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Investigation of the Hydrogen Stratification of the Metal of the Active Gas Pipeline
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Methods for Determining the Quality of Galvanic Chromium Coating
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Modeling Calculation of the Corrosion Rate of Low Carbon Steel in Heat and Power Systems
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Efficiency Analysis of the Friction Material for the Wind Turbine Braking System
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Experimental Study of the Effectiveness of the Vibromechanical Stabilization of Bearing Rings
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Improving Methods of Assessment of a Stress State of Structures According to the Results of Coercive Measurements
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Optimal Shape Selection of Heat Exchangers Surfaces during Convective Heat Transfer
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Photometric Method of Diagnosis of Bearing Units Operating with Hydrocarbon Mixtures
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Qualimetry Rating of Hot-Rolled Pipes
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HomeSolid State PhenomenaSolid State Phenomena Vol. 284Experimental Study of the Effectiveness of the...

Experimental Study of the Effectiveness of the Vibromechanical Stabilization of Bearing Rings

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Abstract:

The paper provides the comparison of vibromechanical technology for stabilization of bearing rings and thermal tempering on the following parameters: performance, energy consumption, and magnitude of residual stresses after treatment. To assess the effectiveness of residual stress relaxation through the usage of vibromechanical energy, there were conducted experimental studies on a specially designed and manufactured prototype of the equipment. The results of experimental studies show that the energy consumption during vibromechanical stabilization is ten times less, and performance is several times higher than during the thermal tempering. Moreover, vibromechanical stabilization allows more effective residual stresses relaxation. The costs for capital investment can be reduced, as the cost of equipment for vibromechanical stabilization is ten times less than the cost of electric furnaces.

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Materials Engineering and Technologies for Production and Processing IV

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Periodical:

Solid State Phenomena (Volume 284)

Pages:

1327-1331

DOI:

https://doi.org/10.4028/www.scientific.net/SSP.284.1327

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Online since:

October 2018

Authors:

Albert Viktorovich Korolev, A.F. Balaev*, A.A. Korolev

Keywords:

Bearing Ring, Residual Stresses, Stress Relaxation, Tempering, Vibromechanical Stabilization

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© 2018 Trans Tech Publications Ltd. All Rights Reserved

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