The tailor-welded blank (TWB) industry, which uses laser welding exclusively, is facing higher demands on quality assurance, both internally to raise efficiency of production lines and externally from their customers (predominantly auto makers). This paper introduces a novel, economical approach to TWB inspection, which employs the principle of magnetic flux leakage (MFL). The development of a laboratory-based MFL inspection tool for TWBs is presented. The effects of inspection system operating parameters are quantified to allow for optimized and robust performance. The operating parameters examined include applied magnetic field strength, scanning velocity, and sampling resolution. The ability of the MFL technique to detect defects that occur in the production environment from CO2 and Nd:YAG welds is clearly demonstrated. Defects include porosity, missed weld, pinholes, mismatch, concavity, and convexity. The issues of robustness and reliability surrounding the implementation of an industrial MFL inspection tool are addressed and suitable recommendations for further development are made.

Topics
Quality assurance, Chemical compounds, Metallurgy, Welding
1.
Auto/Steel Partnership,
Tailor Welded Blank Acceptance Guidelines, Southfield, Michigan
,
1996
.
2.
Bagsarian
,
T.
The Growth in Tailor-Welded Blanks and Hydroformed Parts
.
New Steel Magazine Online
. May 2000. Avail: http://www.newsteel.com/2000/NS0005f1.htm (Accessed March 25,
2003
)
Google Scholar
 
3.
Anonymous.
Tailor-Welded Blanks. University of Toledo
,
Senior Design Clinic
. 2000. Avail: http://www.mime.eng.utoledo.edu/design_clinic/design_expo/fall00pages/2000-04-08/introduction.HTM (Accessed March 25,
2003
)
4.
Black
,
G.
Personal Communication
. ATC Powerlasers. Kitchener, Ontario. June
2003
.
5.
International Standard, ISO 13919-1,
Welding – Electron and Laser-Beam Welded Joints – Guidance on Quality Levels for Imperfections – Part 1:Steel
,
Switzerland
,
1996
6.
Auger
,
M.
Detection of Laser-Welding Defects Using Neural Networks
, M. Sc. Thesis, Queen’s University,
2001
.
7.
Gartner
,
M.
,
Sun
,
A.
,
Kannatey-Asibu
,
E.
Sensor Systems for Real-Time Monitoring of Laser Weld Quality
.
Journal of Laser Applications
. Vol.
11
, No.
4
: August
1999
; pp.
153
168
.
https://doi.org/10.2351/1.521893
Google Scholar
Crossref
Search ADS
 
8.
O’Connor
,
S.
,
Clapham
,
L.
,
Wild
,
P.
Magnetic Flux Leakage Inspection of Tailor-Welded Blanks
.
Measurement and Science Technology
. Institute of Physics Publishing. Vol.
13
: January
2002
; pp.
157
162
.
https://doi.org/10.1088/0957-0233/13/2/303
Google Scholar
Crossref
Search ADS
 
9.
Duley
,
W.W.
Laser Welding
,
New York
:
John Wiley & Sons, Inc
.,
1999
.
Google Scholar
 
10.
Farson
,
D.F.
,
Kim
,
K.R.
Optical and Acoustic Emissions in Laser Welding
. ICALEO:
1998
; pp.
C1
C10
.
Google Scholar
 
11.
Williamson
,
M.
Personal Communication
. Olympic Laser Processing. Michigan. January
2003
.
12.
Haines
,
H.
 et al.
Advanced MFL Signal Analysis Aids Pipe Corrosion Detection
.
Pipe Line & Gas Industry
. Vol.
82
, No.
3
: March
1999
; pp.
49
63
.
Google Scholar
 
13.
Nestleroth
,
J.B.
Bubenik
,
T.A.
Magnetic Flux Leakage Technology for Natural Gas Pipeline Inspection
.
The Gas Research Institute
. February 1999. Avail: http://www.battelle.org/pipetechnology/MFL/MFL98Main.html (Accessed March 25,
2003
)
Google Scholar
 
14.
Jansen
,
H.J.M.
 et al.
Magnetization as a Key Parameter of Magnetic Flux Leakage Pigs for Pipeline Inspection
.
Insight. British Journal for NDT
. Vol.
36
, No.
9
:
1994
; pp.
672
677
.
Google Scholar
 
15.
Atherton
,
D.L.
 et al.
Pipeline Inspection-Tool Speed Alters MFL Signals
.
Oil and Gas Journal
. Vol.
88
: Jan 29,
1990
; pp.
84
86
.
Google Scholar
 
16.
Atherton
,
D.L.
From High Resolution MFL Signals to Accurate Defect Sizing
.
Pipes And Pipelines International
. Vol.
40
, No.
1
: January
1995
; pp.
9
13
.
Google Scholar
 
This content is only available via PDF.
© 2003 Laser Institute of America.
2003
Laser Institute of America
You do not currently have access to this content.