The behaviour of aluminium matrix composites under thermal stresses

Dash, K.; Sukumaran, Suvin; Ray, Bankim Chandra

doi:10.1515/secm-2013-0185

Cited by 26 publications

(11 citation statements)

References 206 publications

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“…Whereas, the results from representative volume model delivered thermal conductivity values as 131 W/m⋅K, 126 W/m⋅K, 107 W/m⋅K and 76.9 W/m⋅K for Al‐ZC0, Al‐ZC1, Al‐ZC2, and Al‐ZC3 respectively. The deviation of simulated results from experimental results is ∼1.9 % for Al‐ZC0, ∼5.03 % for Al‐ZC1, ∼3.35 % for Al‐ZC2, and ∼1.75 % for Al‐ZC3.This discrepancy in simulated and experimental values is attributed to the phenomena like percolation present in the experimental specimens owing to inclusions touching each other, are extremely complicated to model while inclusion are in lower volume fraction [13, 14]. The lower coefficient of thermal expansion of ceramic particles than aluminium alloys may be the cause of this behaviour.…”

Section: Resultsmentioning

confidence: 89%

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Prediction of thermal and thermo‐mechanical behavior of nano‐zirconia reinforced aluminium matrix composites

Shekhawat

Agarwal

Singh

et al. 2022

Materialwissenschaft Werkst

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Aluminium bequeaths the same benefits to medical industry as it does to other industries: it is incredibly lightweight and possesses superior strength-to-weight ratio. This study's aim is to investigate the thermal and thermomechanical behaviour of aluminium 6061 alloy reinforced with nano zirconia (0 wt. % to 15 wt. %; in 5 % steps) for medical applications. The effect of nano zirconia loading on thermal conductivity and thermo-mechanical (thermo-gravimetric analysis and dynamic mechanical analysis) have been systematically investigated. The thermal conductivity (128 W/m•K to 79 W/m•K) decreases with the increasing of nano zirconia particles reinforcement. The storage modulus increases with the nano zirconia particles (64 GPa to 172 GPa), whereas loss modulus indicates an increasing trend concerning the increasing temperature. The thermogravimetric analysis and differential thermal analysis result shows that composites' decomposition temperature improved with the weight percentage of nano zirconia particles. Furthermore, representative volume element analysis is conducted to evaluate the thermal conductivity and results indicates good agreement with the experimental results within a deviation of ~5 %. Keywords: Nano-zirconia / thermal properties / aluminium matrix / composites / representative volume element / ceramics Aluminium bietet der medizinischen Industrie die gleichen Vorteile wie anderen Branchen: Es ist unglaublich leicht und besitzt ein hervorragendes Verhältnis von Festigkeit zu Gewicht. Ziel dieser Studie ist es, das thermische und thermomechanische Verhalten der Aluminiumlegierung 6061, verstärkt mit Nano-Zirkonoxid (0 Gew.-% bis 15 Gew.-%; in 5 %-Schritten) für medizinische Anwendungen zu untersuchen. Die Wirkung der Beladung mit Nanozirkonoxid auf die Wärmeleitfähigkeit und die Thermomechanik (thermogravimetrische Analyse und dynamisch-mechanische Analyse) wurde systematisch untersucht. Die Wärmeleitfähigkeit (128 W/m•K bis 79 W/m•K) nimmt mit zunehmender Verstärkung durch Nano-Zirkonoxid-Partikel ab. Das Speichermodul steigt mit dem Anteil an Nano-Zirkonoxid-Partikeln (64 GPa bis 172 GPa), während das Verlustmodul einen steigenden Trend bezüglich der steigenden Temperatur anzeigt. Die Ergebnisse der thermogravimetrischen Analyse und der Differentialthermoanalyse zeigen, dass sich die Zersetzungstemperatur der Verbundwerkstoffe mit dem Gewichtsprozentsatz der

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Section: Resultsmentioning

confidence: 89%

“…The increasing zirconia content in the aluminium 6061 matrix causes thermal conductivity to decrease, [13,14]. The lower coefficient of thermal expansion of ceramic particles than aluminium alloys may be the cause of this behaviour.…”

Section: Thermal Conductivitymentioning

confidence: 99%

Prediction of thermal and thermo‐mechanical behavior of nano‐zirconia reinforced aluminium matrix composites

Shekhawat

Agarwal

Singh

et al. 2022

Materialwissenschaft Werkst

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“…In addition, this also reduces the thermal stress induced during heat treatment of sample. The authors [13,[17][18][19] reported that CTE mismatch is the reason for generation of thermal stresses during the composite fabrication, which can be minimised by controlled sintering temperature and the use of microwave sintering with SiC susceptors [20,21].…”

Section: Primary Processingmentioning

confidence: 99%

“…From this study, fine grain size, increase in tensile strength, increase in elongation and increase in hardness was observed in heat treated alloy. Khusbu Dash et al [13] studied the various thermal properties of aluminium matrix composite (AMC). The author concluded that thermal expansion mismatch and reinforcement volume in composite is the reason for generation of thermal stresses.…”

Section: Introductionmentioning

confidence: 99%

Synthesis and characterisation of magnesium matrix composite reinforced with titanium dioxide nanoparticulates

Elumalai

Ganesh²

2020

Mater. Res. Express

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In the present work, magnesium matrix composite reinforced with titanium dioxide (TiO 2 ) nanoparticulates was synthesized using powder metallurgy (solid-state processing) technique followed by hybrid microwave heat treatment and hot extrusion. Commercially available magnesium particulates of average particle size 60-300 μm and titanium oxide nanoparticulates of average particle size ∼21 nm was used in this study. Extruded samples of pure magnesium and magnesium titanium dioxide (Mg-TiO 2 ) nanocomposites were characterized for their physical, surface and internal microstructure (2D & 3D), elemental composition and mechanical behaviour. The experimental density and porosity of the composite specimens increases gradually with increase in addition of TiO 2 . Scanning electron micrographs (SEM) composite samples revealed that the nano TiO 2 particulates distributed uniformly throughout the matrix with no significant agglomeration. The same was confirmed through 3D internal microstructure also. The elemental composition, crystalline structure was measured using x-ray diffractograms (XRD) which confirm that no foreign elements exists. Further, the microhardness and nanoindentation of composite samples showed an increasing trend with increase in addition of TiO 2 nanoparticles.

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“…Modeling of stresses, defects, and, in consequence, damage of particle-reinforced composite materials induced by thermal loadings have been widely investigated, cf. [ 8 , 9 , 10 , 11 , 12 ]. Various approaches have been used in modeling of these phenomena.…”

Section: Introductionmentioning

confidence: 99%

Discrete Element Framework for Determination of Sintering and Postsintering Residual Stresses of Particle Reinforced Composites

2020

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In this paper, the discrete element method framework is employed to determine and analyze the stresses induced during and after the powder metallurgy process of particle-reinforced composite. Applied mechanical loading and the differences in the thermal expansion coefficients of metal/intermetallic matrix and ceramic reinforcing particles during cooling produce the complex state of stresses in and between the particles, leading to the occurrence of material defects, such as cracks, and in consequence the composite degradation. Therefore, the viscoelastic model of pressure-assisted sintering of a two-phase powder mixture is applied in order to study the stress field of particle assembly of intermetallic-ceramic composite NiAl/Al2O3. The stress evaluation is performed at two levels: macroscopic and microscopic. Macroscopic averaged stress is determined using the homogenization method using the representative volume element. Microscopic stresses are calculated both in the body of particles and in the contact interface (necks) between particles. Obtained results are in line with the cooling mechanism of the two-phase materials.

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The behaviour of aluminium matrix composites under thermal stresses

Cited by 26 publications

References 206 publications

Prediction of thermal and thermo‐mechanical behavior of nano‐zirconia reinforced aluminium matrix composites

Prediction of thermal and thermo‐mechanical behavior of nano‐zirconia reinforced aluminium matrix composites

Synthesis and characterisation of magnesium matrix composite reinforced with titanium dioxide nanoparticulates

Discrete Element Framework for Determination of Sintering and Postsintering Residual Stresses of Particle Reinforced Composites

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