Standard

Mathematical modeling of martensitic inelasticity and shape memory effects. / Volkov, A. E.; Evard, M. E.; Kurzeneva, L. N.; Likhachev, V. A.; Sakharov, V. Yu; Ushakov, V. V.

в: Technical Physics, Том 41, № 11, 01.11.1996, стр. 1084-1101.

Результаты исследований: Научные публикации в периодических изданияхстатьяРецензирование

Harvard

Volkov, AE, Evard, ME, Kurzeneva, LN, Likhachev, VA, Sakharov, VY & Ushakov, VV 1996, 'Mathematical modeling of martensitic inelasticity and shape memory effects', Technical Physics, Том. 41, № 11, стр. 1084-1101.

APA

Volkov, A. E., Evard, M. E., Kurzeneva, L. N., Likhachev, V. A., Sakharov, V. Y., & Ushakov, V. V. (1996). Mathematical modeling of martensitic inelasticity and shape memory effects. Technical Physics, 41(11), 1084-1101.

Vancouver

Volkov AE, Evard ME, Kurzeneva LN, Likhachev VA, Sakharov VY, Ushakov VV. Mathematical modeling of martensitic inelasticity and shape memory effects. Technical Physics. 1996 Нояб. 1;41(11):1084-1101.

Author

Volkov, A. E. ; Evard, M. E. ; Kurzeneva, L. N. ; Likhachev, V. A. ; Sakharov, V. Yu ; Ushakov, V. V. / Mathematical modeling of martensitic inelasticity and shape memory effects. в: Technical Physics. 1996 ; Том 41, № 11. стр. 1084-1101.

BibTeX

@article{3ea8fb72ae6f4cfe99ae9d63eb83dc31,
title = "Mathematical modeling of martensitic inelasticity and shape memory effects",
abstract = "The concepts of the structure-analytical theory of strength are used to formulate a version of the governing equations for materials undergoing martensitic transformations, taking into account the strains due to elasticity, thermal expansion, and the restructuring of the crystal lattice arising at martensitic transformations occurring under the influence of temperature, stress, and neutron irradiation. Examples of calculations of the strains due to the transformation plasticity, shape memory, and pseudoelasticity are given for model materials with various characters of the statistical scatter of the properties, representing both materials of the titanium nickelide type and iron-manganese alloys. The flow contours of these materials, phase portraits of the thermodynamic cycles of martentsitic energy converters, and the dependence of the strain on the accumulated dose of neutron irradiation are calculated. In most cases the calculated properties are in good qualitative agreement with the available experimental data.",
author = "Volkov, {A. E.} and Evard, {M. E.} and Kurzeneva, {L. N.} and Likhachev, {V. A.} and Sakharov, {V. Yu} and Ushakov, {V. V.}",
year = "1996",
month = nov,
day = "1",
language = "English",
volume = "41",
pages = "1084--1101",
journal = "Technical Physics",
issn = "1063-7842",
publisher = "Pleiades Publishing",
number = "11",

}

RIS

TY - JOUR

T1 - Mathematical modeling of martensitic inelasticity and shape memory effects

AU - Volkov, A. E.

AU - Evard, M. E.

AU - Kurzeneva, L. N.

AU - Likhachev, V. A.

AU - Sakharov, V. Yu

AU - Ushakov, V. V.

PY - 1996/11/1

Y1 - 1996/11/1

N2 - The concepts of the structure-analytical theory of strength are used to formulate a version of the governing equations for materials undergoing martensitic transformations, taking into account the strains due to elasticity, thermal expansion, and the restructuring of the crystal lattice arising at martensitic transformations occurring under the influence of temperature, stress, and neutron irradiation. Examples of calculations of the strains due to the transformation plasticity, shape memory, and pseudoelasticity are given for model materials with various characters of the statistical scatter of the properties, representing both materials of the titanium nickelide type and iron-manganese alloys. The flow contours of these materials, phase portraits of the thermodynamic cycles of martentsitic energy converters, and the dependence of the strain on the accumulated dose of neutron irradiation are calculated. In most cases the calculated properties are in good qualitative agreement with the available experimental data.

AB - The concepts of the structure-analytical theory of strength are used to formulate a version of the governing equations for materials undergoing martensitic transformations, taking into account the strains due to elasticity, thermal expansion, and the restructuring of the crystal lattice arising at martensitic transformations occurring under the influence of temperature, stress, and neutron irradiation. Examples of calculations of the strains due to the transformation plasticity, shape memory, and pseudoelasticity are given for model materials with various characters of the statistical scatter of the properties, representing both materials of the titanium nickelide type and iron-manganese alloys. The flow contours of these materials, phase portraits of the thermodynamic cycles of martentsitic energy converters, and the dependence of the strain on the accumulated dose of neutron irradiation are calculated. In most cases the calculated properties are in good qualitative agreement with the available experimental data.

UR - http://www.scopus.com/inward/record.url?scp=0030522808&partnerID=8YFLogxK

M3 - Article

AN - SCOPUS:0030522808

VL - 41

SP - 1084

EP - 1101

JO - Technical Physics

JF - Technical Physics

SN - 1063-7842

IS - 11

ER -

ID: 43847294