Study of Thermal Modes of Formation of Layered Composites in Roller-Crystallizer

Teimuraz Namicheishvili; Giorgi Kevkhishvili; Julieta Loria; Giorgi Parunashvili; Jilda Gamsakhurdia

doi:10.4028/p-D7z8R0

Paper Titles

Preface

Effect of Modifying with Nanofillers on Epoxy Composites Structure and Thermal Conductivity
p.3

Study of Thermal Modes of Formation of Layered Composites in Roller-Crystallizer
p.17

Nanoclays and Their Notable Increase in Composite Production, in Review
p.25

Structural and Phase Features of Functional Coatings Obtained by Multichamber Detonation Spraying
p.41

Production of ZrB₂-SiC Based UHTCs with Addition of Boron Carbide and Graphene
p.51

Optimization оf Effectiveness Evaluation Method for Intumescent Fire Retardant Coating
p.65

Possibilities of Using a Fire Extinguishing Substance Based on a Water-Soluble Polymer for Extinguishing Flammable Liquids
p.73

Investigation of Fire Extinguishing Properties of Multicomponent Systems with Combined Action Based on Wetted Lightweight Bulk Materials for Extinguishing Polar Flammable Liquids
p.83

HomeMaterials Science ForumMaterials Science Forum Vol. 1165Study of Thermal Modes of Formation of Layered...

Study of Thermal Modes of Formation of Layered Composites in Roller-Crystallizer

Abstract:

In the production of layered steel-based composite materials by the liquid-phase method, an importance is attached to preserving the structural and physical-mechanical characteristics of the steel sheet serving as the middle layer. The temperature field in such a steel layer contacting with aluminum melt at a temperature of ~700°C in a roller-crystallizer is analyzed. A formula is obtained that can be used to determine the temperature distribution in the middle layer of steel at the initial stage of the technological process. A comparison of the theoretical results with experimental studies of the thermal modes of obtaining a layered steel–aluminum composite by the liquid-phase method is carried out.

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Periodical:

Materials Science Forum (Volume 1165)

Pages:

17-23

DOI:

https://doi.org/10.4028/p-D7z8R0

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Online since:

November 2025

Authors:

Teimuraz Namicheishvili, Giorgi Kevkhishvili, Julieta Loria*, Giorgi Parunashvili, Jilda Gamsakhurdia

Keywords:

Aluminum, Composite, Crystallizer, Roll, Smelt, Steel, Temperature Field

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