Al_(0.2) CrFeNiCo and Al_(0.2) CrFeNiCu high entropy alloys were deposited with high velocity oxygen fuel(HVOF)on 316 L substrate.Later,a laser re-melting(LR)process was applied to enhancing the coating microstructure...Al_(0.2) CrFeNiCo and Al_(0.2) CrFeNiCu high entropy alloys were deposited with high velocity oxygen fuel(HVOF)on 316 L substrate.Later,a laser re-melting(LR)process was applied to enhancing the coating microstructure.LR process effects on dry sliding wear and oxidation behaviors were investigated.The mixture of powders with free elements led to the formation of inner oxides in HVOF coatings.The oxide and porosity were eliminated using LR.After LR,FCC was the dominant phase in both alloys,while BCC,sigma and Cr2 O3 phases were observed in Al_(0.2) CrFeNiCo alloy.The hardnesses of the Al_(0.2) CrFeNiCo and Al_(0.2) CrFeNiCu coatings after HVOF were HV 591 and HV 361,respectively.After LR,the hardnesses decreased to HV 259 and HV 270,respectively.Although HVOF coatings were most affected by increased load,they showed the highest wear resistance compared to other samples.The lowest wear resistance could be seen in the substrate.After the oxidation tests,HVOF coating layer was completely oxidized and also,the coating layer was delaminated from the substrate after 50 h oxidation due to its porous structure.LR coatings exhibited better oxidation performance.Al_(0.2) CrFeNiCo was dominantly composed of Cr2 O3,exhibiting a slower-growing tendency at the end of the oxidation tests,while Al_(0.2) CrFeNiCu was composed of spinel phases.展开更多
In this study,CoCrFeNiTi0.5Alx high‐entropy alloys were produced by induction melting and their dry sliding wear behavior was examined at different temperatures.In addition to face‐centered cubic(FCC)phases,low amou...In this study,CoCrFeNiTi0.5Alx high‐entropy alloys were produced by induction melting and their dry sliding wear behavior was examined at different temperatures.In addition to face‐centered cubic(FCC)phases,low amounts of a tetragonal phase were detected in the microstructures of alloys without Al and microscratches were formed by wear particles on the worn surfaces of the alloy specimens.Two body‐centered cubic(BCC)phases were detected in the alloy with 0.5Al and a fatigue‐related extrusion wear mechanism was detected on the worn surface.The alloy specimen with a high Al content exhibited the best wear characteristics.No wear tracks were formed in single‐phase BCC intermetallic alloys at room temperature and they exhibited a higher wear strength at high temperatures when compared to other samples.展开更多
基金financially supported by Scientific Research Funds of Bart?n University(No.2019-FEN-A-012,2019-FEN-A-013)。
文摘Al_(0.2) CrFeNiCo and Al_(0.2) CrFeNiCu high entropy alloys were deposited with high velocity oxygen fuel(HVOF)on 316 L substrate.Later,a laser re-melting(LR)process was applied to enhancing the coating microstructure.LR process effects on dry sliding wear and oxidation behaviors were investigated.The mixture of powders with free elements led to the formation of inner oxides in HVOF coatings.The oxide and porosity were eliminated using LR.After LR,FCC was the dominant phase in both alloys,while BCC,sigma and Cr2 O3 phases were observed in Al_(0.2) CrFeNiCo alloy.The hardnesses of the Al_(0.2) CrFeNiCo and Al_(0.2) CrFeNiCu coatings after HVOF were HV 591 and HV 361,respectively.After LR,the hardnesses decreased to HV 259 and HV 270,respectively.Although HVOF coatings were most affected by increased load,they showed the highest wear resistance compared to other samples.The lowest wear resistance could be seen in the substrate.After the oxidation tests,HVOF coating layer was completely oxidized and also,the coating layer was delaminated from the substrate after 50 h oxidation due to its porous structure.LR coatings exhibited better oxidation performance.Al_(0.2) CrFeNiCo was dominantly composed of Cr2 O3,exhibiting a slower-growing tendency at the end of the oxidation tests,while Al_(0.2) CrFeNiCu was composed of spinel phases.
文摘In this study,CoCrFeNiTi0.5Alx high‐entropy alloys were produced by induction melting and their dry sliding wear behavior was examined at different temperatures.In addition to face‐centered cubic(FCC)phases,low amounts of a tetragonal phase were detected in the microstructures of alloys without Al and microscratches were formed by wear particles on the worn surfaces of the alloy specimens.Two body‐centered cubic(BCC)phases were detected in the alloy with 0.5Al and a fatigue‐related extrusion wear mechanism was detected on the worn surface.The alloy specimen with a high Al content exhibited the best wear characteristics.No wear tracks were formed in single‐phase BCC intermetallic alloys at room temperature and they exhibited a higher wear strength at high temperatures when compared to other samples.
