| ArticleName |
The properties of metal coatings enhanced with diamond nanoparticles |
| ArticleAuthorData |
Belarusian State Technological University, Minsk, Belarus:
N. R. Prokopchuk, Professor at the Department of Polymer Composite Materials, Doctor of Chemical Sciences, Associate Member of the National Academy of Sciences of Belarus, e-mail: tnsippm@belstu.by
A. I. Globa, Associate Professor at the Department of Polymer Composite Materials1, Candidate of Chemical Sciences, e-mail: Orion-2308@yandex.ru
I. O. Laptik, Engineer at the Department of Polymer Composite Materials, e-mail: inna.laptik@yandex.ru
Saint Petersburg Mining University, Saint Petersburg, Russia:
A. G. Syrkov, Professor at the Department of General and Technical Physics, Doctor of Technical Sciences, e-mail: syrkovandrey@mail.ru |
| Abstract |
This paper looks at the possibility to enhance the processability and performance of metal coatings made of water-based single-component paint materials (such as primer and enamel) by introducing diamond nanoparticles. The paint materials were modified with 0.005–0.100%(wt.) nanosized additives. The authors looked at the drying time and physical and mechanical properties of single-layer coatings made of modified paints (such as hardness, impact strength, adhesion) and installed on steel substrates. They also analyzed the protective properties (such as resistance to exposure to water, 3% NaCl solution, industrial oil, diesel) of coatings made of modified primer and enamel with enhanced mechanical properties. It was found that the introduction of diamond nanoparticles significantly shortens the cure time of primer and enamel (water-dispersed acrylic copolymers, pigments, fillers, functional additives, water) installed on ‘08кп’ grade steel. Nanomodified primer and enamel form protective coatings with enhanced adhesion, impact strength, hardness, resistance to water and NaCl solution. |
| References |
1. Globa A. I., Prokopchuk N. R., Laptik I. O. Modification of 2-component paint materials with carbon nanomaterials. Proceedings of BSTU. 2020. Series 2, No. 2. pp. 92–99.
2. Golubchik E. M., Polyakova M. A., Gulin A. E., Safuanova A. I. et al. Understanding the effect of nanomaterials on the consumer properties of water-based paints. Kachestvo v obrabotke materialov. 2018. No. 1. pp. 10–15.
3. Jeevanandam J., Barhoum A., Chan Y. S., Dufresne A., Danquah M. K. Review on nanoparticles and nanostructured materials: history, sources, toxicity and regulations. Beilstein Journal of Nanotechnology. 2018. No. 9. pp. 1050–1074.
4. Ryzhonkov D. I., Levina V. V., Dzidziguri E. L. Nanomaterials: Lear ner’s guide. 2nd edition. Moscow : Binom. Laboratoriya znaniy, 2017. 365 p.
5. Polymer nanocomposites – additives, properties, applications, environmental aspects. March 10, 2021. NanoTrust, Austrian Academy of Sciences. Available at: https://www.nanowerk.com/spotlight/spotid= 57487.php.
6. Prokopchuk N. R. Polymer nanocomposite materials on the basis of elastomeric, oligomeric and thermoplastic matrices. Neftekhimicheskiy kompleks: Science and Technology Bulletin. Supplement to the Vestnik Belneftekhima journal. 2017. No. 1. pp. 2, 3.
7. Ruttkay-Nedecky B., Krystofova O., Nejdl L. et al. Nanoparticles based on essential metals and their phytotoxicity. Journal of Nanobiotechnology. 2017. Vol. 15, Iss. 33. DOI: 10.1186/s12951-017-0268-3.
8. Shinkareva E. V., Koshevar V. D. Anti-corrosion primer on the basis of water-based epoxy emulsion and carbon nanoparticles. Zhurnal prikladnoy khimii. 2016. Vol. 89, No. 1. pp. 68–76.
9. Stepa R. A., Kuhl K. Nanomaterials. The Cooperation Centre (Koope rationsstelle), Hamburg. 31 May 2017. Available at: https://oshwiki.eu/wiki/Nanomaterials.
10. Babaev A. A., Zobov M. E., Terukov E. I., Tkachev A. G. Production of carbon nanofiber reinforced polymer composites. Protection of Metals and Physical Chemistry of Surfaces. 2020. Vol. 56, No. 4. pp. 416–421.
11. Bellotti N., Romagnoli R., Quintero C., Domínguez-Wong C. et al. Nanoparticles as antifungal additives for indoor water borne paints. Progress in Organic Coatings. 2015. Vol. 86. pp. 33–40.
12. Ehsanul Kabir, Vanish Kumar, Ki-Hyun Kim, Yip A. C. K. et al. Environmental impacts of nanomaterials. Journal of Environmental Management. 2018. Vol. 225, Iss. 1. pp. 261–271.
13. GOST 19007–73. Paintwork materials. Method for determination of drying time and degree. Introduced: 01.07.1974.
14. GOST 5233–89. Paint materials. Method for determination of coating hardness with pendulum instrument. Introduced: 01.01.1990.
15. GOST 4765–73. Paint and lacquer materials. Method for determination of impact resistance. Introduced: 01.07.1974.
16. GOST 15140–78. Paintwork materials. Methods for determination of adhesion. Introduced: 01.01.1979.
17. TU RB 100056180.003–2003. Diamond mix. Introduced: 05.02.2004.
18. TU RB 28619110.001–95. Synthetic ultra-dispersed diamonds. Introduced: 1.10.1995. |
