Evaluation of Key Geometrical and Mechanical Properties for Remote Laser Welded AC-170PX Aluminium Joints

IF 0.8 4区材料科学 Q4 MATERIALS SCIENCE, MULTIDISCIPLINARY

Journal of Laser Micro Nanoengineering Pub Date : 2019-04-01 DOI:10.2961/JLMN.2019.01.0001

Abhishek Das, I. Butterworth, I. Masters, D. Williams

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引用次数: 7

Abstract

Use of lightweight materials to produce automotive body structures is one of the key trends adopted by automotive manufacturers to minimise emission of greenhouse gases, and subsequently, reduction of fuel consumption. Aluminium alloys are one of the promising lightweight materials which are increasingly used for automotive body-in-white structures. Such applications demand both efficient and effective joining/welding methods to produce repeatable, durable and strong joints without significant alteration of material properties. Remote laser welding (RLW) is an emerging joining technology and increasingly being used to produce lightweight joints as it satisfies the demand for high production throughput at low cost. This paper investigates the effects of process parameters when seam tracking remote laser welding is used to create an autogenous fillet edge weld of automotive grade aluminum alloy (AC-170PX) in lap configuration without shielding gas. The effects of laser power and welding speed on the key geometric features are reported together with details of the weld microstructure. Joint strength is evaluated by performing a lap shear test. It is found that the laser power and welding speed have dominant influence on key geometric features and subsequently on the lap shear strength. Relatively larger grain size in the fusion zone reduces the microhardness by up to 20% in comparison with the base material.

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远程激光焊接AC-170PX铝接头关键几何力学性能评价

使用轻质材料生产汽车车身结构是汽车制造商为最大限度地减少温室气体排放，进而降低燃料消耗而采用的主要趋势之一。铝合金是一种很有前途的轻质材料，越来越多地用于白色结构的汽车车身。这种应用需要高效和有效的连接/焊接方法，以在不显著改变材料性能的情况下产生可重复、耐用和坚固的接头。远程激光焊接（RLW）是一种新兴的连接技术，由于它满足了低成本高产量的需求，越来越多地被用于生产轻质接头。本文研究了在无保护气体的情况下，采用焊缝跟踪远程激光焊接制造汽车级铝合金（AC-170PX）搭接自角焊缝时工艺参数的影响。报道了激光功率和焊接速度对关键几何特征的影响，以及焊缝微观结构的细节。通过进行搭接剪切试验来评估接头强度。研究发现，激光功率和焊接速度对关键几何特征以及搭接剪切强度有主要影响。与基体材料相比，熔合区中相对较大的晶粒尺寸可使显微硬度降低高达20%。

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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来源期刊

Journal of Laser Micro Nanoengineering 工程技术-材料科学：综合

CiteScore

1.90

自引率

9.10%

发文量

审稿时长

3 months

期刊介绍： Journal of Laser Micro/Nanoengineering, founded in 2005 by Japan Laser Processing Society (JLPS), is an international online journal for the rapid publication of experimental and theoretical investigations in laser-based technology for micro- and nano-engineering. Access to the full article is provided free of charge. JLMN publishes regular articles, technical communications, and invited papers about new results related to laser-based technology for micro and nano engineering. The articles oriented to dominantly technical or industrial developments containing interesting and useful information may be considered as technical communications.