Molten Depth Modeling of Laser Transmission Welding Based on Temperature Distribution of Moving Point Heat Source

Zhang Yan; You Yu Lin; Hui Xia Liu; Pin Li; Ye Cai

doi:10.4028/www.scientific.net/KEM.620.23

Paper Titles

Modeling and Optimization of Laser Direct Joining Process Parameters of Titanium Alloy and Carbon Fiber Reinforced Nylon Based on Response Surface Methodology
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Modeling and Optimization of Mask Assisted Laser Transmission Micro Joining Process
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Experimental Research on Laser Transmission Micro-Joining Based on the Mask
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Molten Depth Modeling of Laser Transmission Welding Based on Temperature Distribution of Moving Point Heat Source
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Numerical Investigation on Laser-Assisted Flow Forming Process
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Impact Analysis of the Force Environment on the KDP Crystal Harmonic Loss Considering the Frame Surface Topography
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Experimental Study of Laser Direct Joining of Metal and Carbon Fiber Reinforced Nylon
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Study of Form Control Algorithm in Atmospheric Pressure Plasma Processing
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HomeKey Engineering MaterialsKey Engineering Materials Vol. 620Molten Depth Modeling of Laser Transmission...

Molten Depth Modeling of Laser Transmission Welding Based on Temperature Distribution of Moving Point Heat Source

Abstract:

Laser transmission welding (LTW) is a new and efficient technology. During LTW of polymers, the size and morphology of the weld have great influence on the welding quality. In order to better evaluate the welding quality and optimize process parameters, many researches on the morphology and mathematical analytical model of the molten pool have been conducted. This study attempts to build an analytical model for calculating the depth of the molten pool (molten depth), based on the temperature field distribution theory of the moving point heat source acting on the semi-infinite body. The influence of the welding power and welding speed on the molten depth is studied emphatically. The mathematical analytical model is solved through MATLAB mathematical software. Subsequently, the test experiment about LTW of PA66 is conducted to validate the model. During the test experiment, the upper layer contains 30 wt. % glass fibers (GF) and the bottom layer contains 30 wt. % carbon fiber (CF). The result shows that the mathematical analytical model can well predict the trend of the molten depth. However, the error exists indeed. The detailed analysis about the error is also made in this article.

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Periodical:

Key Engineering Materials (Volume 620)

Pages:

23-28

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.620.23

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Online since:

August 2014

Authors:

Zhang Yan, You Yu Lin, Hui Xia Liu, Pin Li, Ye Cai

Keywords:

Laser Transmission Welding, Mathematical Models, Molten Depth, Point Heat Source

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