A Case Study for Tunnel Lighting Lifetime Account

Year 2019, , 1101 - 1108, 30.09.2019

Mehmet Sait Cengız

https://doi.org/10.17798/bitlisfen.553245

Abstract

A
lighting device is required to provide minimum lighting level during the
operating time. Contamination on lighting device causes luminous flux to be
lost in lamp and structural imperfections to be formed on the surface of
optical elements. This deficiency in the performance of lighting makes
maintenance of lighting devices necessary. This effect formed by the common
effect of various parameters and implemented periodically is called maintenance
factor. Maintenance factor varies by lighting system, environmental conditions
and features of luminaires. In this study, calculation of maintenance factors
by years and change of lighting levels by different maintenance factors have
been analyzed for high-pressure sodium vapour luminaries in tunnel lighting.
Accordingly, increasing the maintenance factor used as multiplier in
performance calculations will decrease the energy consumed. Therefore,
increasing the Maintenance Factor increases the lighting efficiency.

 

Keywords

Efficiency, Lighting, Maintenance factor, Tunnel lighting

References

• 1. Cengiz M.S., Cengiz, Ç. 2018. Numerical Analysis of Tunnel LED Lighting Maintenance Factor, IIUM Engineering Journal. 19 (2): 154-163.
• 2. Eren, M., Kaynaklı, M., Yapici, I., Gencer, G., Yurci, Y., Cengiz, M.S., Cengiz, Ç. 2017. Numerical Analysis of Maintanance Factor for Tunnel and Road In Solid State Lighting. In: International Conference on Multidisciplinary, Science, Engineering and Technology 2017, Bitlis, 2017, October 27-29, Turkey.
• 3. Gencer, G., Eren, M., Yildirim, S., Kaynaklı, M., Palta, O., Cengiz, M.S., Cengiz, Ç. 2017. Numerical Approach to City Road Lighting Standards, In: International Conference on Multidisciplinary, Science, Engineering and Technology 2017, Bitlis, October 27-29, Turkey
• 4. CIE Technical Report, CIE–88. 2004. Guide for the Lighting of Road Tunnels and Underpasses [R]-2004
• 5. CIE Technical Report, CIE-154. 2003. The Maintenance of Outdoor Lighting Systems.
• 6. CIE Technical Report, CIE-194. 2011. On Site Measurement of the Photometric Properties of Road and Tunnel Lighting.
• 7. Gil-Martín, L.M., Gómez-Guzmán, A., Peña-García, A., 2015. Use of diffusers materials to improve the homogeneity of sunlight under pergolas installed in road tunnels portals for energy savings, Tunn. Undergr. Space Technol., 48 (1): 123–128.
• 8. Cengiz M.S., 2019. The Relationship Between Maintenance Factor and Lighting Level in Tunnel Lighting, Light & Engineering. 2019, 27 (3).
• 9. Cengiz M.S. 2019. A Simulation and Design Study for Interior Zone Luminance in Tunnel Lighting, Light & Engineering, 27 (2): 42-51.
• 10. Çıbuk M., Cengiz M.S. 2019. Determination of Energy Consumptıon Accordıng to Wıreless network Topologıes in Grıd-Free Lighting Systems, Light & Engineering, 27.
• 11. Cengiz M.S., Cengiz, Ç. 2018. Numeric Analysis for the Efficiency of LED and Traditional Luminaries used in Tunnel Lighting, International GAP Renewable Energy and Energy Efficiency Congress, 10-12 May 2018, Şanlıurfa. 347-348.
• 12. Cengiz M.S., Cengiz, Ç., Mamiş, M.S. 2018. Contribution of Reflector Design formed by Numeric Calculations to Energy Efficiency, International GAP Renewable Energy and Energy Efficiency Congress, 10-12 May 2018, Şanlıurfa. 349-350.
• 13. Özkaya, M. 1994. Aydınlatma Tekniği, Birsen Yayınevi, İstanbul.
• 14. Tetri, E., Chenani, S.B., Rasanen R.S. 2018. Advancement in Road Lighting, Light & Engineering, 26 (1): 99-109.
• 15. Cengiz, M.S. 2014. Evaluation of Smart Grids and Turkey. Global Advanced Research Journal of Engineering Technology and Innovation, 3(7): 149-153.
• 16. Efe S.B. 2015. Harmonic filter application for an industrial installation, Engineering of Modern Electric Systems 2015 13th International Conference on, Oradea, Romania, 11-12 June 2015.
• 17. Cengiz, M.S. 2013. Smart meter and cost experiment. Przeglad Elektrotechniczny, 89(11), 206-209.
• 18. Iacomussi, Rossi, G., Soardo, P. 2012. Energy Saving and Environmental Compatibility in Road Lighting, Light & Engineering, 20 (4): 55–63.
• 19. Van Bommel, W., Van Den Beld, G.,. Van Ooyen M. 2003. Industrial Light and Productivity, Lighting & Engineering, 11 (1): 14–21.
• 20. Cengiz, M.S. Mamiş M.S. 2015. Endüstriyel tesislerde verimlilik ve güneş enerjisi kullanımı. VI. Enerji Verimliliği Kalitesi Sempozyunu ve Sergisi, 21-25. 4-6 Haziran 2015, Sakarya, Türkiye
• 21. Cengiz, M.S. Mamiş M.S. 2015. Solution Offers For Efficiency and Savings in Industrial Plants. Bitlis Eren University Journal of Science and Technology 5(1): 24-28.
• 22. Barua, P., Mazumdar, S., Chakraborty, S., Bhattacharjee, S. 2018. Road Classification Based Energy Efficient Design and its Validation for Indian Roads, Light & Engineering, 26 (2): 110-121.
• 23. Peña-García, A., Gil-Martín, L.M., 2013. Study of pergolas for energy savings in road tunnels, Comparison with tension structures, Tunnel.Undergr. Space Technology, 35 (1): 172–177
• 24. Master Son-T Apia Plus –Xtra, HPS-100, 2019. http://www.lighting.philips. com/main/prof/ conventional-lamps-tubes/high-intensity-discharge-lamps/son-highpressure-sodium/master-son-t-apia-plus-xtra/928150219230_EU/product, (Accessed on 2018.05.04).