Surface coatings of an Al-Si-SiC composite were produced on UNS A03560 cast Al-alloy substrates by laser cladding using a mixture of powders of Al-12 wt.% Si alloy and SiC. The microstructure of the coatings depends considerably on the processing parameters. For a specific energy of 26 MJ/m2 the microstructure consists of SiC particles dispersed in a matrix consisting of primary α-Al dendrites and interdendritic α-Al+Si eutectic. For higher specific energies (58 and 87 MJ/m2) SiC reacts and dissolves partially in molten aluminum, leading to a microstructure consisting of primary Al4SiC4 and Si and a small fraction of undissolved SiC particles dispersed in the matrix. Abrasive wear tests were performed on the coatings using a ball cratering device and a suspension of SiC particles (35 wt.% of SiC with an average particle diameter of 4.25 µm) in water as abrasive. The coatings deposited with a low specific energy (26 MJ/m2) exhibit an abrasive wear rate of 0.43 × 10−4 mm3/m and a hardness of 120 HV, while those prepared with higher specific energy (58 MJ/m2) present a higher wear rate (1.7 × 10-4 mm3/m) despite their higher hardness (250 HV). These results show that Al4SiC4 and Si increase the hardness of the material by dispersion hardening but do not contribute to its abrasive wear resistance, because they are softer than the abrasive particles, and confirm that the parameters used to prepare Al-Si-SiC composite coatings by laser cladding must be selected so that only minimal reactions occur between SiC and molten Al. Microploughing and microcutting are the main material removal mechanisms in all samples. Whenever they exist in sufficient proportion, SiC reinforcement particles stop the grooving action of the abrasive, thus decreasing material loss. There is also some evidence of an increased contribution of microcutting as compared to microploughing in samples prepared with high specific energy, an effect that contributes to decrease their wear resistance.

Topics
Dispersion, Thermodynamic properties, Chemical elements, Alloys, Carbides, Materials degradation, Materials synthesis and processing, Ceramics
1.
Eliasson
,
J.
 and
Sandstrom
,
R.
 (
1995
)
Applications of Aluminium Matrix Composites
,
Key Engineering Materials
104-107
,
3
36
.
https://doi.org/10.4028/www.scientific.net/KEM.104-107.3
Google Scholar
Crossref
Search ADS
 
2.
Karantzalis
,
A.E.
,
Wyatt
,
S.
 and
Kennedy
,
A.R.
 (
1997
)
The mechanical properties of Al-TiC metal matrix composites fabricated by a flux-casting technique
,
Materials Science and Engineering A
237
,
200
206
.
https://doi.org/10.1016/S0921-5093(97)00290-6
Google Scholar
Crossref
Search ADS
 
3.
Shorowordi
,
K.M.
,
Laoui
,
T.
,
Haseeb
,
A.S.M.A.
,
Celis
,
J.P.
 and
Froyen
,
L.
 (
2003
)
Microstructure and interface characteristics of B4C, SiC and Al2O3 reinforced Al matrix composites: a comparative study
,
Journal of Materials Processing Technology
142
,
738
743
.
https://doi.org/10.1016/S0924-0136(03)00815-X
Google Scholar
Crossref
Search ADS
 
4.
Shorowordi
,
K.M.
,
Haseeb
,
A.S.M.A.
 and
Celis
,
J.P.
 (
2006
)
Tribo-surface characteristics of Al-B4C and Al-SiC composites worn under different contact pressures, Wear
261
,
634
641
.
Google Scholar
 
5.
Tyagi
,
R.
 (
2005
)
Synthesis and tribological characterization of in situ cast Al-TiC composites, Wear
259
,
569
576
.
Google Scholar
 
6.
Viala
,
J.C.
,
Fortier
,
P.
 and
Bouix
,
J.
 (
1990
)
Stable and Metastable Phase-Equilibria in the Chemical Interaction between Aluminum and Silicon-Carbide
,
Journal of Materials Science
25
,
1842
1850
.
https://doi.org/10.1007/BF01045395
Google Scholar
Crossref
Search ADS
 
7.
Ureña
,
A.
,
Rodrigo
,
P.
,
Gil
,
L.
,
Escalera
,
M.D.
 and
Baldonedo
,
J.L.
 (
2001
)
Interfacial reactions in an Al-Cu-Mg (2009)/SiCw composite during liquid processing - Part II - Arc welding
,
Journal of Materials Science
36
,
429
439
.
https://doi.org/10.1023/A:1004832713790
Google Scholar
Crossref
Search ADS
 
8.
Park
,
J.K.
 and
Lucas
,
J.P.
 (
1997
)
Moisture effect on SiCp/6061 Al MMC: Dissolution of interfacial Al4C3
,
Scripta Materialia
37
,
511
516
.
https://doi.org/10.1016/S1359-6462(97)00133-4
Google Scholar
Crossref
Search ADS
 
9.
Hu
,
C.
,
Xin
,
H.
 and
Baker
,
T.N.
 (
1996
)
Formation of continuous surface Al-SiCp metal matrix composite by overlapping laser tracks on AA6061 alloy
,
Materials Science and Technology
12
,
227
232
.
https://doi.org/10.1179/026708396790165722
Google Scholar
Crossref
Search ADS
 
10.
Vreeling
,
J.A.
 (
2001
)
Laser Melt Injection of Ceramic Particles in Metals
, PhD Thesis,
University of Groningen
,
Groningen, The Netherlands
.
11.
Liechti
,
T.
 (
1996
)
Développement de Revêtements Portants Déposés par Laser sur des Alliages D’Aluminium
, PhD Thesis,
EPFL, Lausanne, Switzerland
.
12.
Rutherford
,
K.L.
 and
Hutchings
,
I.M.
 (
1996
)
A micro-abrasive wear test, with particular application to coated systems
,
Surface & Coatings Technology
79
,
231
239
.
https://doi.org/10.1016/0257-8972(95)02461-1
Google Scholar
Crossref
Search ADS
 
13.
Sahin
,
Y.
 and
Acilar
,
A.
 (
2003
)
Production and properties of SiCp-reinforced aluminium alloy composites, Composites Part A
34
,
709
718
.
Google Scholar
 
14.
Dubourg
,
L.
,
Ursescu
,
D.
,
Hlawka
,
F.
 and
Cornet
,
A.
 (
2005
)
Laser cladding of MMC coatings on aluminium substrate: influence of composition and microstructure on mechanical properties, Wear
258
,
1745
1754
.
Google Scholar
 
15.
Colaço
,
R.
 and
Vilar
,
R.
 (
2005
)
Tribological properties of laser processed Fe-Cr-C alloys
,
Materials Science Forum
473-474,
53
58
.
https://doi.org/10.4028/www.scientific.net/MSF.473-474.53
Google Scholar
 
16.
Leyland
,
A.
 and
Matthews
,
A.
 (
2000
)
On the significance of the H/E ratio in wear control: a nanocomposite coating approach to optimised tribological behaviour, Wear
246
,
1
11
.
Google Scholar
 
17.
Rabinowicz
,
E.
 (
1995
)
Friction and wear of materials
,
John Wiley & Sons
,
193
pp.
Google Scholar
 
18.
Colaço
,
R.
 and
Vilar
,
R.
 (
2003
)
A model for the abrasive wear of metallic matrix particle-reinforced materials, Wear
254
,
625
634
.
Google Scholar
 
19.
Khruschov
,
M.M.
 (
1974
)
Principles of Abrasive Wear, Wear
28
,
69
88
.
Google Scholar
 
20.
Hutchings
,
I.M.
 (
1992
)
Tribology: Friction and Wear of Engineering Materials
,
Edward
Arnold
, pp
148
and pp
136
.
Google Scholar
 
21.
Deuis
,
R.L.
,
Subramanian
,
C.
 and
Yellup
,
J.M.
 (
1998
)
Three-body abrasive wear of composite coatings in dry and wet environments, Wear
214
,
112
130
.
Google Scholar
 
22.
Kok
,
M.
 (
2006
)
Abrasive wear of Al2O3 particle reinforced 2024 aluminium alloy composites fabricated by vortex method, Composites Part A
37
,
457
464
.
Google Scholar
 
23.
Strudel
,
J.L.
 (
1996
) Mechanical Properties of Multiphase Alloys, in
R.W.
Cahn
 and
P.
Haasen
 (ed)
Physical Metallurgy
,
North-Holland
,
2105
2206
.
https://doi.org/10.1016/B978-044489875-3/50030-2
Google Scholar
Crossref
Search ADS
 
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