Influence of Cooling Rate on Final Properties of Laboratory Rolled Products

Petr Kawulok; Ivo Schindler; Karel Milan Čmiel; Jaroslav Sojka; Stanislav Rusz; Rostislav Kawulok

doi:10.4028/www.scientific.net/KEM.592-593.602

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Damage and Fracture Behaviours in Aged Austenitic Materials during High-Temperature Slow Strain Rate Testing
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Structural and Fatigue Properties of Titanium-Steel Bimetallic Composite Obtained by Explosive Welding Technology
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Structural Modifications of the Aluminium Alloy in Conditions of Additional Shock Impulse Load
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Influence of Cooling Rate on Final Properties of Laboratory Rolled Products
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Extrapolation of Sigmoidal Creep Curve by Strain Acceleration Parameter
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Determining Elastic-Plastic Properties of Al6061-T6 from Micro-Indentation Technique
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Production of Al Metal Matrix Composites by the Stir-Casting Method
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Elastic Properties of Porous Alumina, Zirconia and Composite Ceramics
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Influence of Cooling Rate on Final Properties of Laboratory Rolled Products

Abstract:

The objective of investigation was to determine the influence of chosen cooling rates after finish rolling on final microstructural and mechanical properties of the laboratory rolled products from steel 42CrMo4. Metallographic analysis showed that microstructure of rolled products, which were after finish rolling cooled down in accelerated manner by water sprays, was composed mostly by hardening phases and by smaller amount of ferrite. Microstructure of the rolled product cooled down in furnace in decelerated manner was formed by pearlitic blocks with minority occurrence of ferrite. Laboratory rolled products cooled down by more complicated modes, which consisted of combination of their cooling by water sprays with subsequent annealing in furnace, showed different phase morphology and distinct band structure. Results of tensile test have proved that the applied modes of cooling of rolled products by accelerated manner had only very small influence on their final mechanical properties. Considerably cooling the rolled product by decelerated manner in furnace resulted in drop yield strength, but on the other hand in an increase of ductility. More complicated modes of cooling the rolled products, which comprised also their annealing, showed the possibilities of significant influencing the strength, and particularly the plastic properties of the steel 42CrMo4.