激光熔覆Fe_(0.5)NiCoCrCuTi高熵合金涂层的微观结构及性能(英文)
|
摘要
采用激光熔覆工艺在40Cr钢表面制备了Fe_(0.5)NiCoCrCuTi高熵合金涂层,利用带有能谱的扫描电子显微镜(SEM/EDS)、显微/维氏硬度计、摩擦磨损试验机、电化学工作站等对Fe_(0.5)NiCoCrCuTi高熵合金微观结构进行分析并测试其硬度、耐磨性能、耐蚀性能。结果表明:Fe_(0.5)NiCoCrCuTi高熵合金试样主要由涂层、热影响区及基体组成,涂层无气孔、裂纹等缺陷,与基体呈冶金结合;涂层主要由两种形貌的片状组织组成,晶粒排列紧密,晶粒表面分布着细小的粒子;涂层出现元素偏析,但程度较小;细晶强化、固溶强化、析出强化的共同作用使得Fe_(0.5)Ni CoCrCuTi涂层具有高硬度,表面最高硬度为857 HV,约为基体40Cr钢的3.3倍,高硬度及细小尺度析出物为涂层的耐磨性提供了保证;Fe_(0.5)NiCoCrCuTi高熵合金涂层在3.5%NaCl和0.5 mol/L H_2SO_4溶液中的耐蚀性能优异,与304不锈钢相比,自腐蚀电流密度降低两三个数量级,自腐蚀电位分别正移0.230、0.161 V。
The Fe_(0.5)NiCoCrCuTi high entropy alloy coating was prepared by laser cladding on 40 Cr steel surface. The microstructure, hardness, wear resistance and corrosion resistance of Fe_(0.5)NiCoCrCuTi high entropy alloy were investigated by means of scanning electron microscopy and energy dispersive spectroscopy(SEM/EDS), micro/Vickers hardness tester, friction and wear tester and electrochemical workstation. Experimental results show that Fe_(0.5)NiCoCrCuTi high entropy alloy is mainly composed of coating, heat affected zone and the substrate. The coating has no pores, cracks and other defects,metallurgical bonding with substrate; the coating is mainly composed of two kinds of lamellar microstructure morphology, the grains closely arranged, fine particles are distributed on the grain surface.There is element segregation in the coating, but to a relatively small extent. Under the combined action of fine-grained strengthening, solid solution strengthening and precipitation strengthening, the Fe_(0.5)NiCoCrCuTi coating has high hardness, the maximum surface hardness is 857 HV, about 3.3 times as much as the 40 Cr steel. High hardness and fine scale precipitates provided a guarantee for the wear resistance of the coating. The corrosion resistance of Fe_(0.5)NiCoCrCuTi high entropy alloy coating in 3.5%NaCl and 0.5 mol/L in H_2SO_4 solutions are excellent, compared with 304 stainless steel, the corrosion current density were decreased by 2 and 3 orders of magnitude respectively, the corrosion potential were shift toward positive direction for 0.230 V and 0.161 V respectively.
The Fe_(0.5)NiCoCrCuTi high entropy alloy coating was prepared by laser cladding on 40 Cr steel surface. The microstructure, hardness, wear resistance and corrosion resistance of Fe_(0.5)NiCoCrCuTi high entropy alloy were investigated by means of scanning electron microscopy and energy dispersive spectroscopy(SEM/EDS), micro/Vickers hardness tester, friction and wear tester and electrochemical workstation. Experimental results show that Fe_(0.5)NiCoCrCuTi high entropy alloy is mainly composed of coating, heat affected zone and the substrate. The coating has no pores, cracks and other defects,metallurgical bonding with substrate; the coating is mainly composed of two kinds of lamellar microstructure morphology, the grains closely arranged, fine particles are distributed on the grain surface.There is element segregation in the coating, but to a relatively small extent. Under the combined action of fine-grained strengthening, solid solution strengthening and precipitation strengthening, the Fe_(0.5)NiCoCrCuTi coating has high hardness, the maximum surface hardness is 857 HV, about 3.3 times as much as the 40 Cr steel. High hardness and fine scale precipitates provided a guarantee for the wear resistance of the coating. The corrosion resistance of Fe_(0.5)NiCoCrCuTi high entropy alloy coating in 3.5%NaCl and 0.5 mol/L in H_2SO_4 solutions are excellent, compared with 304 stainless steel, the corrosion current density were decreased by 2 and 3 orders of magnitude respectively, the corrosion potential were shift toward positive direction for 0.230 V and 0.161 V respectively.
引文
[1]Yeh J W,Chen S K,Gan J Y,et al.Formation of simple crystal structures in solid-solution alloys with multi-principal metallic elements[J].Metallurgical and Materials Transactions A,2004,35A:2533-2536.
[2]Yeh J W,Chen S K,LIN S J,et al.Nanostructured high-entropy alloys with multi-principal elementsnovel alloy design concepts and outcomes[J].Advanced Engineering Materials,2004,6:299-303.
[3]Pham Thihongnga,Liu Hongxi,Zhang Xiaowei,et al.Microstructure and high-temperature wear behaviors of Co/TiC laser coatings on die steel[J].Optics and Precision Engineering,2013,21(8):2048-2055.(in Chinese)
[4]Li Z M,Pradeep K G,Deng Y,et al.Metastable highentropy dual-phase alloys overcome the strengthductility trade-off[J].Nature,2016,534:227-230.
[5]Ma Chen,Ma Zhuang,Gao Lihong,et al.Laser damage mechanism of flake graphite modified phenolic resin coating[J].Chinese Optics,2017,10(2):249-255.(in Chinese)
[6]Qiu X W,Wu M J,Qi Y,et al.Microstructure and corrosion resistance of Al2CrFeCoCuNixTi high entropy alloy coatings prepared by laser cladding[J].Infrared and Laser Engineering,2018,47(7):0706008.
[7]Qiu X W,Huang C X,Wu M J,et al.Structure and properties of AlCrFeNiCuTi six principal elements equimolar alloy[J].Journal of Alloys and Compounds,2016,658:1-5.
[8]Hsu Y J,Chiang W C.Corrosion behavior of FeCoNiCrCux high-entropy alloys in 3.5%sodium chloride solution[J].Materials Chemistry and Physics,2005,92:112-117.
[9]An Xulong,Liu Qibin,Zheng bo.Microstructure and properties of laser cladding high entropy alloy MoFeCrTiWAlxSiy coating[J].Infrared and Laser Engineering,2014,43(4):1140-1144.(in Chinese)
[10]Liu Hongxi,Tao Xiaode,Zhang Xiaowei,et al.Microstructure and interface distribution of Fe-Cr-SiB-C laser cladding alloy coatings assisted by mechanical vibration[J].Optics and Precision Engineering,2015,23(8):2192-2202.(in Chinese)
[11]Zhang Min,Liu Chang,Ren Bo,et al.Microstructure and mechanical properties of porous Ni alloy fabricated by laser 3D printing[J].Chinese Optics,2016,9(3):335-341.(in Chinese)
[12]Liu Hongxi,Leng Ning,Zhang Xiaowei,et al.Microstructure and wear behavior of WC/Co50composite coatings on 40Cr cutting tool surface prepared by laser cladding[J].Infrared and Laser Engineering,2016,45(1):0120001.(in Chinese)
[13]Zhang A J,Han J S,Su B,et al.Microstructure,mechanical properties and tribological performance of CoCrFeNi high entropy alloy matrix self-lubricating composite[J].Materials&Design,2017,114:253-263.
[14]Li Wei,Liu Guizhong,Guo Jingjie.Microstructure and electrochemical properties of AlxFeCoNiCrTi highentropy alloys[J].Foundry,2009,58(5):431-435.(in Chinese)
[15]Luo Xiaoyan,Liu Guizhong,Li Wei,et al.Microstructure and electrochemical properties of AlFeCoNiCrTiVxhigh-entropy alloys[J].Corrosion&Protection,2010,31(5):355-358.(in Chinese)
[2]Yeh J W,Chen S K,LIN S J,et al.Nanostructured high-entropy alloys with multi-principal elementsnovel alloy design concepts and outcomes[J].Advanced Engineering Materials,2004,6:299-303.
[3]Pham Thihongnga,Liu Hongxi,Zhang Xiaowei,et al.Microstructure and high-temperature wear behaviors of Co/TiC laser coatings on die steel[J].Optics and Precision Engineering,2013,21(8):2048-2055.(in Chinese)
[4]Li Z M,Pradeep K G,Deng Y,et al.Metastable highentropy dual-phase alloys overcome the strengthductility trade-off[J].Nature,2016,534:227-230.
[5]Ma Chen,Ma Zhuang,Gao Lihong,et al.Laser damage mechanism of flake graphite modified phenolic resin coating[J].Chinese Optics,2017,10(2):249-255.(in Chinese)
[6]Qiu X W,Wu M J,Qi Y,et al.Microstructure and corrosion resistance of Al2CrFeCoCuNixTi high entropy alloy coatings prepared by laser cladding[J].Infrared and Laser Engineering,2018,47(7):0706008.
[7]Qiu X W,Huang C X,Wu M J,et al.Structure and properties of AlCrFeNiCuTi six principal elements equimolar alloy[J].Journal of Alloys and Compounds,2016,658:1-5.
[8]Hsu Y J,Chiang W C.Corrosion behavior of FeCoNiCrCux high-entropy alloys in 3.5%sodium chloride solution[J].Materials Chemistry and Physics,2005,92:112-117.
[9]An Xulong,Liu Qibin,Zheng bo.Microstructure and properties of laser cladding high entropy alloy MoFeCrTiWAlxSiy coating[J].Infrared and Laser Engineering,2014,43(4):1140-1144.(in Chinese)
[10]Liu Hongxi,Tao Xiaode,Zhang Xiaowei,et al.Microstructure and interface distribution of Fe-Cr-SiB-C laser cladding alloy coatings assisted by mechanical vibration[J].Optics and Precision Engineering,2015,23(8):2192-2202.(in Chinese)
[11]Zhang Min,Liu Chang,Ren Bo,et al.Microstructure and mechanical properties of porous Ni alloy fabricated by laser 3D printing[J].Chinese Optics,2016,9(3):335-341.(in Chinese)
[12]Liu Hongxi,Leng Ning,Zhang Xiaowei,et al.Microstructure and wear behavior of WC/Co50composite coatings on 40Cr cutting tool surface prepared by laser cladding[J].Infrared and Laser Engineering,2016,45(1):0120001.(in Chinese)
[13]Zhang A J,Han J S,Su B,et al.Microstructure,mechanical properties and tribological performance of CoCrFeNi high entropy alloy matrix self-lubricating composite[J].Materials&Design,2017,114:253-263.
[14]Li Wei,Liu Guizhong,Guo Jingjie.Microstructure and electrochemical properties of AlxFeCoNiCrTi highentropy alloys[J].Foundry,2009,58(5):431-435.(in Chinese)
[15]Luo Xiaoyan,Liu Guizhong,Li Wei,et al.Microstructure and electrochemical properties of AlFeCoNiCrTiVxhigh-entropy alloys[J].Corrosion&Protection,2010,31(5):355-358.(in Chinese)