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The oxidation resistance and tribological properties of Ni-based composites with in situ/ex situ Al2O3 and TiC ceramic phases at high temperatures

Published online by Cambridge University Press:  20 October 2016

Jianyi Wang ,
Wenzhen Wang  and
Junhong Jia
Jianyi Wang
Affiliation:
State Key Laboratory of Solid Lubrication, Lanzhou Institute of Chemical Physics, Chinese Academy of Sciences, Lanzhou 730000, People's Republic of China; and University of Chinese Academy of Sciences, Beijing 100039, People's Republic of China
Wenzhen Wang
Affiliation:
State Key Laboratory of Solid Lubrication, Lanzhou Institute of Chemical Physics, Chinese Academy of Sciences, Lanzhou 730000, People's Republic of China
Junhong Jia*
Affiliation:
State Key Laboratory of Solid Lubrication, Lanzhou Institute of Chemical Physics, Chinese Academy of Sciences, Lanzhou 730000, People's Republic of China
*
a) Address all correspondence to this author. e-mail: jhjia@licp.cas.cn
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Abstract

Ni-based composites with in situ formed Al2O3 and TiC ceramic phases were fabricated by hot pressing technology and that with directly added Al2O3 and TiC particles (ex situ) were also fabricated for comparison. The antioxygenic property and tribological properties of the composites were comparatively studied. The results show that the high-temperature oxidation resistance of the composite with in situ formed Al2O3 and TiC ceramic is superior to that of ex situ composite, and the friction coefficient of in situ composite is lower than that of ex situ composite in the wide temperature range from 400 °C to 1000 °C. The lowest friction coefficient was about 0.19 at 1000 °C and the wear rate of the composites are in the order of magnitude of 10−6 mm3/(N m) at high temperatures. The differences in tribological properties of in situ/ex situ composites are attributed to the formation of the glaze layer composed of MoO3, TiO2, Al2TiO5, NiAl2O4, and NiO on the worn surfaces and the difference of the distribution of the ceramics in the matrix.

Keywords

Ni-based compositestribological propertiesceramic phaseshigh temperature
Type
Articles
Information
Journal of Materials Research , Volume 31 , Issue 20 , 28 October 2016 , pp. 3262 - 3271
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Copyright
Copyright © Materials Research Society 2016 

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References

REFERENCES

Spikes, H.: Tribology research in the twenty-first century. Tribol. Int. 34(12), 789 (2001).Google Scholar
Zhu, S.Y., Bi, Q.L., Yang, J., and Liu, W.M.: Effect of fluoride content on friction and wear performance of Ni3Al matrix high-temperature self-lubricating composites. Tribol. Lett. 43(3), 341 (2011).Google Scholar
Xu, Z.S., Shi, X.L., Wang, M., Zhai, W.Z., Yao, J., Song, S.Y., and Zhang, Q.X.: Effect of Ag and Ti3SiC2 on tribological properties of TiAl matrix self-lubricating composites at room and increased temperatures. Tribol. Lett. 53(3), 617 (2014).Google Scholar
Moghadam, A.D., Omrani, E., Menezes, P.L., and Rohatgi, P.K.: Mechanical and tribological properties of self-lubricating metal matrix nanocomposites reinforced by carbon nanotubes (CNTs) and graphene—A review. Composites, Part B 77, 402 (2015).Google Scholar
Ding, C.H., Li, P.L., Ran, G., Tian, Y.W., and Zhou, J.N.: Tribological property of self-lubricating PM304 composite. Wear 262(5), 575 (2007).CrossRefGoogle Scholar
Li, J.L. and Xiong, D.X.: Tribological properties of nickel-based self-lubricating composite at elevated temperature and counterface material selection. Wear 265(3), 533 (2008).Google Scholar
DellaCorte, C. and Edmonds, B.J.: Nasa PS400: A new high temperature solid lubricant coating for high temperature wear applications. NASA TM-215678 (2009).Google Scholar
Bi, Q.L., Liu, W.M., Yang, J., Ma, J.Q., and Xue, Q.J.: Tribological properties of Ni–17.5Si–29.3Cr alloy at room and elevated temperatures. Tribol. Int. 43(1–2), 136 (2010).Google Scholar
Inman, I.A. and Datta, P.S.: Studies of high temperature sliding wear of metallic dissimilar interfaces. IV: Nimonic 80A versus Incoloy 800HT. Tribol. Int. 44(12), 1903 (2011).CrossRefGoogle Scholar
Rynio, C., Hattendorf, H., Klöwer, J., and Eggeler, G.: The evolution of tribolayers during high temperature sliding wear. Wear 315(1–2), 1 (2014).Google Scholar
Deng, J.X.: Friction and wear behaviour of Al2O3/TiB2/SiC w ceramic composites at temperatures up to 800 °C. Ceram. Int. 27(2), 135 (2001).Google Scholar
Deng, J.X., Cao, T.K., and Liu, L.L.: Self-lubricating behaviors of Al2O3/TiB2 ceramic tools in dry high-speed machining of hardened steel. J. Eur. Ceram. Soc. 25(7), 1073 (2005).Google Scholar
Gül, H., Kılıç, F., Aslan, S., Alp, A., and Akbulut, H.: Characteristics of electro-co-deposited Ni–Al2O3 nano-particle reinforced metal matrix composite (MMC) coatings. Wear 267(5–8), 976 (2009).Google Scholar
Yin, Z.B., Yuan, J.T., Huang, C.Z., Wang, Z.H., Huang, L., and Cheng, Y.: Friction and wear behaviors of Al2O3/TiC micro-nano-composite ceramic sliding against metals and hard materials. Ceram. Int. 42, 1983 (2016).Google Scholar
Kumar, R., Chaubey, A., Bathula, S., Jha, B., and Dha, A.: Synthesis and characterization of Al2O3–TiC nano-composite by spark plasma sintering. Int. J. Refract. Met. Hard. Mater. 54, 304 (2016).Google Scholar
Tian, H.Y., Zhu, D., Qu, N.S., and Zhu, Z.W.: Wear resistance of Ni–Al2O3 nano-composite coatings prepared by electrophoretic-electroplating deposition. Mater. Mech. Eng. 33(3), 65 (2009). (In Chinese).Google Scholar
Lu, J.J., Shang, J., Meng, J.H., and Wang, T.: Friction and wear of Al2O3-based composites with dispersed and agglomerated nanoparticles. In Tribology of Nanocom-posites, Part of the series Materials Forming, Machining and Tribology, Paulo Davim, J. ed.; Springer-Verlag: Berlin, Heidelberg, 2013; p. 61.Google Scholar
Liu, F. and Jia, J.H.: Tribological properties and wear mechanisms of NiCr–Al2O3–SrSO4–Ag self-lubricating composites at elevated temperatures. Tribol. Lett. 49(1), 281 (2013).Google Scholar
Liu, F., Jia, J.H., Yi, G.W., Wang, W.Z., and Shan, Y.: Mechanical and tribological properties of NiCr–Al2O3 composites at elevated temperatures. Tribol. Int. 84, 1 (2015).Google Scholar
Bartuli, C. and Smith, R.: Comparison between Ni–Cr–40 vol% TiC wear-resistant plasma sprayed coatings produced from self-propagating high-temperature synthesis and plasma densified powders. J. Therm. Spray Technol. 5(3), 335 (1996).Google Scholar
Choi, Y., Baik, N.I., Lee, J.S., Hong, S.I., and Hahn, Y.D.: Corrosion and wear properties of TiC/Ni–Mo composites produced by direct consolidation during a self-propagating high-temperature reaction. Compos. Sci. Technol. 61(7), 981 (2001).Google Scholar
Sliney, H.E., Dellacorte, C., and Lukaszewicz, V.: The tribology of PS212 coatings and PM212 composites for the lubrication of titanium 6A1–4V components of a Stirling engine space power system. Tribol. Trans. 38(3), 497 (1995).Google Scholar
DellaCorte, C. and Laskowski, J.: Tribological evaluation of PS300: A new chrome oxide-based solid lubricant coating sliding against Al2O3 from 25 to 650 °C. Tribol. Trans. 40(1), 163 (1997).Google Scholar
Blanchet, T.A., Kim, J.H., Calabrese, S.J., and DellaCorte, C.: Thrust-washer evaluation of self-lubricating PS304 composite coatings in high temperature sliding contact. Tribol. Trans. 45(4), 491 (2002).Google Scholar
Zhao, J.C.: Ultrahigh-temperature materials for jet engines. MRS Bull. 28(9), 620 (2003).Google Scholar
Tjong, S.C. and Ma, Z.Y.: Microstructural and mechanical characteristics of in situ metal matrix composites. Mater. Sci. Eng., R 29(3–4), 51 (2000).Google Scholar
Yang, S., Liu, W.J., and Zhong, M.L.: In-situ TiC reinforced composite coating produced by powder feeding laser cladding. J. Mater. Sci. Technol. 22, 519 (2006).Google Scholar
Zohari, S., Sadeghian, Z., Lotfi, B., and Broeckmann, C.: Application of spark plasma sintering (SPS) for the fabrication of in situ Ni–TiC nanocomposite clad layer. J. Alloys Compd. 633, 479 (2015).Google Scholar
Wang, X.H., Zhang, M., and Du, B.S.: Fabrication in situ TiB2–TiC–Al2O3 multiple ceramic particles reinforced Fe-based composite coatings by gas tungsten arc welding. Tribol. Lett. 41(1), 171 (2011).Google Scholar
Liu, E.Y., Gao, Y.M., Jia, J.H., Bai, Y.P., and Wang, W.Z.: Microstructure and mechanical properties of in situ NiAl–Mo2C nanocomposites prepared by hot-pressing sintering. Mater. Sci. Eng., A 592, 201 (2015).Google Scholar
Wang, J.Y., Shan, Y., Guo, H.J., Wang, W.Z., Yi, G.W., and Jia, J.H.: The tribological properties of NiCr–Al2O3–TiO2 composites at elevated temperatures. Tribol. Lett. 58, 2 (2015).Google Scholar
Liu, E.Y., Gao, Y.M., Jia, J.H., and Bai, Y.P.: Friction and wear behaviors of Ni-based composites containing graphite/Ag2MoO4 lubricants. Tribol. Lett. 50(3), 313 (2013).Google Scholar
Sheng, L.Y., Yang, F., Xi, T.F., and Guo, J.T.: Investigation on microstructure and wear behavior of the NiAl–TiC–Al2O3 composite fabricated by self-propagation high-temperature synthesis with extrusion. J. Alloys Compd. 554(2), 182 (2013).Google Scholar
Hou, G.L., An, Y.L., Zhao, X.Q., Zhou, H.D., and Chen, J.M.: Effect of alumina dispersion on oxidation behavior as well as friction and wear behavior of HVOF-sprayed CoCrAlYTaCSi coating at elevated temperature up to 1000 °C. Acta Mater. 95, 164 (2015).Google Scholar
Liu, E.Y., Gao, Y.M., Bai, Y.P., Yi, G.W., Wang, W.Z., Zeng, Z.X., and Jia, J.H.: Tribological properties of self-lubricating NiAl/Mo-based composites containing AgVO3 nanowires. Mater. Charact. 97, 116 (2014).Google Scholar