Концентрация и передача солнечного света в подземные помещения

Статья исследует перспективы использования естественного света в световодных системах освещения как нового поколения устройств. Работа охватывает принципы дневного освещения, факторы эффективности, предлагая рекомендации для проектирования. Описывается система Light Channel с использованием программного обеспечения TracePro для оптического проектирования. Рассматривается применение солнечного концентратора для снижения потерь освещенности в световодах, особенно в подземных зданиях. Выводы предоставляют основу для повышения эффективности световодных систем освещения.

1. . Zhan Bing. Primary Study of Underground Lighting Design with Imitation of Natural Light // Section of Architectural Physics of the Chinese Architectural Society. Buildings and the Physical Environment of Cities in the Process of Urbanization: Proceedings of the 10th National Conference on Architectural Physics. Chinese Architectural Society, 2008. P. 562-565.

2. . Telegina A. E. Lighting as a Factor in the Formation of Exposition and Exhibition Space: Master’s Thesis in the Direction of Training: 51.04. 04//Museology and Protection of Cultural and Natural Heritage Sites. 2021. – P. 23

3. . Shirvanov R. B. Influence of the level of illumination of workplaces on working conditions (on the example of the Republic of Kazakhstan) // XXI century. Technosphere Safety. – 2021. – T. 6 (2). P. 189-200.

4. . Wang Q, Xu H, Zhang F, et al. Influence of color temperature on comfort and preference for LED indoor lighting//Optik–2017.–№129.– С. 21-29.

5. . Dangol R., Islam M. S., Hyvärinen M, et al. User acceptance studies for LED office lighting: Preference, naturalness and colourfulness // Lighting Research & Technology.– 2015.– Т. 47(1). – С. 36-53.

6. . Hoisington A. J., Stearns-Yoder K. A., Schuldt S. J., et al. Ten questions concerning the built environment and mental health//Building and environment. – 2019. – № 155. – С. 58-69.

7. . Robson E. R. School Architecture: Being Practical Remarks on the Planning, Designing, Building, and Furnishing of School-houses // J. Murray. – 1874.

8. . Ding Lixing, Ou Xiufeng, Lu Haifeng, Zhou Zhaogen, Yang Kailong, Zeng Yuanguang, Yang Hanbin. Light Guide Technology and Its Application in Construction // Energy Saving in Buildings. – 2011. – № 1. – P. 64-67.

9. . B. Bouchet, M. Fontoynont. Daylighting of Underground Spaces: Design Rules//Energy and Buildings. – 1996. – Т.23(3). – С. 293-298.

10. . Du Fang.Energy Saving Lighting Design of Underground Buildings Energy Saving in Buildings. – 2011(1).

11. . Wang Aiying. Introduction to Fiber Optic Lighting System // Collection of Special Reports of the First Scientific and Technical Seminar on the Application of Fiber Optic and Fiber Optic Optics in the Field of Lighting. Beijing: China Lighting Society. – 2000. – P. 111-118.

12. . Xiang Dong. Study of Light Guide Lighting System for Road Tunnels Lighting Design. – 2012. – T. 7(7). – P. 41-49.

13. . Wang Hongwei. Principles and Applications of Dynamic Natural Lighting Architecture: Basic Principles • Design System•Case Study // Chinese Publishing House «Electric Power Press». – 2007.

14. . M. Paroncini. Monitoring of a Light-pipe System. Solar Energy. – 2007. – Т. 82(4). – С. 1180-1186.

15. . Zhi Liang. Method of Calculating Lighting Using Light Guides for Partial Illumination of Underground Premises in Green Construction// Green Construction. – 2014. – T. 6(04). – P. 26-29.

16. . Li Zhenggang. Daylight Lighting System from Roof Light Guide and Its Application // Waterproofing of Buildings in China. – 2013. – № 15. – S. 42-46.

17. . Guo Xiaoyang. Analysis of the application of the light-guided lighting system for lighting underground premises in buildings and its installation // Science and Innovations. – 2014. – № 19. – S. 51-52.

18. . Cui Junlan. Analysis of the Economic Efficiency of Light-Guided Lighting in Buildings // Reform and Opening. – 2015. – № 15. – S. 30-31.

19. . Novikova I, I., Zubtsovskaya N. A., Lobkis M. A. Hygienic Regulation of Natural Lighting: Problems, Tasks, International Experience (Review Article) // Health of the Population and Habitat. – 2020. – T. 3 (324). – S. 10-15.

20. . Liu Xiaotu. Construction Physics (Third Edition)// Construction Physics (Third Edition). China Construction Industry Publishing House. – 2010.

21. . Li D. H. W., Wong S. L., Tsang C. L., et al. A study of the daylighting performance and energy use in heavily obstructed residential buildings via computer simulation techniques // Energy and buildings. – 2006. – Т. 38(11). – С. 1343-1348.

22. . Tanana O. V. Theoretical section. – 2015.

23. . Gorbarenko E.V., Shilovtseva O. A. NATURAL ILLUMINATION OF HORIZONTAL AND VERTICAL SURFACES ACCORDING TO OBSERVATIONS OF MOSCOW STATE UNIVERSITY Construction and reconstruction. – 2018. – № 4. – P. 53-63.

24. . Savelyev V. E. Design and Calculation of Natural Lighting of Premises. – 2022.

25. . Hee W. J., Alghoul M. A., Bakhtyar B., et al. The role of window glazing on daylighting and energy saving in buildings // Renewable and Sustainable Energy Reviews. – 2015. – № 42. – С. 323-343.

26. . Wu Yanpeng. Application of Green Lighting Technology by Sunlight with the Help of Light Guides in Buildings // Collection of Articles «Intelligent and Green Buildings». – 2008. – S. 483-486.

27. . M. S. Mayhoub, D. J. Carter. Hybrid lighting systems: Performance and design // Lighting Res. Technol. – 2012. – № 44. – С. 261-276.

28. . Pacheco R., Ordóñez J., Martínez G. Energy efficient design of building: A review // Renewable and Sustainable Energy Reviews. – 2012. – Т. 16(6). – С. 3559-3573.

29. . W. S. Sun, C. H. Tsuei, C. C. Kuo. Calculating the converted solar energy of sunlight in the LED hybrid light box lighting system // Lighting Res. Technol. – 2013. – № 45. – С. 495-503.

30. . Kocifaj M., Darula S., Kittler R. HOLIGILM: Hollow light guide interior illumination method – An analytic calculation approach for cylindrical lighttubes // Solar energy. – 2008. – Т. 82(3). – С. 247-259.

31. . Wang Wei, Zong Fupeng, Zhao Jianping, Chen Xiaoming, Zhang Bin.Current Situation and Prospects for the Application of Underground Lighting and Light Guide System // Journal of Lighting Engineering. – 2009. – № 20. – P. 64-68.

32. . Wu Yanpeng. Application of green lighting technology in buildings with light guides that collect sunlight. Collection of Smart and Eco-Friendly Buildings. – 2008. – Р. 483-486.

33. . Li Long, Hong Anhui. A Method of Constructing a Lighting System with a Natural Light Guide // Fujian Construction Technologies. – 2018. – No. 5. – P. 67-69.

34. . Soloviev A. K. Hollow Tubular Light Guides and Their Application for Natural Lighting of Buildings // Industrial and Civil Construction. – 2007. – No 2. – Р. 53-55.

35. . Kirpichnikova I. M., Volkova O. S., Malyugina A. A. Optimization of the choice of solar light guides for uniform illumination of the surface of premises in buildings // International Scientific Journal Alternative Energy and Ecology. – 2016. – No 7. – P. 19-24.

36. . Fil N. S. Energy-Efficient Solar Indoor Lighting Alternative Energy and Ecology (ISJAEE). – 2014. – No 5. – P. 16-19. [37]. Lighting Design Standards for Underground Buildings (CECS 45:92) https://www.docin.com/p-2187035947.html

37. . China Construction Research Institute. Technical Standards for Lighting Systems Using Light Guides JGJ/T374-2015 // China Construction Industry Publishing House. – 2016.

38. . Feng Zhikang. Optimization of the Concentration Characteristics of a Linear Focusing Cavity of the Grooved Type and the Study of the Thermal Properties of the System, Yunnan Normal University. – 2016.