摘要
通过高效能超音速等离子喷涂(SAPS)制备WC-Co及WC-Ni Cr金属陶瓷涂层,对比研究了2种涂层的抗冲蚀性能及在热腐蚀条件下的结构和性能演变。结果表明:2种涂层在喷涂过程中均会发生一定程度的脱碳,表现为W_2C相的形成;同时在WC-Co涂层中有少量的Co_3W_3C和Co_6W_6C相生成,且该涂层在热腐蚀后表层的WC相出现了分解与氧化,形成了W_3C、W_6C_(2.54)等脱碳相与CoWO_4、WO_3等氧化物相。在普通冲蚀条件下,WC-Co涂层的抗冲蚀性能更为优异,但热腐蚀会极大降低WC-Co涂层的抗冲蚀性能;与之相反,WC-NiCr涂层中的NiCr相在热腐蚀环境下生成的Cr_2O_3可以有效阻挡涂层内部与外部之间的物质扩散,从而降低了热腐蚀对涂层结构的破坏,在热腐蚀条件下表现出了优良的抗冲蚀性能。
WC-Co and WC-NiCr cermet coatings were deposited by high-efficiency supersonic atmospheric plasma spraying. The erosion resistance of both coatings was comparatively studied in normal or hot corrosion condition. Results indicate that the decarburization happens during the spray of WC-Co or WC-NiCr powders, which leads to the formation of W_2C. Meanwhile, Co_3W_3 C and Co_6W_6 C are also found in the WC-Co coating. Some new phases, such as W_3C, W_6C_(2.54), CoWO_4 and WO_3, are observed in the WC-Co coating due to the decomposition and oxidation of WC during hot corrosion. WC-Co coating shows a higher erosion resistance than WC-NiCr coating; however, the erosion resistance of the former significantly decreases after hot corrosion. On the contrary, the Cr_2O_3 formed during hot corrosion can effectively protect WC from oxidation and thus improve the erosion resistance of the WC-NiCr coating.
引文
[1]Teppernegg T,Klünsner T,Kremsner C et al.Int J Refract Met H[J],2016,56:139
[2]Janka L,Norpoth J,Eicher S.Mater Design[J],2016,98:135
[3]Gisario A,Puopolo M,Venettacci S et al.Int J Refract Met H[J],2015,52:123
[4]Mayrhofer E,Janka L,Mayr W P.Surf Coat Technol[J],2015,281:169
[5]Wu Y S,Zeng D C,Liu Z W et al.Surf Coat Technol[J],2011,206:1102
[6]Wu X,Guo Z M,Guo L C et al.Chin J Rare Metals[J],2014,38:42
[7]Fervel V,Normand B,Coddet C.Wear[J],1999,230(1):70
[8]Zhang Jifu(张吉阜),Liu Min(刘敏),Zhou Kesong(周克崧)et al.Rare Metal Materials and Engineering(稀有金属材料与工程)[J],2016,43(10):2492
[9]Chen Deyong(陈德勇),Luo Zaiqing(罗在清).CementedCarbide(硬质合金)[J],2007,24(1):43
[10]Yuan J H,Ma C W,Yang S L et al.Surf Coat Technol[J],2016,285:17
[11]Al-Mutairi S,Hashmi M S J,Yilbas B S et al.Surf Coat Technol[J],2015,264:175
[12]Bai Y,Han Z H,Li H Q et al.Surf Coat Technol[J],2011,205(13-14):3833
[13]Bai Y,Han Z H,Li H Q et al.Appl Surf Sci[J],2011,257(16):7210
[14]Bai Y,Ding C,Li H et al.J Therm Spray Techn[J],2013,22(7):1201
[15]Bai Y,Tang J J,Qu Y M et al.Ceram Int[J],2013,39:5113
[16]Bai Y,Zhao L,Tang J J et al.Ceram Int[J],2013,39:4437
[17]Han Zhihai(韩志海),Wang Haijun(王海军),Zhou Shikui(周世魁)et al.Foundry Technology(铸造技术)[J],2005,26(12):1157
[18]Wang Haijun(王海军),Han Zhihai(韩志海),Wang Jian(王建)et al.Journal of Academy of Armored Force Engineering(装甲兵工程学院学报)[J],2006,20(1):85
[19]Luthra K L.Metall Trans A[J],1982,13(10):1843
[20]Wang Haijun(王海军).Thermal Spraying Material and Application(热喷涂材料及应用)[M].Beijing:National Defence Industry Press,2008:67
[21]Toma D,Brandl W,Marginean G.Surf Coat Technol[J],2001,138:149