Paper Titles

Comparison of Iron and Chromium Reduction from Chrome Ore Concentrates by Solid Carbon and Carbon Monoxide
p.1152

Quality Control of Building Materials According to Uncertainty of Measurement and Stability of the Technological Process of Production
p.1161

Device for Testing Pipe Billet
p.1166

Indentation Size Effect during Measuring the Hardness of Materials by Spherical Indenter
p.1172

Analysis of Fatigue Damage Accumulation in Structural Materials under Quasi-Random Load
p.1178

Determination of the Load Carrying Capacity of Honeycomb Panels at Fixing Points under an External Load
p.1184

Engineering Method for Analysis of the Ability to Strain-Hardening of Steels
p.1190

Improvement of the Method for the High-Carbon Wire Rod Pearlite Grain Grade Identification
p.1195

Investigation of Magnetic Properties of Various Structural Classes Steels in Weak Magnetic Fields Characteristic for Generation of Thermoelectric Currents in Electron Beam Welding
p.1201

HomeSolid State PhenomenaSolid State Phenomena Vol. 299Analysis of Fatigue Damage Accumulation in...

Analysis of Fatigue Damage Accumulation in Structural Materials under Quasi-Random Load

Article Preview

Abstract:

The spectrum of stresses at a hazardous point on bearing metal structures of mining, road-building and transporting machines, as a rule, is random by nature. Objective complexity of the fatigue process and variety of fatigue crack nucleation mechanisms are the main causes of errors in prediction of their lifespan, along with an experimentally untestable hypothesis of linear summation of damages. The method of complete stress-strain diagrams uses a representative parameter of the fatigue process, selected in accordance with the results of testing, carried out on trained thin specimens of a specific material. The summation of fatigue damages is based on experimental kinematic curves, whose intersection with a load vector is used as a criterion of fatigue failure. It is shown that the approach proposed to calculate the lifespan gives certain advantages, as far as individual properties of the material are concerned, and when it comes to describing the kinetics of the fatigue process and determining the limiting state of the material in a structure.

You might also be interested in these eBooks

Materials Engineering and Technologies for Production and Processing V

Info:

Periodical:

Solid State Phenomena (Volume 299)

Pages:

1178-1183

DOI:

https://doi.org/10.4028/www.scientific.net/SSP.299.1178

Citation:

Cite this paper

Online since:

January 2020

Authors:

Vladimir I. Mironov, Dmitry A. Ogorelkov, Olga A. Lukashuk*

Keywords:

Complete Stress-Strain Diagram, Fatigue Damage, Fracture, Lifespan, Stability, Strain Softening

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

© 2020 Trans Tech Publications Ltd. All Rights Reserved

Share:

Citation:

* - Corresponding Author

[1] V.P. Kogaev, Strength Calculation at Stresses Variable in Time, Mashinostroenie, Moscow, (1993).

[2] V.V. Bolotin, Predicting the Lifespan of Machines and Structures, Mashinostroenie, Moscow, (1984).

[3] N.I. Grinenko, L.I. Shefer, Spectral method of assessing the fatigue lifespan at random loading, J. Problemy prochnosti. 1 (1976) 19-22.

[4] A.S. Gusev, Fatigue Strength and Durability of Structures under Random Loading, Mashinostroenie, Moscow, (1989).

[5] A.N. Savkin, A.A. Sedov, A.V. Andronik, Assessing the lifespan of steel under random loading using phenomenological damage models, J. Izvestiya Volgogradskogo gosudarstvennogo tehnicheskogo universiteta. 21(124) (2013) 38-41.

[6] L.V. Muravieva, Analyzing the lifespan of metal structures under random impacts, J. Promyshlennoe i grazhdanskoe stroitelstvo. 12 (2015) 19-22.

[7] V.F. Terentiev, S.A. Korableva, Fatigue of Metals, Nauka, Moscow, (2015).

[8] S.D. Volkov, V.I. Mironov, Using resistance functions to assess the lifespan of structures, J. Dep. v VINITI. 1883–78 (1978).

[9] I.G. Emeliyanov, V.I. Mironov, Lifespan of Shell Structures, RIO UrO RAN, Yekaterinburg, (2012).

[10] V.I. Mironov, O.A. Lukashuk, D.I. Vichuzhanin, Method for describing fatigue processes in structural materials, J. Solid State Phenom. 265 (2017) 815-820.

DOI: 10.4028/www.scientific.net/ssp.265.815

[11] V.V. Struzhanov, V.I. Mironov, Strain Softening of Materials in Structural Elements, Izd-vo UrO RAN, Yekaterinburg, (1995).

[12] S.A. Sokolov, Structural Mechanics and Metal Structures of Machines, Politehnika. Saint Petersburg, (2011).

[13] G.V. Uzhik (ed.), Fatigue and Strength of Metals, Izd. Inostrannoy Literatury, Moscow, (1963).

[14] N.S. Moskalev, A.Ya. Pronozin, Metal Structures, Izd-vo Associacii stroitelnyh vuzov, Moscow, (2007).

[15] P.A. Pavlov, Mechanical States and Strength of Materials, Izd-vo Leningr. un-ta, Leningrad, (1979).

[16] D.A. Ogorelkov, V.I. Mironov, O.A. Lukashuk, Durability of metal structures under quasi-static load, Proceedings of MATEC Web of Conferences, 224 (2018) 02091.

DOI: 10.1051/matecconf/201822402091

[17] RD 10-399-01. Specifications of parameter recorders for load-lifting cranes, Gosgortehnadzor Rossii, Moscow, (2001).

[18] V.P. Troshhenko, A.Ya. Krasovskiy, V.V. Pokrovskiy, et al., Materials Resistance to Deformation and Softening: Reference Book, Part 2, Nauk. dumka, Kiev, (1994).

[19] I.S. Kamancev, A.P. Vladimirov, E.M. Borodin, Study of processes of crack nucleation under multicycle fatigue of 09G2S pipe steel using the method of speckle interferometry, J. Vestnik Tambovskogo universiteta. 18(4-2) (2013) 1881-1882.

[20] V.I. Mironov, A.V. Kuznetsov, I.G. Emeliyanov, Consideration of cyclic degradation of the material and abnormality of the surface layer mechanical properties in calculating the life of a plate with an opening, J. Strength of Materials, 46(5) (2014) 638-643.

DOI: 10.1007/s11223-014-9594-y