2021
DOI: 10.1007/s40195-021-01204-6
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Microstructure and Improved Thermal Shock Behaviour of an In Situ Formed Metal-Enamel Interlocking Coating

Abstract: A novel metal-enamel interlocking coating was designed and prepared in situ by co-deposition of Ni-enamel composite layer and subsequent air spray of enamel with 10 wt% nanoscale Ni. During the firing process, the external enamel layer was melted and jointed with the enamel particles at the upper part of the Ni-plating layer to form the enamel pegs. Thermal shock tests of pure enamel, enamel with 10 wt% Ni composite and metal-enamel interlocking coatings were conducted at 600 °C in water and static air. The re… Show more

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“…11,13,21 With the addition of Ni content more than 2 wt.%, the Ni nanoparticle dispersion through the enamel matrix was not uniform, and a large number of particles agglomerated, thereby reducing the probability of formation of a ductile phase near the crack tip. Moreover, the agglomerated Ni nanoparticles were more easily oxidized, 37 and the stress and strain were concentrated in a small area near the crack front. In the absence of the plastic deformation of the ductile phase and crack passivation, the stress was not released, resulting in the crack expansion.…”
Section: Bending Performancementioning
confidence: 99%
“…11,13,21 With the addition of Ni content more than 2 wt.%, the Ni nanoparticle dispersion through the enamel matrix was not uniform, and a large number of particles agglomerated, thereby reducing the probability of formation of a ductile phase near the crack tip. Moreover, the agglomerated Ni nanoparticles were more easily oxidized, 37 and the stress and strain were concentrated in a small area near the crack front. In the absence of the plastic deformation of the ductile phase and crack passivation, the stress was not released, resulting in the crack expansion.…”
Section: Bending Performancementioning
confidence: 99%