The use of Al-alloys is increasing in the automotive industry due to the pressing necessity to reduce weight and fuel consumption. Several parts concerning the car body are assembled through welding, where a high-quality seam is a key requirement. For this purpose, laser welding stands as an appealing option. On the other hand, laser welding of Al-alloys is a complex process due to the high reflectivity, reactivity, and crack susceptibility of these materials. In many cases, such issues limit the applicability of the autogenous welding, which is an advantageous feature of laser welding. High brilliance fiber lasers have been an enabling technology for improving the weldability of Al-alloys. However, laser welding of Al-alloys especially in a lap-joint configuration requires robust processing conditions able to maintain seam quality for each weld in high volumes even with part tolerances and tooling variability. Accordingly, this work discusses the process development and monitoring in laser welding of 5754 Al-alloy. In particular, the process was carried out in a double lap-joint configuration with 1 mm sheets, commonly used in automotive applications. A 3 kW fiber laser with in-source integrated monitoring capability was employed as the light source. The process feasibility zone was investigated as a function of laser power and welding speed, while the effect of focal position was investigated for the weld robustness. Weld seam types and defects were identified as well as the monitoring signals associated light back-reflected from the process.

1.
K.
Hong
 and
Y. C.
Shin
, “
Prospects of laser welding technology in the automotive industry : A review
,”
J. Mater. Process. Tech.
, vol.
245
, pp.
46
69
,
2017
.
https://doi.org/10.1016/j.jmatprotec.2017.02.008
Google Scholar
Crossref
Search ADS
 
2.
G.
Barbieri
,
F.
Cognini
,
M.
Moncada
,
A.
Rinaldi
, and
G.
Lapi
, “
Welding of Automotive Aluminum Alloys by Laser Wobbling Processing
,” vol.
879
, pp.
1057
1062
,
2017
.
Google Scholar
 
3.
S.
Ramasamy
 and
C. E.
Albright
, “
CO 2 and Nd – YAG laser beam welding of 5754 – O aluminium alloy for automotive applications
,” vol.
1718
, no. March,
2001
.
Google Scholar
 
4.
G.
Shannon
 and
H.
Chen
, “
Laser Welding of Aluminum and Copper for Battery Welding Applications
,” pp.
1015
1020
,
2009
.
Google Scholar
 
5.
X.
Zhang
,
T.
Huang
,
W.
Yang
,
R.
Xiao
,
Z.
Liu
, and
L.
Li
, “
Microstructure and mechanical properties of laser beam-welded AA2060 Al-Li alloy
,”
J. Mater. Process. Tech.
, vol.
237
, pp.
301
308
,
2016
.
https://doi.org/10.1016/j.jmatprotec.2016.06.021
Google Scholar
Crossref
Search ADS
 
6.
D.
Narsimhachary
,
R. N.
Bathe
,
G.
Padmanabham
, and
A.
Basu
, “
Influence of Temperature Profile during Laser Welding of Aluminum Alloy 6061 T6 on Microstructure and Mechanical Properties
,” pp.
948
953
,
2014
.
Google Scholar
 
7.
S.
Katayama
,
H.
Nagayama
,
M.
Mizutani
, and
Y.
Kawahito
, “
Fibre laser welding of aluminium alloy
,” vol.
7116
, no. September,
2009
.
Google Scholar
 
8.
J.
Coroado
,
S.
Meco
,
S.
Williams
, and
S.
Ganguly
, “
Fundamental understanding of the interaction of continuous wave laser with aluminium
,” pp.
3165
3174
,
2017
.
Google Scholar
 
9.
G.
Xu
 and
Z.
Cheng
, “
Laser keyhole welding on aluminum alloys
,” vol.
3888
, no.
2000
, pp.
710
716
,
2000
.
Google Scholar
 
10.
B.
Chang
,
J.
Blackburn
,
C.
Allen
, and
P.
Hilton
, “
Studies on the spatter behaviour when welding AA5083 with a Yb-fibre laser
,”
Int. J. Adv. Manuf. Technol.
, pp.
1769
1776
,
2016
.
Google Scholar
 
11.
F.
Caiazzo
,
V.
Alfieri
,
F.
Cardaropoli
, and
V.
Sergi
, “
Characterization of lap joints laser beam welding of thin AA 2024 sheets with Yb : YAG disk-laser
,” vol.
8433
, pp.
1
12
,
2012
.
Google Scholar
 
12.
A. C.
Popescu
,
C.
Delval
, and
M.
Leparoux
, “
Control of Porosity and Spatter in Laser Welding of Thick AlMg5 Parts Using High-Speed Imaging and Optical Microscopy
,”
2017
.
Google Scholar
 
13.
N.
Seto
,
S.
Katayama
, and
A.
Matsunawa
, “
Porosity formation mechanism and suppression procedure in laser welding of aluminium alloys
,” vol.
7116
,
2009
.
Google Scholar
 
14.
Y.
Yu
,
C.
Wang
,
X.
Hu
,
J.
Wang
, and
S.
Yu
, “
Porosity in fiber laser formation of 5A06 aluminum alloy
,” vol.
24
, no.
5
, pp.
1077
1082
,
2010
.
Google Scholar
 
15.
X.
Wang
,
F.
Lu
,
H.
Wang
,
H.
Cui
,
X.
Tang
, and
Y.
Wu
, “
Mechanical constraint intensity effects on solidification cracking during laser welding of aluminum alloys
,”
J. Mater. Process. Tech.
, vol.
218
, pp.
62
70
,
2015
.
https://doi.org/10.1016/j.jmatprotec.2014.11.037
Google Scholar
Crossref
Search ADS
 
16.
X.
Cao
,
W.
Wallace
,
J.
Immarigeon
, and
C.
Poon
, “
Research and Progress in Laser Welding of Wrought Aluminum Alloys. II. Metallurgical Microstructures, Defects, and Mechanical Properties
,” vol.
6914
, no. March 2017,
2003
.
Google Scholar
 
17.
X.
Cao
,
W.
Wallace
,
C.
Poon
, and
J.
Immarigeon
, “
Research and Progress in Laser Welding of Wrought Aluminum Alloys. I. Laser Welding Processes
,” vol.
6914
, no. March,
2003
.
Google Scholar
 
18.
B.
Hu
 and
B. H. M.
Richardson
, “
Autogenous laser keyhole welding of aluminum alloy 2024
,” vol.
70
,
2005
.
Google Scholar
 
19.
M.
Jiang
,
W.
Tao
,
S.
Wang
,
L.
Li
, and
Y.
Chen
, “
Effect of ambient pressure on interaction between laser radiation and plasma plume in fiber laser welding
,”
Vaccum
, vol.
138
, pp.
70
79
,
2017
.
https://doi.org/10.1016/j.vacuum.2017.01.012
Google Scholar
Crossref
Search ADS
 
20.
D. Y.
You
,
X. D.
Gao
, and
S.
Katayama
, “
Review of laser welding monitoring
,” vol.
1718
, no. February,
2014
.
Google Scholar
 
21.
J.
Stavridis
,
A.
Papacharalampopoulos
, and
P.
Stavropoulos
, “
Quality assessment in laser welding : a critical review
,” pp.
1825
1847
,
2018
.
22.
S. H.
Lee
 and
J.
Mazumder
, “
Spectroscopic measurements of plasma plume for welding monitoring
,” pp.
638
644
,
2009
.
23.
A. F. H.
Kaplan
,
P.
Norman
, and
I.
Eriksson
, “
Analysis of the Keyhole and Weld Pool Dynamics by Imaging Evaluation and Photodiode Monitoring
,” pp.
1
6
.
24.
F.
Bardin
 et al, “
Optical techniques for real-time penetration monitoring for laser welding
,” vol.
44
, no.
19
, pp.
3869
3876
,
2005
.
Google Scholar
 
25.
P.
De Bono
 et al, “
welding Investigation of optical sensor approaches for real-time monitoring during fibre laser welding
,” vol.
22417
,
2017
.
Google Scholar
 
26.
J.
Yu
,
Y.
Sohn
,
Y.
Whan
, and
J.
Kwak
, “
The development of a quality prediction system for aluminum laser welding to measure plasma intensity using photodiodes
,” vol.
30
, no.
10
, pp.
4697
4704
,
2016
.
Google Scholar
 
27.
D. A. V
Kliner
, “
nLIGHT alta TM : A Versatile, Next - Generation Fiber Laser Platform for kW Materials Processing
.”
28.
H.
Zhao
,
D. R.
White
, and
T.
Debroy
, “
Current issues and problems in laser welding of automotive aluminium alloys
,” vol.
6608
, no. March,
1999
.
Google Scholar
 
29.
K. H.
Leonga
,
K. R.
Saboa
,
P. G.
Sandersa
, and
W. J.
Spawrb
, “
Laser Welding of Aluminum Alloys
,” vol.
2993
, no.
630
,
1997
.
Google Scholar
 
30.
D.
You
,
X.
Gao
, and
S.
Katayama
, “
Multiple-optics sensing of high-brightness disk laser welding process
,”
NDT E Int.
, vol.
60
, pp.
32
39
,
2013
.
https://doi.org/10.1016/j.ndteint.2013.07.005
Google Scholar
Crossref
Search ADS
 
31.
K.
Kamimuki
,
T.
Inoue
,
K.
Yasuda
,
M.
Muro
,
T.
Nakabayashi
, and
A.
Matsunawa
, “
Behaviour of monitoring signals during detection of welding defects in YAG laser welding
.
Study of monitoring technology for YAG laser welding (Report 2)
,” vol.
7116
,
2010
.
Google Scholar
 
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