Optimizing Forms and Size of Windows for Energy Conservation

  • Authors

    • Oleg Sergeychuk
    • Viacheslav Martynov
    • Gennadii Virchenko
    • Iryna Usenko
    2018-10-13
    https://doi.org/10.14419/ijet.v7i4.8.27278
  • insolation, natural illumination, solar map, saving energy

  • The article deals with the problem of optimizing the form and size of the windows. This is important because of significant losses of heat through windows. The article demonstrates how to improve methods accepted as standard in Ukraine for calculating the natural illumination and insolation of houses.

     

     

     

  • References

    1. [1] Sergeychuk O, Martynov V, Usenko D, The definition of the optimal energy-efficient form of the building, International Journal of Engineering & Technology, Vol. 7 (3.2), (2018), pp:667-671.

      [2] Martynov V, Lyalko V, Korba D, Optimization of the location of power generating windows on the edges of buildings in historically formed university-university complexes, Interdepartmental scientific and technical collection "New technologies of construction", State Research Institute of Natural Resources of Ukraine, Vol. 62/1, (2017), pp:29-32.

      [3] Martynov V, Rational orientation of window openings of energy-efficient buildings, Energy efficiency in construction and architecture, Vol. 4, (2013), pp:185-189.

      [4] Szokolay SV, Environmental science handbook for Architects and Buildirs, The Construction Press, Lancaster London New York, (2006), pp.190.

      [5] DBN Ð’.2.5-28-2006: Daylighting and artificial lighting, Minstroj Ukainy, (Ukrainian building regulations, in Ukrainian).

      [6] Podgornyj AL, Schepetova IM, Sergeychuk OV, etc., Light-clear enclosures of buildings, Witrina, (2005).

      [7] Kazansky VM, Krasnyansky GYu, Novominsky VA, Plosky VA, Instantaneous vector transformations in the problems of building thermophysics, Applied Geometry and Engineering Graphics, Vol. 52, (1992), pp:159-162.

      [8] Yuadayev BN, Technical thermodynamics, Heat transfer, Higher school, (1988), pp:479.

      [9] Pugachev EV, Development of architectural lightology in Ukraine, Bulletin of the National Academy of Sciences of Ukraine. un-th water household, NUVG, Vol. 4 (40), (2007), pp:319-325.

      [10] Podgorny OL, Geometrical modeling of solar radiation on different surfaces, Applied Geometry and Engineering Graphics, KIBI, Vol. 54, (1993), pp:10-12.

      [11] Podgorny AL, On the real conditions of solar illumination of architectural objects and shadow formation, Applied Geometry and Engineering Graphics, KNUBA, Vol. 67, (1999), pp:16-20.

      [12] Dvoretsky AT, Morgunova VA, Sergeichuk OV, Spiridonov AB, Methods of designing immovable sun protection devices, Light & Engineering, Vol. 25, No. 1, (2017), pp:115-120.

      [13] Shkirenko S, Muravlov V, Zyma O, “Design of Composite Skin Panels with Solar Panels on the Roofâ€, International Journal of Engineering & Technology, Vol.7, No 3.2, (2018), pp: 398-400. https://doi.org/10.14419/ijet.v7i3.2.14560

      [14] Sivitska, S., Vartsaba, V., & Filonych, O. (2018). Buildings energy-efficient renovation investment. International Journal of Engineering and Technology(UAE), 7(3), 408-412. https://doi.org/10.14419/ijet.v7i3.2.14562

      [15] Leshchenko, M. V., & Semko, V. (2015). Thermal characteristics of the external walling made of cold-formed steel studs and polystyrene concrete. Magazine of Civil Engineering, 60(8), 44-55. https://doi.org/10.5862/MCE.60.6

      [16] Semko, O., Yurin, O., Avramenko, Y., & Skliarenko, S. (2017). Thermophysical aspects of reconstruction of cold roof spaces. Paper presented at the MATEC Web of Conferences, , 116 https://doi.org/10.1051/matecconf/201711602030

  • Downloads

  • How to Cite

    Sergeychuk, O., Martynov, V., Virchenko, G., & Usenko, I. (2018). Optimizing Forms and Size of Windows for Energy Conservation. International Journal of Engineering & Technology, 7(4.8), 399-403. https://doi.org/10.14419/ijet.v7i4.8.27278