Metallurgical characterization of mechanically alloyed MoNiAl-WC reinforced Fe matrix composite
-
Tanju Teker
and
S. Osman Yilmaz
Abstract
MoNiAl-WC reinforced Fe matrix composites were obtained by mechanical alloying. The effect of various reinforcement ratios on microstructure change, elemental characterization and phase transformation were examined by using optical microscopy, scanning electron microscopy, energy dispersion spectroscopy, X-ray diffraction, elemental surface mapping and a microhardness test. Fe and MoNiAl-WC compound and powder mixtures were synthesized by MA and nanocrystalline solid solution was obtained. The increase in the reinforcement ratio reduced grain size in the structure and increased the carbide ratio. The composite demonstrated excellent metallurgical qualities and interface bonding. Moreover, it was found that the amount of porosities increased with increasing reinforcement. X-Ray analysis showed the formation of NiAl, Al3Ni and WC phases.
© 2020 by Walter de Gruyter Berlin/Boston
Articles in the same Issue
- CONTENTS
- Materials Testing
- FACHBEITRÄGE
- Wear and corrosion behavior of Mg-based alloy reinforced with TiC and ZrC particles
- Corrosion resistance of hoisting ropes
- Effect of milling on the microstructure and mechanical property of austenite stainless steel
- Numerical simulation of the crush behavior of tapered tubes
- FEA of SAW penetration of Ramor 500 steel
- Metallurgical characterization of mechanically alloyed MoNiAl-WC reinforced Fe matrix composite
- Friction and wear performance of a copper-based bond emery wheel for rail grinding
- Experimental determination and numerical modeling of the stiffness of a fastener
- Influence of electron beam welding parameters on the weld seam geometry of Inconel 718 at low feed rates
- Mechanical behavior of composite pipes joined with non-embedded and embedded adhesive layers
- Wear properties of WC–Co and WC–CoCr coatings applied by HVOF technique on different steel substrates
- Effect of ultrasonic melt treatment on the tribological behavior of 7075 aluminum alloy
- Effect of TiN particle size on wear behavior of SiAlON-TiN composites
- Turning machinability of alloyed ductile iron compared to forged EN 1.7131 steel
- Numerically modeling spring back and spring go amounts and bending deformations of Cr-Mo alloyed sheet material
- BEZUGSQUELLEN
- IMPRESSUM
Articles in the same Issue
- CONTENTS
- Materials Testing
- FACHBEITRÄGE
- Wear and corrosion behavior of Mg-based alloy reinforced with TiC and ZrC particles
- Corrosion resistance of hoisting ropes
- Effect of milling on the microstructure and mechanical property of austenite stainless steel
- Numerical simulation of the crush behavior of tapered tubes
- FEA of SAW penetration of Ramor 500 steel
- Metallurgical characterization of mechanically alloyed MoNiAl-WC reinforced Fe matrix composite
- Friction and wear performance of a copper-based bond emery wheel for rail grinding
- Experimental determination and numerical modeling of the stiffness of a fastener
- Influence of electron beam welding parameters on the weld seam geometry of Inconel 718 at low feed rates
- Mechanical behavior of composite pipes joined with non-embedded and embedded adhesive layers
- Wear properties of WC–Co and WC–CoCr coatings applied by HVOF technique on different steel substrates
- Effect of ultrasonic melt treatment on the tribological behavior of 7075 aluminum alloy
- Effect of TiN particle size on wear behavior of SiAlON-TiN composites
- Turning machinability of alloyed ductile iron compared to forged EN 1.7131 steel
- Numerically modeling spring back and spring go amounts and bending deformations of Cr-Mo alloyed sheet material
- BEZUGSQUELLEN
- IMPRESSUM
