Cavitation erosion behavior of Hastelloy™ C-276 weld by laser welding

Ni-based Hastelloy C-276 was chosen as the material of the stator and rotor cans of a nuclear main pump for its excellent resistance to corrosive environments and superior mechanical properties. In the present work, the cavitation erosion (CE) behavior of the Hastelloy C-276 thin sheet weld joint wa...

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Bibliographic Details
Published inWear Vol. 420-421; pp. 226 - 234
Main Authors Chai, Dongsheng, Ma, Guangyi, Zhou, Siyu, Jin, Zhuji, Wu, Dongjiang
Format Journal Article
LanguageEnglish
Published Amsterdam Elsevier B.V 15.02.2019
Elsevier Science Ltd
Subjects
Base metal
Cavitation
Cavitation erosion
Container industry
Corrosion resistance
Damage
Grain boundaries
Hastelloy (trademark)
Hastelloy C-276
Inhomogeneity
Laser beam welding
Laser welding
Mechanical properties
Solidification
Surface morphology
Surface roughness
Twin boundaries
Weld metal
Welded joints
Hastelloy C-276
Cavitation erosion
Laser welding
Surface morphology
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Summary:Ni-based Hastelloy C-276 was chosen as the material of the stator and rotor cans of a nuclear main pump for its excellent resistance to corrosive environments and superior mechanical properties. In the present work, the cavitation erosion (CE) behavior of the Hastelloy C-276 thin sheet weld joint was tested. The results indicate that both the CE damages of the weld metal and the base metal initiate at grain boundaries preferentially. The solidification grain boundaries (SGBs) of the weld metal and the twin boundaries (TBs) of the base metal are more susceptible to CE. For the weld metal, due to the microstructure inhomogeneity, regions that show the highest damage intensity are located near the central line of the weld surface where the columnar dendrites interact with the nearly equiaxed dendrites. For the base metal, grains with more TBs are damaged faster compare to other grains. The surface roughness of the eroded surfaces increases with exposure time, and the surface roughness of the base metal increases faster than that of the weld metal. Overall, the resistance to CE of the weld metal is better than that of the base metal. •The CE resistance of the weld metal is better than that of the base metal.•The CE damage initiates at grain boundaries preferentially.•Zones located near the central line of the weld surface are worst damaged.•Twin boundaries of the base metal are more susceptible to CE.
ISSN:0043-1648
1873-2577
DOI:10.1016/j.wear.2018.10.012