2014
DOI: 10.1016/j.triboint.2014.03.006
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Tribological behavior of Ni3Al alloy at dry friction and under sea water environment

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Cited by 23 publications
(7 citation statements)
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“…The friction coefficient decreases first and then increases with increasing film thickness within the range of h c smaller than 18 m. The critical thickness of 9 m is desired for improving the tribological performances for the spindle. (Ma et al, 2010;Su and Kao, 2003;Xu and Shao, 2013;Zhu et al, 2014).The above local increment in the friction coefficient is caused by the reduction in the binding force at the interface between the coating and substrate.…”
Section: At Different Coating Thicknessesmentioning
confidence: 99%
“…The friction coefficient decreases first and then increases with increasing film thickness within the range of h c smaller than 18 m. The critical thickness of 9 m is desired for improving the tribological performances for the spindle. (Ma et al, 2010;Su and Kao, 2003;Xu and Shao, 2013;Zhu et al, 2014).The above local increment in the friction coefficient is caused by the reduction in the binding force at the interface between the coating and substrate.…”
Section: At Different Coating Thicknessesmentioning
confidence: 99%
“…The Ni 3 Al alloys are mostly superior to the commercial alloys, especially in the field of high-temperature properties, in an oxidizing and carburizing environments. The most attractive properties of the Ni 3 Al intermetallics include: a high tensile and compression strength at temperature of 650 ÷ 1100 °C (Figure 1a) [5,9,12,19,20,21,42,43];an increase of flow stress with increasing temperature—an anomalous positive temperature dependence of the yield strength (at 600–900 °C) is a characteristic feature of the Ni 3 Al phase and its alloys [1,2,5,11,12,19,21,43];a high corrosion resistance in oxygen and carbon enriched atmospheres up to 1100 °C, due to a formation of a continuous surface alumina layer (see Table 1) [5,9,12,19,20,21,43,44,45];a high corrosion resistance in organic acids (oxalic and acetic acids), bases (sodium and ammonium hydroxides), and sodium-chloride solution [44,46,47,48,49,50];a high fatigue strength resulting from the elimination of stress concentrations on the second phase particles (e.g., carbides) [9,19,21];a high creep resistance (which is also affected by a grain size) [9,10,12,19,21,42,51,52];an excellent high temperature (above 600 °C) wear resistance [9,12,21,43,44,…”
Section: Properties Of Ni3al-based Alloysmentioning
confidence: 99%
“…a high corrosion resistance in organic acids (oxalic and acetic acids), bases (sodium and ammonium hydroxides), and sodium-chloride solution [44,46,47,48,49,50];…”
Section: Properties Of Ni3al-based Alloysmentioning
confidence: 99%
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“…Several scholars have conducted a series of experiments to research the corrosion and tribological behavior of different materials in seawater. 48 Matei et al 9 investigated the corrosion resistance of coated tools in artificial seawater and found that TiN and TiAlN coatings can isolate the cemented carbide substrate from marine corrosion. Qiao et al 10 reported that B 4 C-based ceramic showed superior corrosion resistance in the marine environment.…”
Section: Introductionmentioning
confidence: 99%