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Abstract

A microstructure-based comprehensive finite element model, which incorporated the deformation/fracture of the matrix alloy, fracture of the particle and decohesion of interface, was built to predict the effects of particle size and shape on the plastic deformation and fracture behaviors in particle-reinforced metal matrix composites. The effect of particle size on the yield strength and work hardening rate of the matrix alloy was demonstrated. When the particle diameter is <10 µm, the fracture of the matrix alloy near the interface dominates the failure mechanism of the composite, whereas changed to particle fracture with particle diameter >10 µm. A cohesive zone model was also included in order to predict interfacial failure behavior. It was noted that SiC/Al interface exhibits a high interfacial bonding strength and the interfacial decohesion was caused by crack propagation from the particle to the interface. The simulation results are in good agreement with the experiment tensile test results in the SiCp/6061Al composite.

Keywords

Metal matrix composites finite element method particle size effect interface micromechanics

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References

Lloyd

. Particle reinforced aluminum and magnesium matrix composites. Int Mater 1994; 39: 1–23.

Karmat

Rollett

Hirth

. Plastic deformation in Al-alloy matrix-alumina particulate composites. Scripta Metall Mater 1991; 25: 27–32.

Gao

Huang

Nix

, et al. Mechanism-based strain gradient plasticity−I. Theory. J Mech Phys Solids 1999; 47: 1239–1263.

Afantis

. On the role of gradients in the localization of deformation and fracture. Int J Eng Sci 1992; 30: 1279–1299.

Fleck

Hutchinson

. A reformulation of strain gradient plasticity. J Mech Phys Solids 2001; 49: 2245–2276.

Gao

Huang

. Taylor-based nonlocal theory of plasticity. Int J Solids Struct 2001; 38: 2615–2637.

Siegmund

Huang

, et al. A study of particle size effect and interface fracture in aluminum alloy composite via an extended conventional theory of mechanism-based strain-gradient plasticity. Compos Sci Technol 2005; 65: 1244–1253.

Nan

Clarke

. The influence of particle size and particle fracture on the elastic/plastic deformation of metal matrix composites. Acta Mater 1996; 44: 3801–3811.

Tohgo

Itoh

Shimamura

. A constitutive model of particulate-reinforced composites taking account of particle size effects and damage evolution. Composites 2010; 41: 313–321.

10.

Yan

Geng

. Experimental and numerical studies of the effect of particle size on the deformation behavior of the metal matrix composites. Mater Sci Eng 2007; 448: 315–325.

11.

Chinmaya

Yung

. Molecular dynamics based cohesive zone law for describing Al–SiC interface mechanics. Composites 2011; 42: 355–363.

12.

Shao

Xiao

Wang

, et al. An enhanced FEM model for particle size dependent flow strengthening and interface damage in particle reinforced metal matrix composites. Compos Sci Technol 2011; 71: 39–45.

13.

Perrier

Touchard

Arnault

, et al. Mechanical behavior analysis of the interface in single hemp yarn composites: DIC measurements and FEM calculations. Polym Test 2016; 52: 1–8.

14.

Canal

González

Molina-Aldareguía

, et al. Application of digital image correlation at the microscale in fiber-reinforced composites. Composites 2012; 43: 1630–1638.

15.

Mehdikhani M, Aravand M, Sabuncuoglu B, et al. Digital image correlation and finite element analysis applied to fiber-reinforced composites at the micro-scale. In: Proceedings of the 20th international conference on composite materials, Copenhagen, 19-24 July 2015, pp. 4315–4313. Denmark: Aalborg University.

16.

Mehdikhani

Aravand

Sabuncuoglu

, et al. Full-field strain measurements at the micro-scale in fiber-reinforced composites using digital image correlation. Compos Struct 2016; 140: 192–201.

17.

Qin

Chen

Zhang

, et al. The effect of particle shape on ductility of SiCp reinforced 6061 Al matrix composites. Mater Sci Eng 1999; 272: 363–370.

18.

Yuan

Xue

, et al. Analysis of the stress states and interface damage in a particle reinforced composite based on a micromodel using cohesive elements. Mater Sci Eng 2014; 589: 288–302.

19.

Shi

Cheng

. An eXtended finite element method (XFEM) study on the effect of reinforcing particles on the crack propagation behavior in a metal-matrix composite. Int J Fatigue 2012; 44: 151–156.

20.

Bouhala

Makradi

Belouettar

, et al. Modelling of failure in long fibres reinforced composites by X-FEM and cohesive zone mode. Composites 2013; 55: 352–361.

21.

Meyer

Waas

. FEM predictions of damage in continuous fiber ceramic matrix composites under transverse tension using the crack band method. Acta Mater 2016; 102: 292–303.

22.

Kikuchi

Wada

. Crack growth simulation in heterogeneous material by S-FEM and comparison with experiments. Eng Fract Mech 2016; 167: 239–247.

23.

Biénias

Debski

Surowska

, et al. Analysis of microstructure damage in carbon/epoxy composites using FEM. Comput Mater Sci 2012; 64: 168–172.

24.

Campilho

RDSG

Banea

Chaves

FJP

, et al. eXtended finite element method for fracture characterization of adhesive joints in pure mode I. Comput Mater Sci 2011; 50: 1543–1549.

25.

Stuparu

Constantinescu

Apostol

, et al. A combined cohesive elements – XFEM approach for analyzing crack propagation in bonded joints. J Adhes 2016; 92: 535–552.

26.

Riccio

Ricchiuto

Di Caprio

, et al. Numerical investigation of constitutive material models on bonded joints in scarf repaired composite laminates. Eng Fract Mech 2017; 173: 91–106.

27.

Chen

Qin

, et al. Finite element analysis about effects of particle morphology on mechanical response of composites. Mater Sci Eng 2000; 278: 96–105.

28.

Reinhardt L and Cordes JA. XFEM modeling of mixed-mode cracks in thin aluminum panels. In: SIMULIA customer conference, Providence, US, 24-27 May 2010, pp.1–3 Providence: Dassault SystÕs Simulia corporation.

29.

Coats

Krawitz

. Effect of particle size on thermal residual stress in WC–Co composites. Mater Sci Eng A 2003; 359: 338–342.

30.

Department of Defense of USA. Military handbook: metallic materials and elements for aerospace vehicle structure, Virginia: Author, 2003.

31.

El-Kady

Fathy

. Effect of SiC particle size on the physical and mechanical properties of extruded Al matrix nanocomposites. Mater Des 2014; 54: 348–353.

32.

Zhang

Ouyang Q

Guo

, et al. 3D Microstructure-based finite element modeling of deformation and fracture of SiCp/Al composites. Compos Sci Technol 2016; 123: 1–9.

33.

Lloyd

. Particle reinforced aluminium and magnesium matrix composites. Int Mater Rev 1994; 39: 1–23.

34.

McWilliams

Sano

Yua

, et al. Influence of hot rolling on the deformation behavior of particle reinforced aluminum metal matrix composite. Mater Sci Eng A 2013; 577: 54–63.

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Plastic deformation and fracture behaviors in particle-reinforced aluminum composites: A numerical approach using an enhanced finite element model

Abstract

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