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Pregled bibliografske jedinice broj: 1003703

A New Finite Element for Higher Order Continuum Theory


Frančeski, Joško; Skozrit, Ivica; Lesičar, Tomislav; Sorić, Jurica
A New Finite Element for Higher Order Continuum Theory // Proceedings of the 9th International Congress of Croatian Society of Mechanics / Marović, Pavo ; Krstulović-Opara, Lovre ; Galić, Mirela (ur.).
Split: HDM, 2018. str. 1-6 (predavanje, međunarodna recenzija, cjeloviti rad (in extenso), znanstveni)


Naslov
A New Finite Element for Higher Order Continuum Theory

Autori
Frančeski, Joško ; Skozrit, Ivica ; Lesičar, Tomislav ; Sorić, Jurica

Vrsta, podvrsta i kategorija rada
Radovi u zbornicima skupova, cjeloviti rad (in extenso), znanstveni

Izvornik
Proceedings of the 9th International Congress of Croatian Society of Mechanics / Marović, Pavo ; Krstulović-Opara, Lovre ; Galić, Mirela - Split : HDM, 2018, 1-6

Skup
9th International Congress of Croatian Society of Mechanics

Mjesto i datum
Split, Croatia, 18-22.09.2018

Vrsta sudjelovanja
Predavanje

Vrsta recenzije
Međunarodna recenzija

Ključne riječi
Finite element, C1 continuity, Aifantis theory of gradient elasticity

Sažetak
Heterogeneous microstructure is present in all engineering materials, and an accurate description of microstructural behavior is necessary in order to correctly predict behavior of macrostructure. Classical continuum mechanics uses local approach and is unable to describe the effect of the microstructural size. Using higher – order continuum theory, which includes microstructural parameter in its formulation, enables to properly model microstructure of a given material. This contribution deals with a new finite element which can be used for modeling heterogeneous materials using higher – order theories. The proposed element is two – dimensional, four node triangle, with displacements and first derivations of displacements as degrees of freedom in corner nodes, and displacements as degrees of freedom in node positioned at triangle centroid in order to satisfy full interpolation polynomial of third degree. The finite element is developed using displacement based method [1] in Cartesian coordinate system and yields linear deformations and constant second-order deformations, and satisfies semi C1 continuity. Such element is feasible for implementation of both classical continuum theory as well as higher – order theories. In this contribution, Aifantis theory of gradient elasticity [2], which is a simplification of more general gradient theory developed by Mindlin [3], is implemented in the finite element formulation. The research proposed continues work performed by Lesičar et al. [4], where the C1 finite element in triangular coordinate system has been developed. The benchmark and patch test results, as well as the comparison between previously developed and new element, are reported in numerical examples.

Izvorni jezik
Engleski

Znanstvena područja
Strojarstvo



POVEZANOST RADA


Projekt / tema
120-1201910-1812 - Numeričko modeliranje procesa deformiranja bioloških tkiva (Jurica Sorić, )
120-1201910-1906 - Modeliranje oštećenja i sigurnost konstrukcija (Zdenko Tonković, )
IP-2013-1-2516

Ustanove
Fakultet strojarstva i brodogradnje, Zagreb