Comparative Numerical Analysis of Keyhole Shape and Penetration Depth in Laser Spot Welding of Aluminum with Power Wave Modulation

Thermo Pub Date : 2024-05-23 DOI:10.3390/thermo4020013
Saeid SaediArdahaei, Xuan-Tan Pham
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Abstract

Keyhole mode laser welding is a valuable technique for welding thick materials in industrial applications. However, its susceptibility to fluctuations and instabilities poses challenges, leading to defects that compromise weld quality. Observing the keyhole during laser welding is challenging due to bright process radiation, and existing observation methods are complex and expensive. This paper alternatively presents a novel numerical modeling approach for laser spot welding of aluminum through a modified mixture theory, a modified level-set (LS) method, and a thermal enthalpy porosity technique. The effects of laser parameters on keyhole penetration depth are investigated, with a focus on laser power, spot radius, frequency, and pulse wave modulation in pulsed wave (PW) versus continuous wave (CW) laser welding. PW laser welding involves the careful modulation of power waves, specifically adjusting the pulse width, pulse number, and pulse shapes. Results indicate a greater than 80 percent increase in the keyhole penetration depth with higher laser power, pulse width, and pulse number, as well as decreased spot radius. Keyhole instabilities are also more pronounced with higher pulse width/numbers and frequencies. Notably, the rectangular pulse shape demonstrates substantially deeper penetration compared to CW welding and other pulse shapes. This study enhances understanding of weld pool dynamics and provides insights into optimizing laser welding parameters to mitigate defects and improve weld quality.
采用功率波调制对铝进行激光点焊时锁孔形状和穿透深度的数值对比分析
锁孔模式激光焊接是工业应用中焊接厚材料的重要技术。然而,它容易受到波动和不稳定性的影响,从而导致缺陷,影响焊接质量。由于激光焊接过程中会产生明亮的辐射,因此在焊接过程中观察锁孔具有挑战性,而且现有的观察方法复杂而昂贵。本文通过改进的混合物理论、改进的水平集(LS)方法和热焓气孔技术,提出了一种新的铝激光点焊数值建模方法。研究了激光参数对锁孔穿透深度的影响,重点是脉冲波(PW)与连续波(CW)激光焊接中的激光功率、光斑半径、频率和脉冲波调制。脉冲波激光焊接涉及对功率波的精心调制,特别是调整脉冲宽度、脉冲数和脉冲形状。结果表明,随着激光功率、脉冲宽度和脉冲数的增加,锁孔穿透深度增加了 80%以上,同时光斑半径也减小了。脉冲宽度/数量和频率越高,锁孔的不稳定性也越明显。值得注意的是,与 CW 焊接和其他脉冲形状相比,矩形脉冲形状的穿透深度更深。这项研究加深了对焊接熔池动力学的理解,并为优化激光焊接参数以减少缺陷和提高焊接质量提供了启示。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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CiteScore
2.10
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