Mathematical Modeling of the Effect of TiC Nanopowder Particles on the Wear Resistance Properties of Low-Alloy Steel

Nozimjon Kholmirzaev; Nosir Saidmakhamadov; Jamshidbek Khasanov; Nuritdin Tadjiev; Bekzod Yusupov; Nargiza Sadikova; Omonjon Yuldashev; Fakhriddin Makhmudov; Ibrokhim Sodik Nosirkhujaev; Zokirjon Nurdinov

doi:10.4028/p-gIS27O

Paper Titles

Improvement of the Technology of Melting of Low Alloy Steel Alloy in an Electric Arc Furnace
p.3

Mathematical Modeling of the Effect of TiC Nanopowder Particles on the Wear Resistance Properties of Low-Alloy Steel
p.11

Study of Variability Phenomena in Direct Energy Deposition of Nickel-Based Superalloy on Geometric Accuracy and Residual Stress Formation
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Detection of Stress Corrosion Cracking in SS304 under Calcium Silicate Thermal Insulation Using Acoustic Emission Technique
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Effect of Annealing Time on Pitting, Intergranular Corrosion, and Hardness of Stainless Steels
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Electrochemical Analysis on Corrosion of Stainless Steels in Molten Nitrate Salt
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Comparative Study of Corrosion Resistance in Heat-Treated Bainitic and Pearlitic Steels in Sodium Chloride Solution under Room and Elevated Temperatures
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Bottom of Line Corrosion Mechanism in Marginal Sour Environment Wet Gas Pipelines
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HomeMaterials Science ForumMaterials Science Forum Vol. 1139Mathematical Modeling of the Effect of TiC...

Mathematical Modeling of the Effect of TiC Nanopowder Particles on the Wear Resistance Properties of Low-Alloy Steel

Abstract:

In this article, the effect of TiC nanopowder particles on the wear resistance of low-alloy steel 35XGCL (analog is JIS G 5111) is mathematically modeled. First of all, the composition for liquefaction in an electric arc furnace was calculated. 5 and 10% TiC nanopowder particles were added to the alloy as a modifier before pouring liquid metal into the ladle. This process was performed before pouring the liquid metal from the furnace into the ladle. 15% of TiC was added in the furnace as a modifier. Lagrangian interpolation polynomial construction was used in this modeling. The amount of wear resistance was calculated by polynomial expression of the function with determination of unknown coefficients. The results obtained on the basis of the developed model were compared with case studies. The results of the analysis are shown by graphs.

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Periodical:

Materials Science Forum (Volume 1139)

Pages:

11-19

DOI:

https://doi.org/10.4028/p-gIS27O

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Online since:

December 2024

Authors:

Nozimjon Kholmirzaev*, Nosir Saidmakhamadov, Jamshidbek Khasanov, Nuritdin Tadjiev, Bekzod Yusupov, Nargiza Sadikova, Omonjon Yuldashev, Fakhriddin Makhmudov, Ibrokhim Sodik Nosirkhujaev, Zokirjon Nurdinov

Keywords:

Crystallization Centers, Ductility, Heat Treatment, Low-Alloy Steel Grade 35XGCL, TiC Nanopowder, Viscosity, Wear Resistance

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