A finite element based method is proposed for calculating stress intensity factors of functionally graded materials (FGMs). We show that the standard domain integral is sufficiently accurate when applied to FGMs; the nonhomogeneous term in the domain integral for nonhomogeneous materials is very small compared to the first term (the standard domain integral). In order to obtain it, the domain integral is evaluated around the crack tip using sufficiently fine mesh. We have estimated the error in neglecting the second term in terms of the radius of the domain for the domain integration, the material properties and their gradients. The advantage of the proposed method is that, besides its accuracy, it does not require the input of material gradients, derivatives of material properties; and existing finite element codes can be used for FGMs without much additional work. The numerical examples show that it is accurate and efficient. Also, a discussion on the fracture of the FGM interlayer structure is given.

Issue Section:
Technical Papers
Topics:
Fracture (Materials), Functionally graded materials, Finite element analysis, Materials properties, Errors, Stress
1.
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3.
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Erdogan
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The Crack Problem for a Nonhomogeneous Plane
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6.
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,
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Cracks in Functionally Graded Materials
,”
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8.
Gu
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R. J.
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b, “
Crack Deflection in Functionally Graded Materials
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T. K.
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10.
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11.
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12.
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295
310
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13.
Parks
D. M.
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A Stiffness Derivative Finite Element Technique for Determination of Crack Tip Stress Intensity Factors
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10
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487
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14.
Parks
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15.
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16.
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Journal of the Mechanics and Physics of Solids
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17.
Shih
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18.
Shih
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19.
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