Your search keyword '"Zárybnická, Lucie"' showing total 5 results

1. Physico-mechanical properties of geopolymers after thermal exposure: Influence of filler, temperature and dwell time.

Author

Perná, Ivana, Zárybnická, Lucie, Mácová, Petra, Šupová, Monika, and Ševčík, Radek

Subjects

*SILICA sand, *PORTLAND cement, *THERMAL properties, *HIGH temperatures, *SURFACE area

Abstract

Geopolymers offer increasingly better physico-mechanical properties concerning thermal exposure at high temperatures compared to ordinary Portland cements (OPC). This paper aims to comprehensively study the use of different types of fillers with different particle size distributions in terms of type (silica sands and cordierites) and surface area, loaded at different temperatures and dwell times (30 min and 180 min). After thermal exposure in the temperature range of 100–1000 °C, geopolymer samples were evaluated regarding physico-mechanical properties compared to samples without thermal exposure, using OPC as a reference material. Geopolymer samples were found to have a denser microstructure than OPC, supporting their better resistance to elevated temperature conditions. In addition, the influence of different filler compositions on the resulting internal structure and porosity was demonstrated. Samples containing fillers in two particle size ranges showed better densification than samples with one particle size range. Conversely, OPC samples showed the least favourable results. In addition, the mechanical behaviour of the geopolymers under static loading, especially in bending and compression tests, showed that the prepared geopolymers exhibited better properties than Portland cement at elevated temperatures, especially in the range of 500–1000 °C. In conclusion, appropriately designed geopolymer compositions have the potential to be a sustainable material, a high-performance alternative to traditional building materials. • Geopolymers (GP) with cordierite and silica sand exposed to 100–1000 °C were studied. • The physico-mechanical properties of the samples after thermal loading were investigated. • The results of the GP samples were compared with ordinary Portland cement (OPC) ones. • GP results suggest solid phase reactions and/or partial sintering at higher temperatures. • GP show better overall properties than OPC in the 500–1000 °C range. [ABSTRACT FROM AUTHOR]

Published

2024

2. Effect of Additives and Print Orientation on the Properties of Laser Sintering-Printed Polyamide 12 Components.

Author

Zárybnická, Lucie, Petrů, Jana, Krpec, Pavel, and Pagáč, Marek

Subjects

*POLYAMIDES, *MANUFACTURING processes, *ALUMINUM powder, *LASER sintering, *FIREPROOFING agents, *THREE-dimensional printing, *PRINT materials

Abstract

3D printing, also known as additive manufacturing, is becoming increasingly popular for prototype processing in industrial practice. Laser sintering, which is a laser powder bed fusion technique, is a versatile and common 3D printing technology, which enables compact and high-quality products. Polyamide 12, a popular 3D printing material, provides reliable mechanical and thermal properties. Weaknesses in applying this technology for polyamide 12 include incomplete information regarding the application of various types of additives and different printing orientations with respect to the properties. This study aimed to investigate the influence of various additives (including carbon fiber, glass fiber, flame retardant, and aluminum powder) combined with polyamide 12, using processing of predefined powder refreshing mixture on the properties of a finished product. The thermal, surface, and mechanical properties of samples printed with five different polyamides 12-based powders at three different print orientations were investigated. It was found that the inclusion of additives decreases the tensile strength and increases the surface roughness of printed components—however, the toughness increases. The results can assist designers in selecting an appropriate material that will produce a finished part with the required properties for a given application. [ABSTRACT FROM AUTHOR]

Published

2022

3. Study of keto-hydrazide crosslinking effect in acrylic latex applied to Portland cements with respect to physical properties.

Author

Zárybnická, Lucie, Pokorný, Jaroslav, Machotová, Jana, Ševčík, Radek, Šál, Jiří, and Viani, Alberto

Subjects

*PORTLAND cement, *LATEX, *MORTAR, *CEMENT composites, *WASTE products, *COMPRESSIVE strength

Abstract

• Acrylic latex additives were produced with and without keto-hydrazide crosslinking from standardly available low-cost raw monomers. • The results indicate that the highest effect on heat flow evolution changes has been detected in the case of latexes without crosslinking. • An important mitigation of liquid water transport properties of latex-modified composites has been achieved. • The developed latex cement-based composites may find utilization as special materials for structures or products for water-loaded constructions. Polymer-modified Portland-based composites are of interest for specific applications, in reason of their properties. There are different types of commercial additives and waste polymer-based materials applied to cement-based composites, however, their impacts on the environment are debatable. This work has prepared new acrylic latex additives with and without keto-hydrazide crosslinking from standardly available low-cost raw monomers. The influence of their incorporation into Portland cement-based fine-grained mortars has been investigated. The obtained results indicate that the highest effect on heat flow evolution changes has been detected in the case of latexes without crosslinking. The incorporation of both latex types into produced cement composites resulted in a significant increase in open porosity connected with the gradual decrease in mechanical resistance, especially the compressive strength. On the other hand, an important mitigation of liquid water transport properties of latex-modified composites has been achieved, and such properties can be tuned according to the used latex type and its concentration. The developed latex cement-based composites may find utilization as special materials for structures or products for water-loaded constructions or in areas with high concentrations of water-soluble salts or other pollutants. [ABSTRACT FROM AUTHOR]

Published

2023

4. Aqueous polyacrylate latex nanodispersions used as consolidation agents to improve mechanical properties of Prague sandstone.

Author

Ševčík, Radek, Machotová, Jana, Zárybnická, Lucie, Mácová, Petra, and Viani, Alberto

Subjects

*MECHANICAL drawing, *ENGINEERED wood, *LATEX, *SANDSTONE, *FLUOROPOLYMERS, *SCANNING electron microscopes, *MONUMENTS

Abstract

• Innovative latex nanodispersions were employed for the consolidation of porous stone. • Their effectiveness to improve mechanical properties of Prague sandstone was proved. • Consolidation can be tuned according to type of applied latex and its concentration. This investigation aims at assessing the potential of polyacrylate latex nanodispersions as consolidation agents for sandstones. Four different latex types, implementing polymer fluorination and chemical crosslinking, have been synthesized at the scope and fully characterized. The Prague sandstone employed in this study has been selected as an example of highly porous stones used as building materials for many historical monuments. Two different concentration levels of nanodispersions have been adopted. The consolidated stone samples have been tested using a combination of physical-mechanical tests and microscopic observations. Compared to the non-treated samples, significant increments of mechanical properties (e.g. up to 3.3 times higher bending strength) have been detected after the consolidation treatment with concentrated products. Moreover, when 10 times diluted latex nanodispersions have been applied, the improvement of mechanical properties has still been significant, while moisture transport properties, such as water absorption, have been found to be comparable with those of the untreated sample. Fluorinated polymers imparted better hydrophobic properties with a contact angle above 100°. Observations using a scanning electron microscope revealed the good filling and bridging capacity of the applied consolidation agents. As demonstrated, by acting on the polymer structure, that is, by tuning the degree of crosslinking, polymer fluorination and gel content, the properties of these novel polyacrylate latex nanodispersions can be tailored to the specific stone and type of decay in order to improve the effectiveness of the treatments and obtain the desired final properties. The flexibility of their chemistry offers new opportunities for preserving objects of cultural heritage that are also at risk due to the ongoing climate change. [ABSTRACT FROM AUTHOR]

Published

2023

5. CaCO 3 Polymorphs Used as Additives in Filament Production for 3D Printing.

Author

Zárybnická, Lucie, Ševčík, Radek, Pokorný, Jaroslav, Machová, Dita, Stránská, Eliška, and Šál, Jiří

Subjects

*THREE-dimensional printing, *CALCIUM carbonate, *CALCITE, *FIBERS, *IMPACT (Mechanics), *VATERITE, *MANUFACTURING processes

Abstract

Nowadays, additive manufacturing—also called 3D printing—represents a well-established technology in the field of the processing of various types of materials manufacturing products used in many industrial sectors. The most common type of 3D printing uses the fused filament fabrication (FFF) method, in which materials based on thermoplastics or elastomers are processed into filaments. Much effort was dedicated to improving the properties and processing of such printed filaments, and various types of inorganic and organic additives have been found to play a beneficial role. One of them, calcium carbonate (CaCO3), is standardly used as filler for the processing of polymeric materials. However, it is well-known from its different applications that CaCO3 crystals may represent particles of different morphologies and shapes that may have a crucial impact on the final properties of the resulting products. For this reason, three different synthetic polymorphs of CaCO3 (aragonite, calcite, and vaterite) and commercially available calcite powders were applied as fillers for the fabrication of polymeric filaments. Analysis of obtained data from different testing techniques has shown significant influence of filament properties depending on the type of applied CaCO3 polymorph. Aragonite particles showed a beneficial impact on the mechanical properties of produced filaments. The obtained results may help to fabricate products with enhanced properties using 3D printing FFF technology. [ABSTRACT FROM AUTHOR]

Published

2022