Low‐cycle fatigue behavior of a newly developed cast aluminum alloy for automotive applications

Mohammed, S.M.A.K.; Li, D.J.; Zeng, Xiaoqin; Chen, D.L.

doi:10.1111/ffe.13035

Cited by 17 publications

(24 citation statements)

References 59 publications

(121 reference statements)

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“…Three pole figures (i.e., {100}, {110} and {111}) are calculated as shown in Figure 5c. A fairly random texture was observed in the material after heat treatment, being similar to that in the as-cast state [16]. Figure 5 shows the EBSD orientation maps of the alloy in the heat-treated condition.…”

Section: Microstructurementioning

confidence: 69%

“…This is mainly attributed to the spheroidization of both types of intermetallic phases (Mg 2 Si and Al 8 (Fe,Mn) 2 Si) in the heat-treated condition, being similar to the spheroidization phenomenon of cementite (or iron carbide Fe 3 C) in pearlitic steels to form the softer and more ductile spheroidite. The EDS analysis of the as-cast alloy can be found elsewhere [16]. Magnesium content in general is primarily responsible for high strength-to-weight ratio, as Mg combines with other elements to form second-phase particles, e.g., Mg 2 Si participles [29,30].…”

Section: Microstructurementioning

confidence: 99%

“…Typically, Al-Mg-Si alloy contains primary α-Al, magnesium silicide (Mg 2 Si) and AlFeSi phases during solidification [15]. Recently, the authors presented the low-cycle fatigue (LCF) characteristics of cast AlMgSiMnFe alloy [16], but it is unknown how heat treatment would affect the microstructure and fatigue behavior. The non-equilibrium nature of solidification (i.e., high cooling rates, pouring velocities and nucleation) leads to micro-segregation and formation of a wide range of intermetallic phases [15,17].…”

Section: Introductionmentioning

confidence: 99%

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Cyclic Deformation Behavior of A Heat-Treated Die-Cast Al-Mg-Si-Based Aluminum Alloy

Mohammed

Gupta

et al. 2020

Materials

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The purpose of this investigation was to study the low-cycle fatigue (LCF) behavior of a newly developed high-pressure die-cast (HPDC) Al-5.5Mg-2.5Si-0.6Mn-0.2Fe (AlMgSiMnFe) alloy. The effect of heat-treatment in comparison with its as-cast counterpart was also identified. The layered (α-Al + Mg2Si) eutectic structure plus a small amount of Al8(Fe,Mn)2Si phase in the as-cast condition became an in-situ Mg2Si particulate-reinforced aluminum composite with spherical Mg2Si particles uniformly distributed in the α-Al matrix after heat treatment. Due to the spheroidization of intermetallic phases including both Mg2Si and Al8(Fe,Mn)2Si, the ductility and hardening capacity increased while the yield stress (YS) and ultimate tensile strength (UTS) decreased. Portevin–Le Chatelier effect (or serrated flow) was observed in both tensile stress–strain curves and initial hysteresis loops during cyclic deformation because of dynamic strain aging caused by strong dislocation–precipitate interactions. The alloy exhibited cyclic hardening in both as-cast and heat-treated conditions when the applied total strain amplitude was above 0.4%, below which cyclic stabilization was sustained. The heat-treated alloy displayed a larger plastic strain amplitude and a lower stress amplitude at a given total strain amplitude, demonstrating a superior fatigue resistance in the LCF regime. A simple equation based on the stress amplitude of the first and mid-life cycles ((Δσ/2)first, (Δσ/2)mid) was proposed to characterize the degree of cyclic hardening/softening (D): D=±(Δσ/2)mid − (Δσ/2)first(Δσ/2)first, where the positive sign “+” represents cyclic hardening and the negative sign “−“ reflects cyclic softening.

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Section: Microstructurementioning

confidence: 69%

Section: Microstructurementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Cyclic Deformation Behavior of A Heat-Treated Die-Cast Al-Mg-Si-Based Aluminum Alloy

Mohammed

Gupta

et al. 2020

Materials

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“…However, as implied in Figure 6B,C, the difference of hysteresis loops between samples solidified at different cooling rate is not obvious for both Srmodified or unmodified conditions; this may be due to limited plastic deformation under 0.3% total strain amplitude. 22 The spacing between fatigue striations in the sample at high cooling rate was observed to be much smaller than the one at low cooling rate, indicating dislocations encountered more obstacles in samples with smaller SDAS due to more frequent interaction between dislocations and grain boundaries. Three regions can be clearly distinguished on fracture surface of all samples, namely the fatigue-crack-initiation region (FCI), the steady-crack-propagation region (SCP), and fast-fracture region (FF).…”

Section: Cyclic Stress Response Behaviormentioning

confidence: 84%

“…Fatigue striations are productions of a repeated blunting-sharpening process because of dislocation slipping in plastic zone in front of the fatigue crack tip in face-centered cubic materials, and the spacing between fatigue striations represents the rate of crack propagation. 22 The spacing between fatigue striations in the sample at high cooling rate was observed to be much smaller than the one at low cooling rate, indicating dislocations encountered more obstacles in samples with smaller SDAS due to more frequent interaction between dislocations and grain boundaries.…”

Section: Cyclic Stress Response Behaviormentioning

confidence: 84%

Quantitative relationship between microstructure characteristics and fatigue parameters of A319 casting alloy

Liu

et al. 2019

Fatigue Fract Eng Mat Struct

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This paper describes a microstructure-based uniaxial strain-controlled fatigue life prediction model applied to A319 aluminum alloy which is widely used in automobile industry. The materials made with different casting conditions are characterized and quantified in terms of secondary dendrite arm spacing (SDAS), size, and aspect ratio of eutectic Si particles. Uniaxial low cycle fatigue tests have been performed on four groups of A319 alloy under different casting conditions in which cooling rate and Sr addition are variables. It is shown that the effect of various degrees of microstructure on the fatigue life and fatigue behavior is obvious. The first part of the paper is quantitatively characterizing the microstructure of samples to identify the influence of different casting conditions. With regard to mechanic properties, the tensile properties and fatigue behavior of samples are analyzed combining with microstructure. Finally, a microstructure-based Manson-Coffin-Basquin model is proposed to predict fatigue life of Al-Si alloy.

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Effect of Heat Treatment and Loading Path on Non-proportional Fatigue Behavior and Fracture Characteristics of an Al-Si Casting Alloy

Zhou

Liu

et al. 2022

J. of Materi Eng and Perform

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Low‐cycle fatigue behavior of a newly developed cast aluminum alloy for automotive applications

Cited by 17 publications

References 59 publications

Cyclic Deformation Behavior of A Heat-Treated Die-Cast Al-Mg-Si-Based Aluminum Alloy

Cyclic Deformation Behavior of A Heat-Treated Die-Cast Al-Mg-Si-Based Aluminum Alloy

Quantitative relationship between microstructure characteristics and fatigue parameters of A319 casting alloy

Effect of Heat Treatment and Loading Path on Non-proportional Fatigue Behavior and Fracture Characteristics of an Al-Si Casting Alloy

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