Does the shear-lag model apply to random fiber networks?
- 1 October 1997
- journal article
- Published by Springer Nature in Journal of Materials Research
- Vol. 12 (10) , 2725-2732
- https://doi.org/10.1557/jmr.1997.0363
Abstract
The shear-lag type model due to Cox (Br. J. Appl. Phys. 3, 72 (1952) is widely used to calculate the deformation properties of fibrous materials such as short fiber composites and random fiber networks. We compare the shear-lag stress transfer mechanism with numerical simulations at small, linearly elastic strains and conclude that the model does not apply to random fiber networks. Most of the axial stress is transferred directly from fiber to fiber rather than through intermediate shear-loaded segments as assumed in the Cox model. The implications for the elastic modulus and strength of random fiber networks are discussed.Keywords
This publication has 18 references indexed in Scilit:
- A variational approach to the theory of the elastic behaviour of multiphase materialsPublished by Elsevier ,2002
- Measurement of stress concentration in a fiber adjacent to a fiber break in a model compositeComposites Science and Technology, 1995
- Breakdown of two-phase random resistor networksPhysical Review B, 1995
- Microscopic mechanics of fiber networksJournal of Applied Physics, 1994
- Fracture behavior of short-fiber reinforced materialsJournal of Materials Research, 1992
- An “engineering” modification to the shear-lag model as applied to whisker and particulate reinforced compositesScripta Metallurgica et Materialia, 1991
- Statistical models for the fracture of disordered media. North‐Holland, 1990, 353 p., ISBN 0444 88551x (hardbound) US $ 92.25, 0444 885501 (paperback) US $ 41.00Crystal Research and Technology, 1991
- Mechanical properties of discontinuous fiber reinforced thermoplastics. II. Random‐in‐plane fiber orientationPolymer Engineering & Science, 1975
- Percolation and conductivity: A computer study. IPhysical Review B, 1974
- The elasticity and strength of paper and other fibrous materialsBritish Journal of Applied Physics, 1952