Orthotropic materials

A particular case of anisotropic material where we can speak of longitudinal and transverse moduli of elasticity are the so-called orthotropic materials; Wood is an example of an orthotropic material, frequently used in construction.

In orthotropic materials the transverse and longitudinal modes of deformation are decoupled. This allows the transverse elasticity modules and longitudinal elasticity modules to be clearly identified. For a general orthotropic material three basic longitudinal elastic moduli (E, E', E*) and three transverse elastic moduli (G,* G', G) can be defined. The latter are defined as:

For a material such as wood the X, Y and Z coordinates above are taken as follows:

• - the X axis is aligned with the longitudinal direction of the fiber.

• - the Y axis is taken perpendicular to the rings of the cross section.

• - the Z axis is taken tangent to the rings of the cross section.

The transverse elasticity modules in these three directions are different for wood and can present large differences in value between them.

Contenido

Los materiales elásticos lineales anisótropos se caracterizan por presentar diferentes valores de las constantes elásticas según la direccionalidad del material. En general, en un material anisotrópico la ley de Hooke,.

donde el tensor de constantes elásticas está dado por:.

en notación de Voigt, que contrae un tensor de orden 4 en una matriz debido a los requerimientos de simetría que impone la conservación del momento angular sobre el tensor de tensiones, .[1]​.

En un material isotrópo el módulo de cizalla se corresponde con el elemento del tensor de constantes elásticas. En materiales con simetría cúbica no simple es posible definir un módulo de cortadura equivalente identificándolo con el elemento de dicho tensor, pero su significado físico cambia. Existen igualmente casos en los que, sin tratarse de un material isótropo ni de simetría cúbica, es posible definir un módulo de cizalla: un caso sería el de los materiales de simetría hexagonal compacta, en los cuales el plano basal tiene simetría cúbica y, por lo tanto, presenta un comportamiento isotrópo dentro del plano.[1]​.

Orthotropic materials

A particular case of anisotropic material where we can speak of longitudinal and transverse moduli of elasticity are the so-called orthotropic materials; Wood is an example of an orthotropic material, frequently used in construction.

In orthotropic materials the transverse and longitudinal modes of deformation are decoupled. This allows the transverse elasticity modules and longitudinal elasticity modules to be clearly identified. For a general orthotropic material three basic longitudinal elastic moduli (E, E', E*) and three transverse elastic moduli (G,* G', G) can be defined. The latter are defined as:

For a material such as wood the X, Y and Z coordinates above are taken as follows:

• - the X axis is aligned with the longitudinal direction of the fiber.

• - the Y axis is taken perpendicular to the rings of the cross section.

• - the Z axis is taken tangent to the rings of the cross section.

The transverse elasticity modules in these three directions are different for wood and can present large differences in value between them.