STUDY OF THE INFLUENCE OF GASOPYROLYSIS RESIN ON THE STRUCTURAL FORMATION OF REZINES
DOI:
https://doi.org/10.51699/zxv8vk88Keywords:
Structure formation, composite, inhibition, thermo-photochemical, process, gas-pyrolysis resins, elastomer, strength, cubic residue, ruptureAbstract
In this work, the possibility of using the tar product of gas-pyrolysis resin - a polymer production waste - in the production of composite elastomeric materials was investigated. The composition and physicochemical properties of gas-pyrolysis resin have been established. It was determined that the boiling and flash point of organic substances used in the production of elastomeric compositions should not be lower than 180°C, therefore, it was heat-treated with gas-pyrolysis resin at 200°C for 4 hours. It has been established that the cubic residue of gas-pyrolysis resin plays an important role in the formation of the structure and properties of elastomeric composite materials as a result of interaction with donor-acceptor bonds during the inhibition of thermo-photochemical processes, the strength of composites during rupture increases, the relative length during stretching slightly decreases, the hardness and -C-C- bond in the vulcanization grid increase, as a result of which the active substances contained in the cubic residue of gas-pyrolysis resins increase.
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