Abstract
To simulate sheet metal forming processes precisely, an in-house dynamic explicit code was developed to apply a new solid-shell element to sheet metal forming analyses, with a corotational coordinate system utilized to simplify the nonlinearity and to integrate the element with anisotropic constitutive laws. The enhancing parameter of the solid-shell element, implemented to circumvent the volumetric and thickness locking phenomena, was condensed into an explicit form. To avoid the rank deficiency, a modified physical stabilization involving the B-bar method and reconstruction of transverse shear components was adopted. For computational efficiency of the solid-shell element in numerical applications, an adaptive mesh subdivision scheme was developed, with element geometry and contact condition taken as subdivision criteria. To accurately capture the anisotropic behavior of sheet metals, material models with three different anisotropic yield functions were incorporated. Several numerical examples were carried out to validate the accuracy of the proposed element and the efficiency of the adaptive mesh subdivision.
Highlights
Solid-shell elements have been a focus of research on modeling thin-walled structures [1,2]
As compared with shell elements which have been widely used for several decades, solid-shell elements are more suitable for double-sided contact situations such as sheet metal forming due to the existence of nodes at the upper and lower surfaces
To decrease the total node number and to improve the computational efficiency dramatically, an adaptive meshing method for shell elements has been widely used in some well-known finite element analysis software for sheet metal forming such as Dynaform (ETA) [18] and Autoform (AutoForm Engineering GmbH, Pfäffikon, Switzerland) [19]
Summary
Solid-shell elements have been a focus of research on modeling thin-walled structures [1,2]. To decrease the total node number and to improve the computational efficiency dramatically, an adaptive meshing method for shell elements has been widely used in some well-known finite element analysis software for sheet metal forming such as Dynaform (ETA) [18] and Autoform (AutoForm Engineering GmbH, Pfäffikon, Switzerland) [19]. This method has not been extensively studied in the field of solid-shell.
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