Семухин Б.С.

УДК 666.1002.34

СЕМУХИН БОРИС СЕМЕНОВИЧ, докт. техн. наук, профессор,

bss@ispms.tsc.ru

Томский государственный архитектурно-строительный университет,

634003, г. Томск, пл. Соляная, 2

Институт физики прочности и материаловедения СО РАН,

634021, г. Томск, пр. Академический, 2/4

АЛТАРЕВА ЛЮДМИЛА МИХАЙЛОВНА, аспирант,

altarevalm@mail.ru

ВОТИНОВ АЛЕКСАНДР ВАЛЕРЬЕВИЧ, аспирант,

chillerus@gmail.com

ОПАРЕНКОВ ЮРИЙ ВАДИМОВИЧ, аспирант,

sprite@sibmail.com

Томский государственный архитектурно-строительный университет,

634003, г. Томск, пл. Соляная, 2

ИСПОЛЬЗОВАНИЕ  ОКСИДОВ  ТИТАНА  И  ЦИРКОНИЯ  В  ПРОИЗВОДСТВЕ  ПЕНОСТЕКОЛЬНЫХ  МАТЕРИАЛОВ  СТРОИТЕЛЬНОГО  НАЗНАЧЕНИЯ

В статье рассмотрены результаты исследований физико-химических, механических свойств нового пеностеклокристаллического строительного материала, которые проявляются в результате применения добавок наноструктурных оксидов ZrO2,TiO2. Показано, что наибольшего эффекта можно добиться, используя самые малые дозы. Эффект позволяет целенаправленно управлять производством многофункциональных строительных материалов нового поколения. Достигнуть высоких результатов возможно путем построения и регулировки структуры материала на разных структурных уровнях. В заключение делается вывод о влиянии энергоинформационных параметров при синтезе пеностеклокристаллических материалов.

Ключевые слова: наноструктура; пеностекло; модифицирующие добавки; наноархитектура.

Библиографический список

  1. New cementitious composite building material with enhanced toughness.Ferro / G. Tulliani, J.M.,Lopez, A.,Jagdale, P.Theoretical & Applied Fracture Mechanics. Apr2015. – V. 76. – P. 67–74. – 8 p.
  2. Study of influence of input vethod of nano-ctructuring additive on pitch matrix properties / Nasibuln A.V., Petrov A.V., Beiylina N.Yu., Dogadin G. Izvestiya Vysshikh Uchebnykh Zavedenii. Seriya Khimiya i Khimicheskaya Tekhnologiya. 2014. – V. 57. – Issue 5. – P. 95–95. 1/6 p.
  3. Physico-mechanical, microstructure characteristics and fire resistance of cement pastes containing Al2O3 nano-particles.Heikal, Mohamed,Ismail, M.N.,Ibrahim, N.S.Construction & Building Materials. Aug2015. – V. 91. – P. 232–242.
  4. Influence of incorporation of nano-silica and recycled aggregates on compressive strength and microstructure of concrete. Mukharjee, Bibhuti Bhusan,Barai, Sudhirkumar V.Construction & Building Materials. Nov2014. – V. 71. – P. 570–578.
  5. Impact of Nano-Cr2O3Addition on the Properties of Aluminous Cements Containing Spinel.Nano-Cr2O3poveikis aliuminatinių cementų, turinčių špinelių, savybėms.Otroj Sasan, Materials Science / Medziagotyra. – 2015. – V. 21. Issue 1. – P. 129–135.
  6. Influences of nano-TiO2 on the properties of cement-based materials: Hydration and drying shrinkage / Zhang, Rui,,Cheng, Xin,,Hou, Pengkun,Ye, Zhengmao // Construction & Building Materials. Apr 2015. – V. 81. – P. 35–41.
  7. State-of-the-art report on use of nano-materials in concrete.Safiuddin / Md.,Gonzalez, Marcelo,Cao, Jingwen,Tighe, Susan L. // International Journal of Pavement Engineering. Nov2014. – V. 15. – Issue 10. – P. 940–949.
  8. Effects of Sb2O3on the Mechanical Properties of the Borosilicate Foam Glasses Sintered at Low Temperature / Chenxi Zhai,Zhe Li,Yumei Zhu,Jing Zhang,Xiuduo Wang,Lejun Zhao, Liuming Pan, Pengfei Wang,// Advances in Materials Science & Engineering. – 2014. – P. 1–6.
  9. Inorganic Molybdenum Octahedral Nanosized Cluster Units, Versatile Functional Building Block for Nanoarchitectonics / Grasset, F.,Cordier, S.,Molard, Y.,Amela-Cortes, M.,Boukherroub, R.,Ravaine, S.,Mortier, M.,Ohashi, N.,Saito, N.,Haneda, H. // Journal of Inorganic & Organometallic Polymers & Materials. Mar2015. – V. 25. – Issue 2. – P. 189–204.
  10. Physical Mesomechanics as a New Paradigm at the Interface of Physics and Mechanics of a Deformable Solid / V. E. Panin and Yu. V. Grinyaev // Physical Mesomechanics. – V. 6. – No. 4. – 2003. – Pp. 9–36.
  11. Rudnev S., Semukhin B. and Klishin A. "Geometrical Modeling of Crystal Structures with Use of Space of Elliptic Riemannian Geometry // Materials Sciences and Applications. – V. 2. – No. 6. – 2011. – Pp. 526–536.
  12. Kazmina, O. Strengthening of Foam Glass Materials Nanomaterials for Structural, Functional and Biomedical Selected / O. Kazmina, B.Semukhin, A. Elistratova // Peer reviewed papers from the Russian-German Forum on Nanotechnology. May 21–24, 2013, Tomsk, Russia Applications in Advanced Materials Research. – V. 872. – P. 79–84.
  13. Семухин, Б.С.Управление структуройи свойствами пеностеклокристаллических материалов / Б.С. Семухин, Л.М. Алтарева, А.В. Вотинов, Ю.В. Опаренков // Вестник Томского государственного архитектурно-строительного университета. – 2015. – № 3(50). – С. 171–178.
  14. Николс, Г. Самоорганизациявнеравновесных системах / Г. Николс, И. Пригожин. – М. : Мир. – 1979. –C. 512.

______________________________

BORIS S. SEMUKHIN, DSc, Professor,

semoukhin@yahoo.com

Tomsk State University of Architecture and Building,

2, Solyanaya Sq., 634003, Tomsk, Russia

Institute of Strength Physics and Materials Science SB RAS,

8/2, Akademicheskii Ave., 634021, Tomsk, Russia

LYUDMILA M. ALTAREVA, Research Assistant,

milaia@sibmail.com

ALEKSANDR V. VOTINOV, Research Assistant,

chillerus@gmail.com

YURI V. OPARENKOV, Research Assistant,

sprite@sibmail.com

Tomsk State University of Architecture and Building,

2, Solyanaya Sq., 634003, Tomsk, Russia

TITANIUM AND  ZIRCONIUM  OXIDES  IN  THE  PRODUCTION  OF  GLASS  FOAM  MATERIALS

The paper presents the research results on the new glass foam material physicochemical and mechanical properties of which are obtained due to titanium and zirconium oxides additives. It is shown that the greater effect can be achieved when using the smallest portions of these oxides that allows to purposefully control the production of multifunctional construction beyond materials. A conclusion is drawn concerning the effect of energoinformational parameters in synthesizing glass foam materials.

Keywords: nanostructure; glass foam; modifying additives; nanoscale architecture.

References

  1. FerroG., Tulliani J.M., Lopez A., ,Jagdale P. New cementitious composite building material with enhanced toughness. Theoretical and Applied Fracture Mechanics. 2015. V. 76. Pp. 67–74.
  2. Nasibuln A.V., Petrov A.V., Beiylina N.Yu., Dogadin G. Study of influence of input method of nano-structuring additive on pitch matrix properties. News of Higher Educational Institutions. Chemistry and Chemical Technology. 2014. V. 57. No. 5. Pp. 95–95.
  3. Heikal Mohamed, Ismail M.N., Ibrahim N.S. Physico-mechanical, microstructure characteristics and fire resistance of cement pastes containing Al2O3 nano-particles. Construction and Building Materials. 2015. V. 91. Pp. 232–242.
  4. Bibhuti Bhusan Mukharjee, Sudhirkumar V. Barai. Influence of incorporation of nano-silica and recycled aggregates on compressive strength and microstructure of concrete. Construction and Building Materials. 2014. V. 71. Pp. 570–578.
  5. Sasan Otroj. Impact of nano-Cr2O3 addition on the properties of aluminous cements containing spinel. Materials Science. 2015. V. 21. No. 1. Pp. 129–135.
  6. Rui Zhang, Xin Cheng, Pengkun Hou, Zhengmao Ye. Influences of nano-TiO2 on the properties of cement-based materials: Hydration and drying shrinkage. Construction and Building Materials. 2015. V. 81. Pp. 35–41.
  7. Md. Safiuddin, Marcelo Gonzalez, Jingwen Cao, Susan Tighe. State-of-the-art report on use of nano-materials in concrete. The International Journal of Pavement Engineering. 2014. V. 15. No. 10. Pp. 940–949.
  8. Chenxi Zhai Zhe Li Yumei Zhu Jing Zhang Xiuduo Wang·Lejun Zhao· Liuming Pan Pengfei Wang. Effects of Sb2O3 on the mechanical properties of the borosilicate foam glasses sintered at low temperature. Advances in Materials Science and Engineering. 2014. Pp. 1–6.
  9. Cordier S., Grasset F., Molard Y., Amela-Cortes M., Boukherroub R., Ravaine S., Mortier M., Ohashi N., Saito N., Haneda H. Inorganic molybdenum octahedral nanosized cluster units, versatile functional building block for nanoarchitectonics. Journal of Inorganic and Organometallic Polymers and Materials. 2015. V. 25. No. 2. Pp. 189–204.
  10. Panin V. E., Grinyaev Yu. V. Physical Mesomechanics as a new paradigm at the interface of physics and mechanics of a deformable solid. Physical Mesomechanics. 2003. V. 6. No. 4. Pp. 9–36.
  11. Rudnev S., Semukhin B., Klishin A. Geometrical modeling of crystal structures with use of space of elliptic Riemannian geometry. Materials Sciences and Applications. 2011. V. 2. No. 6. Pp. 526–536.
  12. Kazmina O., Semukhin B., Elistratova A. Strengthening of foam glass materials. Nanomaterials for Structural, Functional and Biomedical Applications. Advanced Materials Research. 2013. V. 872. Pp. 79–84
  13. Semukhin B.S., Altareva L.M., Votinov A.V., Oparenkov Yu.V. Upravlenie strukturoi i svoistvami penosteklokristallicheskikh materialov [Foam glassceramics structure and properties control]. Vestnik TSUAB. 2015. No. 3. Pp. 171–178. (rus)
  14. Nikols G., Prigozhin I. Samoorganizatsiya v neravnovesnykh sistemakh [Salf-organization in non-equilibrium systems]. Moscow: Mir Publ., 1979. P. 512.

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