340

  • Ссылка в интернете
  • DOI
  • Дата создание в систему UzSCI 16-07-2021
  • Количество прочтений 0
  • Дата публикации 27-03-2021
  • Язык статьиIngliz
  • Страницы95-100
Ключевые слова
Ўзбек

Structurally, ion exchange polymers can be divided into two types: gel-like and macroporous. Copolymers of microporous structure have been obtained by polycondensation of diphenyloxide and furfural in the presence of porous formations - n-heptane and camphor. We have produced a microporous cation exchanger in the presence of 20-60% porous agent for sorption processes. Determined that with the inclusion of 60 percent camphor, the direction of the sorption isotherms of gel and porous cation exchanger varies sharply from that of porous cation exchanger and with the addition of 60 percent n-heptane, which did not necessarily result in any significant qualitative improvements in the polymer structure. An experimental work was conducted to determine the main thermodynamic characteristics of low-temperature and atmospheric pressure water vapor sorption. The results of the measurement of the thermodynamic properties of the aforementioned formulas show that the tangent at intersection 22,704 of the 606,574 axis is equal to -0.1.The range of submicroscopic capillaries varies from 29.76 to 33.87 Ǻ. The results of the measurement of the thermodynamic properties of the aforementioned formulas show that the tangent at intersection 22,704 of the 606,574 axis is equal to -0.1. Depending on the amount and type of the teaser, the specific pore surface region of the corresponding cation exchanger is – 114.24 -147.63. On average, the overall size of pores is 0.17 to 0.25 cm3. The dates from research existing in the polymer matrix pores can be  absorb of not only metal ions, high molecular compounds with cation active centers as well, and leads to use them in process waste water treatment from the same pollutants.

Имя автора Должность Наименование организации
1 Timofeeva E.A. Dotsent Moscow State University named after M.V. Lomonosov
2 Turabdjanov S.M. Professor TDTU
3 Shokhakimova A.A. Katta o'qituvchi TDTU
4 Rahmatov U.N. Katta o'qituvchi TDTU
5 Rakhimova L.S. Dotsent TDTU
Название ссылки
1 1. Biryukov V.V. Fundamentals of industrial biotechnology: a training manual / V.V. Biryukov. Moscow: Kolos C, 2004. 296 p (in Russian).
2 2. Gracheva I.M. Technology of microbial protein preparations, amino acids and fats /I. M. Gracheva, N. M. Gavrilova, L. A. Ivanova. Moscow: Food Industry, 1980. 448 p (in Russian).
3 3. Demin, A. A. Ion-exchange sorption of biologically active substances / A. A. Demin, I. A. Chernova, L. K. Shataeva. Saint-Petersburg: Saint-Petersburg University Publishing House, 2008. 154 p (in Russian).
4 4. Konyukhov, V.Y. Chromatography: a textbook (in Russian) / V.Y. Moscow: Lan, 2012. 222 p (in Russian).
5 5. Mukhlenov I.P. et al. General chemical technology. Textbook. Moscow: Higher School. 1984. 263 p (in Russian).
6 6. Novikov O. N. A method for obtaining macroporous sorbent Application No. 93039680, Russian Federation, MPK6 C08F212/08, C08F2/44, B01J2/30. published 27.12.1996, Bulletin No. 36 (in Russian).
7 7. Turabdzhanov S., Kedelbaev B., and co-authors. New approach to the synthesis of polycondensation ion-exchange polymers. News of the National Academy of Science of the Republic of Kazakhstan. Geology and technical sciences. 2019. Vol 2 (439). Pp.19-26. https://doi.org/10.32014/2019.2518-170X.56
8 8. S.M. Turabjanov, L.S.Rakhimova, T.V.Ponamareva, etc. Investigation of the copper ions sorption from the waste water by phosphorus-acid cation exchanger // Chemical safety. 2018.T. 2. № 2, P. 173 - 182. https://doi.org/10.25514/CHS.2018.2.14115 (in Russian).
9 9. Turabdzhanov S.M., Rakhimova L.S. Perspective Wastewater Treatment from Cu2+ Ions in the Mining Industry IV th International Innovative Mining Symposium E3S Web of Conferences 105, 02025 (2019) https://doi.org/10.1051/e3sconf/201910502025 (Scopus)
10 10. S. M. Turabdzhanov Rakhimova L.S. and co-authors. Studies of factors affecting stability and efficiency of anion exchanger. E3S Web of Conferences 177, 03020 (2020) Ural Mining Decade 2020. https://doi.org/10.1051/e3sconf/202017703020
11 11. Kedelbaev B.Sh, Turabdjhanov S.M and co-authors. Continuous hydrogenation of benzene on promoted skeletary nickel catalysts. News of the, geology and technical sciences. Volume 3. Number 429. (2018). P. 84-87. ISSN 2518-170X (Online), ISSN 2224-5278 (Print) https://doi.org/10.32014/2018.2518-170X (Scopus)
12 12. Turabdzhanov Sadritdin and co-authors. Synthesis of cation exchanger with macroposity and investigating specific properties. News of the National Academy of Science of the Republic of Kazakhstan. Chemistry and technology. Volume 5, Number 443 (2020), 108 – 115 https://doi.org/10.32014/2020.2518-1491.87
13 13. Sorption methods for the extraction of biosynthesis products: a training manual / V.S. Berseneva, V.A. Bakulev - Yekaterinburg: Izdvo Ural, 2018 - 80 p. ISBN 978-5-7996-2495-8 (in Russian).
14 14. Stromberg, A.G.; Semchenko, D.P. Physical chemistry / Under edition of A.G. Stromberg. - MOSCOW: V.N., 1988 (in Russian).
15 15. Slavinskaya G.V., Kovaleva O.V. Study of the laws of kinetics of sorption of dibutylnaphthalene sulfonate of sodium with polyelectrolytes // Sorption and chromatographic processes. 2009. Т. 9. Op. 4. Pages 521-528 (in Russian).
16 16. L.S. Rakhimova, N.M. Abdutalipova, T.T. Tursunov, Sh.A. Mutalov, R.A. Nazirova. Polycondensation Cations containing aromatic nuclei and heterocyclic cycles. W// Composite materials. 2012. №3. Pages 54-58 (in Russian).
17 17. Hamburg Y. D. Chemical Thermodynamics. - Moscow: Knowledge Laboratory, 2016. - — 237 с. - (Textbook for Higher School). - 978-5-906828-74-3, (in Russian).
18 18. http://www.chem.msu.ru/rus/teaching/korobov/spring/lecture6.pdf.
В ожидании