Исследование солнечных параболических коллекторов для использования в системах теплоснабжения частных домов



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  1. Jaramillo OA, Borunda M, Velazquez-Lucho KM, Robles M. Parabolic trough solar collector for low enthalpy processes: an analysis of the efficiency enhancement by using twisted tape inserts. Renew Energy 2016;93:125–41. http://dx.doi.org/10. 1016/j.renene.2016.02.046.

  2. Jaramillo OA, Venegas-Reyes E, Aguilar JO, Castrejón-García R, Sosa-Montemayor F. Parabolic trough concentrators for low enthalpy processes. Renew Energy 2013;60:529–39. http://dx.doi.org/10.1016/j.renene.2013.04.019.

  3. Macedo-Valencia J, Ramírez-Ávila J, Acosta R, Jaramillo OA, Aguilar JO Design. construction and evaluation of parabolic trough collector as demonstrative prototype. Energy Procedia 2014;57:989–98. http://dx.doi.org/10.1016/j.egypro. 2014.10.082.

  4. De Oliveira Siqueira AM, Gomes PEN, Torrezani L, Lucas EO, Da Cruz, Pereira GM. Heat transfer analysis and modeling of a parabolic trough solar collector: an analysis. Energy Procedia 2014;57:401–10. http://dx.doi.org/10.1016/j.egypro. 2014.10.193.

  5. Filho VCP, De Sá AB, Passos JC, Colle S. Experimental and numerical analysis of thermal losses of a parabolic trough solar collector. Energy Procedia 2014;57:381–90. http://dx.doi.org/10.1016/j.egypro.2014.10.191.

  6. Bellos E, Tzivanidis C, Antonopoulos KA, Gkinis G. Thermal enhancement of solar parabolic trough collectors by using nanofluids and converging-diverging absorber tube. Renew Energy 2016;94:213–22. http://dx.doi.org/10.1016/j.renene.2016. 03.062.

  7. Kaloudis E, Papanicolaou E, Belessiotis V. Numerical simulations of a parabolic trough solar collector with nanofluid using a two-phase model. Renew Energy 2016;97:218–29. http://dx.doi.org/10.1016/j.renene.2016.05.046.

  8. Bouvier JL, Michaux G, Salagnac P, Kientz T, Rochier D. Experimental study of a micro combined heat and power system with a solar parabolic trough collector coupled to a steam Rankine cycle expander. Sol Energy 2016;134:180–92. http://dx.doi.org/10.1016/j.solener.2016.04.028.

  9. Toghyani S, Baniasadi E, Afshari E. Thermodynamic analysis and optimization of an integrated Rankine power cycle and nano-fluid based parabolic trough solar collector. Energy Convers Manag 2016;121:93–104. http://dx.doi.org/10.1016/j. enconman.2016.05.029.

  10. Jafari Mosleh H, Mamouri SJ, Shafii MB, Hakim Sima A. A new desalination system using a combination of heat pipe, evacuated tube and parabolic through collector. Energy Convers Manag 2015;99:141–50. http://dx.doi.org/10.1016/j. enconman.2015.04.028. 1016/j.solener.2012.01.009.

  11. Dincer I. Energy and environmental impacts: present and future perspectives. Energy Sources 1998;20(4/5):427 – 53.

  12. Dincer I. Renewable energy, environment and sustainable development. Proceedings of the World Renewable Energy Congress V, Florence, Italy; 1998. p. 2559– 62.

  13. Rosen MA. The role of energy efficiency in sustainable development. Technol Soc 1996;15(4):21 – 6.

  14. Dincer I, Rosen MA. A worldwide perspective on energy, environment and sustainable development. Int J Energy Res 1998;22(15):1305– 21.

  15. Solar Energy, Photovoltaics, and Domestic Hot Water: A Technical and Economic Guide for Project Planners, Builders, and Property Owners

  16. Adaramola, M. (Ed.), 2014. Solar energy: application, economics, and public perception. CRC Press.

  17. A.H. Elsheikh, S.W. Sharshir, M.E. Mostafa, F.A. Essa, M.K.A. Ali Applications of nanofluids in solar energy: a review of recent advances Renew. Sustain. Energy Rev., 82 (2018), pp. 3483-3502

  18. Kalogirou S. The potential of solar industrial process heat applications. Appl Energy 2003;76:337–61.

  19. ASHRAE. Handbook of HVAC Applications, Atlanta; 1995 [chapter 30].

  20. Spate F, Hafner B, Schwarzer K. A system for solar process heat for decentralised applications in developing countries. Proceedings of ISES Solar World Congress, Jerusalem, Israel on CD-ROM; 1999.

  21. Schweiger H. Optimisation of solar thermal absorber elements with transparent insulation. Thesis, Universitat Politecnica de Catalunya, Terrassa, Barcelona, Spain; 1997.

  22. Benz N, Hasler W, Hetfleish J, Tratzky S, Klein B. Flat-plate solar collector with glass TI. Proceedings of Eurosun’98 Conference on CD-ROM, Portoroz, Slovenia; 1998.

  23. Kalogirou S, Eleftheriou P, Lloyd S, Ward J. Design and performance characteristics of a parabolic-trough solarcollector system. Appl Energy 1994;47:341–54.

  24. Seitel SC. Collector performance enhancement with flat reflectors. Solar Energy 1975;17:291–5.

  25. Perers B, Karlsson B, Bergkvist M. Intensity distribution in the collector plane from structured booster reflectors with rolling grooves and corrugations. Solar Energy 1994;53(2): 215–26.

  26. Kalogirou S. Solar energy utilisation using parabolic trough collectors in Cyprus. MPhil Thesis. The Polytechnic of Wales; 1991.

  27. Kearney DW, Price HW. Solar thermal plants-LUZ concept (current status of the SEGS plants). Proceedings of the Second Renewable Energy Congress, Reading UK, vol. 2.; 1992. p. 582–8.

  28. Grasse W. Solar PACES Annual Report, DLR Germany;1995.

  29. Kalogirou S, Eleftheriou P, Lloyd S, Ward J. Low cost high accuracy parabolic troughs: construction and evaluation. Proceedings of the world renewable energy congress III, Reading, UK, vol. 1.; 1994. p. 384–6.

  30. Lupfert E, Geyer M, Schiel W, Zarza E, Gonzalez-Anguilar RO, Nava P. Eurotrough: a new parabolic trough collector with advanced light weight structure. Proceedings of Solar Thermal 2000 International Conference, on CD-ROM, Sydney, Australia; 2000.

  31. Geyer M, Lupfert E, Osuna R, Esteban A, Schiel W, Schweitzer A, Zarza E, Nava P, Langenkamp J, Mandelberg E. Eurotrough: parabolic trough collector developed for cost efficient solar power generation. Proceedings of 11th Solar PACES International Symposium on Concentrated Solar Power and Chemical Energy Technologies on CD-ROM, Zurich, Switzerland; 2002.

  32. Pitz-Paal R. Concentrating solar technologies: the key to renewable electricity and process heat for a wide range of applications. Proceedings of the World Renewable Energy Congress VII on CD-ROM, Cologne, Germany; 2002.

  33. Romero M, Buck R, Pacheco JE. An update on solar central receiver systems projects and technologies. J Solar Energy Engng 2002;124(2):98–108.

  34. Schwarzbo¨zl P, Pitz-Paal R, Meinecke W, Buck R. Costoptimized solar gas turbine cycles using volumetric air receiver technology. Proceedings of the Renewable Energy for the New Millennium, Sydney, Australia; 2000. p. 171–7.

  35. Chavez JM, Kolb GJ, Meinecke W. In: Becker M, Klimas PC, editors. Second generation central receiver technologies: a status report. Karlsruhe, Germany: Verlag; 1993.

  36. Патент РФ № 2464694, опубликовано 10.11.2012, Бюл. №31// Солнечная многофункциональная сильноконцентрирующая энергоустановка/ Абдуллаев Абдул-Гамид Ахмедович, Стребков Дмитрий Семенович

  37. Патент РФ № 2466489, опубликовано 10.11.2012 Бюл. № 31// Солнечная многофункциональная сильноконцентрирующая энергоустановка/ Абдуллаев Абдул-Гамид Ахмедович, Стребков Дмитрий Семенович



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