Your search keyword '"Kosmachev, Pavel V."' showing total 9 results

1. Optimization of 3D Printing Parameters of High Viscosity PEEK/30GF Composites.

Author

Stepanov, Dmitry Yu., Dontsov, Yuri V., Panin, Sergey V., Buslovich, Dmitry G., Alexenko, Vladislav O., Bochkareva, Svetlana A., Batranin, Andrey V., and Kosmachev, Pavel V.

Subjects

ARTIFICIAL neural networks, THREE-dimensional printing, GLASS fibers, COMPUTED tomography, TAGUCHI methods

Abstract

The aim of this study was to optimize a set of technological parameters (travel speed, extruder temperature, and extrusion rate) for 3D printing with a PEEK-based composite reinforced with 30 wt.% glass fibers (GFs). For this purpose, both Taguchi and finite element methods (FEM) were utilized. The artificial neural networks (ANNs) were implemented for computer simulation of full-scale experiments. Computed tomography of the additively manufactured (AM) samples showed that the optimal 3D printing parameters were the extruder temperature of 460 °C, the travel speed of 20 mm/min, and the extrusion rate of 4 rpm (the microextruder screw rotation speed). These values correlated well with those obtained by computer simulation using the ANNs. In such cases, the homogeneous micro- and macro-structures were formed with minimal sample distortions and porosity levels within 10 vol.% of both structures. The most likely reason for porosity was the expansion of the molten polymer when it had been squeezed out from the microextruder nozzle. It was concluded that the mechanical properties of such samples can be improved both by changing the 3D printing strategy to ensure the preferential orientation of GFs along the building direction and by reducing porosity via post-printing treatment or ultrasonic compaction. [ABSTRACT FROM AUTHOR]

Published

2024

2. Fatigue Damage Assessment and Lifetime Prediction of Short Fiber Reinforced Polymer Composites—A Review

Author

Bogdanov, Alexey A., primary, Panin, Sergey V., additional, and Kosmachev, Pavel V., additional

Published

2023

3. Structure and Deformation Behavior of Polyphenylene Sulfide-Based Laminates Reinforced with Carbon Fiber Tapes Activated by Cold Atmospheric Plasma.

Author

Kosmachev, Pavel V., Panin, Sergey V., Panov, Iliya L., and Bochkareva, Svetlana A.

Subjects

*COLD atmospheric plasmas, *LAMINATED materials, *CARBON fibers, *SURFACE roughness, *SHEAR strength, *DEFORMATIONS (Mechanics), *FLEXURAL strength

Abstract

Low-temperature plasma treatment with atmospheric discharge with runaway electrons (DRE) was shown to be an efficient way to activate carbon fiber's (CF) surface and subsequently increase its interlayer shear strength (ILSS) values. It was demonstrated that an acceptable ILSS level was achieved after a DRE plasma treatment duration of 15 min. The treatment of CFs resulted in their surface roughness being increased and their functional groups grafting. The XPS data showed a change in the chemical composition and the formation of reactive oxygen-containing groups. SEM examinations of the PPS/CF laminates clearly demonstrated a difference in adhesive interaction at the PPS/CF interface. After the DRE plasma treatment, CFs were better wetted with the polymer, and the samples cohesively fractured predominantly through the matrix, but not along the PPS/CF interface, as was observed for the sample reinforced with the untreated CFs. The computer simulation results showed that raising the adhesive strength enhanced the ILSS values, but reduced resistance to transverse cracking under the loading pin. In general, higher flexural strength of the PPS/CF laminates was achieved with a greater interlayer adhesion level, which was consistent with the obtained experimental data. [ABSTRACT FROM AUTHOR]

Published

2024

4. Thin antimicrobial silver, copper or zinc containing SiOx films on wood polymer composites (WPC) applied by atmospheric pressure plasma chemical vapour deposition (APCVD) and sol–gel technology

Author

Gerullis, Sven, Pfuch, Andreas, Spange, Sebastian, Kettner, Florian, Plaschkies, Katharina, Küzün, Berrin, Kosmachev, Pavel V., Volokitin, Gennady G., and Grünler, Bernd

Published

2017

5. Surface Modification of Carbon Fibers by Low-Temperature Plasma with Runaway Electrons for Manufacturing PEEK-Based Laminates

Author

Kosmachev, Pavel V., primary, Panin, Sergey V., additional, Panov, Iliya L., additional, and Bochkareva, Svetlana A., additional

Published

2022

6. Deformation Behavior and Fracture Patterns of Laminated PEEK- and PI-Based Composites with Various Carbon-Fiber Reinforcement

Author

Kosmachev, Pavel V, primary, Alexenko, Vladislav O, additional, Bochkareva, Svetlana A, additional, and Panin, Sergey V, additional

Published

2021

7. Obtaining Heat-Resistant Materials with the Use of Silica Nanoparticles

Author

Vlasov, Viktor A., primary, Kosmachev, Pavel V., additional, Skripnikova, Nelli K., additional, Otmahov, Vladimir, additional, and Bezukhov, Konstantin, additional

Published

2016

8. Production of Ceramic Brick Based on Aluminum-Silicate Wastes

Author

Vlasov, Viktor A., primary, Skripnikova, Nelli K., additional, Yuriev, Ivan Yu., additional, Kosmachev, Pavel V., additional, Litvinova, Viktoria A., additional, and Nikonenko, Elena L., additional

Published

2016

9. Structure and Deformation Behavior of Polyphenylene Sulfide-Based Laminates Reinforced with Carbon Fiber Tapes Activated by Cold Atmospheric Plasma.

Author

Kosmachev PV, Panin SV, Panov IL, and Bochkareva SA

Abstract

Low-temperature plasma treatment with atmospheric discharge with runaway electrons (DRE) was shown to be an efficient way to activate carbon fiber's (CF) surface and subsequently increase its interlayer shear strength (ILSS) values. It was demonstrated that an acceptable ILSS level was achieved after a DRE plasma treatment duration of 15 min. The treatment of CFs resulted in their surface roughness being increased and their functional groups grafting. The XPS data showed a change in the chemical composition and the formation of reactive oxygen-containing groups. SEM examinations of the PPS/CF laminates clearly demonstrated a difference in adhesive interaction at the PPS/CF interface. After the DRE plasma treatment, CFs were better wetted with the polymer, and the samples cohesively fractured predominantly through the matrix, but not along the PPS/CF interface, as was observed for the sample reinforced with the untreated CFs. The computer simulation results showed that raising the adhesive strength enhanced the ILSS values, but reduced resistance to transverse cracking under the loading pin. In general, higher flexural strength of the PPS/CF laminates was achieved with a greater interlayer adhesion level, which was consistent with the obtained experimental data., Competing Interests: The authors declare no conflict of interest.

Published

2023