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Marina V. Antonova
Kazan National Research Technological University
STUDY OF THE ANTISTATIC PROPERTIES OF MATERIALS TREATED WITH COLLOIDAL COMPOSITIONS BASED ON METAL NANOPARTICLES
Antonova M. V. Study of the antistatic properties of materials treated with colloidal composi- tions based on metal nanoparticles. Technologies & Quality. 2023. No 2(60). P. 10–14. (In Russ.) https://doi.org/10.34216/2587-6147-2023-2-60-10-14.
DOI: https://doi.org/10.34216/2587-6147-2023-2-60-10-14
УДК: 677
EDN: LSIQUH
Publish date: 2023-05-10
Annotation: The article provides a short overview of the application of metal nanoparticles in the textile indus- try, describes their properties and application`s fields. The definitions of electrification, electrostatic field, electric charge density are given. The application of processing of fabrics by polyurethane dispersion and metal nanoparticles in technological processes of textile materials finishing is justified. The objects of the study are cotton fabric`s samples with addition of synthetic fibres, colloidal solutions of silver and copper nanoparticles, aqueous polyurethane dispersion. The antistatic properties of the fabrics have been studied. The electrostatic field intensity of the samples was measured on the device ST-01, with the density of the electric charge calculating according to the intensity values. It has been experimentally established, that the processing of fabrics by solutions of nanoparticles of metals contributes to reduction of intensity of their electrostatic field to 65 %, compared with the initial samples. It is noted that treatment of fabrics by polyure- thane dispersion in combination with copper nanoparticles gives no clear antistatic properties to the blended fabrics.
Keywords: colloidal compositions, nanoparticles, polyurethane dispersion, antistatic properties, electric field, strength
Literature list: 1 Antonova M. V., Ilyushina S. V., Krasina I. V. Methods of imparting antibacterial properties to textile fibres. Overview*.Vestnik Kazanskogo tekhnologicheskogo universiteta. [Bulletin of Kazan Technological University]. 2014;17,18:56–61. (In Russ.) 2 Kiseleva A. Yu., Shushina I. A., Kozlova O. V., Telegin F. Yu. Bactericide textiles on the basis of bioactive preparations and nanosilver. Izvestiya vysshih uchebnyh zavedenij. Tekhnologiya legkoj promyshlennosti [Proceedings of higher educational institutions. Light industry technology]. 2011;12,2:110–112. (In Russ.) 3 Ma Xiaole, Zheng Keli, Chen Yinghao Properties, аpplications and мethods of оbtainingnano-silver. Setevoe izdanie: Mezhdunarodnyj studencheskij nauchnyj vestnik [International Student Research Bulletin]. 2018;6. (In Russ.). URL: https://eduherald.ru/ru/article/view?id=19414. (Assecced: 09.03.2023). 4. Wael Ali, et all. Electrical conductivity of silver nanoparticle doped carbon nanofibres measured by CS-AFM. RSC Adv, 2019;9:4553–4562. 5. Yusupova G. R., Sнarafutdinov R. E., Antonova M. V. Study of the effect of silver nanoparticles on the electrifiability of linings* Novye tekhnologii i materialy legkoj promyshlennosti [New light industry tech- nologies and materials]. Kazan, Kazan. St. Technol. Univ. Publ. 2022;255–257. (In Russ.) 6. Rzheusskij S. E., Avchinnikova E. A., Vorob'eva S. A. Nanodiagnostics And Antimicrobial Properties of Copper Nanoparticles. Vestnik farmacii [Bulletin of Pharmacy]. 2014;3(65). (In Russ.). URL: https://cyberleninka.ru/article/n/nanodiagnostika-i-antimikrobnye-svoystva-nanochastits-medi (Assecced: 09.03.2023). 7. Taussarova B. R., Rakhimova S. M., Cellulosic Textile Materials With Antibacterial Properties Modified With Copper Nanoparticles. Khimija Rastitel’nogo Syr’ja [Raw plant chemistry]. 2018;1:163–169. (In Russ.) 8. Yugova I. S., Kuznecov A. V. Comparative Analysis Of Copper Properties In Nano- And Microstructures* Mezhdunarodnyj studencheskij nauchnyj vestnik [International Student Research Bulletin]. 2015;6. (In Russ.). URL: https://eduherald.ru/ru/article/view?id=14281(Assecced: 09.03.2023). 9. Shakurova Ch. M., Bogdanova V. I. Influence of fibre composition on the electrifiability of textile materials*. Vestnik Kazanskogo tekhnologicheskogo universiteta [Bulletin of Kazan Technological University]. 2013;10:65–66. (In Russ.) 10. Hajrullov D. A., Karimov K. N., Voznesenskij E. F., Karnouhov A. E., Timoshina Yu. A., Grebenshchikova M. M., Antonova M. V., Zhelonkin Ya. O., Kogogin E. A. Investigation of the antistatic properties of fibre materials with vacuum-plasma coatings*. III Mezhdunarodnaya konferenciya “Gazorazryadnaya plazma I sintez nanostruktur” [III International Conference on Gas Discharge Plasma and Synthesis of Nanostructures]. Kazan, Buk Publ., 2022. Р. 238–243. (In Russ.).
Author's info: Marina V. Antonova, Kazan National Research Technological University, Kazan, Russia, marisha.10@list.ru, https://orcid.org/0000-0002-7313-7804