Design and Investigation of Hard Metal Composites Modified by Nanoparticles

Zeer

Yasinsky

et al. 2022

J. Phys.: Conf. Ser.

A new stereological model of nanostructured hard metal composites is suggested which describes the packing density, structural parameters and fracture toughness depending on the sizes, volume of the carbides and addition of nanoparticles Al2O3. The results of complex theoretical and experimental investigations of hard metal composites based on powder mixtures (WC-Co)-Al2O3(nano) are presented, which confirm the possibility of improvement of the structure parameters (with the average size of the binder interlayer being up to 0.12 μm and carbide grain up to 1μm), increasing the hardness 15-18 HV, GPa, fracture toughness, K1c, 16-19 MPa m1/2, transverse rupture toughness, σи - 2700 MPa. The results of the modeling experiments are in satisfactory agreement with the measurements of structure parameters and fracture toughness.

Section: Resultsmentioning

confidence: 91%

Section: Resultsmentioning

confidence: 99%

Investigation of nanostructured hard metal composites obtained from powder mixtures (WC-Co)-Al₂O₃

Zeer

Yasinsky

et al. 2022

J. Phys.: Conf. Ser.

“…The hardness and density parameters of the material do not differ significantly from the base material and are at the level: but the values of the microhardness of the interlayer of binder material -cobalt, which was estimated with the help of nanoindentation, are slightly increased, since the known effect of dispersive hardening at the level of structural fragments (Co-Al 2 O 3 ) is realized. On the basis of the experimentally obtained positive results and the revealed features of the structure formation of heterophase carbide composites, the geometric model described in detail [4,8] was refined and corrected, including the known and new density positions packaging of bimodal and polymodal dispersed systems. A new model of heterogeneous carbide structures assumes the use of composite submicron powders (WC-Co), obtained by various methods, which provides the maximum packing density and high homogeneity of the mutual distribution of phase constituents of the composite (Fig.…”

Section: Type 3 Polydesperse Heterogeneous Structurementioning

confidence: 99%

“…There are known effective methods and processing technologies enabling the retention of submicron carbide grains due to introduction of nanosized powders of vanadium, chromium, tantalum carbides or other nanopowders of oxides, nitrides which act as growth inhibitors of the main phase WC in sintering process [3]. In [4] it is shown that the efficiency of modification of the hard metals by nanoparticles of inhibitors Al 2 O 3 substantially depends on the size, concentration and volume fraction of all components of WC-Co-Al 2 O 3 composite. Excessive concentration of nanoparticles in the local volume between carbide grains increases the degree of contact and the formation of agglomerates.…”

Section: Introductionmentioning

confidence: 99%

Combined Application of Composite Powders WC-Co and Additives of Nanoparticles as an Effective Method of Improving the Properties of Hard Metals

Yasinski

Binchurov

et al. 2018

KEM

Self Cite

The results of experimental studies show that the use of composite powders (WC-Co) in combination with the modification by the additives of ceramic nanoparticles allows controlling the parameters of the microstructure and increasing the strength of the binder and the level of physical and mechanical properties of the hard metal in general. The coating of carbide particles with a layer of a binder is an effective starting method that allows to obtain a bulk compound that preserves the unique properties of the initial nanopowders and ensures a uniform distribution of the phases (WC, Co, Al2O3). Such multiphase fragmentary nanostructured composite is characterized by additional heterogeneity, determined by the differences in size and elastic properties of the phases. By combining the sizes and properties of the phase components in such heterogeneous composite, it is possible to increase the fracture energy (i.e. Palmqvist fracture toughness) up to 20 - 22 MPa∙m1/2 as a result of inhibition on inclusions of nanoparticles the stress relaxation and change in the trajectory of the intergranular crack. Based on the proposed stereological models and experimentally established relationships between composition and microstructure parameters, the required volume concentrations of nanoparticles’ additives and composite powders (WC-Co) were determined.

“…Numerical values of composite particle parameters and thickness of a coating layer from metal binder on carbide composite powders can be also determined basing on a simple ratio: Vh/Vcm = 6h/dm, where: Vcm -volume of composite particle. Solving this system of equations and using equations of the geometric model developed earlier [10,12] for WC-Co-nanoAl 2 O 3 (ZrO 2 ) the optimum volume of modifying additives at different ratios of average sizes d m / d f and volume of particles ν m / ν f can be determined In accordance with the geometric model calculation a prediction about the amount of additives needed to obtain compacts with the highest packing density is possible. Estimates were made in the carbide phase size in the range of d m (WC) from 0.5 to 3 µm and for ultrafine particle sizes of 0,008 to 0.1 µm.…”

Section: Theory/calculationmentioning

confidence: 99%

Influence of Additives of Nanoparticles on Structure Formation of Fine-Grained Hardmetals

Abkaryan

Binchurov

et al. 2017

KEM

Self Cite

This paper introduces a new concept of coated fine carbides modified by nanoparticles Al2O3, ZrO2 (inhibitors) as the starting method for improved hardmetals. The study involved computational and experimental methods to determine functional relationships between the parameters of microstructure, sizes, volume content of additives of nanoparticles and properties (transverse rupture toughness, hardness, fracture toughness) of the heterophase hardmetal composites. Factors having a positive influence on the structure of hardmetals are the decrease in the average size and contiguity of carbide grains due to SPS-consolidation and ultrasonic activation during mixing. The study of microstructural parameters by scanning electron microscopy in a combination with x-ray phase analysis indicates high statistical homogeneity of the relative distribution of nanoparticles (inhibitors) in the cobalt binder between carbide grains and the formation of nanostructured inclusions in hardmetal composites.