Laser surface treatment of ceramics with melting and re-solidification is generally associated with the development of thermally-induced cracks. These cracks result from the low thermal conductivity of ceramic materials, their brittleness and high melting temperatures, which lead to the built-up of large temperature gradients. Avoiding crack-formation is possible by controlling the cooling rate and thermal gradient. This can be achieved by applying pre- and post-heating methods or by scanning the laser beam at relatively slow speeds. The latter technique has been successfully applied for the development of crack-free surfaces in alumina-based refractory ceramics. However, the relatively slow speed limits the practicability of the technique. This paper investigates the effects of various beam shapes on cooling rate and, hence, interaction time and processing speed. A commercial finite element package program (ADINA) has been used to simulate beam geometries, including, rectangular, line, triangular and rhomboid. The cooling rates associated with these beam geometries have been assessed and compared with those for the circular beam shape. Experimental results have been used to assess the reliability of the model predictions.

Topics
Thermal conductivity, Lasers, Oxides, Crack formation, Ceramics
1.
Wei
,
P.S.
,
Ho
,
C.Y.
,
Shian
,
M.D.
,
Hu
,
C.L.
Three-Dimensional Analytical Temperature Field and Its Application to Solidification Characteristics in High- and Low-Power-Density-Beam Welding
.
Int. J. Heat Mass Transfer.
Vol.
40
:
1997
;
2283
2292
Google Scholar
Crossref
Search ADS
 
2.
Shuja
,
S.Z.
,
Yilbas
,
B.S.
,
3-Dimensional Conjugate Laser Heating of a Moving Slab
.
App. Sur. Sci.
Vol.
167
:
2000
;
134
148
Google Scholar
Crossref
Search ADS
 
3.
Kar
,
A.
,
Scott
,
J.E.
,
Latham
,
W.P.
Effects of Mode Structure on Three-Dimensional Laser Heating Due to Single or Multiple Rectangular Laser Beams
.
J. Appl. Phys.
Vol.
80
: July,
1996
;
667
674
Google Scholar
 
4.
Dai
,
K.
,
Shaw
,
L.
,
Thermal and Stress Modelling of Multi-Material Laser Processing
.
Acta Mater.
Vol.
49
:
2001
;
4171
4181
Google Scholar
Crossref
Search ADS
 
5.
Matsumoto
,
M.
,
Shiomi
,
M.
,
Osakada
,
K.
,
Abe
,
F.
,
Finite Element Analysis of Single Layer Forming on Metallic Powder Bed in Rapid Prototyping by Selective Laser Processing
.
Int. J. Mach. Tools Manuf.
Vol.
452
:
2002
;
61
67
Google Scholar
 
6.
Shankar
,
V.
,
Gnanamuthu
,
D.
,
Computational Simulation of Heat Transfer in Laser Melted Material Flow
.
AIAA 24th Int. Aerospace Sci. Meeting
,
Reno, Nevada
:
1986
;
1
10
Google Scholar
Crossref
Search ADS
 
7.
Yang
,
L.X.
,
Peng
,
X.F
,
Wang
,
B.X.
Numerical Modelling and Experimental Investigation on the Characteristics of Molten Pool During Laser Processing
.
Int. J. Heat Mass Transfer.
Vol.
44
:
2001
;
4465
4473
Google Scholar
Crossref
Search ADS
 
8.
Kingery
,
W.D.
Factors Affecting Thermal Stress Resistance of Ceramic Materials
.
J. Am. Ceram. Soc.
Vol.
38
:
1955
;
3
15
Google Scholar
Crossref
Search ADS
 
9.
The Pyrometer Handbook
.
IMPAC Electronic GmbH
.
2000
;
60
10.
Resistal KR85C Technical Data Sheet No 593, RHI Dinaris GmbH, 2000
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2002
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