An investigation on the development and wear performance of chromium-MWCNTs transformed HVOF sprayed nano-WC-CoCr coatings

This research work presents a detailed study of development and wear performance of high chromium and multiwalled carbon nanotubes (MWCNTs) reinforced nano-WC-CoCr based coatings. The CoCr binder matrix was modified by increasing the Cr element (10 & 16 wt%) and keeping the fixed proportion of M...

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Bibliographic Details
Published in:Surface & coatings technology 2020-04, Vol.388, p.125610-16, Article 125610
Main Authors: Thakur, Lalit, Arora, N.
Format: Article
Language:English
Subjects:
Abrasive erosion
Abrasive wear
Binders (materials)
Chromium
CNT
Coating
Fracture toughness
Gluing
Grains
High velocity oxyfuel spraying
HVOF
Indentation
Microhardness
Morphology
Multi wall carbon nanotubes
Porosity
Process parameters
Protective coatings
Spray guns
Surface roughness
Tungsten carbide
WC-10Co-4Cr
Wear
Wear resistance
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Summary:This research work presents a detailed study of development and wear performance of high chromium and multiwalled carbon nanotubes (MWCNTs) reinforced nano-WC-CoCr based coatings. The CoCr binder matrix was modified by increasing the Cr element (10 & 16 wt%) and keeping the fixed proportion of MWCNTs (2 wt%). The coating deposition was done by using Praxair JP-5000 HVOF spray gun with optimized process parameters. SEM, EDS, and XRD were performed to study the surface morphologies, elemental compositions and phases present in the feedstock powders and developed coatings. Micro-hardness, percentage porosity, surface roughness and indentation fracture toughness of the deposited coatings were evaluated. The solid particle erosion and reciprocating abrasive wear testing were conducted in order to evaluate the wear resistance of modified coatings. The worn-out surfaces obtained after erosion testing revealed the removal of material by microcutting and ploughing of CoCr binder matrix, pull-out and fracturing of nano-WC grains. The SEM images revealed the formation of wear tracks on the coatings surfaces, which were caused by the micro-cutting and sideways displacement of CoCr and nano-WC grains during the reciprocating abrasive wear testing. The addition of Cr in higher proportion along with MWCNTs significantly enhanced the fracture toughness of nano-WC-CoCr coating. The improvement in fracture toughness may be attributed to increased metallic binder contents along with the bridging and gluing of splats by MWCNTs. The nano-WC-CoCr coating with 10 wt% Cr + 2 wt% MWCNTs exhibited the enhanced wear resistance in all the test conditions as compared to the other coatings. •WC-CoCr coatings were deposited by using kerosene fueled HVOF spray process.•CoCr binder matrix was modified by increasing the Cr and addition of MWCNTs.•Increased proportion of Cr and MWCNTs improved the fracture toughness of coating.•Solid particle erosion and reciprocating abrasive wear testing were conducted.•WC-CoCr coating with 10 wt% Cr + 2 wt% MWCNTs showed the highest wear resistance.
ISSN:0257-8972
1879-3347
DOI:10.1016/j.surfcoat.2020.125610