رحمانی نیا, میلاد, قریشی, مجید (2025). Experimental Modeling and Process Optimization of Laser Transmission Welding with Fiber Optic Laser for Polymethyl Methacrylate in Zigzag Path. , 25(5), 271-278. doi: 10.48311/mme.2025.24030
میلاد رحمانی نیا; مجید قریشی. "Experimental Modeling and Process Optimization of Laser Transmission Welding with Fiber Optic Laser for Polymethyl Methacrylate in Zigzag Path". , 25, 5, 2025, 271-278. doi: 10.48311/mme.2025.24030
رحمانی نیا, میلاد, قریشی, مجید (2025). 'Experimental Modeling and Process Optimization of Laser Transmission Welding with Fiber Optic Laser for Polymethyl Methacrylate in Zigzag Path', , 25(5), pp. 271-278. doi: 10.48311/mme.2025.24030
رحمانی نیا, میلاد, قریشی, مجید Experimental Modeling and Process Optimization of Laser Transmission Welding with Fiber Optic Laser for Polymethyl Methacrylate in Zigzag Path. , 2025; 25(5): 271-278. doi: 10.48311/mme.2025.24030

Experimental Modeling and Process Optimization of Laser Transmission Welding with Fiber Optic Laser for Polymethyl Methacrylate in Zigzag Path

مهندسی مکانیک مدرس
Article 3, Volume 25, Issue 5, 1404, Pages 271-278    PDF (1017.03 K)
DOI: 10.48311/mme.2025.24030
Authors
میلاد رحمانی نیا* 1; مجید قریشی2
1دانشگاه خواجه نصیرالدین طوسی
2دانشگاه صنعتی خواجه نصیرالدین طوسی
Abstract
Polymethyl methacrylate (PMMA) is extensively used in automotive, aerospace, and consumer products industries due to its favorable mechanical characteristics. Laser Transmission Welding (LTW) has recently gained attention as an advanced joining method for creating strong, narrow, and lightweight welds in thermoplastics like PMMA. This study examines the effects of three key process parameters—laser power, welding speed, and scan line spacing—on the LTW performance when bonding two transparent PMMA sheets using a fiber laser along a zigzag path. The main objective is determining the feasibility of practical welding at low laser power while achieving high joint strength. Experimental design and optimization were conducted using Analysis of Variance (ANOVA) and Response Surface Methodology (RSM). ANOVA confirmed that all three parameters significantly influenced lap-shear force. RSM results showed that higher laser power, lower welding speed, and reduced scan line spacing increased heat input and improved weld strength, with a maximum lap-shear force of 1256 N. In contrast, lower laser power, faster welding, and wider spacing reduced heat input and resulted in a minimum strength of 245 N. Desirability-based optimization identified optimal settings of 30 W laser power, 400 mm/s welding speed, and 0.015 mm scan line spacing, predicting a lap-shear force of 1249.2 N with 99.3% confidence. The results demonstrate that zigzag LTW of PMMA is feasible at low power levels, attributed to uniform heat distribution and consistent melting achieved by the zigzag path.
Keywords
Laser transmission welding; Polymethyl methacrylate; Transparent polymer welding parameters; Zigzag Path; Response Surface Methodology (RSM); Optimization
References
Statistics
Article View: 3,700
PDF Download: 4,652
Statistics
Number of Journals45
Number of Issues2,171
Number of Articles24,674
Article View24,454,623
PDF Download17,557,935