In this study, Cu-TiC composites were successfully produced using hot
pressing method. Cu-TiC powder mixtures were hot-pressed for 4 min at 600,
700 and 800?C under an applied pressure of 50 MPa. Phase composition and
microstructure of the composites hot pressed at different temperatures were
characterized by X-ray diffraction, scanning electron microscope, and optic
microscope techniques. Microstructure studies revealed that TiC particles
were distributed uniformly in the Cu matrix. With the increasing sintering
temperature, hardness of composites changed between 64.5 HV0.1 and 85.2
HV0.1. The highest electrical conductivity for Cu-10 wt.% TiC composites was
obtained for the sintering temperature of 800?C, with approximately 68.1%
IACS.
In this paper, wear properties of NiCrBSi-SiC coatings were investigated using the ball-on-disk wear test. In experimental study, NiCrBSi-SiC powders were sprayed using a high-velocity oxygen fuel technique on an SAE 1030 steel substrate. Powder mixtures with different weight mixing ratios, NiCrBSi + 10 wt% SiC, NiCrBSi + 20 wt% SiC and NiCrBSi + 40 wt% SiC coatings were prepared. The deposited coatings are compared in terms of their phase composition, microstructure and hardness. It is proved that the degree of mixing of the NiCrBSi and SiC components in the powder has a massive effect on the phase composition, microstructure and hardness of the coatings. Wear tests were conducted on both the uncoated and coated substrates at same normal load, speed, and wear distance. It has been determined that the coated substrates exhibit a very good tribological performance in comparison to the uncoated substrate. The increase in the adhesive wear resistance provided by the
In this study, AlCu matrix hybride composites with various ratios of boron carbide (B4C), hexagonal boron nitride (hBN), and graphite (Gr) were produced by using hotpressing method. The microstructure, density, mechanical and corrosion properties of these composites were investigated. Optical microscopy, scanning electron microscopy, and X-ray diffraction were used to characterize the microstructures, and the experimental densities of the composites were measured using a helium pycnometer. The mechanical properties including the hardness and transverse rupture strength were investigated using hardness and three-point bending tests, respectively. In addition, the hybrid composites were immersed in an aqueous solution of 3.5 wt.-percent NaCl at pH 3 for potentiodynamic and corrosion rate measurements. These tests revealed that a microstructure in which reinforcing particles are almost homogeneously dispersed in the matrix was obtained. Density measurements have shown that very dense and compact hybrid AMCs are produced. The hardness and transverse rupture strength of the composites were significantly increased by particulate addition to the matrix. Depending on the type and amount of reinforcement material, differences in the corrosion resistance of the hybrid composites have been determined. The results show that AlCu-8B 4 C-2Gr hybrid composite material has the highest corrosion resistance among the composite materials.
The aim of this work was to investigate the effect of cBN content and sintering temperature on the transverse rupture strength (TRS) of cBN/diamond cutting tools produced by hot pressing. The segments containing different cBN content were manufactured under 35 MPa pressure at 600, 650 and 700°C with a 3 minutes sintering time. The TRS of segments were determined using three-point bending test. Microstructure and phase composition of fracture surface of segments were determined by scanning electron microscopy (SEM), and X-ray diffraction (XRD) analysis. The obtained results show that the TRS of the segments with cBN were higher than that of the segments with diamond
The aim of this study was to investigate the effect of sintering temperature
and boron carbide content on wear behavior of diamond cutting segments. For
this purpose, the segments contained 2, 5 and 10 wt.% B4C were prepared by
hot pressing process carried out under a pressure of 35 MPa, at 600, 650 and
700 ?C for 3 minutes. The transverse rupture strength (TRS) of the segments
was assessed using a three-point bending test. Ankara andesite stone was cut
to examine the wear behavior of segments with boron carbide. Microstructure,
surfaces of wear and fracture of segments were determined by scanning
electron microscopy (SEM-EDS), and X-ray diffraction (XRD) analysis. As a
result, the wear rate decreased significantly in the 0-5 wt.% B4C contents,
while it increased in the 5-10 wt.% B4C contents. With increase in sintering
temperature, the wear rate decreased due to the hard matrix.
In this study, NiB-TiC composite materials were produced using powder metallurgy. In the Ni-TiC-B powder mixture, TiC was fixed at a rate of 5 %, 5, 10 and 15 % boron was added and mechanical alloying was carried out. The prepared powder mixtures were cold pressed under pressure of 400 MPa and sintered in an argon atmosphere at 800 o C for 2 hours. Microstructure, phase formation, hardness, wear and corrosion properties of the samples were investigated in detail. Scanning electron microscopy (SEM) was used for microstructure analysis and X-ray diffractogram (XRD) was used for phase formation detection. The hardness measurements of the samples were measured by a microhardness measuring device. Densities of the samples were determined by Archimedes' principle. The corrosion tests were performed potentiodynamic polarization curves of the composite materials in 3.5 % NaCl solution. Wear tests were carried out the composite materials under a load of 10 N. Results showed that by increasing the amount of B, the wear and corrosion resistance increased.
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