For quality assurance in the manufacture of automotive parts, the integrity of the laser-beam welds joining steel parts must be monitored. A considerable number of on-line inspection systems have being developed to improve weld quality. Traditional monitoring systems are realized through wired systems, formed by communication cables and sensors. These systems suffer from two main drawbacks: a) the sensor cables are easily damaged and conflict with ease of installation and retrofit into industrial plants, b) the installation and maintenance of the sensors cables is much more expensive than the cost of the sensors themselves. Integration of electronics, sensors, wireless communications, has prompted monitoring folks to consider alternatives that reduce wiring costs, make connections not feasible previously, and retrofit more measurement points cost effectively as well. This paper presents a prototype sensing device to achieve wireless and powerless operation for implementing a monitoring laser welding system. The weld monitor is designed to be simple, low cost, and able to withstand a harsh manufacturing environment.

Topics
Quality assurance, Wireless communications, Welding
1.
Chen
,
H. B.
,
Li
,
L.
,
Brookfield
,
D. J.
,
Williams
,
K.
, and
Steen
,
W. M.
 (
1991
). Laser process monitoring with dual wavelength sensors. In:
Proc. ICALEO 91
,
San Jose, CA. Orlando, FL
:
Laser Institute of America
,
SPIE 1722
, pp.
113
122
.
Google Scholar
 
2.
G.
D’Angelo
,
G.
Pasquettaz
,
A.
Terreno
 (
2007
).
Laser process monitoring at FIAT group
. In:
Proc. EALA 07 - Bad Nauheim/Frankfurt
,
Germany
,
30/31 January 2007
.
Google Scholar
 
3.
C.
Alippi
,
G.
D’Angelo
,
V.
Piuri
 et al (
2003
).
Composite techniques for quality analysis in automotive laser welding
.
CIMSA 2003 – Lugano
,
Switzerland
,
29-31 July 2003
.
Google Scholar
Crossref
Search ADS
 
4.
G.
D’Angelo
,
G.
Pasquettaz
,
A.
Terreno
 (
2006
).
Improving the analysis of laser welding process by the reassigned time-frequency representations
. In:
Proc. ICALEO 06
,
Scottsdale, AZ
.
Google Scholar
Crossref
Search ADS
 
5.
G.
D’Angelo
,
A.
Terreno
 (
2007
).
Wireless laser welding monitoring for automotive application
. In:
Proc. ICALEO 07
,
Orlando, FL
.
Google Scholar
Crossref
Search ADS
 
6.
P. G.
Sanders
,
J. S.
Keske
,
G.
Kornecki
, and
K. H.
Leong
. Real-time Monitoring of Laser Beam Welding Using Infrared Weld Emissions.
Technology Development Division Argonne National Laboratory Argonne
, IL 60439
USA
7.
Bagger
,
C.
,
Miyamoto
,
I.
,
Olsen
,
F.
, and
Maruo
,
H.
 (
1991
).
On-line control of the CO2 laser welding process
. In:
Beam Technology Conference Proceedings
,
Karlsruhe, Germany
,
March 13-14
, DVS-Berichte 135, pp.
1
6
.
Google Scholar
 
8.
Olsen
,
F. O.
,
Jørgensen
,
H.
,
Bagger
,
C.
,
Kristensen
,
T.
, and
Gregersen
,
O.
 (
1992
). Recent investigations in sensorics for adaptive control of laser cutting and welding. In:
Proc. LAMP2
,
Nagoka, Japan
:
High Temperature Society of Japan
, pp.
405
414
.
Google Scholar
 
9.
Chang
,
D.U.
 (
1994
).
Monitoring laser weld quality in real time
.
Indust. Laser Rev.
15
16
,
November
Google Scholar
 
10.
A.
Ancona
,
V.
Spagnolo
,
P.M.
Lugara
 and
M.
Ferrara
,. (
2001
).
Optical sensor for real-time monitoring of CO2 laser welding process
,
Applied Optics
, Vol.
40
(
33
), pp.
6019
25
https://doi.org/10.1364/AO.40.006019
Google Scholar
Crossref
Search ADS
PubMed
 
11.
Chari
,
M.V.K.
 (
1987
).
Electromagnetic field computation of open boundary problem by a semi-analytic approach
.
IEEE Transactions on Magnetics 1987
,
23
,
3566
3568
.
https://doi.org/10.1109/TMAG.1987.1065735
Google Scholar
Crossref
Search ADS
 
12.
F.
De Flaviis
,
M. G.
Noro
,
R.E.
Diaz
,
G.
Franceschetti
,
N. G.
Alexopoulos
, (
1998
).
A Time-Domain Vector Potential Formulation for the Solution of Electromagnetic Problems
.
IEEE Microwave and Guided Wave Letters
, Vol.
8
, No.
9
,
https://doi.org/10.1109/75.720465
Google Scholar
 
13.
Time domain vector potential formulation for the solution of electromagnetic problems
,” in
IEEE AP-S Int. Symp.
,
Montreal, Canada, July
1997
.
14.
G.
Franceschetti
 (
1983
).
Campi Elettromagnetici. Ed.
Boringhieri
Google Scholar
 
15.
G.
Franceschetti
,
I.
Pinto
 (
1980
).
Volterra series solution of Maxwell equation in non-linear media.
Google Scholar
 
16.
Ali
Muhtaroglu
, et al., (
2008
).
Integration of thermoelectrics and photovoltaics as auxiliary power sources in mobile computing applications
.
Journal of Power Sources
177
(
2008
)
239
246
https://doi.org/10.1016/j.jpowsour.2007.11.016
Google Scholar
Crossref
Search ADS
 
17.
L.
Mateu
,
C.
Codrea
,
N.
Lucas
,
M.
Pollak
 and
Peter
Spies
 (
2006
).
Energy Harvesting for Wireless Communication Systems Using Thermogenerators.
Google Scholar
 
18.
A.
Muhtaroglu
,
A.
von Jouanne
 (
2006
)-
Proceedings of the Sixth International Workshop on Micro and Nanotechnology for Power Generation and Energy Conversion Applications (PowerMEMS 2006)
.
19.
A.
Muhtaroglu
,
A.
Yokochi
,
A.
von Jouanne
, (
2007
).
J. Micromech. Microeng.
171767
1772
.
Google Scholar
 
20.
A.
Muhtaroglu
,
A.
Yokochi
,
A.
von Jouanne
, (
2007
).
A sustainable power architecture for mobile computing systems
,
J. Power Sources
Google Scholar
 
21.
European Commission: European cooperation on the field of scientific and technical research
(
1999
): “
Digital mobile radio towards future generation systems
”,
Final report
,
Bruxelles
.
This content is only available via PDF.
© 2010 Laser Institute of America.
2010
Laser Institute of America
You do not currently have access to this content.