Tuning the Composition and Microstructure of Fe-Based Alloy Thick Coatings for Heavy Duty Applications

Ludovica Rovatti; N. Palamini; Maurizio Vedani; G. Schubert

doi:10.4028/www.scientific.net/MSF.762.501

Paper Titles

Welding of Aluminum Matrix Composites
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Phase Transitions and Microstructural Processes in Shape Memory Alloys
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Semi-Massive Nanocrystallised Composites: From the Process to Mechanical and Microstructural Investigations
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Surface Patterning of Stainless Steel in Prevention of Fouling in Heat Transfer Equipment
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Tuning the Composition and Microstructure of Fe-Based Alloy Thick Coatings for Heavy Duty Applications
p.501

Microstructure and Strength of Si₃N₄ Joints Bonded with Sialon-Oxynitride Glass
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The Effects of Phosphotungstic Heteropoly Acid on Degradation Behaviour of Hardened Epoxide Polymers in Near-Critical Water
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Simulation of the Hot Extrusion Process of Sintered WCu40 Covered with a Steel Cup
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Microstructure and Reaction Mechanism of Multi-Laminated Ti-(SiC_p/Al) Composites Subjected to Annealing at 1300°C
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HomeMaterials Science ForumMaterials Science Forum Vol. 762Tuning the Composition and Microstructure of...

Tuning the Composition and Microstructure of Fe-Based Alloy Thick Coatings for Heavy Duty Applications

Abstract:

Thick coatings for heavy duty applications in many industrial fields are produced by generating hard layers of Fe-based complex alloys on the critical surfaces. The composition and structure of these coatings have to be carefully tuned in order to generate a defect-free layer after solidification and to meet the expected service conditions. The present study is aimed at investigating and developing improved Fe-based alloys for the above described thick coatings by a careful definition of the microstructural features required to bear service conditions and by defining the optimal compositions to achieve the desired properties. Primary carbide distribution and size as well as steel matrix composition are the main microstructural features that will be evaluated in order to fine tune coating performance in terms of toughness and hardness. The experimental part of the investigation here presented will be mainly concerned to laboratory casting the above alloys and to assess their microstructure and properties.

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Periodical:

Materials Science Forum (Volume 762)

Pages:

501-509

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.762.501

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Online since:

July 2013

Authors:

Ludovica Rovatti, N. Palamini, Maurizio Vedani, G. Schubert

Keywords:

Carbide, Hardfacing Alloys, Microstructure, Wear Resistance

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