This work discusses the advantages of micropolar theory in modeling anisotropic composite materials with microstruc-ture. A homogenized constitutive model starting from a representative volume element is proposed in order to find an equivalent continuum. Classical (e.g., Cauchy of Grade 1) continua are not always suitable to accurately approximate the behavior of such composites because no size effects, nor lack of symmetries in strain and stress, can be taken into account. This study focuses on composites made of hexagonal rigid particles which interact among themselves through elastic interfaces, so that the deformation energy of the material is concentrated only at the interfaces. Three particle geometries are investigated such as orthotetragonal, auxetic, and chiral. Novel results have been achieved by presenting the behavior of panels with various material symmetries and subjected to concentrated loads.
Multiscale analysis of anisotropic materials with hexagonal microstructure as micropolar continua / Fantuzzi N.; Trovalusci P.; Luciano R.. - In: INTERNATIONAL JOURNAL FOR MULTISCALE COMPUTATIONAL ENGINEERING. - ISSN 1543-1649. - ELETTRONICO. - 18:2(2020), pp. 265-284. [10.1615/IntJMultCompEng.2020032920]
Multiscale analysis of anisotropic materials with hexagonal microstructure as micropolar continua
Fantuzzi N.
;
2020
Abstract
This work discusses the advantages of micropolar theory in modeling anisotropic composite materials with microstruc-ture. A homogenized constitutive model starting from a representative volume element is proposed in order to find an equivalent continuum. Classical (e.g., Cauchy of Grade 1) continua are not always suitable to accurately approximate the behavior of such composites because no size effects, nor lack of symmetries in strain and stress, can be taken into account. This study focuses on composites made of hexagonal rigid particles which interact among themselves through elastic interfaces, so that the deformation energy of the material is concentrated only at the interfaces. Three particle geometries are investigated such as orthotetragonal, auxetic, and chiral. Novel results have been achieved by presenting the behavior of panels with various material symmetries and subjected to concentrated loads.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
