{"id":566,"date":"2012-06-03T23:51:35","date_gmt":"2012-06-03T19:51:35","guid":{"rendered":"http:\/\/nanobuild.ru\/en_EN\/?p=566"},"modified":"2014-06-03T23:52:51","modified_gmt":"2014-06-03T19:52:51","slug":"nanobuild-3-2013-pages-60-70","status":"publish","type":"post","link":"https:\/\/nanobuild.ru\/en_EN\/nanobuild-3-2013-pages-60-70\/","title":{"rendered":"Nanobuild-3-2013-pages-60-70"},"content":{"rendered":"

Pages:\u00a0\u00a0 60 – 70<\/strong><\/p>\n

OPERATIONAL PROPERTIES AS THE INDICATORS OF SULFUR BINDERS NANOMODIFICATION<\/strong><\/p>\n

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Authors:<\/strong>KOROLEV Evgenij Valerjevich, Doctor of Engineering, Professor, Director of the Research and Educational Center \u00abNanotechnology\u00bb;<\/p>\n

KISELEV Denis Georgievich, postgraduate;<\/p>\n

ALBAKASOV Azamat Ilkinovich, Ph.D. in Engineering, Associate Professor, Dean of the Department of Architecture and Construction<\/p>\n

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Extended Abstract:<\/strong>\u00a0 Both computed dependence and theoretical estimation of the variation range for generalized material\u2019s quality criterion are presented. It is shown that first of all realization of nanotechnology should be held in respect to the properties which determine the area of material\u2019s application. As the particular criteria of the material\u2019s quality, it is most appropriate to use the attributes which are closely connected to the intrinsic features of the process or property being analyzed. The technology of sulfur-based binders was the area of application of nanoscale improvement of disperse phases. It was found that sulfur-based binders are chemically resistant materials (according to RU GOST 25246\u201382**). Fillers nanomodification increases resistance of materials within the predicted range of values.<\/p>\n

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Key words: <\/strong>technology of nanomodification, generalized quality criterion, sulfur-based binders, sulfur.<\/p>\n

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References: <\/em><\/strong><\/p>\n

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4. Bazhenov Yu.M. <\/em>Nanoscale-improved chemical-resistant sulfur-based building ma\u00adterials \/ Yu.M. Bazhenov, E.V. Korolev, I.Yu. Evstifeeva et al. Moscow: Russian State Agrarian University \u2013 Moscow Timiryazev Agricultural Academy. 2008. 167 p.<\/p>\n

5. Garkina I.A. <\/em>Model of destruction of composites \/ I.A. Garkina, A.M. Danilov, E.V. Korolev \/\/ Review of Applied and Industrual Mathematics. Vol. 15. \u2116 3. 2008. P. 459\u2013460.<\/p>\n

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8. Korolev E.V. <\/em>Nanomodified chemical-resistant building materials \/\/ Scientific Her\u00adald of the Voronezh State University of Architecture and Civil Engineering. Con\u00adstruction and Architecture: Construction and Architecture. Voronezh: Voronezh SUACE. 2008. \u2116 2(10). P. 51\u201359.<\/p>\n

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12. Avgustinik A.I. <\/em>Ceramics. Leningrad: Stroyizdat. 1975. 592 p.<\/p>\n

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14. Korolev E.V. <\/em>Radiation-protective and chemical resistant sulfur construction mate\u00adrials \/ E.V. Korolev, Ju.M. Bazhenov, A.I. Albakasov. Penza-Orenburg: IPK OGU. 2010. 364 p.<\/p>\n

15. Proshin A.P. <\/em>High-weight sulfur-based radiation-protective building materials \/ A.P. Proshin, E.V. Korolev, S.A. Boltyshev. Penza: PSUAC. 2005. 224 \u0441.<\/p>\n

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