TY - JOUR
T1 - An optimum triangular plate element based on DSPM with incomplete quadratic functions and an assumed orthogonality condition
AU - Katili, Andi Makarim
AU - Bletzinger, Kai Uwe
AU - Katili, Irwan
N1 - Publisher Copyright:
© 2024 Elsevier Ltd
PY - 2024/6/1
Y1 - 2024/6/1
N2 - This paper focuses on the formulation and evaluation of a triangular bending plate element, taking into account the shear effect, with 3 DOFs at each corner node. The new element, called DSPM3, is developed from T3γr element by increasing the linear (lower order) rotation function βx and βy with incomplete quadratic functions (higher-order). An assumed orthogonality condition between lower and higher bending energies is applied using a free formulation approach to pass the bending moment patch test. A discrete shear constraint is applied on each element side to provide a constant shear strain along the side and simultaneously avoid the shear-locking problem. The constant transverse shear strain on each side of the element is then projected to the corner nodes using the Discrete Shear Projection Method (DSPM). The values at each node are then averaged to represent the constant shear strain in the element domain. The element application on static and free vibration analysis of isotropic plates demonstrates excellent convergence behaviour, superiority, and precision compared to the T3γr element on which the development was based.
AB - This paper focuses on the formulation and evaluation of a triangular bending plate element, taking into account the shear effect, with 3 DOFs at each corner node. The new element, called DSPM3, is developed from T3γr element by increasing the linear (lower order) rotation function βx and βy with incomplete quadratic functions (higher-order). An assumed orthogonality condition between lower and higher bending energies is applied using a free formulation approach to pass the bending moment patch test. A discrete shear constraint is applied on each element side to provide a constant shear strain along the side and simultaneously avoid the shear-locking problem. The constant transverse shear strain on each side of the element is then projected to the corner nodes using the Discrete Shear Projection Method (DSPM). The values at each node are then averaged to represent the constant shear strain in the element domain. The element application on static and free vibration analysis of isotropic plates demonstrates excellent convergence behaviour, superiority, and precision compared to the T3γr element on which the development was based.
KW - Discrete Shear Projection Method
KW - DSPM3
KW - Free formulation
KW - Independent transverse shear strains
KW - Orthogonality conditions
KW - Reissner-Mindlin plate
UR - http://www.scopus.com/inward/record.url?scp=85185537194&partnerID=8YFLogxK
U2 - 10.1016/j.compstruc.2024.107301
DO - 10.1016/j.compstruc.2024.107301
M3 - Article
AN - SCOPUS:85185537194
SN - 0045-7949
VL - 296
JO - Computers and Structures
JF - Computers and Structures
M1 - 107301
ER -