Experimental study of heat-insulating aerogel-based nanomaterials

Experimental study of heat-insulating aerogel-based nanomaterials

Автор: Baikov I.R., Smorodova O.V., Trofimov A.Yu., Kuznetcova E.V.

Журнал: Nanotechnologies in Construction: A Scientific Internet-Journal @nanobuild-en

Рубрика: Power engineering nanotechnologies

Статья в выпуске: 4 Vol.11, 2019 года.

Бесплатный доступ

Research and synthesis of materials with fundamentally new properties play the key role in the development of modern science and technology. The most perspective materials are considered to be aerogels: nanostructured materials with many useful properties. The mesoporous structure of airgels determines their widespread use, both in industry and in science. Over the past few decades, nanostructured silica-based material has become an integral part of many industry segments: thermal and noise insulation, electronics, chemistry, medicine, environmental protection, industrial and fire safety, energy, aerospace industry, consumer goods and military technology. The article discusses an experimental study of the heat-shielding properties of a heat-insulating material based on silicon oxide airgel – Insuflex. This is a flexible rolled material used for thermal insulation of elements of technological installations, pipelines, valves and control valves. Using the method of ordinal statistics, the exponential dependence of the coefficient of thermal conductivity of the airgel on the average temperature of the sample is determined. The results obtained indicate the possibility of energy-efficient use of the material in heat supply and heat consumption systems.

Еще

Thermal conductivity, thermal insulation, aerogel, modeling, measurement

Короткий адрес: https://sciup.org/142227480

IDR: 142227480   |   DOI: 10.15828/2075-8545-2019-11-4-462-477

Список литературы Experimental study of heat-insulating aerogel-based nanomaterials

  • Baikov I.R., Smorodova O.V., Kitaev S.V. Investigation of properties of liquid ceramic thermal insulation materials. Nanotehnologii v stroitel’stve = Nanotechnologies in Construction. 2018, Vol. 10, no. 5, pp. 106–121. DOI: dx.doi. org/10.15828/2075- 8545-2018-10-5-106-121. (In Russian).
  • Kistler S.S. Coherent expanded aerogels and jellies. Nature. 1931. Vol. 127 (3211). P. 741.
  • Pimenov V.G., Sheveleva Ye.Ye., Sakharov A.M. Ustanovka dlya sverkhkriticheskoy sushki: izgotovleniye, opyt raboty i polucheniye nizkoplotnykh polimernykh aerogeley [Installation for supercritical drying: manufacturing, work experience and obtaining low-density polymer airgels].Sverkhkriticheskiye flyuidy: Teoriya i praktika [Supercritical fluids: Theory and practice]. 2011. Vol. 6. No. 4. Pp. 77–87. (In Russian).
  • Pierre A.C., Pajonk G.M. Chemistry of Aerogels and Their Applications. Chem. Rev. 2002. V. 102. pp. 4243–4265.
  • Rubtsov I.V., Denisov I.A., Varlamov B.S. Aerogel’ – material budushchego [Airgel – the material of the future].V sbornike: V Mezhdunarodnaya nauchno-prakticheskaya konferentsiya molodykh uchenykh, posvyashchennaya 54-y godovshchine poleta YU.A. Gagarina v kosmos sbornik nauchnykh statey. Filial VUNTS VVS «VVA» imeni professora N.Ye. Zhukovskogo i YU.A. Gagarina [In the collection: V International scientific and practical conference of young scientists dedicated to the 54th anniversary of the flight of Yu.A. Gagarin in space collection of scientific articles. Branch of VUNC Air Force “VVA” named after Professor N.E. Zhukovsky and Yu.A. Gagarin] (Krasnodar). 2015. С. 63–67. (In Russian).
  • Hwang S.E., Jang H.H., Hyun H.H., Ahn Y.S. Effective preparation of crack-free silica aerogels via ambient drying. J. Sol- Gel Sci. Techn. 2007. No. 41. Pp.139–146.
  • Yokogawa H. Thermal Conductivity of Silica Aerogels. Handbook of Sol_Gel Science & Technology‖, vol. 2(13). 2005. Kluwer Academic Publishers, New York, USA.
  • Dowson M., Harrison D., Craig S., Gill Z. Improving the Thermal Performance of Single Glazed Windows using Translucent Granular Aerogel. International Journal of Sustainable Engineering. 2011. No. 4(3). Рр. 266–280.
  • Men’shutina N.V., Katalevich A.M., Smirnova I. Polucheniye aerogeley na osnove dioksida kremniya metodom sverkhkriticheskoy sushki [Obtaining airgels based on silicon dioxide by the method of supercritical drying]. Sverkhkriticheskiye flyuidy: Teoriya i praktika [Supercritical fluids: Theory and practice.] 2013. Vol. 8. No 3. Pp. 49–55. (In Russian).
  • Pustovgar A.P., Vedenin A.D. Teploizolyatsionnyye nanokompozity na osnove aerogelya kremnezema [Heat-insulating nanocomposites based on silica airge]. Nauchno-tekhnicheskiy vestnik Povolzh’ya [Scientific and Technical Bulletin of the Volga Region]. 2013. No 1. Pp. 252–254. (In Russian). Available at: https://elibrary.ru/download/elibrary_18800022_16720559.pdf. (accessed: 10.08.2019).
  • Buznik V.M., Kablov Ye.N., Koshurina A.A. Materialy dlya slozhnykh tekhnicheskikh ustroystv arkticheskogo primeneniya [Materials for complex technical devices of Arctic use]. Nauchno-tekhnicheskiye problemy osvoyeniya Arktiki [Scientific and technical problems of Arctic development] RAN. M.: Nauka, [RAS. M.: Nauka,] 2015. Pp. 275–285. (In Russian).
  • Dolbin A.V., Khlystyuk M.V., Yesel’son V.B., Gavrilko V.G., Vinnikov N.A., Basnukayeva R.M. Sorbtsiya vodoroda kremniyoksidnym aerogelem pri nizkikh temperaturakh [Hydrogen sorption by silicon oxide airgel at low temperatures]. Fizika nizkikh temperature [Low Temperature Physics] 2018. Vol. 44. No 2. Pp. 191–196. (In Russian). Available at: https://elibrary.ru/download/ elibrary_32266236_44926583.pdf. (accessed: 10.08.2019).
  • Men’shutina N.V., Katalevich A.M., Lebedev A.Ye. Nanostrukturirovannyye materialy na osnove dioksida kremniya: aerogel’, kserogel’, kriogel’ [Nanostructured materials based on silicon dioxide: airgel, xerogel, cryogel]. Yestestvennyye i tekhnicheskiye nauki [Natural and technical sciences.] 2013. No. 2 (64). Pp. 374–376. (In Russian).
  • Ismail A.A., Ibrahim I.A. Impact of supercritical drying and heat treatment on physical properties of titania/silica aerogel monolithic and its applications. J. Applied Catalysis A: General. 2008. Vol. 346 (1–2). Pp. 200–205.
  • Kwon Y.G., Choi S.Y., Kang E.S., Baek S.S. Ambient-dried silica aerogel doped with TiO2 powder for thermal insulation. J. Mater. Sci. 2000. No. 35. Pp. 6075–6079.
  • Ivanov N.N., Ivanov A.N. Teploizolyatsionnyy aerogel’ i p’yezoaktivnaya plenka PVDF – sovremennyye, perspektivnyye materialy dlya kosmicheskoy tekhniki i kosmicheskogo priborostroyeniya [Heat-insulating airgel and piezoactive PVDF film – modern, promising materials for space technology and space instrument engineering].Vestnik NPO im. S.A. Lavochkina [Issue NPO after S.A. Lavochkin.] 2011. No 2 (8). Pp. 46–52. (In Russian). Available at: https://elibrary.ru/download/elibrary_16386904_43616464. pdf. (accessed: 10.08.2019).
  • Kuznetsova Ye.V., Turumtayev G.R., Khristolyubova D.V. Ekonomicheskoye obosnovaniye primeneniya sovremennykh teploizolyatsionnykh materialov v stroitel’noy otrasli [The economic rationale for the use of modern thermal insulation materials in the construction industry]. Yevraziyskiy yuridicheskiy zhurnal [Eurasian Law Journal.] 2018. No. 11 (126). Pp. 393–394. (In Russian).
  • Askhadullin R.Sh., Osipov A.A., Gulevskiy V.A., Ul’yanov V.V., Ivanov I.I., Kharchuk S.Ye. Issledovaniye mekhanizmov sinteza anizotropnykh nanostruktur v zhidkikh metallakh. Svoystva i perspektivnyye oblasti ikh primeneniya [Study of the synthesis mechanisms of anisotropic nanostructures in liquid metals. Properties and promising areas of their application]//V sbornike: Trudy regional’nogo konkursa proyektov fundamental’nykh nauchnykh issledovaniy [In the collection: Proceedings of the regional competition of fundamental scientific research projects] Kaluga, 2016. Pp. 84–97. (In Russian). Available at: https://elibrary.ru/ download/elibrary_28430107_60072610.pdf. (accessed: 10.08.2019).
  • Razd’yakonova G.I., Kokhanovskaya O.A., Likholobov V.A. Sintez poroshkov aerogel’nogo tipa na osnove tekhnicheskogo ugleroda [Synthesis of airgel-type powders based on carbon black].Perspektivnyye materialy [Promising material]. 2014. No. 8. Pp. 68–74. (In Russian). Available at: https://elibrary.ru/download/elibrary_21844829_77073953.pdf. (accessed: 10.08.2019).
  • Martynov P.N., Askhadullin R.SH., Yudintsev P.A. Aerogel’ ALOOH: polucheniye, svoystva, primeneniye [Airgel ALOOH: production, properties, application]. Nanotekhnika [Nanotechnology]. 2006. No. 1 (5). Pp. 35–41. (In Russian).
  • Vedenin A.D., Vityaz’ P.A., Galinovskiy A.L., Ivanova I.S., Mazalov YU.A., Pustovgar A.P., Sudnik L.V. Eksperimental’noye issledovaniye teploizolyatsionnykh aerogel’nykh kompozitov gidrotermal’nogo reaktora [An experimental study of heat-insulating airgel composites of a hydrothermal reactor]. Tekhnologiya metallov [Metal Technology]. 2016. No. 4. Pp. 43–47. (In Russian).
  • Kiyamov I.K., Vachitova R.I., Saracheva D.A., Mazankina D.V., Sitdikova I. P. The use of nanomaterials in pipe insulation. Nanotehnologii v stroitel’stve = Nanotechnologies in Construction. 2019, Vol. 11, no. 2, pp. 194–202. DOI: 10.15828/2075-8545- 2019-11-2-194-202.
  • Saati T. Prinyatiye resheniy pri zavisimostyakh v obratnykh svyazyakh: Analiticheskiye seti [Decision making with dependencies in feedbacks: Analytical networks]/ per. s angl.; nauch. red. A.V. Andreychenkov, O.N. Andreychenkova [trans. from English; scientific ed. A.V. Andreichenkov, O.N. Andreichenkova]. Moskva. Izdatel’stvo LKI [Moscow: Publishing house LCI], 2008. 360 p. (In Russian).
Еще
Статья научная
SciUp 2024 © 2024 ©