Your search keyword '"Metallic matrix composites"' showing total 240 results

1. Fabrication and Properties of Ni3Si-TiC Composites by In Situ Reaction Sintering.

Author

Niu, Muye, Bao, Shuai, Wu, Jianjie, Zhang, Xinghua, Chen, Hao, and Jin, Yunxue

Subjects

MECHANICAL wear, MATERIAL fatigue, SPECIFIC gravity, SINTERING, FRETTING corrosion, ALLOY fatigue, TRIBOLOGY

Abstract

Ni3Si-based composites with different TiC contents are fabricated by in situ reaction sintering method. The phase composition, microstructure, microhardness, and tribological properties of the composites are studied. The results show that the addition of TiC particles prevents the formation of γ-Ni31Si12 phase, and the composites mainly consist of β1-Ni3Si and TiC phases. The composites have high hardness and relative density, and the values are above 580 HV and 87%, respectively. The friction coefficients are as low as 0.22. The wear rates of the composites are in the order of 10–6 mm3 m−1, which are two orders of magnitude lower than that of Ni3Si alloy. The primary wear mechanism of Ni3Si alloy is oxidation wear and slight abrasive wear, and the composites with TiC addition are oxidation wear and fatigue wear. The incorporation of TiC particles improves the tribological performance of Ni3Si alloy significantly. The composite with 20 wt.% TiC has the optimal tribological property. [ABSTRACT FROM AUTHOR]

Published

2023

2. Friction and Wear Perfomance of WC Reinforced Aluminum Bronze Produced by EBAM Technique.

Author

Moskvichev, E. N., Shamarin, N. N., and Filippov, A. V.

Subjects

*ALUMINUM bronze, *FRICTION, *SLIDING wear, *TUNGSTEN carbide, *METALLIC composites, *MICROSTRUCTURE, *WEAR resistance

Abstract

The paper considers the process of creation of an aluminum bronze-based metal-matrix composite straightened with tungsten carbide particles by the method of electron-beam additive manufacturing. To create composites, a combined printing method with powder and wire material feeding has been used. The microstructure study showed that varying the printing parameters during the process has made possible to achieve a homogeneous distribution of particles of the strengthening phase in the matrix. Carbide particles undergo refining caused by the electron beam. The particles size of obtained composite is 4 times finer compared to the initial powder size. Dry sliding wear studies showed strong wear character and dependence of the friction coefficient on the hardening particles size. [ABSTRACT FROM AUTHOR]

Published

2023

3. Fabrication and Properties of Ni3Si-TiC Composites by In Situ Reaction Sintering

Author

Niu, Muye, Bao, Shuai, Wu, Jianjie, Zhang, Xinghua, Chen, Hao, and Jin, Yunxue

Published

2023

4. Effect of Powder Feed Rate of Plasma-Sprayed Fe–Cr–Mo–B–C Coatings on Microstructure, Tribology and Corrosion in 3.5% NaCl Solution.

Author

Sorour, Ahmad A., Adesina, Akeem Yusuf, Hussein, Mohamed A., and Al-Daajani, Bander F.

Subjects

*TRIBOLOGY, *MICROSTRUCTURE, *COMPOSITE coating, *SURFACE coatings, *PLASMA spraying, *METAL spraying

Abstract

Many process parameters of air plasma spray, such as deposition power, speed, and working distance, significantly influence the resulting microstructural, mechanical, tribological, and corrosion properties of the deposited coatings. Among these parameters, the feed rate plays a vital role in the microstructural evolution and achieved properties. Thus, this study investigates the effect of feed rates (10, 20, and 45 g/min) on the microstructure, tribological, and corrosion of Fe–Cr–Mo–B–C composite coatings fabricated using air plasma spray. The results showed that as the powder feed rate was reduced, the thickness, porosity, and amorphous fraction of the coating decreased due to a higher temperature and velocity of the particles at the point of impact. The lower feed rate increased the formed crystalline phases (Fe, Cr, Mo)23C6 and (Fe, Cr, Mo)7C6, which were embedded in the amorphous matrix. As a result, the hardness increased from about 0.72 GPa (at 45 g/min feed rate) to about 1.0 GPa (at 20 g/min feed rate) and 1.3 GPa (at 10 g/min feed rate). Similarly, the elastic modulus increased from about 40 GPa at 45 g/min feed rate to about 52 and 68 GPa at 20 and 10 g/min feed rates, respectively. Consequently, the sliding wear resistance was improved by up to 27 and 50% at a reduced feeding rate of 20 and 10 g/min, respectively. The principal wear mechanisms were adhesion and oxidation. The electrochemical corrosion resistance in a 3.5% NaCl solution was significantly increased at the lowest feed rate. [ABSTRACT FROM AUTHOR]

Published

2022

5. Tailoring the Mechanical, Tribological and Corrosion Behavior of Fe-Based Metallic Glass Coating Synthesized Using Atmospheric Plasma Spraying.

Author

Pandey, Krishna Kant, Singh, Pushpender, Pathak, Abhishek, Bijalwan, Pavan, Dutta, Monojit, Banerjee, Atanu, and Keshri, Anup Kumar

Subjects

*METAL coating, *PLASMA spraying, *GLASS coatings, *METALLIC glasses, *METALLIC composites, *GAS flow

Abstract

Since the last few decades, plasma spraying has gained its reputation to produce excellent metallic glass coatings because of its high process controllability. Present work studies the effect of various plasma spray parameters on the mechanical, tribological and the corrosion properties of plasma sprayed Fe-based bulk metallic glass (BMG) coating. The in-flight particle velocity and temperature were monitored using the accuraspray diagnostic sensor. Among different sets of parameters, combination of higher power at lower feed rate and higher gas flow provided the maximum density of the coating due to better melting of the particles. XRD analysis showed that high-temperature exposure of the in-flight particles incepted few traces of oxides and carbides in the coating, apart from the intrinsic α- and γ-phases of the Fe-based feedstock. The corrosion resistance of the coatings was highly influenced by the stand-off distance, keeping all the other parameters at higher values. The reason may be attributed to the more number of powder particles melting at higher power and impinging on the substrates at quite lesser time. Current work concludes that the various properties of the Fe-based BMG coating are seriously tailored by different sets of plasma parameters that urge to govern the overall coating properties. [ABSTRACT FROM AUTHOR]

Published

2022

6. CNTs REINFORCED METALLIC MATRIX COMPOSITE: A REVIEW ON CNTs PERCENTAGE, TYPES, MATRIXES, AND PRODUCTION METHODS.

Author

RUBEL, Robiul Islam, ALI, Md. Hasan, AKRAM, Md. Washim, ALDEKHAIL, Abdulkarim, and ALANAZI, Salman

Subjects

PRODUCTION methods, STATISTICS, PERCENTILES, CARBON nanotubes

Abstract

Metallic matrix composites (MMCs) reinforced with carbon nanotubes (CNTs) significantly strengthen the base matrix. CNTs-MMCs are light in weight and very small fractions (vol% or wt%) of well-dispersed CNTs enhance mechanical properties effectively. The research on it is now broadening in different directions. Few parameters dominate the CNTs-MMCs properties that needed to be known before creating new composites. CNTs percentage, types, matrixes, production methods are some of them. A broad detail of the present CNTs-MMCs is helpful for the future. No statistical data is available so far to demonstrate the recent trends of CNTs-MMC. Since CNTs-MMCs are major composite groups applied for many engineering applications, an overview of the present prospects of these composites will be helpful for future research. In this paper, we have strived to gather information about the CNTs-MMCs and presented it through appropriate statistical illustrations to outline various data on this research field. [ABSTRACT FROM AUTHOR]

Published

2022

7. Effect of Equal Channel Angular Pressing on Mechanical and Tribological Properties of Sintered Al-Sn Composites.

Author

Rusin, N. M., Skorentsev, A. L., and Kolubaev, E. A.

Subjects

SOLID lubricants, METALLIC composites, COMPOSITE structures, SLIDING friction, WEAR resistance, POWDER metallurgy, TIN

Abstract

Evolution of structure of two-phase sintered Al-Sn composites during equal channel angular pressing (ECAP) without rotation of the sample between the passes (route A) was studied. The macrostructure with alternating thin Al and Sn interlayers was formed in the flow plane of the samples under the ECAP processing. It was found that the law of the changes in the parameters of the structure of the composites can be described using the geometry of ECAP. The greatest changes in the macrostructural parameters and increase in the strength of the composites were observed during the first two passes. The consequence of the thinning of aluminum interlayers is an increase in the depth of deformation of the subsurface layer and decrease in distance between tin interlayers which are sources of solid lubricant. As a result, the wear intensity of the sintered Al-Sn composites is additionally decreased under dry friction against steel if the sliding direction is perpendicular to the elongated phases interlayers. It was established that the composite containing about 40% Sn has the highest wear resistance. [ABSTRACT FROM AUTHOR]

Published

2020

8. Microstructures and Properties of Graphite Nanoflake/6061Al Matrix Composites Fabricated via Spark Plasma Sintering.

Author

Chen, Guodong, Chang, Hao, Sun, Jian, Wang, Bing, Yang, Lei, Zhang, Jianhua, and Tang, Wenming

Subjects

MICROSTRUCTURE, GRAPHITE, SINTERING, SPECIFIC gravity, BENDING strength

Abstract

Two types of graphite nanoflakes (GNFs), GNFA for 30-100 μm in diameter and less than 100 nm in thickness, and GNFB for 0.5-10 μm in diameter and less than 20 nm in thickness, were used to fabricate GNF/6061Al matrix composites with GNF fractions ranging from 5 to 15 wt.% via spark plasma sintering (SPS) at 610 °C under a load of 35 MPa. The effects of GNF size and content on microstructures and properties of the composites were investigated. The results show that uniform mixing of GNFs in the 6061Al powder was achieved through mechanical and ultrasonic stirring. When the GNFs were well dispersed, the composites were dense. An interfacial zone of 15-18 nm in thickness was formed and composed of two layers, a poorly crystalline layer and an amorphous layer. No Al4C3 was detected in the interfacial zone. The relative densities, bending strengths, thermal conductivities (TCs), and coefficients of thermal expansion (CTEs) (room temperature to 100 °C) of the 10 wt.% GNFA/6061Al matrix composites were 98.5%, 120 MPa, 155 W m−1 K−1 in the X–Y direction and 61 W m−1 K−1 in the Z direction, and 14.2 ppm K−1 in the X–Y direction and 12.1 ppm K−1 in the Z direction, respectively. Those of the 10 wt.% GNFB/6061Al matrix composites were 97.8%, 70 MPa, 110 W m−1 K−1 in the X–Y direction and 90 W m−1 K−1 in the Z direction, and 15.4 ppm K−1 in the X–Y direction and 14.7 ppm K−1 in the Z direction, respectively. The GNFB/6061Al matrix composites showed lower differences of TC and CTE between the X–Y and Z directions. Therefore, the anisotropy of the microstructures and properties of the composites in three dimensions were significantly reduced. [ABSTRACT FROM AUTHOR]

Published

2020

9. Synthesis and Properties of Porous Ti-20 wt.% HA Nanocomposites.

Author

Niespodziana, K.

Subjects

HYDRIDES, NANOCOMPOSITE materials, ALLOYS, ZINC plating, CORROSION resistance

Abstract

In the present study, porous titanium-20 wt.% hydroxyapatite nanocomposites were produced by the combination of mechanical alloying and powder metallurgical process with the addition of titanium hydride particles as the blowing agent. The powder mixture of Ti, HA and spacer particles were milled, pressed and heat-treated to decompose the hydride particles and to sinter into highly porous Ti-HA materials. The resulting microstructures were characterized using x-ray diffraction and scanning electron microscope with energy-dispersive spectrometry. The porosity, compressive strength and corrosion resistance of the porous nanocomposites were investigated. The results show that the compressive strength of porous Ti-HA can be tailored between 210 and 497 MPa by changing the content of blowing agent between 25 and 75%. The increase in the weight ratio of titanium hydride (from 25 to 75%) causes almost a twofold increase in the porosity and decreases the corrosion resistance (by almost two orders of magnitude). The present study has demonstrated that the porous Ti-HA nanocomposites are promising scaffold biomaterials for bone tissue engineering by virtue of their appropriate mechanical and corrosion properties and highly porous structure. [ABSTRACT FROM AUTHOR]

Published

2019

10. Experimental and Numerical Analyses of the Consolidation Process of AA 7075-2 wt.% ZrO2 Powders by Equal Channel Angular Pressing.

Author

Hernández-Martínez, S. E., Cruz-Rivera, J. J., Garay-Reyes, C. G., and Hernández-Rivera, J. L.

Subjects

ALUMINUM alloys, POWDER metallurgy, EXTRUSION process, METALLIC composites, ZIRCONIUM oxide, NUMERICAL analysis

Abstract

AA7075 matrix composite was obtained by mechanical alloying using ZrO2 particles as reinforcement. After that, the powders were cold-compacted into an aluminum tube and consolidated by equal channel angular pressing at 220 °C. The temperature influence was analyzed, and it was found by scanning electron microscopy that this route gave the minimum pore percentage. Besides, it was noticeable that the hardness was wide superior in comparison with the AA 7075 aged bulk alloy. In addition, there was no evidence of any chemical reaction between ZrO2 and alloying elements at the temperature employed. On the other hand, it was numerically and experimentally demonstrated that the more strained regions exhibited a higher relative density values. [ABSTRACT FROM AUTHOR]

Published

2019

11. Influence of sintering temperature on the electrical conductivity of Al2O3/Cu composites compacted by high velocity compaction

Author

LI He, YIN Hai-qing, YI Shan-jie, DilFaraz Khan, CAO Hui-qin, ZHANG Tong, and QU Xuan-hui

Subjects

metallic matrix composites, oxide dispersion strengthening, copper, alumina, high velocity compaction, sintering temperature, electrical conductivity, Mining engineering. Metallurgy, TN1-997, Environmental engineering, TA170-171

Abstract

Oxide dispersion strengthening(ODS) copper has the characteristics of both high strength and high conductivity. The porosity is an important factor influencing the electrical conductivity. 0.9Al2O3/Cu powder was compacted by a high velocity compaction(HVC) technique. The influence of impact velocity on the green density of Al2O3 dispersion strengthening copper was studied,and the green density of 8.46 g·cm-3 was got at the impact velocity of 9.4 m·s-1. The dependence of the electrical conductivity on sintering temperature was investigated. The results from sintering steps showed that the higher the sintering temperature was,the higher the electrical conductivity was at the same green density level. Fracture surface and SEM observations indicated that the samples were inadequately sintered at the sintering temperature of 950℃,with particle boundaries and some pores being visible obviously. When the sintering temperature rose up to 1080℃,the pores tended to spheroidize,the particle boundaries disappeared,and the dimples appeared on the fracture surface,showing a typical plastic fracture characteristic. The electrical conductivity of the sintered compacts was measured to be 71.3% IACS.

Published

2015

12. Fabrication and Mechanical Properties of In Situ Synthesized Ti2AlN/TiAl Composite.

Author

Wang, Daqun, Sun, Dongli, Han, Xiuli, Wang, Qing, Zhang, Ningbo, and Xu, Feixing

Subjects

TITANIUM-aluminum alloys, MECHANICAL properties of metals, METALLIC composites, MICROSTRUCTURE, POWDER metallurgy, CRACK propagation (Fracture mechanics), STRESS-strain curves, BENDING stresses

Abstract

TiAl matrix composites reinforced with Ti2AlN were fabricated by in situ reactive method of powder metallurgy. Microstructures, bending properties at room temperature and compressive properties at elevated temperatures were investigated in contrast with those of TiAl alloy. The results reveal that the microstructure of TiAl matrix is significantly refined due to the synthesis of Ti2AlN. 15 vol.%Ti2AlN/TiAl exhibits excellent bending properties at room temperature, with bending strength of 753 MPa and fracture strain of 0.74%, which are 24.3 and 19.7% higher than those of TiAl alloy. The compressive strength of Ti2AlN/TiAl is markedly improved in comparison to that of TiAl alloy at elevated temperatures. Noticeably, the compressive strength of 15 and 35 vol.%Ti2AlN/TiAl increases by 67.4 and 58.7% at 1000 °C, respectively. The remarkable enhancement of mechanical performance is mainly due to the noteworthy refinement of TiAl matrix and the efficient obstruction of Ti2AlN particles to crack propagation, as well as the effective load-carrying role of Ti2AlN with high elastic modulus. [ABSTRACT FROM AUTHOR]

Published

2018

13. Composites Strengthened with Graphene Platelets and Formed in Semisolid State Based on α and α/β MgLiAl Alloys.

Author

Dutkiewicz, Jan, Rogal, Łukasz, Fima, Przemyslaw, and Ozga, Piotr

Subjects

MAGNESIUM-lithium alloys, METALLIC composites, GRAPHENE, SEMISOLID metal processing, AGGLOMERATES (Chemistry)

Abstract

MgLiAl base composites strengthened with graphene platelets were prepared by semisolid processing of ball-milled alloy chips with 2% of graphene platelets. Composites strengthened with graphene platelets show higher hardness and yield stress than the cast alloys, i.e., 160 MPa as compared to 90 MPa for as-cast alloy MgLi9Al1.5. Mechanical properties for MgLiAl-based composites were similar or higher than for composites based on conventional AZ91 or WE43 alloys. The strengthening however was not only due to the presence of graphene, but also phases resulting from the reaction between carbon and lithium, i.e., Li2C2 carbide. Graphene platelets were located at globules boundaries resulting from semisolid processing for all investigated composites. Graphene platelets were in agglomerates forming continuous layers at grain boundaries in the composite based on the alloy MgLi4.5Al1.5. The shape of agglomerates was more complex and wavy in the composite based on MgLi9Al1.5 alloy most probably due to lithium-graphene reaction. Electron diffraction from the two-phase region α + β in MgLi9Al1.5 indicated that [001]α and [110]β directions are rotated about 4° from the ideal relationship [001] hex || [110] bcc phases. It showed higher lattice rotation than in earlier studies what is most probably caused by lattice slip and rotation during semisolid pressing causing substantial deformation particularly within the β phase. Raman spectroscopy studies confirmed the presence of graphene platelets within agglomerates and in addition the presence mainly of Li2C2 carbides in composites based on MgLi4.5Al1.5 and Mg9Li1.5Al alloys. From the character of Raman spectra refinement of graphene platelets was found in comparison with their initial size. The graphene areas without carbides contain graphene nanoplatelets with lateral dimension close to initial graphene sample. Electron diffraction allowed to confirm the presence of Li2C2 carbide at the surface of agglomerates found from Raman spectroscopy results. [ABSTRACT FROM AUTHOR]

Published

2018

14. Influence of Temperature of Accumulative Roll Bonding on the Mechanical Properties of AA5083-1% Al2O3 Composite.

Author

Farhadipour, P., Sedighi, M., and Heydari Vini, M.

Subjects

*METALLIC composites, *HEAT treatment of metals, *MICROHARDNESS testing

Abstract

The influence of rolling temperature on the microstructure and mechanical properties of AA5083-1% Al2O3 composites has been analyzed in this study. The alloy was deformed with the method of warm accumulative roll bonding in various temperature conditions, i.e., at ambient temperature, 200°C, and 300°C up to 5 cycles (휀 = 4). The structure has been studied with scanning electron microscopy (SEM), and mechanical properties of the deformed material have been measured by tensile test as well as Vickers microhardness test. It was established that the rolling temperature had a significant effect on the mechanical properties and microstructure of the manufactured MMCs. High strength, low elongation, and high average Vickers microhardness were obtained for the material processed at lower temperatures, i.e., at ambient temperature. Whereas, by increasing the rolling temperature to 300°C, the toughness and elongation ranges were greater than for the MMCs manufactured at lower temperatures. [ABSTRACT FROM AUTHOR]

Published

2018

15. The effect of Ni and Zr additions on hardness, elastic modulus and wear performance of Al-SiCp composite

Author

Lattanzi, Lucia, Etienne, Andrea, Li, Ziyu, Chandrashekar, Gnanesh T., Gonapati, Santosh R., Awe, Samuel A., Jarfors, Anders E.W., Lattanzi, Lucia, Etienne, Andrea, Li, Ziyu, Chandrashekar, Gnanesh T., Gonapati, Santosh R., Awe, Samuel A., and Jarfors, Anders E.W.

Abstract

The strive for lightweight in the automotive industry points to aluminium metal matrix composites as substitutes of cast iron in brake discs. The wear performance of the material is critical, besides suitable mechanical resistance and thermal properties. The present study investigated the wear behaviour of Al-Si alloys reinforced with silicon carbide particles. The matrix alloy was added with nickel and zirconium, and nanoindentation was performed to determine intermetallic phases' hardness and elastic modulus. The addition of 20 wt% carbides determined an elastic modulus 35–40 % higher than the matrix alloys. Wear rate was in the 2–8 * 10-5 mm3/N * m range for all materials. The tribo-layer had a critical role in the wear performance, as the coefficient of friction decreased during wear.

Published

2022

16. The Effects of Hydroxyapatite Addition on the Properties of the Mechanically Alloyed and Sintered Mg-RE-Zr Alloy.

Author

Kowalski, K., Nowak, M., Jakubowicz, J., and Jurczyk, M.

Subjects

MAGNESIUM alloys, HYDROXYAPATITE, SINTER (Metallurgy), CORROSION in alloys, MECHANICAL behavior of materials, MICROSTRUCTURE, BIODEGRADABLE materials, ATOMIC force microscopy

Abstract

This paper discusses the influence of the chemical composition on the microstructure, mechanical and corrosion properties of mechanically alloyed and sintered (Mg-4Y-5.5Dy-0.5Zr)- x wt.% HA composites. Mechanical alloying for 25 h of the Mg-4Y-5.5Dy-0.5Zr composition, followed by sintering under argon at 550 °C for 2 h, led to the formation of a bulk alloy with an ultrafine grained microstructure. With the increase of the hydroxyapatite content in the (Mg-4Y-5.5Dy-0.5Zr)- x wt.% HA composite, a reduction of the grain sizes of the bulk material was noticeable. In the case of the bulk (Mg-4Y-5.5Dy-0.5Zr)-10 wt.% HA composite, the grain sizes of approx. 60 nm have been recorded by atomic force microscopy. The final microstructure of the synthesized composites strongly influenced the mechanical and corrosion properties. The Mg-4Y-5.5Dy-0.5Zr alloy was characterized by higher average values of Young's modulus (36.6 GPa). In the case of the (Mg-4Y-5.5Dy-0.5Zr)-5 wt.% HA scaffolds with the porosity of 48%, the Young's modulus was equal to 7.1 GPa. The (Mg-4Y-5.5Dy-0.5Zr)-10 wt.% HA composite was more corrosion resistant ( I = 5.849 × 10 A cm, E = −1.565 V versus SCE) than Mg-4Y-5.5Dy-0.5Zr alloy ( I = 4.838 × 10 A cm, E = −1.555 V versus SCE). The influence of hydrofluoric acid treatment on the corrosion behavior of the (Mg-4Y-5.5Dy-0.5Zr)-5 wt.% HA composite was also investigated. The electrochemical test showed that the corrosion resistance of fluoride-treated specimens was higher, compared with the untreated samples in the Ringer's solution. In conclusion, fluoride-treated (Mg-4Y-5.5Dy-0.5Zr)-HA composites are biodegradable materials with adjustable mechanical and corrosive properties. [ABSTRACT FROM AUTHOR]

Published

2016

17. Preparation and Wear Resistance of Aluminum Composites Reinforced with In Situ Formed TiO/AlO.

Author

Qin, Q., Huang, B., Li, W., and Zeng, Z.

Subjects

ALUMINUM composites, WEAR resistance, TRIBOLOGICAL ceramics, MECHANICAL wear, MECHANICAL abrasion

Abstract

An in situ TiO/AlO-reinforced Al composite is successfully prepared using a powder metallurgy route by the reaction of TiCO and Al powder. The TiCO powder is produced by carrying out a carbothermic reduction of titanium dioxide at 1000 °C. XRD results show that the final product is composed of Al, TiO, AlO, and AlTi. Morphology examination of the composite reveals the presence of bigger blocks of TiO and fine particles of AlO and the volume fraction of reinforcement is found to range between 18 and 55%. As the volume fraction of the reinforced materials approaches 50%, the particles start to agglomerate. Dry sliding wear tests conducted using a conventional pin-on-disk testing machine show that the wear resistance of the composite is higher than that of the pure aluminum ingot. The wear rate of the composite increases almost linearly with the increase in the wear distance. The sliding wear test shows that as the volume fraction of the reinforced phase increases, the coefficient of friction decreases. The wear mechanism is also discussed. [ABSTRACT FROM AUTHOR]

Published

2016

18. Influence of fabric architecture on compressive and failure mechanism of Cf/Mg composite fabricated by LSEVI.

Author

Ju, Luyan, Qi, Lehua, Wei, Xinliang, Li, Hejun, and Zhou, Jiming

Subjects

*CALIFORNIUM, *MAGNESIUM compounds, *COMPOSITE materials, *COMPRESSION loads, *COMPRESSIVE strength

Abstract

Four kinds of C f /Mg composites with different fabric architectures were fabricated by liquid–solid extrusion following vacuum infiltration (LSEVI) technique. The influence of fabric architecture on compressive properties of C f /Mg composites was investigated, and the microstructure and failure surfaces were examined by SEM. The results showed that C f /Mg composites were anisotropic material and the fabric architecture had great influence on their compressive performance. Moreover, fabric crimp had a negative influence on compressive properties of C f /Mg composite. The composite with non-woven carbon fabric perform had the highest compressive strength ( XY direction). Compared with 3 K plain-woven carbon cloth composite whose fiber bundles had 3000 monofilaments, 1 K plain-woven carbon cloth composite had better compressive properties. The analysis of failure surface indicated that the failure modes of C f /Mg composites were mainly shear failure and delamination failure. [ABSTRACT FROM AUTHOR]

Published

2016

19. ADVANCED COMPOSITE MATERIAL USED IN SCRAMJET ENGINE

Author

Tumbde Nishit, Prof. Nitin Ulmek, Tumbde Nishit, and Prof. Nitin Ulmek

Abstract

Propelled flying machine motors require propelled materials to meet their objectives of execution, push to-weight proportion, and eco-friendliness. There are three primary materials-related drivers for the improvement of cutting edge motors.This paper chiefly centers around a concise audit of the present status of composite materials, for example, Polymer lattice composites, Metal network composites and Ceramic Matrix Composites (CMCs).

Published

2021

20. Hierarchical Heterostructured FeCr–(Mg–Mg2Ni) Composite with 3D Interconnected and Lamellar Structures Synthesized by Liquid Metal Dealloying

Author

Jeong, Y. B., Wada, T., Joo, S. -H., Park, J. -M., Kim, H. S., Okulov, I. V., Kim, K. B., Kato, H., Jeong, Y. B., Wada, T., Joo, S. -H., Park, J. -M., Kim, H. S., Okulov, I. V., Kim, K. B., and Kato, H.

Abstract

Liquid metal dealloying (LMD) has recently attracted significant attention. Because the LMD process enables the production of three-dimensional (3D) interconnected non-noble metallic materials. In addition, the metallic melt medium is useful for the development of heterostructure (HS) metal–metal composites. However, the solidified liquid metal phase (low melting point metals such as Mg, Bi, Sn, or Cu) has a much lower strength than the developed ligament phase (e.g., Fe, FeCr, Ti, etc.). In this study, the soft Mg phase was strengthened by adding alloying element of Ni. A eutectic composition of Mg–10 at.% Ni melt leads to the formation of fine eutectic structure of (Mg–Mg2Ni) within 3D interconnected morphology. This hierarchical heterostructured composite consisted of FeCr ligament and Mg–Mg2Ni lamellar, and a high yield strength of 280 MPa and a noticeable elongation (1.5%) were achieved. The complex 3D morphology of ligament and lamellar geometrically constraint each other, and it prevents the early fracture of brittle Mg–Mg2Ni lamellar phase. The alloy design for the LMD melt gives insights for hierarchical HS materials with outstanding mechanical properties for structural applications. © 2021 The Authors.

Published

2021

21. Corrosion Resistance of Al–CNT Metal Matrix Composites

Author

Popov, V. V., Pismenny, A., Larionovsky, N., Lapteva, A., Safranchik, D., Popov, V. V., Pismenny, A., Larionovsky, N., Lapteva, A., and Safranchik, D.

Abstract

The design of aluminium–graphite metal matrix composites (MMCs) with advanced mechanical properties and high corrosion resistance is in demand for aerospace, transportation, and industrial applications. Breakthroughs in this field are limited due to the tendency of aluminium– graphite MMCs to corrode. In the present research, aluminium‐based MMCs were produced by a relatively novel combined two‐staged method. Multiwall carbon nanotubes (MWCNTs) were added into molten Al1070 and processed by high‐pressure die casting followed by cyclic extrusion. For the composites produced by this method, it was previously demonstrated that mechanical properties are improved in comparison with pure aluminium alloys. In the current study, the manufactured Al–MWCNT composites were investigated by electrochemical tests (such as open circuit potential), potentiodynamic tests, linear polarization tests, and electrochemical impedance spectra to understand the corrosion resistance of the obtained composite material. The experimental testing of the corrosion resistance of Al–MWCNT MMCs showed that due to the advantages of the fabrication method, the addition of CNTs to aluminium does not cause a radical decrease of corrosion resistance. © 2021 by the authors. Licensee MDPI, Basel, Switzerland.

Published

2021

22. Corrosion Resistance of Al–CNT Metal Matrix Composites

Author

Vladimir V. Popov, Natalya Larionovsky, Alla Pismenny, A. V. Lapteva, and Daniel Safranchik

Subjects

Technology, GRAPHITE, EXPERIMENTAL TESTING, ELECTROCHEMICAL CORROSION, 02 engineering and technology, 01 natural sciences, law.invention, ALUMINUM CORROSION, law, Aluminium, General Materials Science, PRESSURE DIE CASTING, Composite material, ELECTROCHEMICAL IMPEDANCE SPECTRA, 010302 applied physics, Microscopy, QC120-168.85, Communication, 021001 nanoscience & nanotechnology, Microstructure, Engineering (General). Civil engineering (General), Die casting, POTENTIODYNAMIC TESTS, Extrusion, MULTIWALLED CARBON NANOTUBES (MWCN), Electrical engineering. Electronics. Nuclear engineering, TA1-2040, 0210 nano-technology, ALUMINIUM METAL MATRIX COMPOSITES, MECHANICAL PROPERTIES, Materials science, Fabrication, CNT, LINEAR POLARIZATION, chemistry.chemical_element, Carbon nanotube, CARBON NANOTUBES, Corrosion, OPEN CIRCUIT POTENTIAL, ELECTROCHEMICAL TEST, 0103 physical sciences, Pitting corrosion, METALLIC MATRIX COMPOSITES, corrosion, carbon nanotubes, QH201-278.5, FABRICATION METHOD, CORROSION, TK1-9971, CORROSION RESISTANCE, chemistry, Descriptive and experimental mechanics, aluminium metal matrix composites

Abstract

The design of aluminium–graphite metal matrix composites (MMCs) with advanced mechanical properties and high corrosion resistance is in demand for aerospace, transportation, and industrial applications. Breakthroughs in this field are limited due to the tendency of aluminium– graphite MMCs to corrode. In the present research, aluminium‐based MMCs were produced by a relatively novel combined two‐staged method. Multiwall carbon nanotubes (MWCNTs) were added into molten Al1070 and processed by high‐pressure die casting followed by cyclic extrusion. For the composites produced by this method, it was previously demonstrated that mechanical properties are improved in comparison with pure aluminium alloys. In the current study, the manufactured Al–MWCNT composites were investigated by electrochemical tests (such as open circuit potential), potentiodynamic tests, linear polarization tests, and electrochemical impedance spectra to understand the corrosion resistance of the obtained composite material. The experimental testing of the corrosion resistance of Al–MWCNT MMCs showed that due to the advantages of the fabrication method, the addition of CNTs to aluminium does not cause a radical decrease of corrosion resistance. © 2021 by the authors. Licensee MDPI, Basel, Switzerland. Acknowledgments: This article is based upon work from COST Action CA15102 “CRM‐EX‐ TREME—Solutions for Critical Raw Materials under Extreme Conditions” and COST Innovators’ Grant IG15102 “ITHACA—Innovative and sustainable TecHnologies for reducing critical raw mA‐ terials dependence for Cleaner transportation Applications” supported by COST (European Coop‐ eration in Science and Technology) www.cost.eu.

Published

2021

23. Friction stir welding/processing of metals and alloys: A comprehensive review on microstructural evolution

Author

Philip J. Withers, Amir Mostafaei, Rustam Kaibyshev, Adrian P. Gerlich, Joseph D. Robson, Aude Simar, Gürel Çam, Farzad Khodabakhshi, Alexis Deschamps, Akbar Heidarzadeh, David P. Field, Sergey Mironov, Azarbaijan Shahid Madani University, Belgorod National Research University, Iskenderun Technical University, Université Catholique de Louvain = Catholic University of Louvain (UCL), University of Waterloo [Waterloo], University of Tehran, Illinois Institute of Technology (IIT), Washington State University (WSU), University of Manchester [Manchester], Science et Ingénierie des Matériaux et Procédés (SIMaP), Institut de Chimie du CNRS (INC)-Centre National de la Recherche Scientifique (CNRS)-Université Grenoble Alpes (UGA)-Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP ), Université Grenoble Alpes (UGA), Mühendislik ve Doğa Bilimleri Fakültesi -- Makina Mühendisliği Bölümü, Çam, Gürel, Azarbaijan Shahid Madani University - Department of Materials Engineering, Belgorod National Research University - n/a, Iskenderun Technical University - Department of Mechanical Engineering, UCL - SST/IMMC/IMAP - Materials and process engineering, University of Waterloo - Department of Mechanical and Mechatronics Engineering, University of Tehran - School of Metallurgy and Materials Engineering, Illinois Institute of Technology - Department of Mechanical, Materials and Aerospace Engineering, Washington State University - School of Mechanical and Materials Engineering, The University of Manchester - Department of Materials, Université Grenoble-Alpes - CNRS,Grenoble INP, SIMaP, and The University of Manchester - Henry Royce Institute, Department of Materials

Subjects

Friction stir processing, Friction stir welding, Welded Joints, Intermetallic, Stacking fault energy, 02 engineering and technology, Welding, 01 natural sciences, law.invention, Intermetallic compound layer, Bobbins, Recovery, law, Dissimilar material joints, General Materials Science, Microstructure, ComputingMilieux_MISCELLANEOUS, 010302 applied physics, Multidisciplinary, Austenitic stainless-steel, Strain rate, High strain rates, Textures, Metals and alloys, [CHIM.MATE]Chemical Sciences/Material chemistry, 021001 nanoscience & nanotechnology, In-situ nanocomposite, Metallurgy, Aluminum-matrix composites, Joint performance, 0210 nano-technology, Materials science, Friction, Welds, Materials Science, Tool rotational speed, Context (language use), Processing, Research laboratories, Friction stir welding(FSW), Metallic matrix composites, Az31 magnesium alloy, 0103 physical sciences, Processing parameters, Friction stir welding/processing, High-entropy alloy, Welded dissimilar joints, Joint (geology), Microstructural evolution, Precipitation (chemistry), Continuous dynamic recrystallization, Microstructural control, Recrystallization, Al-mg alloy, Metal matrix composites

Abstract

The unique combination of very large strains, high temperatures and high strain rates inherent to friction stir welding (FSW) and friction stir processing (FSP) and their dependency on the processing parameters provides an opportunity to tailor the microstructure, and hence the performance of welds and surfaces to an extent not possible with fusion processes. While a great deal of attention has previously been focused on the FSW parameters and their effect on weld quality and joint performance, here the focus is on developing a comprehensive understanding of the fundamentals of the microstructural evolution during FSW/P. Through a consideration of the mechanisms underlying the development of grain structures and textures, phases, phase transformations and precipitation, microstructural control across a very wide range of similar and dissimilar material joints is examined. In particular, when considering the joining of dissimilar metals and alloys, special attention is focused on the control and dispersion of deleterious intermetallic compounds. Similarly, we consider how FSP can be used to locally refine the microstructure as well as provide an opportunity to form metal matrix composites (MMCs) for near surface reinforcement. Finally, the current gaps in our knowledge are considered in the context of the future outlook for FSW/P.

Published

2021

24. Friction Stir Processing of Al-TiB In Situ Composite: Effect on Particle Distribution, Microstructure and Properties.

Author

Yadav, Devinder and Bauri, Ranjit

Subjects

ALUMINUM alloys, METALLIC composites, FRICTION stir processing, PARTICLE size distribution, GRAIN refinement

Abstract

Aluminum-based in situ composites suffer from the age-old issue of particle segregation along the grain boundaries after casting. In the present study, friction stir processing (FSP) was employed as a secondary process to improve the distribution of in situ formed TiB particles in Al-based composite. All the agglomerates of TiB were broken, and uniform distribution of particles was achieved after double-pass FSP. Also, FSP removed the casting defects and caused significant grain refinement of the Al matrix. The microstructure was characterized by equiaxed fine grains with average size of 3 µm and narrow grain size distribution. The microstructural refinements and homogenization after FSP not only enhanced the strength but also improved the ductility of the as-cast composite. [ABSTRACT FROM AUTHOR]

Published

2015

25. Abnormally high strength and low electrical resistivity of the deformed Cu/Mg-composite with a big number of Mg-filaments

Author

Volkov, A. Y., Antonov, B. D., Patrakov, E. I., Volkova, E. G., Komkova, D. A., Kalonov, A. A., Glukhov, A. V., Volkov, A. Y., Antonov, B. D., Patrakov, E. I., Volkova, E. G., Komkova, D. A., Kalonov, A. A., and Glukhov, A. V.

Abstract

Cu/Mg-composites, the copper matrix of which contains 1, 7 and 2730 magnesium filaments, were obtained by hyrdoextrusion at room temperature. The structure, mechanical and electrical properties of the deformed composite rods and thin wires were investigated. The yield strength and electrical resistivity were theoretically calculated and these estimations were compared with the experimental results. The XRD-method allowed discovering a change of the lattice constant of the Cu-matrix under deformation of the composites. It has been concluded that, under severe plastic deformation, a supersaturated Cu-based solid solution forms on the Cu/Mg-interface. As a result, the strength of the deformed Cu/Mg-composite with minimal volume fraction but maximal surface area of magnesium is abnormally high. A thick Cu-sleeve provides low electrical resistivity of this Cu/Mg-composite. The obtained results can be used for the development of high-strength Cu-based conductors. © 2019 The Authors

Published

2020

26. In-situ time-lapse SKPFM investigation of sensitized AA5083 aluminum alloy to understand localized corrosion

Author

Liew, Y., Örnek, C., Pan, Jinshan, Thierry, D., Wijesinghe, S., Blackwood, D. J., Liew, Y., Örnek, C., Pan, Jinshan, Thierry, D., Wijesinghe, S., and Blackwood, D. J.

Abstract

Sensitized AA5083-H2 aluminum alloy was exposed to chloride-laden thin-film electrolyte at ambient temperature (20%–85% relative humidity) and the local Volta potential measured, in-situ and in real-time, using the Scanning Kelvin Probe Force Microscopy, with the intention to elucidate the earliest stage of localized corrosion. Positive Volta potentials vs alloy matrix were measured for magnesium silicides in ambient air, which, however, underwent a severe nobility loss during corrosion, causing their nobility to invert to active potentials (negative) relative to the alloy matrix. The reason for the nobility inversion was explained by the preferential dissolution of Mg2+, which resulted in an electropositive surface. Aluminides, both with and without silicon, were seen to form the main cathodes at all exposure conditions. The local alloy matrix next to closely-separated aluminides were seen to adopt the Volta potential of the neighbor aluminides, which, hence, resulted in local corrosion protection. The phenomenon of nobility adoption introduced in this work raises questions regarding the anode-to-cathode ratio, which was observed to change during corrosion, and the resulting impact to localized micro-galvanic corrosion. This work further demonstrates that it is necessary to measure the Volta potential during corrosion to reflect the true relationship between the Volta potential and corrosion potential or breakdown potential., QC 20210223

Published

2020

27. Fabrication and Mechanical Properties of In Situ Synthesized Ti2AlN/TiAl Composite

Author

Wang, Daqun, Sun, Dongli, Han, Xiuli, Wang, Qing, Zhang, Ningbo, and Xu, Feixing

Published

2018

28. Influence of Temperature of Accumulative Roll Bonding on the Mechanical Properties of AA5083–1% Al2O3 Composite

Author

Farhadipour, P., Sedighi, M., and Heydari Vini, M.

Published

2018

29. Characteristics of alumina particles in dispersion-strengthened copper alloys.

Author

Zhang, Xue-hui and Li, Xiao-xian

Abstract

Two types of alumina dispersion-strengthened copper (ADSC) alloys were fabricated by a novel in-situ reactive synthesis (IRS) and a traditional internal oxidation (IO) process. The features of alumina dispersoids in these ADSC alloys were investigated by X-ray diffraction, scanning electron microscopy, and high-resolution transmission electron microscopy. It is found that nano-sized γ-AlO particles of approximately 10 nm in diameter are homogeneously distributed in the IRS-ADSC composites. Meanwhile, larger-sized, mixed crystal structure alumina with rod-shaped morphology is embedded in the IO-ADSC alloy. The IRS-ADSC composites can obtain better mechanical and physical properties than the IO-ADSC composites; the tensile strength of the IRS-ADSC alloy can reach 570 MPa at room temperature, its electrical conductivity is 85% IACS, and the Rockwell hardness can reach 86 HRB. [ABSTRACT FROM AUTHOR]

Published

2014

30. Fabrication and densification enhancement of SiC-particulate-reinforced copper matrix composites prepared via the sinter-forging process.

Author

Shabani, Mohammadmehdi, Paydar, Mohammad, and Moshksar, Mohammad

Abstract

The fabrication of copper (Cu) and copper matrix silicon carbide (Cu/SiC) particulate composites via the sinter-forging process was investigated. Sintering and sinter-forging processes were performed under an inert Ar atmosphere. The influence of sinter-forging time, temperature, and compressive stress on the relative density and hardness of the prepared samples was systematically investigated and subsequently compared with that of the samples prepared by the conventional sintering process. The relative density and hardness of the composites were enhanced when they were prepared by the sinter-forging process. The relative density values of all Cu/SiC composite samples were observed to decrease with the increase in SiC content. [ABSTRACT FROM AUTHOR]

Published

2014

31. Mechanical and microstructural characterization of Al7075/SiC nanocomposites fabricated by dynamic compaction.

Author

Atrian, A., Majzoobi, G., Enayati, M., and Bakhtiari, H.

Abstract

This paper describes the synthesis of Al7075 metal matrix composites reinforced with SiC, and the characterization of their microstructure and mechanical behavior. The mechanically milled Al7075 micron-sized powder and SiC nanoparticles are dynamically compacted using a drop hammer device. This compaction is performed at different temperatures and for various volume fractions of SiC nanoparticles. The relative density is directly related to the compaction temperature rise and indirectly related to the content of SiC nanoparticle reinforcement, respectively. Furthermore, increasing the amount of SiC nanoparticles improves the strength, stiffness, and hardness of the compacted specimens. The increase in hardness and strength may be attributed to the inherent hardness of the nanoparticles, and other phenomena such as thermal mismatch and crack shielding. Nevertheless, clustering of the nanoparticles at aluminum particle boundaries make these regions become a source of concentrated stress, which reduces the load carrying capacity of the compacted nanocomposite. [ABSTRACT FROM AUTHOR]

Published

2014

32. Abnormally high strength and low electrical resistivity of the deformed Cu/Mg-composite with a big number of Mg-filaments

Author

A. V. Glukhov, D. A. Komkova, E. G. Volkova, B. D. Antonov, A. Yu. Volkov, A. A. Kalonov, and E.I. Patrakov

Subjects

Materials science, Composite number, MECHANICAL AND ELECTRICAL PROPERTIES, chemistry.chemical_element, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Lattice constant, PLASTIC DEFORMATION, Electrical resistivity and conductivity, lcsh:TA401-492, COMPOSITE RODS, General Materials Science, HIGH STRENGTH, Composite material, BIMETALLIC COMPOSITES, Electrical conductor, METALLIC MATRIX COMPOSITES, TERNARY SYSTEMS, Magnesium, Mechanical Engineering, SEVERE PLASTIC DEFORMATIONS, 021001 nanoscience & nanotechnology, SEVERE PLASTIC DEFORMATION, DIFFUSION COUPLE, 0104 chemical sciences, ELECTRICAL CONDUCTIVITY, chemistry, MAGNESIUM, Mechanics of Materials, CU/MG DIFFUSION COUPLE, ELECTRIC CONDUCTIVITY, BIMETALLIC COMPOSITE, lcsh:Materials of engineering and construction. Mechanics of materials, Severe plastic deformation, Deformation (engineering), 0210 nano-technology, MECHANICAL PROPERTIES, Solid solution, COPPER MATRIX

Abstract

Cu/Mg-composites, the copper matrix of which contains 1, 7 and 2730 magnesium filaments, were obtained by hyrdoextrusion at room temperature. The structure, mechanical and electrical properties of the deformed composite rods and thin wires were investigated. The yield strength and electrical resistivity were theoretically calculated and these estimations were compared with the experimental results. The XRD-method allowed discovering a change of the lattice constant of the Cu-matrix under deformation of the composites. It has been concluded that, under severe plastic deformation, a supersaturated Cu-based solid solution forms on the Cu/Mg-interface. As a result, the strength of the deformed Cu/Mg-composite with minimal volume fraction but maximal surface area of magnesium is abnormally high. A thick Cu-sleeve provides low electrical resistivity of this Cu/Mg-composite. The obtained results can be used for the development of high-strength Cu-based conductors. © 2019 The Authors Ural Branch, Russian Academy of Sciences, UB RAS The work was carried out in the framework of a state task according to the theme ?Pressure? No. AAAA-A18-118020190104-3. The studies of structure and mechanical properties of the samples were carried out at the Electron Microscopy Department and Mechanical Test Department of the Collective-Use Center of the Institute of Metal Physics (Ural Branch, Russian Academy of Sciences). The X-ray diffraction studies were carried out in the ?Composition of Compounds? Center of Collaborative Access, Institute of High-Temperature Electrochemistry, Ural Branch, Russian Academy of Sciences.

Published

2020

33. Chip formation in machining metal bonded grinding layers

Author

Berend Denkena, Thilo Grove, and Vino Suntharakumaran

Subjects

Machinability, Wear resistance, Cost-intensive, 0209 industrial biotechnology, Turning, Materials science, Dewey Decimal Classification::600 | Technik::670 | Industrielle und handwerkliche Fertigung, High wear resistance, 02 engineering and technology, Metallic matrix composites, Surface roughness, 020901 industrial engineering & automation, 0203 mechanical engineering, Machining, ddc:670, Wheels, Grinding wheels, Gear manufacturing, Composite material, Turning operations, Dressing, General Environmental Science, Chip formation, Metal matrix composite, High thermal conductivity, Grinding wheel, Cutting edges, Dewey Decimal Classification::600 | Technik, Grinding, 020303 mechanical engineering & transports, Metals, Thermal conductivity, Chip formations, Material removal rate, General Earth and Planetary Sciences, Gear manufacture, ddc:600, Acoustic emission testing, Wheel dressing, Grinding (machining)

Abstract

Gears demand increasingly high quality regarding acoustic emissions, surface roughness and lifetime. Therefore, grinding is often the last step in the process chain of gear manufacturing. Grinding wheel grain sizes of 30 micrometers lead to high surface quality and metal bonded CBN-grains allow a high wear resistance and profile stability of the grinding tool. Consequently, an increase of the material removal rates and thus productivity is possible without increasing the thermal load on the workpiece due to the grinding wheels’ high thermal conductivity. However, the time and cost intensive dressing process in combination with the high profile requirements for gear grinding prevent the wide application of metal bonded tools for this application. This challenge can be solved using a new dressing approach with geometrically defined cutting edges. Metal bonded CBN-grinding layers have a structure similar to metal-matrix-composites, which can be machined by using the turning operation. The aim of this work is to verify the machinability of metal bonded CBN-grinding layers. In the present work, the chip formation for metal bonded grinding layers is presented.

Published

2018

34. Additive manufacturing of martensitic stainless steel matrix composites with simultaneously enhanced strength-ductility and corrosion resistance.

Author

Chen, Wei, Xiao, Bo, Xu, Lianyong, Han, Yongdian, Zhao, Lei, and Jing, Hongyang

Subjects

*MARTENSITIC stainless steel, *CORROSION resistance, *RESIDUAL stresses, *GRAIN refinement, *METALLIC composites, *STAINLESS steel corrosion

Abstract

Many traditional methods for strengthening martensitic stainless steel (SS) typically come at the sacrifice of ductility. Herein, we report a configuration design of ceramic particles for reinforcing additively manufactured 15-5 PH martensitic SS with an optimized combination of high-strength and impressively larger ductility via the micron-sized TiC addition. High strength is ascribed to grain refinement, Orowan bowing strengthening, and abundant nucleation of nanoscale (Nb,Ti)C precipitates, while high elongation correlates to the reduced oxide inclusion content, martensite/austenite duplex microstructure, and progressive transformation-induced plasticity effect. In addition, severe localized corrosion is completely inhibited. This work shows the great potential of additive manufacturing technology to fabricate Fe-based composites with unique microstructures, low residual stress levels, excellent corrosion resistance, and an exceptional combination of strength and ductility for practical applications. [ABSTRACT FROM AUTHOR]

Published

2022

35. Sintering behavior of Cr in different atmospheres and its effect on the microstructure and properties of copper-based composite materials.

Author

Wang, Ye, Yan, Qing-zhi, Zhang, Fei-fei, Ge, Chang-chun, Zhang, Xiao-lu, and Zhao, Hai-qin

Abstract

Copper matrix composites consisting of chromium (Cr) or ferrochrome (Cr-Fe) as strengthening elements and molybdenum disulfide as a lubricant had been sintered in nitrogen and hydrogen atmosphere, respectively. Their morphology and energy-dispersive X-ray spectrometry (EDS) analysis showed that serious interaction occurred between MoS and Cr (or Cr-Fe) particles when the samples were sintered in hydrogen atmosphere. Chromium sulfide compound (CrS) was formed as a reaction product, which decreased the density and strength of the composites remarkably. This interaction was inhibited when the samples were sintered in nitrogen atmosphere; thus, the mechanical properties of the composites were improved. [ABSTRACT FROM AUTHOR]

Published

2013

36. Microstructural and mechanical properties of Al-4.5wt% Cu reinforced with alumina nanoparticles by stir casting method.

Author

Valibeygloo, N., Azari Khosroshahi, R., and Taherzadeh Mousavian, R.

Abstract

The microstructure and mechanical properties of Al-4.5wt% Cu alloy reinforced with different volume fractions (1.5vol%, 3vol%, and 5vol%) of alumina nanoparticles, fabricated using stir casting method, were investigated. Calculated amounts of alumina nanoparticles (about ϕ50 nm in size) were ball-milled with aluminum powders in a planetary ball mill for 5 h, and then the packets of milled powders were incorporated into molten Al-4.5wt% Cu alloy. Microstructural studies of the nanocomposites reveal a uniform distribution of alumina nanoparticles in the Al-4.5wt% Cu matrix. The results indicate an outstanding improvement in compression strength and hardness due to the effect of nanoparticle addition. The aging behavior of the composite is also evaluated, indicating that the addition of alumina nanoparticles can accelerate the aging process of the alloy, resulting in higher peak hardness values. [ABSTRACT FROM AUTHOR]

Published

2013

37. Exploration of Al-based matrix composites reinforced by hierarchically spherical agents.

Author

Zhang, Li, Wu, Bao-lin, Zhao, Yu-hua, and Du, Xing-hao

Abstract

Al-based composites reinforced with Al-Ti intermetallic compounds/Ti metal hierarchically spherical agents were successfully fabricated by powder metallurgy. This kind of structure produces strongly bonded interfaces as well as soft/hard/soft transition regions between the matrix and reinforced agents, which are beneficial to load transfer during deformation. As expected, the resultant composites exhibit promising mechanical properties at ambient temperature. The underlying mechanism was also discussed in this paper. [ABSTRACT FROM AUTHOR]

Published

2013

38. High-frequency induction heated sintering of ball milled Fe-WC nanocomposites.

Author

Zakeri, M., Zanganeh, T., and Najafi, A.

Abstract

Fe-WC nanocomposites were successfully fabricated by high-frequency induction heated sintering of ball milled nanostructure powders. The ball milled powders were characterized by X-ray diffraction. Density measurements by the Archimedes method show that all sintered samples have the relative density higher than 95%. Studies on the effects of WC content, milling speed, and milling time indicate that a higher milling speed and a more WC content lead to the improvement of mechanical properties. There is a very good distribution of WC particles in the Fe matrix at the milling speed of 650 r/min. For the sintered sample 20-5-650 (20wt% WC, milling time of 5 h, and milled speed of 650 r/min), the maximum Brinell hardness and yield stress are obtained to be 3.25 GPa and 858 MPa, respectively. All sintered samples have brittle fracture during compression test except the sample 20-5-650. [ABSTRACT FROM AUTHOR]

Published

2013

39. Effect of sintering parameters on the microstructure and thermal conductivity of diamond/Cu composites prepared by high pressure and high temperature infiltration.

Author

Chen, Hui, Jia, Cheng-chang, and Li, Shang-jie

Abstract

Pure Cu composites reinforced with diamond particles were fabricated by a high pressure and high temperature (HPHT) infiltration technique. Their microstructural evolution and thermal conductivity were presented as a function of sintering parameters (temperature, pressure, and time). The improvement in interfacial bonding strength and the maximum thermal conductivity of 750 W/(m·K) were achieved at the optimal sintering parameters of 1200°C, 6 GPa and 10 min. It is found that the thermal conductivity of the composites depends strongly on sintering pressure. When the sintering pressure is above 6 GPa, the diamond skeleton is detected, which greatly contributes to the excellent thermal conductivity. [ABSTRACT FROM AUTHOR]

Published

2013

40. Corrosion properties in a simulated body fluid of Mg/β-TCP composites prepared by powder metallurgy.

Author

Wang, Yong, Wu, Ze-hong, Zhou, Hong, Liao, Zhi-dong, and Zhang, Heng-fei

Abstract

Magnesium matrix composites (MMC) reinforced with 5wt% tricalcium phosphate (TCP) particles were prepared by powder metallurgy. Pure magnesium (CP-Mg) was fabricated by the same procedure for comparison. Scanning electron microscopy and energy- dispersive X-ray spectroscopy analyses revealed that TCP particles were distributed homogeneously in the MMC. In order to investigate the corrosion properties, MMC samples were immersed in a simulated body fluid (SBF) at 310±0.5 K for 72 h. The mass loss of the samples in SBF and the pH values of the SBF were evaluated. Moreover, electrochemical measurements were conducted in the SBF. It was shown that the corrosion rate of the MMC decreased with the addition of TCP compared with CP-Mg. Hydroxyapatite was formed on the surface of MMC samples after immersion in the SBF for 72 h but not on the surface of CP-Mg. [ABSTRACT FROM AUTHOR]

Published

2012

41. Processing of nanostructured metallic matrix composites by a modified accumulative roll bonding method with structural and mechanical considerations.

Author

Yaghtin, Amir, Salahinejad, Erfan, and Khosravifard, Ali

Abstract

Particulate reinforced metallic matrix composites have attracted considerable attention due to their lightweight, high strength, high specific modulus, and good wear resistance. Al/BC composite strips were produced in this work by a modified accumulative roll bonding process where the strips were rotated 90° around the normal direction between successive passes. Transmission electron microscopy and X-ray diffraction analyses reveal the development of nanostructures in the Al matrix after seven passes. It is found that the BC reinforcement distribution in the matrix is improved by progression of the process. Additionally, the tensile yield strength and elongation of the processed materials are increased with the increase of passes. [ABSTRACT FROM AUTHOR]

Published

2012

42. Selective interfacial bonding and thermal conductivity of diamond/Cu-alloy composites prepared by HPHT technique.

Author

Chen, Hui, Jia, Cheng-chang, Li, Shang-jie, Jia, Xian, and Yang, Xia

Abstract

Cu-based and Cu-alloy-based diamond composites were made by high-pressure-high-temperature (HPHT) sintering with the aim of maximizing the thermal conductivity of the composites. Improvements in interfacial bonding strength and thermo-physical properties of the composites were achieved using an atomized copper alloy with minor additions of Co, Cr, B, and Ti. The thermal conductivity (TC) obtained exhibited as high as 688 W·m·K, but also as low as 325 W·m·K. A large variation in TC can be rationalized by the discrepancy of diamond-matrix interfacial bonding. It was found from fractography that preferential bonding between diamond and the Cu-alloy matrix occurred only on the diamond {100} faces. EDS analysis and Raman spectra suggested that selective interfacial bonding may be attributed to amorphous carbon increasing the wettability between diamond and the Cu-alloy matrix. Amorphous carbon was found to significantly affect the TC of the composite by interface modification. [ABSTRACT FROM AUTHOR]

Published

2012

43. Predicted interfacial thermal conductance and thermal conductivity of diamond/Al composites with various interfacial coatings.

Author

Liang, Xuebing, Jia, Chengchang, Chu, Ke, and Chen, Hui

Abstract

The interfacial thermal conductance (ITC) and thermal conductivity (TC) of diamond/Al composites with various coatings were theoretically studied and discussed. A series of predictions and numerical analyses were performed to investigate the effect of thickness, sound velocity, and other parameters of coating layers on the ITC and TC. It is found that both the ITC and TC decline with increasing coating thickness, especially for the coatings with relatively low thermal conductivity. Nevertheless, if the coating thickness is close to zero, or quite a small value, the ITC and TC are mainly determined by the constants of the coating material. Under this condition, coatings such as Ni, TiC, MoC, SiC, and Si can significantly improve the ITC and TC of diamond/Al composites. By contrast, coatings like Ag will exert the negative effect. Taking the optimization of interfacial bonding into account, conductive carbides such as TiC or MoC with low thickness can be the most suitable coatings for diamond/Al composites. [ABSTRACT FROM AUTHOR]

Published

2011

44. Fabrication, microstructures, and properties of copper matrix composites reinforced by molybdenum-coated carbon nanotubes.

Author

Nie, Junhui, Jia, Chengchang, Jia, Xian, Zhang, Yafeng, Shi, Na, and Li, Yi

Abstract

Multiwalled carbon nanotubes (CNTs) were coated by a molybdenum layer using carbonyl thermal decomposition process with a precursor of molybdenum hexacarbonyl. The Mo-coated CNTs (Mo-CNTs) were added into copper powders to fabricate Mo-CNT/Cu composites by means of mechanical milling followed by spark plasma sintering. The Mo-CNTs were uniform dispersion in the Cu matrix when their contents were 2.5 vol.%-7.5 vol.%, while some Mo-CNT clusters were clearly observed at additions of 10.0 vol.%-15.0 vol.% Mo-CNTs in the mixture. The mechanical, electrical, and thermal properties of the Mo-CNT/Cu composites were characterized, and the results showed that the tensile strength and hardness were 2.0 and 2.2 times higher than those of CNT-free specimens, respectively. Moreover, the Mo-CNT/Cu composites exhibited an enhanced thermal conductivity but inferior electrical conductivity compared with sintered pure Cu. The uncoated CNT/Cu composites were fabricated by the similar processes, and the measured tensile strength, hardness, thermal conductivity, and electrical conductivity of the CNT/Cu composites were lower than those of the Mo-CNT/Cu composites. [ABSTRACT FROM AUTHOR]

Published

2011

45. Thermal conductivity of diamond/copper composites with a bimodal distribution of diamond particle sizes prepared by pressure infiltration method.

Author

Chen, Chao, Guo, Hong, Chu, Ke, Yin, Fazhang, Zhang, Ximing, Han, Yuanyuan, and Fan, Yeming

Abstract

The thermal conductivity of diamond/copper composites with bimodal particle sizes was studied. The composites were prepared through pressure infiltration of liquid copper into diamond preforms with a mixture of 40 and 100 μm-size diamonds. The permeability of the preforms with different coarse-to-fine volume ratios of diamonds was investigated. The thermal conductivity of the diamond/copper composites with bimodal size distribution was compared to the theoretical value derived from an analytical model developed by Chu. It is predicted that the diamond/copper composites could reach a higher thermal conductivity and their surface roughness could be improved by applying bimodal diamond particle sizes. [ABSTRACT FROM AUTHOR]

Published

2011

46. Thermal conductivity behavior of SPS consolidated AlN/Al composites for thermal management applications.

Author

Dun, Bo, Jia, Xian, Jia, Chengchang, and Chu, Ke

Abstract

lN/Al composites are a potentially new kind of thermal management material for electronic packaging and heat sink applications. The spark plasma sintering (SPS) technique was used for the first time to prepare the AlN/Al composites, and attention was focused on the effects of sintering parameters on the relative density, microstructure and, in particular, thermal conductivity behavior of the composites. The results showed that the relative density and thermal conductivity of the composites increased with increasing sintering temperature and pressure. The composites sintered at 1550°C for 5 min under 70 MPa showed the maximum relative density and thermal conductivity, corresponding to 99% and 97.5 W·m·K, respectively. However, the thermal conductivity of present AlN/Al composites is still far below the theoretical value. Possible reasons for this deviation were discussed. [ABSTRACT FROM AUTHOR]

Published

2011

47. Pressure infiltrated Cu/diamond composites for LED applications.

Author

Fan, Yeming, Guo, Hong, Xu, Jun, Chu, Ke, Zhu, Xuexin, Jia, Chengchang, Yin, Fazhang, and Zhang, Ximin

Abstract

Diamond reinforced copper (Cu/diamond) composites were prepared by a pressure infiltration technique. The composites show a super high conductivity of 713 W·m·K in combination with an extremely low coefficient of thermal expansion (CTE) of 7.72 × 10 K (25-100°C), which are achieved by modifying the copper matrix with adding 0.3 wt.% of boron to get a good thermal contact between the matrix and the diamond particles. By adopting a series of postmachining techniques the composites were made into near-net-shape parts, and an electroless silver coating was also successfully plated on the composites. Finally, their potential applications in the thermal management of light emitting diodes (LED) were illustrated via prototype examples. [ABSTRACT FROM AUTHOR]

Published

2011

48. A Novel Approach for Composite Wear Plate Fabrication by Using Vertical Centrifugal Casting

Author

Mustafa Ozkaya, İbrahim Savaş Dalmiş, and Serdar Yilmaz

Subjects

Cast iron, Wear resistance, Materials science, Powder metals, Composite number, Elemental distribution, 02 engineering and technology, engineering.material, Carbide, Fabrication, Metallic matrix composites, 0203 mechanical engineering, Coating, Centrifugal casting (industrial), Vertical centrifugal castings, Vertical centrifugal casting, Graphite, Composite material, Abrasive wear, Centrifugal casting, Particle reinforcement, Wear plate, Carbide particles, Spheroidal graphite cast iron, Abrasive, Abrasives, Condensed Matter Physics, Plates (structural components), Effect of sizes, Reinforcement, 020303 mechanical engineering & transports, Plate metal, Casting (metalworking), engineering, Metal matrix composites, Abrasion, Carbides, Matrix materials

Abstract

A novel approach of wear plate fabrication by vertical centrifugal casting was proposed and demonstrated in this paper. Wear plates were reinforced by the addition of M7C3 carbide particles during vertical centrifugal casting. The effect of size and the weight ratio of the carbide particles on wear resistance were investigated. The prepared carbide particles were used as 150-2000 ?m in size and 3-20 g in weight per casting. Spheroidal graphite cast iron has been used as matrix material. During casting, the machine was operated at 250 rpm. The carbide powders have been formed a local coating of 300-1600 µm thickness on the sample tip surfaces. The average thickness of the composite formed on the sample surface was found to be 1000-1200 µm. The elemental distributions were analyzed by EDS. XRD and XPS were used for characterizing the phase structures. The samples were subjected to a "block on ring" abrasive wear test. It has been observed that the abrasion resistance of samples having a powder size of 1000-2000 ?m has the highest abrasion resistance. © 2019 Kauno Technologijos Universitetas. All Rights Reserved. AR.13.18, NKUBAP.00.17 This work was supported by Research Fund of the Tekirdağ Namık Kemal University. Project Number: NKUBAP.00.17.AR.13.18

Published

2019

49. Comparison of the Effects of B4C and SiC Reinforcement in Al-Si Matrix Alloys Produced via PM Method

Author

Sinan Aksöz, Engin Tan, Hakan Ada, and Yavuz Kaplan

Subjects

FastMap, Materials science, Al-Si matrix MMCs, PM, Silicon carbide, law.invention, Si matrix, Matrix (mathematics), Metallic matrix composites, Microvickers, SiC reinforcement, Optical microscope, Powder metallurgy, law, Boron carbide, Composite material, Reinforcement, Silicon alloys, Metal matrix composite, Reinforcement ratios, Aluminum alloys, Promethium, Light metals, SEM, Scanning electron microscopy

Abstract

Reinforcement kind and ratios have significant effects on the metal matrix composite (MMC) materials. In this study, two different (B4C and SiC) reinforcement compounds between 5 and 15 wt% reinforcement ratios were used in Al-Si main matrix composite materials. Samples were produced via powder metallurgy (PM) method and were subjected to metallographic investigation with; SEM, EDS, FASTMAP, Optical Microscope analyzing methods. Microvickers measurements were carried out as HV1 load. The effects of B4C and SiC reinforcement in MMC were compared in details with these investigations. © 2019, The Minerals, Metals & Materials Society.

Published

2019

50. Production of the AA2196-TiB2 MMCs via PM Technology

Author

Yavuz Kaplan, Hakan Ada, Engin Tan, and Sinan Aksöz

Subjects

FastMap, Al-Li alloys, Materials science, Powder metals, Reinforcement materials, Alloy, Hardness values, engineering.material, law.invention, Matrix (mathematics), Metallic matrix composites, Optical microscope, Powder metallurgy, Hardness, law, Titanium alloys, Powder metallurgy technologies, Composite material, Reinforcement, Lithium alloys, Metal matrix composite, Binary alloys, Aluminum alloys, Light metals, SEM, AA2196-TiB2 MMCs, engineering, Scanning electron microscopy

Abstract

In this study, metal matrix composite (MMC) materials were produced via powder metallurgy (PM) technology. Main matrix was obtained with AA2196 (Al-Li Alloy) and TiB2 was used as reinforcement materials. In study; TiB2 reinforcements ratio were chosen between 5 and 15%wt. The metallographic investigation was realized with; SEM, EDS, FASTMAP, Optical Microscope analyzing techniques. Hardness values were obtained with HV1. In the study, the reinforcements could be distributed in main matrix homogeneously, via PM technique. The MMCs hardness values increased with the edition of TiB2 reinforcement. © 2019, The Minerals, Metals & Materials Society.

Published

2019