The tribological properties of Fe3Al-20 wt% Al2O3 composites, prepared by means of mechanical alloying and plasma-activated sintering, were investigated under air atmosphere against GCr15 bearing steels from room temperature to 500 °C. It was found that the friction coefficient of the composites (at 200 °C/350 °C) decreased with increasing temperature and the value was lower than that of Fe3Al alloys at the same temperature, and the friction coefficient increased again at 500 °C. Moreover, the wear rates of all the pins and discs were low at the medium/high temperatures. The dominant wear mechanism of the composites is microplowing and a little oxidation wear at room temperature. However, at elevated temperatures, oxidation wear and a little microplowing are found to be the main wear mechanism. There is also spalling induced by microfracture at 500 °C. The in situ Fe3Al-20 wt% Al2O3 composites have excellent wear resistance at a wide temperature range.
LiuCTStringerJMundyJN. Ordered intermetallic alloys: An assessment. Intermetallics1997; 5: 579–596.
5.
MorrisDG. Possibilities for high-temperature strengthening in iron aluminides. Intermetallics1998; 6: 753–758.
6.
StoloffNS. Iron aluminides: Present status and future prospects. Mater Sci Eng A1998; 258: 1–14.
7.
SteinFSchneiderAFrommeyerG. Flow stress anomaly and order-disorder transitions in Fe3Al-based Fe-Al-Ti-X alloys with X = V, Cr, Nb, or Mo. Intermetallics2003; 11: 71–82.
8.
MaJQHaoJYBiQL. Tribological properties of a Fe3Al material in sulfuric acid corrosive environment. Wear2010; 268: 264–268.
9.
SharmaGLimayePKSundararamanM. Wear resistance of Fe-28Al-3Cr intermetallic alloy under wet conditions. Mater Lett2007; 61: 3345–3348.
GuanXSIwasakiKKishiK. Dry sliding wear behavior of Fe-28Al and Fe-28Al-10Ti alloys. Mater Sci Eng A2004; 366: 127–134.
12.
LiJYinYSMaHT. Preparation and properties of Fe3Al-based friction materials. Tribol Int2005; 38: 159–163.
13.
MaupinHEWilsonRDHawkJA. An abrasive wear study of ordered Fe3Al. Wear1992; 159: 241–247.
14.
SharmaGLimayePRamanujanR. Dry-sliding wear studies of Fe3Al-ordered intermetallic alloy. Mater Sci Eng A2004; 386: 408–414.
15.
ZhuSMTamuraMSakamotoK. Characterization of Fe3Al-based intermetallic alloys fabricated by mechanical alloying and HIP consolidation. Mater Sci Eng A2000; 292: 83–89.
16.
YangJLaPQLiuWM. Tribological properties of Fe3Al–Fe3AlC0.5 composites under dry sliding. Intermetallics2005; 13: 1184–1189.
17.
KrasnowskiMWitekAKulikT. The FeAl–30% TiC nanocomposite produced by mechanical alloying and hot-pressing consolidation. Intermetallics2002; 10: 371–376.
18.
GaoMXPanYOliveiraFJ. High strength TiC matrix Fe28Al toughened composites prepared by spontaneous melt infiltration. J Eur Ceram Soc2006; 26: 3853–3859.
19.
SunKLiACuiX. Sintering technology research of Fe3Al/Al2O3 ceramic composites. J Mater Process Technol2001; 113: 482–485.
20.
KreinRSchneiderASauthoffG. Microstructure and mechanical properties of Fe3Al-based alloys with strengthening boride precipitates. Intermetallics2007; 15: 1172–1182.
21.
KökMÖzdinK. Wear resistance of aluminium alloy and its composites reinforced by Al2O3 particles. J Mater Process Technol2007; 183: 301–309.
22.
JasimKMDwarakadasaE. Wear in Al–Si alloys under dry sliding conditions. Wear1987; 119: 119–130.
23.
AghajanianMKRocazellaMABurkeJT. The fabrication of metal matrix composites by a pressureless infiltration technique. J Mater Sci1991; 26: 447–454.
24.
MukherjeeSBandyopadhyayS. A novel way to make Fe3Al/Al2O3 composite. Mater Sci Eng A1995; 202: 123–127.
25.
ZadraMCasariFLonardelliI. In-situ precipitation of Al2O3 and [kappa]-Fe3AlC0.5 in iron aluminides through spark plasma sintering: Microstructures and mechanical properties. Intermetallics2007; 15: 1650–1658.
26.
MinaminoYKoizumiYTsujiN. Microstructures and mechanical properties of bulk nanocrystalline Fe–Al–C alloys made by mechanically alloying with subsequent spark plasma sintering. Sci Technol Adv Mater2004; 5: 133–143.
27.
PauschitzARoyMFranekF. Mechanisms of sliding wear of metals and alloys at elevated temperatures. Tribol Int2008; 41: 584–602.
28.
RajaramGKumaranSSrinivasa RaoT. Studies on high temperature wear and its mechanism of Al–Si/graphite composite under dry sliding conditions. Tribol Int2010; 43: 2152–2158.
29.
BaiYPXingJDWuHL. Study on preparation and mechanical properties of Fe3Al-20 wt% Al2O3 composites. Mater Des2012; 39: 211–219.
30.
WangJXingJDQiuZM. Effect of fabrication methods on microstructure and mechanical properties of Fe3Al-based alloys. J Alloys Compd2009; 488: 117–122.
31.
Wang J. Microstructure evolution mechanism, mechanical properties, friction and wear characteristic of Fe3Al prepared by MA-PAS. Xi’an Jiaotong University, Xi’an, 2010, pp.72–85.
32.
WangJXingJDCaoL. Dry sliding wear behavior of Fe3Al alloys prepared by mechanical alloying and plasma activated sintering. Wear2010; 268: 473–480.
33.
KongHAshbyMF. Wear mechanisms in brittle solids. Acta Metall Mater1992; 40: 2907–2920.
34.
AshbyMFAbulawiJKongHS. Temperature maps for frictional heating in dry sliding. Tribol Lett1991; 34: 577–587.
35.
AshbyMFLimSC. On surface temperatures at dry sliding surfaces. Scr Metall Mater1990; 24: 805–810.
36.
StottFH. The role of oxidation in the wear of alloys. Tribol Int1998; 31: 61–71.
37.
AhmadiHLiDYNouriM. Effects of yttria addition on microstructure, mechanical properties, wear resistance and corrosive wear resistance of TiNi alloy. J Mater Sci Technol2009; 25: 645–648.
38.
ChenHHXingJDWeiL. Application of wear-resistant materials handbook. Beijing: Machinery Industry Press, 2006.
39.
KimYSKimYH. Sliding wear behavior of Fe3Al-based alloys. Mater Sci Eng A1998; 258: 319–324.
