论文信息 - USE OF GRADED FINITE ELEMENTS TO MODEL THE BEHAVIOR OF NONHOMOGENEOUS MATERIALS

USE OF GRADED FINITE ELEMENTS TO MODEL THE BEHAVIOR OF NONHOMOGENEOUS MATERIALS

A finite element with a spatially varying material property field is formulated and compared to a conventional, homogeneous element for solving boundary value problems involving continuously nonhomogeneous materials. The particular element studied is a two-dimensional plane stress element with linear interpolation and an exponential material property gradient. However, the main results are applicable to other types of elements and property gradients. Exact solutions for a finite rectangular plate subjected to either uniform displacement or traction either perpendicular or parallel to the property gradient are used as the basis for comparison. The results show that for identical meshes with equal number of degrees-of-freedom, the graded elements give more accurate local stress values than conventional elements in some boundary value problems, while in other problems the reverse is true.

Michael H. Santare | John Lambros | M. Santare | J. Lambros

[1] Fazil Erdogan. Fracture mechanics of functionally graded materials , 1995 .

[2] F. Erdogan,et al. The crack problem for a nonhomogeneous plane , 1983 .

[3] Noboru Konda,et al. The mixed mode crack problem in a nonhomogeneous elastic medium , 1994 .

[4] F. Erdogan,et al. The Surface Crack Problem for a Plate With Functionally Graded Properties , 1997 .

[5] Robert J. Asaro,et al. Crack deflection in functionally graded materials , 1997 .

[6] Michael H. Santare,et al. Experimental investigation of the quasi-static fracture of functionally graded materials , 2000 .

[7] Robert J. Asaro,et al. Cracks in functionally graded materials , 1997 .

[8] Robert J. Asaro,et al. A Simplified Method for Calculating the Crack-Tip Field of Functionally Graded Materials Using the Domain Integral , 1999 .

[9] Michael H. Santare,et al. Numerical Calculation of Stress Intensity Factors in Functionally Graded Materials , 2000 .