5: 97–109.
22.
PirchNWissenbachK. Mechanisms during laser bending. J Laser Appl2008; 20: 135–139.
23.
NathUYadavV. An experimental validation of thermo-mechanical analytical model in laser bending process. In: Advances in Modelling and Optimization of Manufacturing and Industrial Systems, Springer Nature, 2023, pp. 455–474.
24.
AnsariPKazemi GhouhakiRAhmadiF. Investigation of the effect of ultrasonic vibration on the performance of the friction drilling by FEM simulation. Proc IMechE, Part E2024; 09544089241242612.
25.
MazdakSSheykholeslamiMRGholamiM, et al. A statistical model for estimation of bending angle in laser bending of two-layer steel-aluminum sheets. Opt Laser Technol2023; 157: 108575.
26.
KantRJoshiSN. A numerical investigation into the effect of forced convection cooling on the performance of multi-scan laser bending process. In: Application of lasers in manufacturing. Singapore: Springer Nature, 2019, pp. 24–43.
27.
Esmaeil KhandandelSHossein SeyedkashiSMMoradiM. Numerical and experimental analysis of the effect of forced cooling on laser tube forming. J Braz Soc Mech Sci Eng2021; 43(7): 338.
28.
MulaySPaliwalVBabuNR. Analytical model for prediction of bend angle in laser forming of sheets. Int J Adv Manuf Technol2020; 109(3): 699–715.
29.
RoohiAHMoslemi NaeiniHHoseinpour GolloM. An experimental investigation of parameters effect on laser forming of Al6061-T6 sheets. Proc IMech Eng, Part L2015; 231(5): 433–442.
30.
DongWZhangYBaoL, et al. Effects of laser scanning strategy on bending behavior and microstructure of DP980 Steel. Materials2024; 17: 2415.
31.
SafariMAlves de SousaRJoudakiJ. Comprehensive assessment of laser tube bending process by response surface methodology. Steel Res Int2022; 94: 2200230.
32.
ChenM-LJeswietJBatesPJ, et al. Experimental study on sheet metal bending with medium-power diode laser. Proc IMech Eng, Part B2008; 222(3): 381–389.
33.
Hoseinpour GolloMMahdavianSMMoslemi NaeiniH. Statistical analysis of parameter effects on bending angle in laser forming process by pulsed Nd:YAG laser. Opt Laser Technol2011; 43(3): 475–482.
34.
KantRJoshiSN. Thermo-mechanical studies on bending mechanism, bend angle and edge effect during multi-scan laser bending of magnesium M1A alloy sheets. J Manuf Process2016; 23: 135–148.
35.
ImhanKIBaharudinBTHTZakariaA, et al. Improve the material absorption of light and enhance the laser tube bending process utilizing laser softening heat treatment. Opt Laser Technol2018; 99: 15–18.
36.
AbediHRHoseinpour GolloM. An experimental study of the effects of surface roughness and coating of Cr2O3 layer on the laser-forming process. Opt Laser Technol2019; 109: 336–347.
37.
Che JamilMSSheikhMALiL. A study of the effect of laser beam geometries on laser bending of sheet metal by buckling mechanism. Opt Laser Technol2011; 43(1): 183–193.
38.
LambiaseF. An analytical model for evaluation of bending angle in laser forming of metal sheets. J Mater Eng Perform2012; 21(10): 2044–2052.
39.
SafariMRabieeAHJoudakiJ. Developing a support vector regression (SVR) model for prediction of main and lateral bending angles in laser tube bending process. Materials2023; 16: 3251.
40.
KotobiMHonarpishehM. Experimental and numerical investigation of through-thickness residual stress of laser-bent Ti samples. J Strain Anal Eng Des2017; 52(6): 347–355.
41.
GheorghiesCNicoaraDPaunoiuV, et al. Numerical prediction of residual stresses in laser bending of stainless steel sheet metals. Key Eng Mater2009; 410-411: 629–640.
