Abrasive wear of materials based on plasticized polyvinyl chloride

The purpose of the study is to apply a previously developed model for predicting abrasive wear of products made of thermoplastic polyurethanes to materials based on plasticized polyvinyl chloride. Confirmation of the validity of the proposed approach to assess the impact of various wear factors on weight reduction of plasticized polyvinyl chloride (PVC). Comparative analysis of wear of materials based on thermoplastic polyurethane and plasticized PVC.

1. Barruta B, Blancheton J.P, Champagnec J.Y, Grasmick A. Mass transfer efficiency of a vacuum airlift-application to water recycling in aquaculture systems//Aquac Eng. 2012. V.46. №1. Р. 18–26.

2. Gao М., Wan М., Zhou Х. Thermal degradation and flame retardancy of flexible polyvinyl chloride containing solid superacid//J. Thermal Analysis and Calorimetry. 2019. V. 138. №3. Р. 387–396.

3. Zhang С., Song В., Shan J. , Ni Q., Wu F., Wang S. Design and optimization of a new tube aeration device//Aquaculture Inter. 2020. V. 28. №3. Р. 985–999.

4. Petrukhina N. N., Golubeva M. A., Maksimov A. L. Synthesis and Use of Hydrogenated Polymers//Russian J. Appl. Chem. 2019. V. 92. №6. Р. 715–733.

5. Dharmaraj М.М., Chakraborty B. C., Begum S., Natarajan R., Chandramohan S. Effect of nanoclay reinforcing filler in nitrile rubber/ polyvinyl chloride blend: frequency response of dynamic viscoelasticity and vibration damping//Iranian Polym. J. 2022. V. 31. №6. Р. 1247–1261.

6. Колесников А.А., Дедов А.В., Шарова Л.И. Истираемость термопластичного полиуретана для эластичных резервуаров хранения топлива//Все материалы. Энциклопедический справочник 2019. №3. С. 29–33.

7. Колесников А.А., Дедов А.В., Рыбаков Ю.Н., Кюннап Р.И. Истирание термопластичного полиуретана после контакта с бензином // Все материалы. Энциклопедический справочник. 2020. №3. С. 30–35.

8. Колесников А.А., Дедов А.В., Рыбаков Ю.Н., Кюннап Р.И. Влияние солнечного излучения на истирание полимерных резервуаров склада временного хранения топлива // Материаловедение. 2020. №8. С. 14–19.

9. Guo A., Demydov D., Zhang W. Polyols and Polyurethanes from Hydroformylation of Soybean Oil//J. Polym. Environ. 2002. V. 10. №1–2. Р. 49–52.

10. Zlatanic A., Lava C., Zhang W., Petrović Z.S. Effect of Structure on Properties of Polyols and Polyurethanes Based on Different Vegetable Oils//J. Polym. Sci. Pol. Phys. 2004. V. 42. №5. Р.809–816

11. Chattopadhyay D. K., Raju, K.V. Structural engineering of polyurethane coatings for high performance applications//Prog. Polym. Sci. 2007. V. 32. №2. Р. 352–418.

12. Liu Y., Tan H Effect of accelerated xenon lamp aging on the mechanical properties and structure of thermoplastic polyurethane for stratospheric airship envelope//J. Wuhan University of Technology-Mater. Sci. Ed. 2014, V. 29. №6. Р. 1270–1276.

13. Рыбаков Ю.Н. Вклад в теорию и практику химмотологии в области создания полевых средств хранения горючего//Химия и технология топлив и масел. 2014. №5. С. 23–26

14. Momber A. W., Irmer M. Taber abrasive wear resistance of organic offshore wind power coatings at varying normal forces//J. Coatings Technol. Res. 2021. V. 18. №7. Р. 729–740.

15. Nazarov, V.G., Stolyarov, V.P., Gagarin, M.V. Simulation of chemical modification of polymer surface//J. Fluorine Chem. 2014. V. 161. №5. Р. 120–127.

16. Nazarov V.G., Stolyarov V.P. Modified polymer substrates for the formation of submicron particle ensembles from colloidal solution// Colloid J. 2016. V. 78. №1. Р. 75–82.