Numerical simulation of elastic linear micropolar media based on the pore space length scale assumption

Numerical simulation of elastic linear micropolar media based on the pore space length scale assumption

The 3D micropolar theory numerical simula­tions have been performed on the brittle isotro­pic materials (amorphous glass, brittle rock and two different lightweight concretes) with differ­ent pore sizes using the cylindrical models under uniaxial compressive loading. To pursue this goal, it is assum...

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Bibliographic Details
Date:2008
Main Authors: Jeong, J., Adib-Ramezani, H., Al-Mukhtar, M.
Format: Article
Language:English
Published: Інститут проблем міцності ім. Г.С. Писаренко НАН України 2008
Series:Проблемы прочности
Subjects:
Научно-технический раздел
Online Access:http://dspace.nbuv.gov.ua/handle/123456789/48275
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Journal Title:Digital Library of Periodicals of National Academy of Sciences of Ukraine
Cite this:Numerical simulation of elastic linear micropolar media based on the pore space length scale assumption / J. Jeong, H. Adib-Ramezani, M. Al-Mukhtar // Проблемы прочности. — 2008. — № 4. — С. 43-60. — Бібліогр.: 37 назв. — англ.

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Digital Library of Periodicals of National Academy of Sciences of Ukraine
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Summary:The 3D micropolar theory numerical simula­tions have been performed on the brittle isotro­pic materials (amorphous glass, brittle rock and two different lightweight concretes) with differ­ent pore sizes using the cylindrical models under uniaxial compressive loading. To pursue this goal, it is assumed that first, second and third microrotation constants (a, fi, and y), which appear in the couple stress equilibrium equation, are proportional to the square of aver­ age pore diameter or so called characteristic length. Unexpectedly such an assumption leads to a constant polar ratio and consequently, the polar ratio cannot be accounted for as a mate­ rial constant. The present phenomenon substan­tiates the existence of a redundant material constant for the 3D micropolar media. Accord­ ingly, the micropolar shear constant c is a mterial constant. Different coupling numbers N , with relevant domain are numerically investi­gated to explore the characteristic features of the micropolar shear constant c. According to the results obtained in this paper, the present methodology shows a very good convergence and is consistent with the physically accepted results for the heterogeneous and homogeneous materials including nano- and microscale pores, whereas several unconverted or discontinuous stress fields are found out when using meso­scale pores. The latter disadvantage is believed to be caused by the impact of voids ratio varia­tion under quasistatic loading.

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