Improvement of Thermophysical Characteristics of Polymer Coatings for Protecting Water Transport by Using a Mixture of Discrete Organic Fibers

Sapronov, Oleksandr; Buketov, Andriy; Sapronova, Lyudmila; Mokiy, Oleksandr; Vorobiov, Pavlo; Banha, Mykhailo; Straka, Ľuboslav

doi:10.2478/mspe-2025-0060

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Improvement of Thermophysical Characteristics of Polymer Coatings for Protecting Water Transport by Using a Mixture of Discrete Organic Fibers

Autorzy

Sapronov Oleksandr , Buketov Andriy , Sapronova Lyudmila , Mokiy Oleksandr , Vorobiov Pavlo , Banha Mykhailo , Straka Ľuboslav

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DOI

10.2478/mspe-2025-0060

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Abstrakty

This work presents the technological aspects of the reinforcement of the thermosetting binder to improve the thermophysical characteristics of polymeric materials and protective coatings based on them. Epoxy binder ED-20 was used to form polymer materials, which were polymerized with polyethylene polyamine (PEPA) in the ratio: 100 parts by weight of ED-20 epoxy oligomer and 10 parts by weight of PEPA hardener. A mixture of discrete organic fibers with the content of q = 0.25-2.00 wt.% was used to improve the thermophysical properties of polymer materials. The key parameters for determining the temperature range for the future operation of the designed composite materials without changing their properties were defined by thermogravimetric analysis (TGA) and differential thermal analysis (DTA). The maximum temperature of the mass loss beginning is Т0 = 624.0°K; the relative mass loss is εm = 65.7%; the initial temperature of the exoeffect is Тn = 475.5°K; and the maximum temperature of the exoeffect peak is Tmax = 545.5°K. The mathematical calculation of the activation energy of thermal destruction was performed to determine the resistance to the degradation of chemical bonds under the temperature influence. It has been proven that composites filled with a discrete organic fiber mixture with the content of q = 0.75 wt.% are characterized by the maximum activation energy (Ea = 167.2 kJ/mol), which indicates the thermal stability of reinforced composites.

Słowa kluczowe

epoxy binder hardener a mixture of discrete organic fibers polymer material heat resistance destruction relative mass loss activation energy

Wydawca

STE GROUP

Czasopismo

Management Systems in Production Engineering

Rocznik

2025

Tom

nr 4 (33)

Strony

576--585

Opis fizyczny

Bibliogr. 58 poz., rys., tab.

Twórcy

autor

Sapronov Oleksandr

oo.sapronov@gmail.com

Kherson State Maritime Academy Department of Transport Technologies and Mechanical Engineering Independence Ave 20, 73000 Kherson, Ukraine

https://orcid.org/0000-0003-1115-6556

autor

Buketov Andriy

buketov@tntu.edu.ua

Kherson State Maritime Academy Department of Transport Technologies and Mechanical Engineering Independence Ave 20, 73000 Kherson, Ukraine

https://orcid.org/0000-0001-9836-3296

autor

Sapronova Lyudmila

l.o.sapronova@gmail.com

Kherson State Maritime Academy Department of Transport Technologies and Mechanical Engineering Independence Ave 20, 73000 Kherson, Ukraine

autor

Mokiy Oleksandr

spezkompl@spec-k.com.ua

Odessa National Polytechnic University, Shevchenko, 1, Odesa, Ukraine, 65044

autor

Vorobiov Pavlo

Vorobyov020291@gmail.com

Kherson State Maritime Academy Vessel’s Power Plants Operation Department Independence Ave 20, 73000 Kherson, Ukraine

https://orcid.org/0000-0003-4120-2023

autor

Banha Mykhailo

defold.fp@gmail.com

Kherson State Maritime Academy Department of Transport Technologies and Mechanical Engineering Independence Ave 20, 73000 Kherson, Ukraine

autor

Straka Ľuboslav

luboslav.straka@tuke.sk

Technical University of Košice Faculty of Manufacturing Technologies with a seat in Prešov Bayerova 1, 080 01 Prešov, Slovak Republic

https://orcid.org/0000-0003-0914-2155

Bibliografia

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Bibliografia

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