Cladding coatings are fabricated on the surface of 0Cr13 ferritic stainless steel by laser cladding with no-carbon and low-carbon alloy powder respectively. The microstructure, phases and properties including micro-hardness, abrasive resistance and corrosion resistance of the cladding layers are investigated by optical microscope(OM), scanning electron microscopy(SEM), energy dispersive spectrometry (EDS), X-ray diffractometry(XRD), friction and wear tester and electrochemical workstation. The results show that these two kinds of alloy powder form good cladding layers without defects such as cracks and pores. The microstructures of the cladding layers mainly consist of equiaxed grain, cellular crystal, dentrite and interdendritic eutectic. The common phases of the two cladding layers are α-Fe、Fe-C、Cr、Cr9.1Si0.9、Fe9.7Mo0.3、Fe10.8Ni and Fe19Mn. Besides, interstitial compound phase Cr7C3 and martensite phase C0.055Fe1.945 are observed in the low-carbon cladding layer. The low-carbon cladding layer with a hardness of 750 HV0.5 shows the highest wear resistance and electrolytic corrosion resistance in comparison with the 0Cr13 matrix with a hardness of 250 HV0.5 and the no-carbon cladding layer with a hardness of 650 HV0.5. Softening occurred at the heat affect zone (HAZ) of no-carbon cladding layer. Both of the two cladding layers show a more stable frictional characteristic compared with matrix.
ZHANG Guodong
,
YANG Hui
,
WANG Qiyu
,
ZHANG Yazhi
,
LI Zhenggang
,
HUANG Xudong
,
LIAO Yunsheng
. Microstructure and Properties of Laser Cladding Layer on Ferritic Stainless Steel[J]. Journal of Mechanical Engineering, 2016
, 52(12)
: 37
-45
.
DOI: 10.3901/JME.2016.12.037
[1] 毛辉. 00Cr12型铁素体不锈钢焊接热影响区组织与性能研究[D]. 北京:机械科学研究总院,2009.
MAO Hui. Study on the microstructures and properties of HAZ in 00Crl2 ferrite stainless steel[D]. Beijing:Mechanical Science Research Institute,2009.
[2] 龚建勋,肖逸锋,张清辉. 高硬度铁素体不锈钢耐磨堆焊药芯焊丝:中国,2008100306079[P]. 2008-02-04.
GONG Jianxun, XIAO Yifeng,ZHANG Qinghui. Wearable flux cored wires with high hardness used for ferritic stainless steel:China,2008100306079[P]. 2008-02-04.
[3] 张迪,王英杰,刘景凤,等. 一种堆焊用铁素体不锈钢气体保护焊药芯焊丝:中国,2013102099661[P]. 2013-05-30.
ZHANG Di,WANG Yingjie,LIU Jingfeng,et al. One kind of gas shielded arc welding flux cored wire used for ferritic stainless steel:China,2013102099661[P]. 2013-05-30.
[4] 张鹏,石青,苏永祥. 4003铁素体不锈钢A-TIG焊接性能研究[J]. 热加工工艺,2014,43(9):168-171.
ZHANG Peng,SHI Qing,SU Yongxiang. Study on A-TIG weldability of 4003 ferritic stainless steel[J]. Hot Working Technology,2014,43(9):168-171.
[5] 熊腊森. 焊接工程基础[M]. 北京:机械工业出版社,2008.
XIONG Lasen. Foundation of welding engineering[M]. Beijing:China Machine Press,2008.
[6] DUBOURG L,ARCHAMBEAULT J. Technological and scientific landscape of laser cladding process in 2007[J]. Surface & Coatings Technology,2008,202(24):5863-5869.
[7] ZHOU Shengfeng,DAI Xiaoqin,ZHENG Haizhong. Microstructure and wear resistance of Fe-based WC coating by multi-track overlapping laser induction hybrid rapid cladding[J]. Optics & Laser Technology,2012(1):190-197.
[8] WANG Qinying,ZHANG Yangfei,BAI Shulin,et al. Microstructures,mechanical properties and corrosion resistance of Hastelloy C22 coating produced by laser cladding[J]. Journal of Alloys & Compounds,2013,553(6):253-258.
[9] YAN Hua,WANG Aihua,XU Kaidong,et al. Microstructure and interfacial evaluation of Co-based alloy coating on copper by pulsed Nd:YAG multilayer laser cladding[J]. Journal of Alloys & Compounds,2010,505(2):645-653.
[10] 赵彦华,孙杰,李剑峰. KMN钢激光熔覆FeCr合金修复组织性能及耐磨耐蚀性研究[J]. 机械工程学报,2015,51(8):37-43.
ZHAO Yanhua,SUN Jie,LI Jianfeng. Research on microstructure properties and wear and corrosion resistance of FeCr repaired coating on KMN steel by laser cladding[J]. Journal of Mechanical Engineering,2015,51(8):37-43.
[11] 曾维华,刘洪喜,蒋业华,等. SUH409L铁素体不锈钢表面激光熔覆层的组织与性能[J]. 金属热处理,2011,36(7):10-16.
ZENG Weihua,LIU Hongxi,JIANG Yehua,et al. Microstructure and properties of laser cladding coating on SUH409L ferritic stainless steel[J]. Heat Treatment of Metals,2011,36(7):10-16.
[12] 樊丁,李晓康,张建斌. 激光熔覆Mo 2 C-Co基合金的工艺参数对其组织的影响[J]. 兰州理工大学学报,2012,38(2):1-5.
FAN Ding,LI Xiaokang,ZHANG Jianbin. Influence of processing parameters of laser clad Mo 2 C-Co-based alloy on its microstructure[J]. Journal of Lanzhou University of Technology,2012,38(2):1-5.
[13] 张国栋,李莉,刘念,等. 打壳锤头等离子堆焊镍基涂层组织和性能[J]. 机械工程学报,2014,50(20):70-76.
ZHANG Guodong,LI Li,LIU Nian,et al. Structure and properties of nickel-based surfacing on crust breaker deposited by plasma arc welding[J]. Journal of Mechanical Engineering,2014,50(20):70-76.
[14] 崔忠圻,覃耀春. 金属学与热处理[M]. 北京:机械工业出版社,2007.
CUI Zhongqi,QIN Yaochun. Metallography and heat treatment[M]. Beijing:China Machine Press,2007.
[15] ZHANG Hui,ZOU Yong,ZOU Zengda,et al. Effects of chromium addition on microstructure and properties of TiC-VC reinforced Fe-based laser cladding coatings[J]. Journal of Alloys & Compounds,2014,614(10):107-112.
[16] ZHANG Hui,ZOU Yong,ZOU Zengda,et al. Microstructure and properties of Fe-based composite coating by laser cladding Fe-Ti-V-Cr-C-CeO 2 powder[J]. Optics & Laser Technology,2015,65:119-125.
[17] SCHUSTER J C,DU Y. Thermodynamic description of the system Ti-Cr-C[J]. Calphad,1999(23):393-408.
[18] PARAMESWARAN P,SAROJA S,VIJAVALAKSHMI M,et al. Decomposition modes of austenite in Cr Mo ferritic steels[J]. Journal of Nuclear Materials,1996,232:226-232.
[19] CHEN Xiaowei,QIAO Guiying,HAN Xiulin,et al. Effects of Mo,Cr and Nb on microstructure and
mechanical properties of heat affected zone for Nb-bearing X80 pipeline steels[J]. Materials & Design,2014,53(1):888-901.
[20] HANSEN N. Hall-Petch relation and boundary strengthening[J]. Cripta Materialia,2004,51(8):801-806.
[21] 束德林. 工程材料力学性能[M]. 北京:机械工业出版社,2008.
SHU Delin. Mechanical property of engineering materials[M]. Beijing:China Machine Press,2008.
[22] 樊丁,李强,张建斌. 激光熔覆FeNiCrAl合金涂层的组织与腐蚀性能[J]. 兰州理工大学学报,2009,35(2):13-16.
FAN Ding,LI Qiang,ZHANG Jianbin. Microstructure and corrosion performance of laser melt-clad FeNiCrAl alloying coating[J]. Journal of Lanzhou University of Technology,2009,35(2):13-16.
