H.C.Lin1)
,
J.Y.Wang1)
,
Q.Z.Yang1)
,
L.J.Guo2) and D.X.Lan2) 1)Departmentof Mechanical Engineering
,
QingDao Institute of Architecture and Engineering
,
Qingdao 266033
,
China 2)Institute of Machinery
,
Qingdao266000
,
China
金属学报(英文版)
Thermalfatiguebehaviorsof Nibased alloychromium carbidecompositecoating madeby a vacu um fusionsintering method are discussed. Resultsshowedthatthermalfatiguebehaviorisassoci ated with cyclic uppertemperature and coating thickness. Asthe thickness of coating decreases,thethermalfatigueresistanceincreases. Thethermalfatigueresistancecuts down with thether malcyclic uppertemperature rising. Thecrack growth rate decreases with theincreasein cyclicnumber untilcrackarrests. Thetractofthermalfatiguecrackcracksalongtheinterfacesof phas es. Thecompositecoating possesseshigheroxidation resistance.
关键词:
compositecoating
,
null
,
null
S.T. Wang
,
S.W. Yang
,
K.W. Gao
,
X.L. He
金属学报(英文版)
For 18 months, a newly developed low alloy weathering steel has been exposed in two coastal sites (Qingdao in the north China, Wanning in the south China). The different corrosion behaviors of the exposed side and the underside of the samples were characterized by X-ray diffraction (XRD), polarization curve, electrochemical impedance spectroscopy (EIS), scanning electron microscopy (SEM), and N$_{2}$ adsorption approach. It was found that the samples exhibited higher corrosion rate in Wanning than that in Qingdao. The underside of the samples corrodes more seriously than the exposed side in Qingdao, whereas the result in Wanning is just the reverse. The protection performance of rust layers mainly depends on its compactness and the enrichment of Cu and Cr is a secondary causation. The different compactness of rust layers in the exposed side and the underside originates from different corrosion conditions of the two sides.
关键词:
alloy weathering steel
,
null
