SAFETY OF BUILDING SYSTEMS. ECOLOGICAL PROBLEMS OF CONSTRUCTION PROJECTS. GEOECOLOGY

Mathematical model of heat-mass exchange processes in a flat solar collector SUN 1

Вестник МГСУ 1/2016
  • Tunik Aleksandr Aleksandrovich - National Research Irkutsk State Technical University (NR ISTU) degree-seeking student, Department of Engineering Communications and Life Support Systems, Heat-and-power engineer, Department of Energy Account, National Research Irkutsk State Technical University (NR ISTU), 83 Lermontova str., Irkutsk, 664074, Russian Federation; Этот e-mail адрес защищен от спам-ботов, для его просмотра у Вас должен быть включен Javascript .

Страницы 126-142

In a flat solar collector SUN 1 The active development of environmental friendly energy sources alternative to HPPs is currently of great importance in the world. Such alternative energy sources are: water, ground, sun, wind, biofuel, etc. If we have a look at the atlas of solar energy resources on the territory of Russia, we can make a conclusion, that in many regions of our country solar activity level allows using solar collector. Though the analysis of different models of solar collector showed, that most of them are ineffective in the regions with cold climate, though the solar activity of these regions is of a great level. In this regard, a mathematical model of heat-mass exchange processes in flat solar collectors is introduced in this article. The model was a basis for the development of a new solar collector, named SUN 1, which has an original heating tubes form. This form allows heat transfer medium to be under the influence of solar energy for a longer time and consequently to warm to a higher temperature, increasing the warming rapidity.

DOI: 10.22227/1997-0935.2016.1.126-142

Библиографический список
  1. Solovyova E.G., Kondratenkov A.N. Sistema avtonomnogo energosnabzheniya zdaniya v usloviyakh ІІ klimaticheskoy zony [Independent Power Supply System of a Building in the Second Climate Zone]. Vestnik MGSU [Proceedings of Moscow State University of Civil Engineering]. 2013, no. 10, pp. 208—215. (In Russian)
  2. Alferov Zh.I., Andreev V.M., Zimigorova N.S., Tret’yakov D.N. Fotoelektricheskie svoystva geteroperekhodov AlGaAs-GaAs [Photovoltaic Properties of the Heteroface Junction AlGaAs-GaAs]. FTP. 1969, vol. 3, no. 11, pp. 1633—1637. (In Russian)
  3. Frid S.E., Kolomiets Yu.G., Mordynskiy A.V., Suleymanov M.Zh., Arsatov A.V., Oshchepkov M.Yu. Effektivnost’ solnechnykh vodonagrevateley v klimaticheskikh usloviyakh Rossii [Effectiveness of Solar Water Heaters in the Climatic Conditions of Russia]. Izvestiya vysshikh uchebnykh zavedeniy. Severo-Kavkazskiy region. Seriya: Tekhnicheskie nauki [News of the Institutions of Higher Education. North Caucasian Region. Series: Technical Sciences]. 2012, no. 6, pp. 21—26. (In Russian)
  4. Takaev B.V., Kazandzhan B.I., Solodov A.P. Vozdushnyy solnechnyy kollektor s prozrachnoy teplovoy izolyatsiey kapillyarnogo tipa [Air-type Solar Collector with Transparent Heat Insulation of Capillary Type]. 1-ya Vserossiyskaya shkola-seminar molodykh uchenykh i spetsialistov : sbornik nauchnykh trudov [1st All-Russian School-Seminar of Young Scientists and Specialists: Collection of Scientific Articles]. Moscow, MEI Publ., 2002, pp. 256—261. (In Russian)
  5. Bayzhabaginov A.M., Bulatbaev F.N., Bulatbaeva Yu.F. Sravnitel’nyy analiz effektivnosti raboty solnechnykh elementov dlya vybora ob”ekta issledovaniya i vnedreniya [Comparative Analysis of Solar Elements Effectiveness for Choosing the Subject of Research and Implementation]. Strategiczne putania swiatowej nauki — 2014 : materialy X Mezhdunarodnoy nauchno-prakticheskoy konferentsii [Proceedings of the 10th International Science and Practice Conference “Strategiczne putania swiatowej nauki — 2014”]. 2014, vol. 35, Przemyśl: Nauka i studia Publ., pp. 25—29. (In Russian)
  6. Rakhnov O.E., Saklakov I.Yu., Potapov A.D. Osobennosti postroeniya skhem teplosnabzheniya ot avtonomnykh istochnikov dlya krupnykh proizvodstvennykh kompleksov i logisticheskikh tsentrov v urbosistemakh na ekologicheskikh printsipakh [Features of Construction Schemes of Self-heating Sources for Large Industrial Complex and Logistics Centers in Urbosystems on Ecological Principles]. Vestnik MGSU [Proceedings of Moscow State University of Civil Engineering]. 2013, no. 11, pp. 177—187. (In Russian)
  7. Popel’ O.S., Frid S.E., Kolomiets Yu.G., Kiselev S.V., Terekhova E.N. Atlas resursov solnechnoy energii na territorii Rossii [Atlas of Solar Energy Sources on Russian Territory]. Moscow, Ob”edinennyy institut vysokikh temperatur RAN Publ., 2010, 54 p. (In Russian)
  8. Gagarin V.G., Guvernyuk S.V. Matematicheskaya model’ emissii volokon pri obduve vozdushnym potokom mineralovatnykh izdeliy i ee ispol’zovanie pri prognozirovanii dolgovechnosti uteplitelya ventiliruemogo fasada [Mathematical Model of Filament Emission during the Blow-off of Mineral-Cotton Products with Air Flow and its Use while Forecasting the Durability of Ventilated Faсade Insulation]. Vestnik Otdeleniya stroitel’nykh nauk Rossiyskoy akademii arkhitektury i stroitel’nykh nauk [Proceedings of Construction Sciences Department of the Russian Academy of Architecture and Construction Sciences]. 2009, no. 13, p. 135. (In Russian)
  9. Troshkina G.N., Chertishchev V.V. Raschet parametrov sistemy solnechnogo teplosnabzheniya [Calculating the Parameters of Solar Heat Supply System]. Materialy dokladov Rossiyskogo natsional’nogo simpoziuma po energetike [Materials of the Reports of Russian National Symposium on Energy Industry]. Ekaterinburg, 2001, pp. 297—299. (In Russian)
  10. Khavanov P.A., Markevich Yu.G., Chulenev A.S. Fiziko-matematicheskaya model’ teploobmena v kondensatsionnykh poverkhnostyakh teplogeneratorov [Physical and Mathematical Model of Heat Transfer in Condensation Surfaces of Heat Generators]. Internet-Vestnik VolgGASU. Seriya: Politematicheskaya [Internet Proceedings of Volgograd State University of Architecture and Civil Engineering. Polythematic Series]. 2014, no. 4 (35), article 22. Available at: http://vestnik.vgasu.ru/attachments/22KhavanovMarkevichChulenev-2014_4_35_.pdf. (In Russian)
  11. Kuznetsov G.V., Sheremet M.A. Matematicheskoe modelirovanie teplomassoperenosa v usloviyakh smeshannoy konvektsii v pryamougol’noy oblasti s istochnikom tepla i teploprovodnymi stenkami [Mathematical Modeling of Heat-Mass Exchange in the Conditions of Mixed Convection in a Rectangular Region with Heating Source and Heat Conductive Walls]. Teplofizika i aeromekhanika [Thermal Physics and Air Mechanics]. 2008, vol. 15, no. 1, pp. 107—120. (In Russian)
  12. Tabunshchikov Yu.A., Brodach M.M. Matematicheskoe modelirovanie i optimizatsiya teplovoy effektivnosti zdaniy [Mathematical Modelling and Optimization of Thermal Effectiveness of Buildings]. Moscow, AVOK-PRESS Publ., 2002, 194 p. (In Russian)
  13. Klyayn S.A., Daffi Dzh., Bekman U.A. Analiz perekhodnykh rezhimov v solnechnykh kollektorakh tipa «goryachiy yashchik» [Analysis of the Transient Modes in Solar Collectors of the Type “Hot Box”]. Trudy Amerikanskoy obshchestva inzhenerov-mekhanikov. Seriya A: Energeticheskie mashiny i ustanovki [Works of the American Society of Mechanic Engineers. Series A: Energy-Converting Machinery and Systems]. 1974, no. 2, 30 p. (In Russian)
  14. Klein S.A. The Effects of Thermal Capacitance upon the Performance. Transactions of the Conference on the Use of Solar Energy. University of Arizona Press, vol. 2, part 1, 74. 1958.
  15. Hottel H.C., Woertz B.B. Performance of Flat-Plate Collectors. Trans. ASME. 64, 91, 1942.
  16. Rettikh G. Kollektory i geliotermicheskie sistemy [Collectors and Solar Energy Systems]. Russian Translation. Minsk, Mezhdunarodnyy gosudarstvennyy ekologicheskiy universitet im. A.D. Sakharova Publ., 2007, 43 p. (In Russian)
  17. Burdonov A.E., Barakhtenko V.V., Zelinskaya E.V., Tolmacheva N.A. Teploizolyatsionnyy material na osnove termoreaktivnykh smol i otkhodov teploenergetiki [Thermal Insulation Materials Based on Thermosetting Resins and Thermal Energy Waste]. Stroitel’nye materialy [Construction Materials]. 2015, no. 1, pp. 48—52. (In Russian)
  18. Tolstoy M.Yu., Akinina N.V., Tunik A.A. Patent 112364 RU, MPK F24J2/24. Solnechnyy kollektor [Russian Patent 112364 RU, MPK F24J2/24. Solar Collector]. No. 2011130485/06 ; appl. 21.07.2011 ; publ. 10.01.2012, bulletin no. 1. Patent Holder GOU IrGTU. (In Russian)
  19. Sadilov P.V., Petrenko V.N. Vnedrenie avtomatizirovannoy gelioustanovki goryachego vodosnabzheniya v g. Sochi [Implementation of the Automated Solar Units of Hot Water Supply in Sochi]. Velikie reki — 2004 : materialy Mezhdunarodnogo nauchno-promyshlennogo foruma (18—21 maya 2004 g.) [Great Rivers — 2004 : Materials of the International Scientific Industrial Forum (May 18—21, 2004)]. Nizhniy Novgorod, 2004, p. 40. (In Russian)
  20. Erofeev V.Ya., Kabanov M.V., Tarasova A.I., Gupalo D.F. Patent 2313046 RU, MPK F24J2/38. Avtonomnaya sistema slezheniya za peremeshcheniem solntsa po nebosvodu [Russian Patent 2313046 RU, MPK F24J2/38. Automated Tracking System of Solar Motion in the Sky]. No. 2006103187/06 ; appl. 03.02.2006 ; publ. 20.12.2007. Patent holder: Institut monitoringa klimaticheskikh i ekologicheskikh sistem. (In Russian)
  21. Shinyakov Yu.A., Shurygin Yu.A., Arzhanov V.V., Osipov A.V., Teushchakov O.A., Arzhanov K.V. Avtomatizirovannaya fotoelektricheskaya ustanovka s povyshennoy energeticheskoy effektivnost’yu [Automated Photoelectric Unit with Increased Energy Efficiency]. Doklady tomskogo gosudarstvennogo universiteta sistem upravleniya i radioelektroniki [Reports of Tomsk State University of Control Systems and Radio Electronics]. 2011, no. 2-1 (24), pp. 282—287. (In Russian)

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