Your search keyword '"Lapčíková B"' showing total 5 results

1. Improved mechanical properties of graphene-modified basalt fibre–epoxy composites

Author

Sepetcioglu Harun, Lapčík Lubomír, Lapčíková Barbora, Vašina Martin, Hui David, Ovsík Martin, Staněk Michal, Murtaja Yousef, Kvítek Libor, Lapčíková Tereza, and Zmeškal Oldřich

Subjects

graphene-modified basalt fibres, composite pipes, epoxy polymer, mechanical testing, Technology, Chemical technology, TP1-1185, Physical and theoretical chemistry, QD450-801

Abstract

In industrial applications, the potential of basalt fibre-reinforced polymer (BFRP) composite pipes as a compelling alternative to glass and carbon fibre-reinforced composite pipes is recognized. Their high recyclability makes them a viable option for aerospace, marine, and automotive applications. In this study, a comparison is made between the mechanical properties of virgin basalt–epoxy composite pipes and graphene-modified counterparts. To conduct the experiments, pipe section specimens were prepared using a flex grinding machine. Graphene nanoplatelets (GnPs), serving as an exceptional reinforcing material, were uniformly incorporated into the basalt–epoxy composites at a specific concentration. The inclusion of these nanoplatelets resulted in significant changes in mechanical stiffness compared to the virgin basalt–epoxy composite pipes. A series of tests, including uniaxial tensile, Charpy impact, microhardness, Shore D hardness, uniaxial 3-point bending, and dynamic displacement transmissibility tests, were carried out to assess the mechanical properties of both graphene-reinforced and virgin basalt–epoxy pipes. The findings indicated that the pure basalt–epoxy composite exhibited lower ductility compared to the graphene basalt–epoxy composites after undergoing uniaxial mechanical loading. Non-destructive dynamic mechanical vibration testing was used to investigate the complex mechanical response of the materials under examination. The observed complex frequency-dependent responses reflected the mutual ductile/brittle mechanical performance of the developed composites.

Published

2024

2. Study of mechanical properties of epoxy/graphene and epoxy/halloysite nanocomposites

Author

Lapčík Lubomír, Sepetcioğlu Harun, Murtaja Yousef, Lapčíková Barbora, Vašina Martin, Ovsík Martin, Staněk Michal, and Gautam Shweta

Subjects

graphene, halloysite, nanocomposites, epoxy polymer, ctbn rubber, mechanical testing, Technology, Chemical technology, TP1-1185, Physical and theoretical chemistry, QD450-801

Abstract

This article aimed to compare various mechanical properties of epoxy/graphene and epoxy/halloysite nanocomposites. Graphene nanoplatelets (GnPs) and halloysite nanotubes (HNTs) were used as fillers at different concentrations. The studied fillers were dispersed in the epoxy resin matrices. Elastic–plastic mechanical behavior modulation was observed utilizing the fillers’ nanoparticles and carboxyl-terminated butadiene–acrylonitrile copolymer rubber-modified epoxy resin. The hypothesis of the possible preceding inter-particle gliding of the individual GnPs in the complex resin nanocomposite matrix during mechanical testings was also confirmed. Increased ductility (elongation at break increased from 0.33 mm [neat matrix] to 0.46 mm [1 wt% GnPs] [39% increase]) and plasticity of the GnP nanocomposite samples were observed. In contrast, the decreasing mechanical stiffness as reflected in the decreased Young’s modulus of elasticity (from 3.4 to 2.7 GPa [20% decrease]) was found for the epoxy/HNT nanocomposites. The obtained dynamic stiffness of the investigated nanocomposites confirmed the complexity of the mechanical response of the studied material systems as a combination of the ductile and brittle phenomena.

Published

2023

3. Enhancement of the mechanical properties of HDPE mineral nanocomposites by filler particles modulation of the matrix plastic/elastic behavior

Author

Murtaja Yousef, Lapčík Lubomír, Sepetcioglu Harun, Vlček Jakub, Lapčíková Barbora, Ovsík Martin, and Staněk Michal

Subjects

nanosized mineral fillers, hdpe, composites, mechanical properties, Technology, Chemical technology, TP1-1185, Physical and theoretical chemistry, QD450-801

Abstract

Two different nanosized mineral fillers (nano calcium carbonate and nanoclay) were used in the high density poly(ethylene) (HDPE) composites pilot plant production. Structural and mechanical properties of the prepared composites were examined in this study. The homogenous filler distribution was confirmed in the tested samples by scanning electron microscopy, transmission electron microscopy, and energy dispersive spectroscopy analyses. The fillers’ fortifying effect on polymer composites’ mechanical performance was confirmed as indicated by the increased elastic modulus and indentation modulus. Additionally, the possible modulation of the plastic-elastic mechanical behavior was confirmed by the type of the filler as well as its concentration used in the final composites testing articles.

Published

2022

4. Study of the material engineering properties of high-density poly(ethylene)/perlite nanocomposite materials

Author

Lapčík Lubomír, Vašina Martin, Lapčíková Barbora, Staněk Michal, Ovsík Martin, and Murtaja Yousef

Subjects

perlite fillers, hdpe composites, mechanical testing, vibration damping, thermal analysis, Technology, Chemical technology, TP1-1185, Physical and theoretical chemistry, QD450-801

Abstract

This paper was focused on application of the perlite mineral as the filler for polymer nanocomposites in technical applications. A strong effect of the perlite nano-filler on high-density poly(ethylene) (HDPE) composites’ mechanical and thermal properties was found. Also found was an increase of the Young’s modulus of elasticity with the increasing filler concentration. Increased stiffness from the mechanical tensile testing was confirmed by the nondestructive vibrator testing as well. This was based on displacement transmissibility measurements by means of forced oscillation single-degree-of freedom method. Fracture toughness showed a decreasing trend with increasing perlite concentration, suggesting occurrence of the brittle fracture. Furthermore, ductile fracture processes were observed as well at higher filler concentrations by means of SEM analysis. There was also found relatively strong bonding between polymer chains and the filler particles by SEM imagining.

Published

2020

5. Materials characterization of advanced fillers for composites engineering applications

Author

Lapčík Lubomír, Vašina Martin, Lapčíková Barbora, Hui David, Otyepková Eva, Greenwood Richard W., Waters Kristian E., and Vlček Jakub

Subjects

mineral fillers, surface properties, sound absorption, mechanical properties, powder rheology, Technology, Chemical technology, TP1-1185, Physical and theoretical chemistry, QD450-801

Abstract

Four different minerals were investigated; hollow spheres of calcium carbonate, platy mica, needle like wollastonite and glassy perlite and characterized via iGC for surface energy, Freeman powder rheology for flow characterization, cyclic uniaxial die compaction for modulus of elasticity and frequency dependent sound absorption properties. Particle surface energy and particle shape strongly affected the packing density of powder beds. In the case of higher porosity and thus lower bulk density, the powders acoustic absorption was higher in comparison with higher packing density materials. Surface energy profiles and surface energy distributions revealed clear convergence with powder rheology data, where the character of the powder flow at defined consolidation stresses was mirroring either the high cohesion powders properties connected with the high surface energy or powder free flowing characteristics, as reflected in low cohesion of the powder matrix.

Published

2019