The preliminary stage of asphalt mixture production involves the drying and dedusting of coarse aggregates. The most common types of coarse aggregates used are limestone and basalt. In the process of drying and dedusting the dryer filter accumulates large quantities of waste in the form of mineral powder.
This paper introduces an investigation into limestone powder waste as a potential microfiller of polymer composites. Physical characteristics such as the granulation the of powder collected from the filter - in terms of the season of its collection and the type of input materials used - were analysed. A scanning electron microscope (SEM) was used for the investigation described within this paper. The obtained results were compared against those of other materials which can be used as polymer composites microfillers.
Fabrication and microstructure of the AlSi11 matrix composite containing 10 % volume fraction of CrFe30C8 particles were presented in this paper. Composite suspension was manufactured by using mechanical stirring. During stirring process the temperature of liquid metal, time of mixing and rotational speed of mixer were fixed. After stirring process composite suspension was gravity cast into shell mould. The composites were cast, applying simultaneously an electromagnetic field. The aim of the present study was to determine the effect of changes in the frequency of the current power inductor on the morphology of the reinforcing phase in the aluminum matrix. The concept is based on the assumption that a chromium-iron matrix of CrFe30C8 particles dissolves and residual carbide phases will substantially strengthen the composite. The microstructure and interface structure of the AlSi11/CrFe30C8 composite has been studied by optical microscopy, scanning microscopy and X-ray diffraction.
The paper presents the method of preparing a composite slurry composed of AlSi11 alloy matrix and 10 vol.% of SiC particles, as well as
the method of its high-pressure die casting and the measurement results concerning the castability of the obtained composite. Composite
castings were produced at various values of the piston velocity in the second stage of injection, diverse intensification pressure values, and
various injection gate width values. There were found the regression equations describing the change of castability of the examined
composite as a function of pressure die casting process parameters. The conclusion gives the analysis and the interpretation of the obtained
results.
The durability characteristics of Engineered Cementitious Composites (ECC) with various fibers such as polypropylene and glass were investigated in view of developing composites with high resistance to cracking. ECC offer large potential for durable civil infrastructure due to their high tensile strain capacity and controlled micro-crack width. In this study, fibre volume fractions (0.5%, 1%, 1.5%, and 2%) of both polypropylene and glass fibers varied and durability measures such as a rapid chloride penetration test, sorptivity, water absorption, acid attack, and sulphate attack were measured. Increasing the fiber content up to 1.5% improved the durability properties of ECC. The test results indicate that the glass fiber-reinforced Engineered Cementitious Composites have better durability characteristics than polypropylene fiber-reinforced ECC.
This paper discusses the mechanical properties of a material fabricated from commercially available metal powder mixtures designed for
use as a metal matrix of diamond impregnated composites. The mixtures with the catalogue numbers CSA and CSA800 provided by a
Chinese producer are suitable for experimental laboratory testing. The specimens were fabricated in a graphite mould using hot pressing.
The material was tested for density, porosity, hardness, and tensile strength under static loading. A scanning electron microscope (SEM)
was used to analyze the microstructure and cleavage fracture of broken specimens. It was essential to determine how the chemical
composition and the fabrication process affected the microstructure and properties of the material. The properties of the sinters were
compared with those of hot pressed specimens fabricated from sub-micron size cobalt powder (Cobalt SMS). Although the as-consolidated
material is inferior to cobalt, it displays a favourable combination of hardness, yield strength and ductility, and seems to have a great
potential for moderate and general purpose applications.
The measurement results concerning the abrasive wear of AlSi11-SiC particles composites are presented in paper. The method of
preparing a composite slurry composed of AlSi11 alloy matrix and 10, 20% vol.% of SiC particles, as well as the method of its highpressure
die casting was described. Composite slurry was injected into metal mould of cold chamber pressure die cast machine and
castings were produced at various values of the piston velocity in the second stage of injection, diverse intensification pressure values, and
various injection gate width values. Very good uniform arrangement of SiC particles in volume composite matrix was observed and these
results were publicated early in this journal. The kinetics of abrasive wear and correlation with SiC particles arrangement in composite
matrix were presented. Better wear resistance of composite was observed in comparison with aluminium alloy. Very strong linear
correlation between abrasive wear and particle arrangement was observed. The conclusion gives the analysis and the interpretation of the
obtained results.
The paper presents the method of preparing a composite slurry composed of AlSi11 alloy matrix and 10 vol.% of SiC particles, as well as
the method of its high-pressure die casting and the measurement results concerning the tensile strength, the yield point, the elongation and
hardness of the obtained composite. Composite castings were produced at various values of the piston velocity in the second stage of
injection, diverse intensification pressure values, and various injection gate width values. There were found the regression equations
describing the change of mechanical properties of the examined composite as a function of pressure die casting process parameters. The
conclusion gives the analysis and the interpretation of the obtained results.
This paper deals with computer modelling of the retention of a synthetic diamond particle in a metallic matrix produced by powder
metallurgy. The analyzed sintered powders can be used as matrices for diamond impregnated tools. First, the behaviour of sintered cobalt
powder was analyzed. The model of a diamond particle embedded in a metallic matrix was created using Abaqus software. The
preliminary analysis was performed to determine the mechanical parameters that are independent of the shape of the crystal. The
calculation results were compared with the experimental data. Next, sintered specimens obtained from two commercially available powder
mixtures were studied. The aim of the investigations was to determine the influence of the mechanical and thermal parameters of the
matrix materials on their retentive properties. The analysis indicated the mechanical parameters that are responsible for the retention of
diamond particles in a matrix. These mechanical variables have been: the elastic energy of particle, the elastic energy of matrix and the
radius of plastic zone around particle.
Oxide fiber-reinforced Ni-base composites have long been considered as attractive heat-resistant materials. After several decades of active research, however, interest in these materials began to decline around mid-1990’s due chiefly to 1) a lack of manufacturing technology to grow inexpensive single-crystal oxide fibers to be used in structural composites, and 2) fiber strength loss during processing due to chemical interactions with reactive solutes in the matrix. The cost disadvantage has been mitigated to a large extent by the development of innovative fiber fabrication processes such as the Internal Crystallization Method (ICM) that produces monocrystalline oxide fibers in a cost-effective manner. Fiber strength loss has been an equally restrictive issue but recent work has shown that it may be possible to design creep-resistant composites even when fiber surface reconstruction from chemical interactions has degraded the strength of extracted fibers tested outside the matrix. The key issue is the optimization of the composite- and interface structure. Reaction-formed defects may be healed by the matrix (or a suitable coating material) so that the fiber residing in the matrix may exhibit diminished sensitivity to flaws as compared to fibers extracted from the matrix and tested in isolation of the matrix. Generally, the Ni-base/Al2O3 composites exhibit acceptable levels of wettability and interface strength (further improved with the aid of reactive solutes), which are required for elevated-temperature creep-resistance. In order to harness the full potential of these composites, the quality of the interface as manifested in the fiber/matrix wettability, interface composition, interphase morphology, and interface strength must be designed. We identify key issues related to the measurement of contact angle, interface strength, and chemical and structural properties at the fiber/matrix interface in the Ni/alumina composites, and present the current state-ofthe-art in understanding and designing the Ni/alumina interface. There should be no doubt that optimization of the interface- and composite microstructure through judicious control of the fabrication process and surface modification shall yield technologically promising Ni-base/oxide fiber composites.
A simple resistance-based method was used to study the epoxy-carbon composite material. Measurement of changes of the resistance between contacts, located on the composite specimens, allows detecting the damage process in quasi-static and fatigue tests. The method can be useful to determine the margin of safety of composite elements.
The presented work describes the results of examination of the mechanical properties of castings made either of AlSi9Mg alloy matrix
composite reinforced with short carbon fibre or of the pure AlSi9Mg alloy. The tensile strength, the yield strength, Young’s modulus, and
the unit elongation were examined both for initial castings and for castings made of the remelted composite or AlSi9Mg alloy. After
preparing metallographic specimens, the structure of the remelted materials was assessed. A few non-metallic inclusions were observed in
the structure of the remelted composite, not occurring in the initial castings. Mechanical testing revealed that all the examined properties of
the initial composite material exceed those of the non-reinforced matrix. A decrease in mechanical properties was stated both for the metal
matrix and for the composite after the remelting process, but this decrease was so slight that it either does not preclude them from further
use or does not restrict the range of their application.
Polymer composite materials based on the Moplen HP400R polypropylene matrix with a filler from walnut shell flour with 30, 40 and 50% content and 200-315 µm and 315-443 µm fraction were produced by the injection method. The effect of filler content was analysed on the processing properties of the composites such as: MFR Melt Flow Rate and the MVR Melt Volume-flow Rate, as well as the temperature of the filler flour decomposition using the TGA thermogravimetric analysis method. The following was also determined: density, hardness, tensile strength and stiffness modulus of elasticity of the materials in question. The obtained composite material was characterised by low density, which increased with the rising filler content. It was found that the applied natural filler has increased the hardness and stiffness modulus of the composite and decreased the tensile strength.
The sound absorption property of polyurethane (PU) foams loaded with natural tea-leaf fibers and luffa cylindrica (LC) has been studied. The results show a significant improvement in the sound absorption property parallel to an increase in the amount of tea-leaf fibers (TLF). Using luffa-cylindrica as a filler material improves sound absorption properties of soft foam at all frequency ranges. Moreover, an increase in the thickness of the sample resulted in an improvement of the sound absorption property. It is pleasing to see that adding tea-leaf fibers and luffa-cylindrica to the polyurethane foam demonstrate a significant contribution to sound absorption properties of the material and it encourages using environmental friendly products as sound absorption material in further studies.
Cast magnesium matrix composites reinforced with silicon carbide particles were investigated by using Raman microscopy. 3C, 4H and 6H polytypes of SiC particles were identified in the investigated composites. Additionally, Mg2Si compound was detected by Raman microscopy in the composites microstructure.
Preliminary tests aimed at obtaining a cellular SiC/iron alloy composite with a spatial structure of mutually intersecting skeletons, using a
porous ceramic preform have been conducted. The possibility of obtaining such a composite joint using a SiC material with an oxynitride
bonding and grey cast iron with flake graphite has been confirmed. Porous ceramic preforms were made by pouring the gelling ceramic
suspension over a foamed polymer base which was next fired. The obtained samples of materials were subjected to macroscopic and
microscopic observations as well as investigations into the chemical composition in microareas. It was found that the minimum width of a
channel in the preform, which in the case of pressureless infiltration enables molten cast iron penetration, ranges from 0.10 to 0.17 mm. It
was also found that the ceramic material applied was characterized by good metal wettability. The ceramics/metal contact area always has
a transition zone (when the channel width is big enough), where mixing of the components of both composite elements takes place.
A eutectic reaction is a basic liquid-solid transformation, which can be used in the fabrication of high-strength in situ composites.
In this study an attempt was made to ensure directional solidification of Fe-C-V alloy with hypereutectic microstructure. In this alloy, the
crystallisation of regular fibrous eutectic and primary carbides with the shape of non-faceted dendrites takes place. According to the data
given in technical literature, this type of eutectic is suitable for the fabrication of in-situ composites, owing to the fact that a flat
solidification front is formed accompanied by the presence of two phases, where one of the phases can crystallise in the form of elongated
fibres.
In the present study an attempt was also made to produce directionally solidifying vanadium eutectic using an apparatus with a very high
temperature gradient amounting to 380 W/cm at a rate of 3 mm/h. Alloy microstructure was examined in both the initial state and after
directional solidification. It was demonstrated that the resulting microstructure is of a non-homogeneous character, and the process of
directional solidification leads to an oriented arrangement of both the eutectic fibres and primary carbides.
The paper presents the results of research of impact strength of aluminum alloy EN AC-44200 based composite materials reinforced with
alumina particles. The research was carried out applying the materials produced by the pressure infiltration method of ceramic preforms
made of Al2O3 particles of 3-6m with the liquid EN AC-44200 Al alloy. The research was aimed at determining the composite resistance
to dynamic loads, taking into account the volume of reinforcing particles (from 10 to 40% by volume) at an ambient of 23°C and at
elevated temperatures to a maximum of 300°C. The results of this study were referred to the unreinforced matrix EN AC-44200 and to its
hardness and tensile strength. Based on microscopic studies, an analysis and description of crack mechanics of the tested materials were
performed. Structural analysis of a fracture surface, material structures under the crack surfaces of the matrix and cracking of the
reinforcing particles were performed.