The influence of void size on the micropolar constitutive properties of model heterogeneous materials

2014

Proc. R. Soc. A.

In planar micropolar elasticity theory, the degree of micropolarity exhibited by a loaded heterogeneous material is quantified by a dimensionless constitutive parameter, the coupling number. Theoretical predictions of this parameter derived by considering the mechanical behaviour of regular, two-dimensional lattices with straight connectors suggest that its value is dependent on the connectivity or topology of the lattice with the coupling number in a square lattice predicted to be notably higher than in its hexagonal counterpart. A second constitutive parameter reflecting the intrinsic lattice size scale, the characteristic length, is also predicted to be topologydependent. In this paper, we compare the behaviour of alternative two-dimensional heterogeneous materials in the context of micropolar elasticity. These materials consist of periodic arrays of circular voids within a polymeric matrix rather than a lattice of straight connectors. Two material variants that differ only in their matrix topology are investigated in particular. Values of the additional micropolar constitutive parameters are obtained for each material from both experimental tests and finite-element analyses. The values determined for these parameters, particularly the coupling number, suggest that their topological dependence differs appreciably from the theoretical predictions of the lattice models.

mentioning

confidence: 99%

On the coupling number and characteristic length of micropolar media of differing topology

McGregor

2014

Proc. R. Soc. A.

“…While the method generally shows equivalent predictive performance for the stress concentration problem when compared to the equivalent finite element based procedure, this performance varies slightly less as one of the additional constitutive parameters, the coupling factor, is altered. This supports the preferential use of the method in quantifying this parameter from experimental data via an inverse iterative approach [21,22]. Using the CV-MPLST in an inverse method the characteristic length and coupling number have been successfully quantified for a model two phase aluminium composite.…”

Section: Discussionmentioning

confidence: 54%

“…Micropolar constitutive properties are difficult to identify experimentally and few properties have been published. The higher order element, set out here, has been used in an iterative inverse procedure to identify the micropolar constitutive properties of model two phase metal composite beam [21] and polymer ring [22] samples. This inverse procedure has produced a simple method to determine constitutive properties.…”

Section: Introductionmentioning

confidence: 99%

A higher order control volume based finite element method to predict the deformation of heterogeneous materials

Beveridge

Nash

2013

Computers & Structures

Self Cite

Materials with obvious internal structure can exhibit behaviour, under loading, that cannot be described by classical elasticity. It is therefore important to develop computational tools incorporating appropriate constitutive theories that can capture their unconventional behaviour. One such theory is micropolar elasticity. This paper presents a linear strain control volume finite element formulation incorporating micropolar elasticity. Verification results from a micropolar element patch test as well as convergence results for a stress concentration problem are included. The element will be shown to pass the patch test and also exhibit accuracy that is at least equivalent to its finite element counterpart.

“…Characteristic length values were determined from the gradient of the stiffness variation while modulus values were identified from the interception of this variation with the stiffness axis. Subsequently, comparable behaviour was observed in slender ring samples with similar heterogeneity that were loaded diametrically [Waseem et al, 2013] and in ring samples in which the topology of the void array constituting the heterogeneity was varied [McGregor & Wheel, 2014].…”

Section: Size Effects In a Two Phase Laminated Beammentioning

confidence: 55%

“…The generalized continuum theories already mentioned predict size effects in which size scale reduction results in an apparent increase in stiffness. Behaviour like this has been observed in both polymeric foams [Lakes, 1983[Lakes, , 1986Anderson & Lakes, 1994] and materials comprised of a two dimensional homogeneous matrix perforated by a regular array of circular voids Waseem et al, 2013;McGregor & Wheel, 2014]. However, there are materials such as cortical bone, for which both increasing and decreasing stiffness with reducing size have been reported [Yang & Lakes, 1982;Choi et al, 1990].…”

Section: Introductionmentioning

confidence: 92%

Paradoxical Size Effects in Composite Laminates and Other Heterogeneous Materials

Advanced Structured Materials

Frame

Riches

2016

Size effects in which there is an apparent increase in stiffness with reducing size scale are forecast in those heterogeneous materials that have constitutive behaviour described by more generalized continuum theories such as couple stress, micropolar or micromorphic elasticity. This short paper considers possibly the simplest heterogeneous material exhibiting such size effects, a two phase composite laminate consisting of alternating layers of stiff and compliant material, and shows that when loaded in bending the nature of the size effect actually depends on the composition of the sample surfaces. The laminate material is apparently capable of exhibiting a diversity of size effects some of which are compatible with the predictions of generalized continuum theories while others are contradictory. Another heterogeneous material consisting of a periodic or regular array of voids within a classically elastic matrix is then considered. Detailed finite element analysis shows that the diversity of size effects encountered in the laminate material may also be observed in this more representative material thereby providing some insight into the contradictory size effects that have sometimes been reported elsewhere in the literature.