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HomeSolid State PhenomenaSolid State Phenomena Vol. 299The Method of Testing Cylindrical Specimen for...

The Method of Testing Cylindrical Specimen for Torsion in Order to Determine the Rheological Properties of Materials Sensitive to the Strain Rate

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Abstract:

The article provides an overview of existing methods of testing specimen for torsion, in order to determine the rheological properties of materials. In addition, the approaches to the post-processing experimental data, obtained in the form of torque-twist angle curve, are reviewed. It is shown that there is no universal and reliable method to study the rheological properties of materials that are sensitive to the strain rate. This paper proposes the new testing method that takes into account the effects of strain rate hardening initially. This method is that the torsion tests are carried out with the variable grips acceleration. The post-processing of obtained experimental data can be carried out with the use of modified Nadai method. In addition, with the use of mathematical modeling it is shown that the new method is reliable, regardless of material properties. The application for invention of the new testing method No2018132149 was directed in Federal Institute of Industrial Property on September, 7, 2018.

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Materials Engineering and Technologies for Production and Processing V

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Periodical:

Solid State Phenomena (Volume 299)

Pages:

501-507

DOI:

https://doi.org/10.4028/www.scientific.net/SSP.299.501

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Online since:

January 2020

Authors:

Mikhail Erpalov*, Dmitry Pavlov

Keywords:

Rheological Properties, Strain Hardening, Strain Rate Hardening, Strain Resistance, Stress-Strain Curve, Torsion Test

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© 2020 Trans Tech Publications Ltd. All Rights Reserved

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[1] F.J. Bell, Experimental basis of mechanics of deformable solids. Part I. Small deformation. Moscow, Nauka, (1984).

[2] P.I. Polukhin, G. Ya.Gun, A.M. Galkin, Resistance to plastic deformation of metals and alloys. Moscow, Metallurgiya, (1976).

[3] Ju.N. Rabotnov, Strength of materials, Moscow, (1962).

[4] Yu.N. Loginov, S.L. Demakov, A.G. Illarionov, A.A. Popov, Effect of the strain rate on the properties of electrical copper. Russian Metallurgy (Metally), 3 (2011) 194-201.

DOI: 10.1134/s0036029511030098

[5] A.V. Konovalov, Constitutive relations for metals under high-temperature plastic strains. Mechanics of Solids. Vol. 44, 1 (2009) 98-104.

DOI: 10.3103/s0025654409010105

[6] A.A. Umanskiy, V.N. Kadykov, A.V. Golovatenko, Improvement of the rolling schedule for railroad rails in breakdown stands of the universal rolling mill. Chernye Metally, 11 (2016) 16-21.

[7] A.A. Bogatov, M.V. Erpalov, Causes of formation and ways of elimination of defects on the internal surface of upset tube ends. Metal Science and Heat Treatment. Vol. 58, 1-2 (2016) 33-36.

DOI: 10.1007/s11041-016-9960-4

[8] M.V. Erpalov, A.A. Bogatov, Research on metal forming in pipe ends upsetting process. Solid State Phenomena. Vol. 265. (2017) 1076-1080.

DOI: 10.4028/www.scientific.net/ssp.265.1076

[9] A.A. Bogatov, D.A. Pavlov, V.B. Timofeev, E.A. Pavlova, Theoretical and experimental study of non-steady-state pipe reduction process using a Tesa 20-102 mill. Metallurgist. Vol. 62, 5-6 (2018) 559-567.

DOI: 10.1007/s11015-018-0693-z

[10] A.A. Bogatov, D.A. Pavlov, Study of metal strained state during workpiece reduction in a three-roll screw-rolling mill. Metallurgist. Vol. 61, 3-4 (2017) 311-317.

DOI: 10.1007/s11015-017-0494-9

[11] A. Nadai, Theory of flow and fracture of solids. Vol. 2. New York: McGraw-Hill Book Company, (1963).

[12] D.S. Fields, W.A. Backofen, Determination of strain-hardening characteristics by torsion testing. ASTM Proceeding. Vol. 57, (1957) 1259-1272.

[13] J.J. Jonas, F. Montheillet, L.S. Toth, C. Ghosh, Effects of varying twist and twist rate sensitivities on the interpretation of torsion testing data, Materials Science and Engineering A. Vol. 591, (2014) 9-17.

DOI: 10.1016/j.msea.2013.10.069

[14] S. Khoddam, P.D. Hodgson, Post processing of the hot torsion test results using a multi-dimensional modelling approach. Materials and Design. Vol. 31, 5 (2010) 2578-2584.

DOI: 10.1016/j.matdes.2009.11.029

[15] S. Khoddam, P.D. Hodgson, A heuristic model selection scheme for representing hot flow data using the hot torsion test results, Materials and Design. Vol. 31, 4 (2010) 2011-2017.

DOI: 10.1016/j.matdes.2009.10.027

[16] S. Cooreman, D. Lecompte, H. Sol, J. Vantomme, D. Debruyne, Identification of mechanical material behavior through inverse modeling and DIC. Experimental Mechanics. Vol. 48, 4 (2008) 421-433.

DOI: 10.1007/s11340-007-9094-0

[17] T. Sheppard, D.S. Wright, Determination of flow stress: Part 1. Constitutive equation for aluminum alloys at elevated temperatures. Metals Technology. Vol. 6, 1 (1979) 215-223.

DOI: 10.1179/030716979803276264

[18] K. Laber, A. Kawalek, S. Sawicki, H. Dyja et al. Application of torsion test for determination of rheological properties of 5019 aluminium alloy. Key Engineering Materials. Vol. 682. (2016) 356-361.

DOI: 10.4028/www.scientific.net/kem.682.356

[19] A. Hensel, T. Spittel, Calculation of power parameters in metal forming processes. Handbook. Moscow, Metallurgiya, (1982).

[20] S.P. Burkin, R.F. Iskhakov, B.V. Ovsyannikov et al. Torsion testing machine for cylindrical specimens. Patent RF No. 2379649. Applied: 14.04.2008. Published: 20.01.2010. Bulletin No. 2.

[21] M.V. Erpalov, E.A. Kungurov, Examination of hardening curves definition methods in torsion test. Materials Physics and Mechanics. Vol. 38, 1 (2018) 82-89.

DOI: 10.4028/www.scientific.net/ssp.284.598

[22] V.E. Shneyder, A.I. Slutsky, A.S. Shumov, Short course of higher mathematics. Moscow, Vysshaya shkola (1972).

[23] M.V. Erpalov, D.A. Pavlov, Control and experimental data processing in torsion testing with variable acceleration. CIS Iron and Steel Review, (2018).

DOI: 10.17580/cisisr.2018.02.15