Effect of heat treatment on mechanical and tribological properties of aluminum metal matrix composites

Sam, Manu; Radhika, N.; Sai, Katru Pavan

doi:10.1177/0954406220922253

Cited by 16 publications

(6 citation statements)

References 23 publications

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“…These loose debris form a tribo-layer composition (MML). [64][65] Based on the obtained COF results at 55 N, it is confirmed that the values are in accordance with the tribolayer consisting Fe, Al, and oxides, which is produced out of sliding action over the counter plate. Similar observations are reported during the mono-directional dry sliding action of Al/13wt%B 4 C composites against a phenol-based brake pads.…”

Section: Reciprocating Wear Testingsupporting

confidence: 61%

Tribological and mechanical characterization of as-cast and thermal treated Al-9Si/SiC graded composite

Radhika

Sam

Thangamayandi

et al. 2022

Proceedings of the Institution of Mechanical Engineers, Part C:

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Tribology and mechanical properties of thermal treated Al-9Si/10wt%SiC functionally graded composite are compared with as-cast condition. The composite was centrifugally cast as a hollow cylindrical component (Ø(outer) 100 × Ø(inner) 60 × 100 mm), characterized at three wall layers (up to 3, 10, and 18 mm) from the outer periphery. Metallographic analysis on as-cast composite and thermal treated components revealed graded structure and spheroidization of acicular Si, respectively. Elemental mapping and phase formations were confirmed through Energy-dispersive Spectroscopy (EDS) and X-Ray Diffraction (XRD) analysis. Outer layer of thermal treated component revealed maximum improvement in hardness (26%) and tensile strength (15%) compared to as-cast. Brittle mode of failure was featured through fractography. A combination of adhesive and abrasive mechanisms were predominant during reciprocating wear. EDS analysis of wear debris formed at intermediate sliding distance (1250 m) confirmed the oxide layer formation. Thus, the thermal treated composites are developed for automotive engine components vulnerable to wear.

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Section: Reciprocating Wear Testingsupporting

confidence: 61%

Tribological and mechanical characterization of as-cast and thermal treated Al-9Si/SiC graded composite

Radhika

Sam

Thangamayandi

et al. 2022

Proceedings of the Institution of Mechanical Engineers, Part C:

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“…47 The chance between the measured density and theoretical density values display the porosity percentage in produced compositions and may impress the properties the composites. From the density and porosity studies, it can be analyzed that the moderate increase in the theoretical density value is due to the higher density of MgO particles (3.58 g/cm 3 ) than the matrix alloy density (2.96 g/ cm 3 ). Besides, the air entrapment above the melting point and trapped gases inside the agglomerated particulates might be decreased the density and raised the porosity content of the composites.…”

Section: Discussionmentioning

confidence: 99%

“…The composite materials are materials produced to obtain new materials with the desired properties by the combination of various materials. [1][2][3][4] Metal matrix composites (MMCs) are mostly used in space, defense, automotive, and aviation fields, such as space telescopes, platform carrier parts, reflectors, and support parts of space communication devices, due to their lightweight, high specific strength, fatigue resistance, wear resistance and corrosion resistance, and electrical conductivity properties. [5][6][7][8] MMCs are obtained by applying advanced techniques such as stir casting, powder metallurgy, compo-casting, squeeze casting, melting vacuum impregnation, hot pressing, and diffusion welding by adding different reinforcement materials into a metallic phase.…”

Section: Introductionmentioning

confidence: 99%

Development and characterization of Al2024/magnesium oxide/CNTs/ hybrid composites via stir casting method

Kurt

Ergül

Başyiğit

et al. 2022

Proceedings of the Institution of Mechanical Engineers, Part E:

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In this research, the aluminum (Al2024) matrix composites are reinforced with nano magnesium oxide (MgO) and multi-walled carbon nanotubes (MWCNTs). The aim of Al2024 alloy reinforced with MgO and MWCNTs is to reveal the effects of the reinforcement particle ratio on the microstructure and mechanical properties of the hybrid composites, to find the optimum hybrid ratio, and to form a stronger hybrid composite. The composites with the different hybrid ratios are produced via stir casting method. The theoretical and measured densities and porosity content of the composites are studied. The microstructure and fracture surface of the composites are examined by optical microscopy, scanning electron microscopy (SEM), and electron dispersive spectrum (EDS). The hardness, compression, and tensile properties of the composites are studied in this work. Results indicated that the hardness of the aluminum (Al) matrix composites (AMCs) is significantly improved after the reinforcement with MgO and carbon nanotube (CNT), and also heat treatment of T6. The stress–strain curve of the composites is tested by a material testing machine. The maximum tensile and compression strengths are obtained at Al2024-0.2 wt.% (MgO 50% + CNT 50%) the composite as 226 MPa and 684 MPa, respectively .The hardness, compression, and tensile strengths of the hybrid composites are higher than 1.51, 1.39, and 1.31 than that of the base metal. After heat treatment of T6, the maximum harness, compression, and tensile strengths are obtained by 102 HB, 730 MPa, and 277 MPa, respectively, which are 1.82, 1.49, and 1.61 times higher hardness than that that of the base Al2024 alloy. The main strengthening mechanism of nano-MgO particles and MWCNTs-reinforced Al2024/MgO/CNTs composites is observed by the precipitation strengthening mechanism.

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“…The composite with 4 wt.% Ti exhibited the highest weight loss and showed extensive plastic deformation when examined under electron microscope. Sam et al [ 84 ] reported tribo-mechanical studies on an LM25 composite reinforced with TiB 2 , WC, and ZrO 2 and produced by squeeze-casting. The cast composite was solutionized at 520 °C for about 8 h, followed by aging at 165 °C for 4, 6, and 8 h. The wear tests were conducted as per the RSM model with applied load, sliding speed, and distance ranging from 10–50 N, 1–4 m/s, and 500–2500 m, respectively.…”

Section: Mechanical and Tribological Properties Of Al-based Mmcsmentioning

confidence: 99%

Mechanical and Tribological Properties of Aluminum-Based Metal-Matrix Composites

Lakshmikanthan¹,

Angadi²,

Malik

et al. 2022

Materials

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This review article focuses on the aluminum-based metal matrix composites (Al-based MMCs). Studies or investigations of their mechanical and tribological properties performed by researchers worldwide in the past are presented in detail. The processing techniques and applications for Al-based MMCs are also documented here. A brief background on the composite materials, their constituents, and their classification, as well as the different matrix materials and particulates used in Al-based MMCs, can be found in this review. Then, an overview of dual-particle-size reinforced composites, heat treatment of Al alloys, and temper designations used in heat treatment are also included. In addition, the factors influencing the mechanical and wear properties of Al-based MMCs are discussed. The primary objective is that both present and future researchers and investigators will be assisted by the comprehensive knowledge compiled in this article to further explore and work towards the betterment of society in general.

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Effect of heat treatment on mechanical and tribological properties of aluminum metal matrix composites

Cited by 16 publications

References 23 publications

Tribological and mechanical characterization of as-cast and thermal treated Al-9Si/SiC graded composite

Tribological and mechanical characterization of as-cast and thermal treated Al-9Si/SiC graded composite

Development and characterization of Al2024/magnesium oxide/CNTs/ hybrid composites via stir casting method

Mechanical and Tribological Properties of Aluminum-Based Metal-Matrix Composites

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