The Effect of Fe-Rich Intermetallics on the Weibull Distribution of Tensile Properties in a Cast Al-5 Pct Si-3 Pct Cu-1 Pct Fe-0.3 Pct Mg Alloy

Zahedi, Hamid; Emamy, M.; Razaghian, A.; Mahta, M.; Campbell, John B.; Tiryakioğlu, Murat

doi:10.1007/s11661-006-9068-3

Cited by 58 publications

(36 citation statements)

References 31 publications

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“…(16)) and therefore decreases the uniform strain to failure. The highest influence of strain hardening parameters is observed for ρ=2; however, the effect is in practice smaller than that, since most realistic values for brittle metals and engineering ceramics give ρ between 5 and 20 (roughly, ρ=3-20 for ceramics, ρ=8-20 for powder metallurgy steels, ρ>30 for wrought steels) [20][21][22][28][29][30][31][32][33][34][35][36]. We now examine more systematically the influence exerted by the five dimensionless parameters governing the problem: n, m, ρ, γ and φ, taking n between 0 and 0.5 and m between 0 and 0.1, the Weibull modulus ρ between 5 and 10 (above 10 the ductile phase influence becomes negligible), and γ between 0 and 1.…”

Section: Resultsmentioning

confidence: 99%

“…Where ρ plays (at fixed φ) a more important role is where elongations are low: there, its influence can be considerable, as shown by the high slope of the iso-deformation lines or by the increase in tensile elongation that is, for example, brought by going from ρ = 7 to ρ = 15 when φ equals 10 12 : the ductility then goes roughly from 1 to 10%. Table 2 gives relevant physical properties of a few brittle metals in which fracture statistics have been reported in the form of two-parameter Weibull statistics (often, three-parameter Weibull statistics are given instead [31,32,35,37,[46][47][48][49][50][51][52][53][54]); note that these are often for deformation at temperatures well below ambient. Let us consider a "typical" medium-strength brittle steel, with E = 210 GPa, σ 0 = 1,500 MPa and L 0 = 1 m, leaving the Weibull parameter ρ as a free-floating variable.…”

Section: Engineering Implicationsmentioning

confidence: 99%

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Tensile elongation of unidirectional or laminated composites combining a brittle reinforcement with a ductile strain and strain-rate hardening matrix

Cohades¹,

Mortensen²

2014

Acta Materialia

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We use the long-wavelength model of Hutchinson and Neale (Hutchinson JW, Neale KW. Acta Metall 1977;25:839) and Ghosh (Ghosh AK. Acta Metall 1977;25:1413) to estimate the uniform tensile elongation of two-phase composites deforming quasistatically according to the equistrain rule of mixtures, in which one phase is ductile while the other fractures progressively according to twoparameter Weibull statistics. We use shear-lag models in the literature to quantify load transfer from the ductile phase to the fractured brittle phase, to estimate the influence of matrix strain and strain-rate hardening, of brittle phase fracture characteristics, and of phase volume and strength ratios, on the composite strain to failure as dictated by the onset of unstable necking. Calculations show that strain and strain-rate hardening of the ductile phase do relatively little to increase the ductility of the composite. Two parameters play a dominant role, namely the brittle phase Weibull modulus and a dimensionless parameter describing load transfer across the two phases. The main practical implication of this analysis is that, to produce reasonably ductile two-phase composites, the best strategy is to aim for small layer thicknesses. IntroductionMany composite materials combine a ductile matrix with a brittle reinforcement: ceramic or carbon fibre reinforced metals fall in this category, as do some laminated metal composites and many other layered materials (such as thin film structures or ceramic-coated metals) [1][2][3][4]. When such composites are strained in tension the brittle phase develops cracks that cut its fibres or layers in two along a plane normal to the applied load; in laminated composites these are known as "tunnel cracks". Final fracture of the material may then happen in one of two ways. One is sudden brittle failure, caused by a propagative localization of internal damage that cuts abruptly the entire specimen in two; many strongly bonded ceramic or carbon fibre reinforced composites fail in this way [5][6][7], as do some particle reinforced composites [8]. Alternatively, internal damage accumulates stochastically throughout the material, in gradual and uncorrelated fashion. The composite is then likely to fail by strain localization, reaching its ultimate tensile strength at a smooth maximum along its stress-strain curve, and sometimes deforming significantly thereafter, while deformation concentrates in a portion of the sample's gauge length. Weakly bonded fibre reinforced composites (e.g., [5]), ceramic particle reinforced metals (e.g., [8,9]), two-phase metal alloys [10] or laminated metal composites [11] can all fail in this way. Strain hardening and strain-rate hardening then both play an important role: even small increases in a ductile material's strain hardening rate, or in its strain-rate sensitivity, can noticeably increase the tensile elongation when it is governed by the onset of strain localization.

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Section: Resultsmentioning

confidence: 99%

Section: Engineering Implicationsmentioning

confidence: 99%

Tensile elongation of unidirectional or laminated composites combining a brittle reinforcement with a ductile strain and strain-rate hardening matrix

Cohades¹,

Mortensen²

2014

Acta Materialia

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“…the presence of structural defects such as porosity, oxide films, macro-and micro-porosity. While yield strength is relatively unaffected by porosity, [25][26][27] both UTS and elongation to fracture decrease with increased amount of porosity. 25,27 Defects generally affect fracture strength, elongation to fracture and fatigue life of cast aluminium alloys 28,29 and cause variations in properties achieved during the casting process.…”

Section: Introductionmentioning

confidence: 97%

“…The mechanical properties are also reduced by the presence of iron-rich intermetallic phases, most importantly α-, β-and π-Fe phases, 7,23,24 and by the structural integrity [25][26][27][28][29][30][31][32] of the component, i.e. the presence of structural defects such as porosity, oxide films, macro-and micro-porosity.…”

Section: Introductionmentioning

confidence: 99%

Simulation of mechanical behaviour of cast aluminium components

Olofsson

2012

International Journal of Cast Metals Research

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A literature review on methods to consider mechanical behaviour of cast aluminium alloys in finite element method (FEM) simulations of cast aluminium components has been performed. The mechanical behaviour is related to several microstructural parameters achieved during the casting process. Three different methods to consider these microstructural parameters are introduced. One method predicts the mechanical behaviour of the component using casting process simulation software. The other two methods implements numerical models for mechanical behaviour of cast aluminium into the FEM simulation. Applications of the methods are shown, including combinations with statistical methods and geometry optimisation methods. The methods are compared, and their different strengths and drawbacks are discussed.

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“…However, Fe-rich particles have different morphologies and sizes depending upon chemical composition and thermal history [2] and different morphologies will affect properties in different ways. The plate-like β-particles in complex 3D structures [3] (Al 5 FeSi) are the most studied and their morphology has been shown to degrade mechanical properties [4,5]. Wang et al [6] states that the β-particles are the most detrimental Fe-rich particles because they act as stress concentrations due to their sharp edges.…”

Section: Introductionmentioning

confidence: 99%

The Effects of Fe-Particles on the Tensile Properties of Al-Si-Cu Alloys

Bjurenstedt

Seifeddine

Jarfors

2016

Metals

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Abstract:The effect of Fe-rich particles has been a topic for discussion in the aluminum casting industry because of the negative impact they exert on the mechanical properties. However, there are still contradictions on the effects of various morphologies of Fe-particles. In this study, microstructural characterization of tensile tested samples has been performed to reveal how unmodified and modified Fe-rich particles impact on the tensile behavior. Analysis of additions of Fe modifiers such as Mn and Cr, showed higher amounts of primary Fe-rich particles (sludge) with increased porosity and, as result, degraded tensile properties. From the fracture analysis of tensile tested hot isostatic pressed (HIPed) samples it could be concluded that the mechanical properties were mainly governed by the Fe-rich particles, which were fracturing through cleavage, not by the porosity.

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The Effect of Fe-Rich Intermetallics on the Weibull Distribution of Tensile Properties in a Cast Al-5 Pct Si-3 Pct Cu-1 Pct Fe-0.3 Pct Mg Alloy

Cited by 58 publications

References 31 publications

Tensile elongation of unidirectional or laminated composites combining a brittle reinforcement with a ductile strain and strain-rate hardening matrix

Tensile elongation of unidirectional or laminated composites combining a brittle reinforcement with a ductile strain and strain-rate hardening matrix

Simulation of mechanical behaviour of cast aluminium components

The Effects of Fe-Particles on the Tensile Properties of Al-Si-Cu Alloys

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