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http://dx.doi.org/10.11004/kosacs.2013.4.1.001

Numerical Evaluation of Fundamental Finite Element Models in Bar and Beam Structures  

Ryu, Yong-Hee (Department of Civil Engineering, North Carolina State University)
Ju, Bu-Seog (Department of Civil Engineering, North Carolina State University)
Jung, Woo-Young (Department of Civil Engineering, Gangneung-WonJu National University)
Limkatanyu, Suchart (Department of Civil Engineering, Faculty of Engineering, Prince of Songkla University)
Publication Information
Journal of the Korean Society for Advanced Composite Structures / v.4, no.1, 2013 , pp. 1-8 More about this Journal
Abstract
The finite element analysis (FEA) is a numerical technique to find solutions of field problems. A field problem is approximated by differential equations or integral expressions. In a finite element, the field quantity is allowed to have a simple spatial variation in terms of linear or polynomial functions. This paper represents a review and an accuracy-study of the finite element method comparing the FEA results with the exact solution. The exact solutions were calculated by solid mechanics and FEA using matrix stiffness method. For this study, simple bar and cantilever models were considered to evaluate four types of basic elements - constant strain triangle (CST), linear strain triangle (LST), bi-linear-rectangle(Q4),and quadratic-rectangle(Q8). The bar model was subjected to uniaxial loading whereas in case of the cantilever model moment loading was used. In the uniaxial loading case, all basic element results of the displacement and stress in x-direction agreed well with the exact solutions. In the moment loading case, the displacement in y-direction using LST and Q8 elements were acceptable compared to the exact solution, but CST and Q4 elements had to be improved by the mesh refinement.
Keywords
finite element analysis; matrix stiffness method; accuracy-study; constant strain triangle; linear strain triangle; bilinear rectangle; quadratic rectangle;
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