Material Science Aspects of Alloy Modification by Nanocompositions of Plasma-Chemical Synthesis

Vladimir Bolshakov; Nataliia Kalinina; Diana Нlushkova; Igor Kіrichenko; Oleksandr Voronkov; Luidmila Kostina

doi:10.4028/www.scientific.net/KEM.864.278

Paper Titles

Viscoelastic Resistance of the Surface Layer of Steel Products to Shock Attack of a Spherical Pellet
p.217

Analysis of the Bearing Capacity of Adhesive Joint of Honeycomb Cores of Sandwich Structures with the Continuous Adhesive Layer
p.228

Austenite Transformation Behavior and Mechanical Properties of Constructional V, Nb-Alloyed TRIP-Assisted Steel
p.241

Modeling the Optimal Composition of Structural Epoxy Composites Filled with Dispersed Metal Waste
p.250

Influence of Scale Factor on Structuring of Epoxy Polymer Products under the Action of Thermal Energy
p.257

Assessment of Hydroabrasive Wear Resistance of Construction Materials with Functional Coatings, which are Formed by Resource-Saving and Environmentally Friendly Technologies
p.265

Material Science Aspects of Alloy Modification by Nanocompositions of Plasma-Chemical Synthesis
p.278

Profitability of Production of Stainless Steel + Zirconium Metals Combination Adapters
p.285

High-Copper Cast Irons for the Products of Tribotechnical Applied
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HomeKey Engineering MaterialsKey Engineering Materials Vol. 864Material Science Aspects of Alloy Modification by...

Material Science Aspects of Alloy Modification by Nanocompositions of Plasma-Chemical Synthesis

Abstract:

Crystallographic characteristics of nanodispersed materials obtained by plasma-chemical synthesis were studied. Using industrial equipment for plasma-chemical synthesis the nanodispersed powders of high-melting carbide, nitride, carbonitride and silicide class compounds based on titanium, magnesium, aluminium, silicon were obtained. Technology for synthesis of powder fraction less than 100 nm was developed. The efficiency of nanodisperce compositions use in smelting of structural steels was determined. In the result of 10Г2С steel modification with Ti (CN) nanopowder strength, plastic properties and impact toughness were improved. Elemental composition of nanodispersed composition was determined: SiC, TiC, TiN, Ti (CN), AlN, Mg₂Si, Mg₃N₂. The elemental composition of synthesized compounds corresponded to stoichiometric composition. Microdiffractional patterns of the particles were analysed, it was shown that nanopowders belong to the solid crystalline bodies with metallic bond. It has been found, that titanium carbonitride Ti (CN) particles have face-centered and silicon carbide (SiC) particles have hexagonal crystal lattice. Experiments for steel 10Г2 and 10Г2С modifying with nanopowder compositions on base of Ti (CN) and SiC were carried out. The efficiency of nanodisperce compositions use in smelting of structural steels was determined. In the result of 10Г2С steel modification with Ti (CN) nanopowder strength, plastic properties and impact toughness were improved. The choice of nanodisperce titanium carbonitride Ti (CN) powders with 100 nm fraction for light alloy steels modifying was justified. The required criteria for choice of nanopowder modifiers were obtained: insolubility in smelt, correspondence of crystal lattice to steel matrix, commensurability with austenite germ critical radius in crystallizing.

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Key Engineering Materials (Volume 864)

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278-284

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.864.278

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Online since:

September 2020

Authors:

Vladimir Bolshakov, Nataliia Kalinina, Diana Нlushkova*, Igor Kіrichenko, Oleksandr Voronkov, Luidmila Kostina

Keywords:

Crystallographic Characteristics, Mechanical Characteristics, Modifying, Nanodispersed Composition, Plasma-Chemical Synthesis, Structural Steel

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