采用分步高能球磨、快速感应烧结制备Ni基耐高温自润滑涂层IS304(IS:Induction Sintering), 涂层中高温润滑相BaF2/CaF2尺寸仅为1mm左右、低温润滑相Ag尺寸小于2mm, 并且BaF2/CaF2主要分布于强化相Cr2O3中.摩擦实验中当温度为室温~250℃时,IS304涂层的摩擦系数较高, 由于润滑相尺寸的细化以及润滑相BaF2/CaF2分布位置的改变,使得摩擦副在高速瞬时接触中产生的瞬态温升可以有效地激活BaF2/CaF2的自润滑性能,最终在压力及摩擦力的作用下形成自润滑表面膜, 使得IS304涂层在280℃时即可具有较低的摩擦系数
Ni-based high temperature self-lubricating IS304 (IS: Induction Sintering) composites with BaF2/CaF2and Ag particles as lubricants were prepared by ball milling and induction sintering techniques. The microstructure of the IS304 composites is dense and the size of selflubricating particles is very fine. BaF2/CaF2 particlesare in dimension of about 1 μm and particles are less than 2 μm respectively,while some BaF2/CaF2 particles are distributed in Cr2O3particles. The synthesized IS304 composites exhibite high friction coefficientin the temperature range from roomtemperature to 250℃. However, thefriction coefficient dramatically decreased at 280℃ while the friction coefficient of coarsecomposites dramatically decreased at 330-350℃ in the same test condition due to the formation of self-lubricating fluoride films. The fluoride films formed on the worn surface of synthesized composites is attributed to the size refinement and appropriate distribution offluorides, which can lead toa higher temperature rise (flash temperature) at the instantaneous contactingsurface.
参考文献
| [1] | Dellacorte C, Sliney H E. Tribological Properties of PM212: a High-temperature, Self-lubricating Powder Metallurgy Composite. NASA-TM-102355, 1990. [2] Bogdanski M S, Sliney H E, Dellacorte C. The Effect of Processing and Compositional Changes on the Tribology of PM212 in Air. NASA-TM-105945, 1993.[3] Stanford M K, Ward L D, Dellacorte C. Effect of Prolonged Exposure to High Temperature Air on Physical Characteristics of a Powder Metallurgy Composite Solid Lubricant. NASA-TM- 213603, 2006.[4] Dellacorte C. The effect of counterface on the tribological performance of a high temperature solid lubricant composite from 25 to 650℃. Surf. Coat. Technol., 1996, 86-87: 486-492.[5] Wang W C. Application of a high temperature self-lubricating composite coating on steam turbine components. Surf. Coat. Technol., 2004, 177-178: 12-17.[6] Kalin M. Influence of flash temperatures on the tribological behaviour in low-speed sliding: a review. Mater. Sci. Eng. A, 2004, 374(1/2): 390-397.[7] Ohuchi H, Enomoto Y. Frictional heat-stimulated exo-electron emission from alumina sliding surfaces. Appl. Phys. Lett., 1995, 66(10): 1205-1207.[8] 李鹏亮, 周敬恩, 席生歧(LI Peng-Liang, et al). 高能球磨制备立方AlN及其高温相变. 无机材料学报(Journal of Inorganic Materials), 2006, 21(4): 821-827.[9] Shuaib M, Davies T J. Wear behaviour of a REFEL SiC containing fluorides up to 900℃. Wear, 2001, 249(1/2): 20-30.[10] Wang H M, Yu Y L, Li S Q. Microstructure and tribological properties of laser clad CaF2/Al2O3 self-lubrication wear-resistant ceramic matrix composite coatings. Scripta Mater., 2002, 47(1): 57-61.[11] Skopp A, Woydt M, Habig K H. Tribological behavior of silicon nitride materials under unlubricated sliding between 22℃ and 1000℃. Wear, 1995, 181-183: 571-580.[12] Hu J J, Muratore C, Voevodin A A. Silver diffusion and high-temperature lubrication mechanisms of YSZ-Ag-Mo based nanocomposite coatings. Comp. Sci. Technol., 2007, 67(3/4): 336-347. |
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