Computerized Study of Intense Deformed State of Grinding Plate of High-Manganese Steel

Ivan Nikolaevich Erdakov

doi:10.4028/www.scientific.net/SSP.284.563

Paper Titles

A Study of the Influence of the Manufacturing Process Parameters on the Distribution of Residual Stresses in Pipe Walls during Sink Drawing
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FEM Simulation of Copper Busbar Pressing on the Continuous Extrusion Line "CONFORM"
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The Investigation of the Influence of Friction and Roll Calibration on the Pipe Formation during Plug Rolling
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The Investigation of Pipe Ends Formation under Reduction Mill Rolling
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Computerized Study of Intense Deformed State of Grinding Plate of High-Manganese Steel
p.563

Constructing Isotherms of Oxygen Solubility in the Liquid Metal of the Cu-Na-K-O System
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Thermodynamic Assessment of the Na-Cu and Na-K Binary Systems
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Development of the Algorithm for Determination of Mechanical Properties of Steel 20 with Different Levels of Cumulative Fatigue Damage with the Application of Compact Samples
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Impact of High-Frequency Vibrations on Metal Items Resistance to Cyclic and Axial Loads
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Computerized Study of Intense Deformed State of Grinding Plate of High-Manganese Steel

Abstract:

The article studies peculiarities of shrinkage formation during induration of a grinding plate made of high-manganese steel. It suggests a method evaluating influence of the defect of such kind on intense deformed state of a grinding plate occurring in the result of impact loads of preparation grinding plates. The finite-element method in the DEFORM software package is used for calculating lumped voltages for different parameters of circular section macropores.

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Periodical:

Solid State Phenomena (Volume 284)

Pages:

563-567

DOI:

https://doi.org/10.4028/www.scientific.net/SSP.284.563

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Online since:

October 2018

Authors:

Ivan Nikolaevich Erdakov*

Keywords:

DEFORM Software Package, Finite-Element Method, Grinding Plate, High-Manganese Steel, Intense Deformed State, Internal Shrinkage, Lumped Voltage

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