TY - JOUR
T1 - Load relaxation of a flat rigid circular indenter on a gel half space
AU - Lin, Yu Yun
AU - Hu, Bao Wun
N1 - Funding Information:
The authors gratefully acknowledge helpful discussions with Dr C.Y. Hui of Cornell University and Dr K.R. Shull of Northwestern University. The authors also thank for the support by National Science Council (93-2211-E-006-069) in Taiwan.
PY - 2006/10/15
Y1 - 2006/10/15
N2 - When a saturated elastic gel is suddenly indented to a fixed displacement, δ, by a flat circular rigid indenter, the solvent cannot escape immediately, this gives rise to a pressure gradient in the solvent and the solvent flows until the pressure in it goes to zero everywhere, and all the stresses are transferred to the elastic network. This load transfer process causes, the indenter load, F, to decrease with time t, with a characteristic time constant, τ, which is given by a2/Dc, where Dc is the cooperative diffusion coefficient and a is the radius of the circular punch. This load relaxation behavior can be used to extract the elastic moduli and the cooperative diffusion coefficient of the gel. A detailed finite element analysis shows the load relaxation as a function of normalized time (t/τ) and how it depends on the shear modulus G and the Poisson's ratio ν of the drained gel. Using this result, we found that the energy release rate available for detaching the punch in a pull-off test can be estimated. It is found that the energy release rate decreases with time for a fixed displacement.
AB - When a saturated elastic gel is suddenly indented to a fixed displacement, δ, by a flat circular rigid indenter, the solvent cannot escape immediately, this gives rise to a pressure gradient in the solvent and the solvent flows until the pressure in it goes to zero everywhere, and all the stresses are transferred to the elastic network. This load transfer process causes, the indenter load, F, to decrease with time t, with a characteristic time constant, τ, which is given by a2/Dc, where Dc is the cooperative diffusion coefficient and a is the radius of the circular punch. This load relaxation behavior can be used to extract the elastic moduli and the cooperative diffusion coefficient of the gel. A detailed finite element analysis shows the load relaxation as a function of normalized time (t/τ) and how it depends on the shear modulus G and the Poisson's ratio ν of the drained gel. Using this result, we found that the energy release rate available for detaching the punch in a pull-off test can be estimated. It is found that the energy release rate decreases with time for a fixed displacement.
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U2 - 10.1016/j.jnoncrysol.2006.07.007
DO - 10.1016/j.jnoncrysol.2006.07.007
M3 - Article
AN - SCOPUS:33748960438
SN - 0022-3093
VL - 352
SP - 4034
EP - 4040
JO - Journal of Non-Crystalline Solids
JF - Journal of Non-Crystalline Solids
IS - 38-39
ER -