Structure and Properties of Multicomponent Bronze Depending on the Crystallization Conditions

Anton Viktorovich Korchmit; N.V. Martyushev

doi:10.4028/www.scientific.net/AMM.756.303

Paper Titles

Structure and Properties of Multicomponent Tin Leaded Bronzes upon Die-Casting Depending on Pouring Temperature
p.281

Physical-Mechanical Properties of Corundum-Zirconium Ceramic Obtained by the Technology of Radial Magnetoimpulse Pressing
p.286

Influence of Phase Composition on Properties of Corundum-Zirconium Ceramic
p.293

Oxide Powder Plasma Processing by Low-Energy Ions of Titanium
p.299

Structure and Properties of Multicomponent Bronze Depending on the Crystallization Conditions
p.303

Mechanical Properties of Spun Castings of Multicomponent Bronze Depending on the Casting Conditions
p.308

Low-Melting Glass-Ceramic Composites with Low Linear Thermal Expansion Coefficient for Radio-Electronics
p.313

Phase Composition and Mechanical Properties Modification in Cr/Ti System by Short-Pulsed High Intensity Ion Beams Treatment
p.319

Investigation of Ultradispersed Powders Fe_xO_y Obtained in the Electric Discharge Plasma
p.325

HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vol. 756Structure and Properties of Multicomponent Bronze...

Structure and Properties of Multicomponent Bronze Depending on the Crystallization Conditions

Abstract:

This work presents the characteristic properties of powdered materials sintering under conditions of liquid-phase sintering. It has been established that to implement the liquid-phase sintering advantages it is necessary to do temperature research when the liquid-phase concentration does not exceed the critical one. Impact strength is the highest for the bronze, casted in a chill mould at 1220°С, and the lowest for the bronze, casted in aluminum-chromium-phosphate moulds at the same temperature.

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Periodical:

Applied Mechanics and Materials (Volume 756)

Pages:

303-307

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.756.303

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Online since:

April 2015

Authors:

Anton Viktorovich Korchmit*, N.V. Martyushev

Keywords:

Crystallization, Impact Strength, Multicomponent Bronze, Pouring Temperature, Strength

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