Study of Dynamic Properties on NMMCs Material Using Ansys/LS-DYNA

Dynamic properties of Nanostructured Metal Matrix Composites (NMMCs) materials consisting of nanograined aluminum matrix with nano or micro-sized ceramics particulates are calculated using Ansys/LS-DYNA in this paper. There are three conditions for the mechanics analysis involved the target with 10 vol. % SiC, 30 vol. % SiC and 50 vol. % SiC. It is assumed that the SiC particles uniformly distributed in the matrix. According to the analysis, the strength of NMMCs material is reduced, and the deformation of target is weakened by the vol. % of SiC increasing.

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Effect of Magnesium Addition on Processing the Al-0.8 Mg-0.7 Si/SiCp Metal Matrix Composites

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.787.553 ◽

2015 ◽

Vol 787 ◽

pp. 553-557 ◽

Cited By ~ 3

Author(s):

L. Poovazhagan ◽

K. Rajkumar ◽

P. Saravanamuthukumar ◽

S. Javed Syed Ibrahim ◽

S. Santhosh

Keyword(s):

Surface Tension ◽

Metal Matrix Composites ◽

Molten Metal ◽

Metal Matrix ◽

Microstructural Analysis ◽

Aluminum Matrix ◽

Stir Casting ◽

Matrix Composites ◽

Alloying Element ◽

Sic Particles

Metal matrix composites (MMCs) play a vital role in today’s engineering industries. Stir casting is one of the most inexpensive methods for the production of particulate reinforced metal matrix composites. However there are few problems encountered in stir casting such as the problem of poor wettability of the reinforcement particles in the matrix metal. The reinforcement particles have the tendency to either settle at the bottom of the crucible or they tend to float at the top of molten metal. This is due to the greater surface tension of the molten metal. Various techniques are available to improve the wettability of the ceramic particles in metal matrix which includes Particle treatment, Particle coating and Addition of alloying agent. In this work, Magnesium (Mg) was used as the alloying element to improve the wettability of SiC particles in the Al matrix. Mg is used to reduce the surface tension of molten aluminum (Al) thus promoting proper wetting. To understand the effect of Mg on improving the wettability of SiC in aluminum matrix, different weight percentages of SiC particles reinforced aluminum alloy 6061(AA6061) based MMCs were fabricated in stir casting method by adding Mg as alloying element. The cast specimens were subjected to microstructural analysis, tension tests and hardness tests. Results showed that addition of Mg with SiC in AA6061 matrix significantly improved the wetting between Al and SiC; subsequently MMCs possessed enhanced mechanical properties.

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Wettability in Metal Matrix Composites

Metals ◽

10.3390/met11071034 ◽

2021 ◽

Vol 11 (7) ◽

pp. 1034

Author(s):

Massoud Malaki ◽

Alireza Fadaei Tehrani ◽

Behzad Niroumand ◽

Manoj Gupta

Keyword(s):

Metal Matrix Composites ◽

Metal Matrix ◽

Aluminum Matrix ◽

Interfacial Strength ◽

High Strength ◽

Aluminum Matrix Composites ◽

Matrix Composites ◽

Metal Matrix Nanocomposites ◽

Aerospace Applications ◽

Matrix Nanocomposites

Metal matrix composites (MMCs) have been developed in response to the enormous demand for special industrial materials and structures for automotive and aerospace applications, wherein both high-strength and light weight are simultaneously required. The most common, inexpensive route to fabricate MMCs or metal matrix nanocomposites (MMNCs) is based on casting, wherein reinforcements like nanoceramics, -carbides, -nitrides, elements or carbon allotropes are added to molten metal matrices; however, most of the mentioned reinforcements, especially those with nanosized reinforcing particles, have usually poor wettability with serious drawbacks like particle agglomerations and therefore diminished mechanical strength is almost always expected. Many research efforts have been made to enhance the affinity between the mating surfaces. The aim in this paper is to critically review and comprehensively discuss those approaches/routes commonly employed to boost wetting conditions at reinforcement-matrix interfaces. Particular attention is paid to aluminum matrix composites owing to the interest in lightweight materials and the need to enhance the mechanical properties like strength, wear, or creep resistance. It is believed that effective treatment(s) may enormously affect the wetting and interfacial strength.

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Predictive Computational Model for Damage Behavior of Metal-Matrix Composites Emphasizing the Effect of Particle Size and Volume Fraction

Materials ◽

10.3390/ma14092143 ◽

2021 ◽

Vol 14 (9) ◽

pp. 2143

Author(s):

Shaimaa I. Gad ◽

Mohamed A. Attia ◽

Mohamed A. Hassan ◽

Ahmed G. El-Shafei

Keyword(s):

Finite Element ◽

Metal Matrix Composites ◽

Metal Matrix ◽

Volume Fraction ◽

Particulate Composites ◽

Aluminum Matrix Composites ◽

Matrix Composites ◽

Zone Method ◽

Stress Strain ◽

The Matrix

In this paper, an integrated numerical model is proposed to investigate the effects of particulate size and volume fraction on the deformation, damage, and failure behaviors of particulate-reinforced metal matrix composites (PRMMCs). In the framework of a random microstructure-based finite element modelling, the plastic deformation and ductile cracking of the matrix are, respectively, modelled using Johnson–Cook constitutive relation and Johnson–Cook ductile fracture model. The matrix-particle interface decohesion is simulated by employing the surface-based-cohesive zone method, while the particulate fracture is manipulated by the elastic–brittle cracking model, in which the damage evolution criterion depends on the fracture energy cracking criterion. A 2D nonlinear finite element model was developed using ABAQUS/Explicit commercial program for modelling and analyzing damage mechanisms of silicon carbide reinforced aluminum matrix composites. The predicted results have shown a good agreement with the experimental data in the forms of true stress–strain curves and failure shape. Unlike the existing models, the influence of the volume fraction and size of SiC particles on the deformation, damage mechanism, failure consequences, and stress–strain curve of A359/SiC particulate composites is investigated accounting for the different possible modes of failure simultaneously.

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Interfacial Aspects of Metal Matrix Composites Prepared from Liquid Metals and Aqueous Solutions: A Review

Metals ◽

10.3390/met10101400 ◽

2020 ◽

Vol 10 (10) ◽

pp. 1400

Author(s):

Peter Baumli

Keyword(s):

Aqueous Solutions ◽

Physical Properties ◽

Metal Matrix Composites ◽

Metal Matrix ◽

Liquid Metals ◽

Interfacial Phenomena ◽

Matrix Composites ◽

Good Adhesion ◽

Mechanical And Physical Properties ◽

The Matrix

The paper reviews the preparation of the different metallic nanocomposites. In the preparation of composites, especially in the case of nanocomposites, interfacial phenomena play an important role. This review summarizes the literature on various interfacial phenomena, such as wettability and reactivity in the case of casting techniques and colloidal behavior in the case of electrochemical and electroless methods. The main contribution of this work lies in the evaluation of collected interfacial phenomena and difficulties in the production of metal matrix composites, for both nano-sized and micro-sized reinforcements. This study can guide the composite maker in choosing the best criteria for producing metal matrix composites, which means a real interface with good adhesion between the matrix and the reinforcement. This criterion results in desirable mechanical and physical properties and homogenous dispersion of the reinforcement in the matrix.

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Production of Al Metal Matrix Composites by the Stir-Casting Method

Key Engineering Materials ◽

10.4028/www.scientific.net/kem.592-593.614 ◽

2013 ◽

Vol 592-593 ◽

pp. 614-617 ◽

Cited By ~ 1

Author(s):

Konstantinos Anthymidis ◽

Kostas David ◽

Pavlos Agrianidis ◽

Afroditi Trakali

Keyword(s):

Mechanical Properties ◽

Metal Matrix Composites ◽

Automobile Industry ◽

Metal Matrix ◽

Aluminum Matrix ◽

Stir Casting ◽

Aluminum Matrix Composites ◽

Matrix Composites ◽

Casting Method ◽

Alloy Matrix

It is well known that the addition of ceramic phases in an alloy e.g. aluminum, in form of fibers or particles influences its mechanical properties. This leads to a new generation of materials, which are called metal matrix composites (MMCs). They have found a lot of application during the last twenty-five years due to their low density, high strength and toughness, good fatigue and wear resistance. Aluminum matrix composites reinforced by ceramic particles are well known for their good thermophysical and mechanical properties. As a result, during the last years, there has been a considerable interest in using aluminum metal matrix composites in the automobile industry. Automobile industry use aluminum alloy matrix composites reinforced with SiC or Al2O3 particles for the production of pistons, brake rotors, calipers and liners. However, no reference could be cited in the international literature concerning aluminum reinforced with TiB particles and Fe and Cr, although these composites are very promising for improving the mechanical properties of this metal without significantly alter its corrosion behavior. Several processing techniques have been developed for the production of reinforced aluminum alloys. This paper is concerned with the study of TiB, Fe and Cr reinforced aluminum produced by the stir-casting method.

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Creep Deformation of Particle-Strengthened Metal-Matrix Composites

Journal of Engineering Materials and Technology ◽

10.1115/1.3226440 ◽

1989 ◽

Vol 111 (1) ◽

pp. 99-105 ◽

Cited By ~ 13

Author(s):

Z. G. Zhu ◽

G. J. Weng

Keyword(s):

Constitutive Equation ◽

Metal Matrix Composites ◽

Creep Strain ◽

Creep Deformation ◽

Creep Resistance ◽

Metal Matrix ◽

Order Approximation ◽

Stress Redistribution ◽

Matrix Composites ◽

The Matrix

A multiaxial theory of creep deformation for particle-strengthened metal-matrix composites is derived. This derivation is based on the observation that there are two major sources of creep resistance in such a system. The first, or metallurgical effect, arises from the increased difficulty of dislocation motion in the presence of particles and is accounted for by a size- and concentration dependent constitutive equation for the matrix. The second, or mechanics effect, is due to the continuous transfer of stress from the ductile matrix to the hard particles and the corresponding stress redistribution is also incorporated in the derivation. Both power-law creep and exponential creep in the matrix, each involving the transient as well as the steady state, are considered. The constitutive equations thus derived can provide the development of creep strain of the composite under a combined stress. The multiaxial theory is also simplified to a uniaxial one, whose explicit stress-creep strain-time relations at a given concentration of particles are also given by a first- and second-order approximation. The uniaxial theory is used to predict the creep deformation of an oxide-strengthened cobalt, and the results are in reasonably good agreement with the experiment. Finally, it is demonstrated that a simple metallurgical approach without considering the stress redistribution between the two constituent phases, or a simple mechanics approach without using a modified constitutive equation for the metal matrix, may each underestimate the creep resistance of the composite, and, therefore, it is important that both factors be considered in the formulation of such a theory.

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Transmission Electron Microscope Specimen Preparation of Metal Matrix Composites Using the Focused Ion Beam Miller

Microscopy and Microanalysis ◽

10.1007/s100050010048 ◽

2000 ◽

Vol 6 (5) ◽

pp. 452-462 ◽

Cited By ~ 4

Author(s):

Julie M. Cairney ◽

Robert D. Smith ◽

Paul R. Munroe

Keyword(s):

Electron Microscope ◽

Metal Matrix Composites ◽

Transmission Electron Microscope ◽

Metal Matrix ◽

Focused Ion Beam ◽

Ion Beam ◽

Matrix Composites ◽

Transmission Electron ◽

The Matrix ◽

Ceramic Reinforcement

AbstractTransmission electron microscope samples of two types of metal matrix composites were prepared using both traditional thinning methods and the more novel focused ion beam miller. Electropolishing methods were able to produce, very rapidly, thin foils where the matrix was electron transparent, but the ceramic reinforcement particles remained unthinned. Thus, it was not possible in these foils to study either the matrix-reinforcement interface or the microstructure of the reinforcement particles themselves. In contrast, both phases in the composites prepared using the focused ion beam miller thinned uniformly. The interfaces in these materials were clearly visible and the ceramic reinforcement was electron transparent. However, microstructural artifacts associated with ion beam damage were also observed. The extent of these artifacts and methods of minimizing their effect were dependent on both the materials and the milling conditions used.

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Laser-ultrasonic study of the local porosity of reactive cast aluminum-matrix composites

Industrial laboratory Diagnostics of materials ◽

10.26896/1028-6861-2021-87-5-34-42 ◽

2021 ◽

Vol 87 (5) ◽

pp. 34-42

Author(s):

N. B. Podymova ◽

I. E. Kalashnikov ◽

L. I. Kobeleva

Keyword(s):

Metal Matrix Composites ◽

Metal Matrix ◽

Aluminum Matrix ◽

Amplitude Distribution ◽

Aluminum Matrix Composites ◽

Matrix Composites ◽

Cast Aluminum ◽

Laser Ultrasonic ◽

Local Porosity

One of the most critical manufacturing defects of cast metal-matrix composites is a non-uniform porosity distribution over the composite volume. Unevenness of the distribution leads not only to local softening, but also plays a key role in the evolution of the damage process under the external loads. The goal of the study is to apply a new laser-ultrasonic method to in-situ study of a local porosity in reactive cast aluminum-matrix composites. The proposed method is based on statistical analysis of the amplitude distribution of backscattered broadband pulses of longitudinal ultrasonic waves in the studied materials. Laser excitation and piezoelectric detection of ultrasound were carried out using a laser-ultrasonic transducer. Two series of reactive cast aluminum-matrix composites were analyzed: reinforced by in situ synthesized Al3Ti intermetallic particles in different volume concentrations and by Al3Ti added with synthetic diamond nanoparticles. It is shown that for both series of the composites, the amplitude distribution of backscattered ultrasonic pulses is approximated by the Gaussian probability distribution applicable for statistics of large number of independent random variables. The empirical dependence of the half-width of this distribution on the local porosity in composites of two series is approximated by the same nearly linear function regardless of the size and fraction of reinforcing particles. This function was used to derive the formula for calculation of the local porosity in the studied composites. The developed technique seems to be promising in revealing potentially dangerous domains with high porosity in reactive-cast metal-matrix composites.

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