Abstract
Previous studies introduced a constitutive theory for fiber reinforced hyperelastic materials that allows the fibers to undergo microstructural changes. In this theory, increasing deformation of the matrix leads to increasing stretch of the fibers that causes their gradual dissolution. The dissolving fibers reassemble in the direction of maximum principal stretch of the matrix. The implications of the constitutive theory were first studied for two homogeneous deformations: uniaxial extension along the fibers and simple shear in the direction normal to the fibers. The constitutive theory was then used in treatment of the non-homogeneous deformation of combined axial stretch and twisting. The emphasis was on the determination of the influence of increasing axial stretch and twist on the spatial distribution of fiber dissolution and reassembly within the cylinder and also on the axial force and torque applied to the end faces of the cylinder.
The present work is concerned with another aspect of combined axial stretch and twisting of the cylinder, namely unloading following dissolution and reassembly of some of the fibers. In this case, the cylinder is given an initial twist until there is an inner core of original fiber/matrix material and an outer sheath of remodeled fiber/matrix material. A condition is established that determines the combinations of axial stretch and twist that cause no additional dissolution and reassembly of fibers during unloading. It is also shown that there is a residual axial stretch and twist if the axial force and torque become zero. A numerical example illustrates this for a particular choice of matrix and fiber properties.
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Dedicated to the memory of Donald Carlson, a much appreciated friend and colleague.
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Demirkoparan, H., Pence, T.J. & Wineman, A. Fiber Remodeling During Torsion of a Fiber Reinforced Hyperelastic Cylinder—Unloading Behavior. J Elast 104, 163–185 (2011). https://doi.org/10.1007/s10659-011-9329-2
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DOI: https://doi.org/10.1007/s10659-011-9329-2
Keywords
- Constitutive behavior
- Fiber dissolution and reassembly
- Fiber reinforcement
- Fiber reorientation
- Hyperelastic
- Pure torsion