LED street light

LED street light

LED street light in the United Kingdom
Type	LED, street light

An LED street light or road light is an integrated light-emitting diode (LED) light fixture that is used for street lighting.

Design and style

LED street light beam pattern

An LED street light is an integrated light that uses light emitting diodes (LED) as its light source. These are considered integrated lights because, in most cases, the luminaire and the fixture are not separate parts. In manufacturing, the LED light cluster is sealed on a panel and then assembled to the LED panel with a heat sink to become an integrated lighting fixture.

Different designs have been created that incorporate various types of LEDs into a light fixture. Either few high-power LEDs or many low-power LEDs may be used. The shape of the LED street light depends on several factors, including LED configuration, the heat sink used with the LEDs and aesthetic design preference.

Heat sinks for LED street lights are similar in design to heat sinks used to cool other electronics such as computers. Heat sinks tend to have as many grooves as possible to facilitate the flow of hot air away from the LEDs. The area of heat exchange directly affects the lifespan of the LED street light.

The lifespan of an LED street light is determined by its light output compared to its original design specification. Once its brightness decreases by 30 percent, an LED street light is considered to be at the end of its life.

Most LED street lights have a lens on the LED panel, which is designed to cast its light in a rectangular pattern, an advantage compared to traditional street lights, which typically have a reflector on the back side of a high-pressure sodium lamp. In this case, much of the luminance of the light is lost and produces light pollution in the air and surrounding environment.

A drawback of LED focus panels is that most light is directed to the road, and less light to the footpaths and other areas. This can be addressed by the use of specialized lens design and adjustable mounting spigots.

In performing a LED street lighting project, easy LED luminary models simplify the optimization for high-performance illumination designs.^[1] These practical equations may be used to optimize LED street lighting installations in order to minimize light pollution, increase comfort and visibility, and maximize both illumination uniformity and light utilization efficiency.

Energy efficiency

The life span of an LED as compared to other light sources^[2]

The primary appeal of LED street lighting is energy efficiency compared to conventional street lighting fixture technologies such as high pressure sodium (HPS) and metal halide (MH). Research continues to improve the efficiency of newer models of LED street lights (modernizing with LED street lights). However, LED street lighting is not as efficient as SOX street lighting in the United Kingdom. ^{[clarification needed]}

An LED street light based on a 901-milliwatt output LED can normally produce the same amount of (or higher) luminance as a traditional light, but requires only half of the power consumption. LED lighting does not typically fail, but instead decreases in output until it needs to be replaced.^[2] It is estimated that installation of energy efficient street lighting in the 10 largest metropolitan areas in the U.S. could reduce annual carbon dioxide emissions by 1.2 million metric tons, the equivalent of taking 212,000 vehicles off the road, and save at least $90 million annually in electricity costs.^[3][4]

As LED lighting fixtures normally produce less illumination^[5] it is important to use a well-distributed illumination pattern in order to produce the same illumination as higher-lumen conventional fixtures. For example, different LEDs in one fixture can target different points on the street.

Advantages of LED street lights

• Low energy consumption: Many LED lighting retrofits have been claimed to dramatically reduce energy use.^[6]
• Long and predictable lifetime: The projected lifetime of LED street lights is usually 10 to 15 years, two to four times the life of currently prevalent HPS. (LEDs themselves do not generally fail or “burn out” in a way comparable to other technologies, and barring catastrophic failure of other mechanical or electronic components of the LED fixture, lifetimes are typically set by a decrease in luminous output of 30%. But the functional lifetime of an LED fixture is limited by the weakest link; associated drive electronics are typically projected to last about 50,000 hrs. It is important to understand that no LED streetlighting products have been in service long enough to confirm the projections). If realized in practice, the less frequent need to service or replace LEDs will mean lower maintenance cost.
• More accurate color rendering: The color rendering index is the ability of a light source to correctly reproduce the colors of the objects in comparison to an ideal light source. Improved color rendering makes it easier for drivers to recognize objects.
• Quick turn on and off: Unlike fluorescent and high-intensity discharge (HID) lamps, such as mercury vapor, metal halide, and sodium vapor lamps, which take time to heat up once switched on, LEDs come on with full brightness instantly.
• RoHS compliance: LEDs don't contain mercury or lead, and don't release poisonous gases if damaged.
• Optically efficient lighting equipment: Other types of street lights use a reflector to capture the light emitted upwards from the lamp. Even under the best of conditions, the reflector absorbs some of the light. Also for fluorescent lamps and other lamps with phosphor coated bulbs, the bulb itself absorbs some of the light directed back down by the reflector. The glass cover, called a refractor, helps project the light down on the street in a desired pattern but some light is wasted by being directed up to the sky (light pollution). LED lamp assemblies (panels) can send light in the desired directions without a reflector.
• Higher light output even at low temperatures: While fluorescent lights are comparably energy efficient, on average they tend to have lesser light output at winter temperatures.

Disadvantages of LED street lights

Malfunctioning LED street lights flickering

Defective LED street light turned purple

• Many people dislike the ambiance produced by LEDs with color temperatures of 4000K or higher. 2700K and 3000K LEDs are mostly used for indoor lighting.^[7][8]
• The initial cost of LED street lighting is high and as a consequence it takes several years for the savings on energy to pay for that. The high cost derives in part from the material used since LEDs are often made on sapphire or other expensive substrates.^[9]
• As a result of the Purkinje effect, the dark-adapted human eye is very sensitive to blue and green light that LED street lights emit in large amounts, as compared to the yellow and orange high-pressure sodium lights that are typically being replaced.^[10][11][12] This magnifies the effect of light pollution - particularly sky glow.
• The major increase in the blue and green content of artificial sky glow arising from widespread LED lighting is likely to increase impacts on bird migration and other nocturnal animal behaviours.^[13]
• Blue-rich light pollution from LED streetlights can disrupt circannual rhythms and cause the complete loss of an organism's seasonal clock. This impacts important behaviors such as feeding, reproduction, thermoregulation and hibernation. In some cases the failure to hibernate or properly thermoregulate due to this loss of seasonal timing can kill the organism.^[14][15][16]
• There is progressive wear of layers of phosphor in white LEDs. The change in color slowly moves devices from one photobiological risk group to a higher one.^[17] Manufacturing problems can lead to defects of LED street lights resulting in delamination of the phosphor coating layer much sooner than the design life of the lights. This causes the white LED lights to turn blue or purple.^[18] The issues of large scale defective lights happened in many cities in United States and Canada.^[19][20]
• Malfunctioning LED street lights can cause them to flicker, creating a strobe light effect.^[21] Partial power outages can also cause the same effect as the LED street lights can detect residual electrical current.^[22] The strobe effect may trigger seizures in some people.^[23]
• The blue-rich spectrum of LED streetlights is less effective than the yellow-dominant spectrum of Sodium lighting in producing a targeted luminance level on roadways, as the spectral reflectance of roadway pavement is higher for longer wavelengths of light. Due to this difference in spectral reflectance, much of the light produced by an LED streetlight is absorbed by the pavement rather than reflected.^[24]
• LED streetlights produce greater levels of glare than previous sodium light sources. This is largely due to fixtures with smaller source areas resulting in increased luminance levels, a metric of light intensity. The blue-rich spectrum of LED streetlights also leads to increased levels of glare, especially discomfort glare.^[25][26]
• The blue-rich spectrum of LED streetlights leads to greater impacts of Rayleigh Scattering, where short wavelengths of light scatter within small particles more than long wavelengths of light do. This increased light scattering within the atmosphere leads to increased skyglow. During bad weather such as heavy rain, snow or fog, this scattering can create physical walls of light that obstruct vision.^[27]
• As the human eye ages the lens of the eye yellows. This changes the spectral transparency of the lens to favor longer wavelengths of light, with significant losses in transparency for shorter wavelengths of light. Due to this spectrum-based loss in transparency the blue-rich spectrum of LED streetlights becomes less visible as an individual ages. For example in the eye of someone aged 50, the light transmission of a 4000K LED is 11% lower than that of a 2700K LED, relative to someone aged 25.^[28][24]

Health concerns

• Exposure to the light of white LED bulbs suppresses melatonin by up to five times more than exposure to the light of pressure sodium bulbs.^[29] The fact that white light, emitting at wavelengths of 400-500 nanometers suppresses the production of melatonin produced by the pineal gland is known. The effect is disruption of a human being’s biological clock resulting in poor sleeping and rest periods.^[30]
• Research at the University of Madrid Complutense University^[31] has claimed that long term exposure to LED Street-lighting can cause irreparable harm to the retina of the human eye. The Madrid study said this was caused by the high level of radiation in the’’blue band’’^[32][33]
• Artificial night-time lighting has various effects on humans (not to mention wildlife) and exposure to optical radiation affects human physiology and behavior, both directly and indirectly. Many areas are not well understood, and a position statement from the Illuminating Engineering Society (IES) emphasizes mainly the need for further research.^[34]
• There is a risk from glare. A French government report published in 2013 indicated that a luminance level higher than 10,000 cd/m2 causes visual discomfort whatever the position of the lighting unit in the field of vision. As the emission surfaces of LEDs are highly concentrated point sources, the luminance of each individual source can be 1000 times higher than the discomfort level. The level of direct radiation from this type of source can therefore easily exceed the level of visual discomfort^[17][35]

References

1. I. Moreno, M. Avendaño-Alejo, "Modeling LED street lighting," Appl. Opt. 53, 4420 (2014). https://www.osapublishing.org/ao/abstract.cfm?uri=ao-53-20-4420
2. Street lighting technology comparison Archived 2013-03-01 at the Wayback Machine
3. Grow, Robert T., Energy Efficient Streetlights - Potentials for Reducing Greater Washington's Carbon Footprint, March, 2008
4. "Study: New street light technology could save energy, money". 6 April 2008.
5. "LED Street Light". www.northernlights-direct.co.uk. Archived from the original on 20 July 2015. Retrieved 4 October 2016.
6. Kostic, A.M. et al., Light-emitting diodes in street and roadway lighting – a case study involving mesopic effects, Lighting Research and Technology 45:217, 2013, doi: 10.1177/1477153512440771
7. Benya, James. "Nights in Davis". Retrieved 21 April 2016.
8. Chaban, Matt (23 March 2015). "LED Streetlights in Brooklyn Are Saving Energy but Exhausting Residents". New York Times. Retrieved 21 April 2016.
9. "How LED Streetlights Work". science.howstuffworks.com. 22 June 2009. Retrieved 4 October 2016.
10. Limiting the impact of light pollution on human health, environment and stellar visibility, Journal of Environmental Management, Volume 92, Issue 10, October 2011, Pages 2714-2722 by Fabio Falchi, Pierantonio Cinzano, Christopher D. Elvidge, David M. Keith, Abraham Haim
11. Luginbuhl, C.B. et al., The impact of light source spectral power distribution on sky glow. Journal of Quantitative Spectroscopy and Radiative Transfer, 2014, v. 139; p. 21., doi:10.1016/j.jqsrt.2013.12.004
12. Aubé, M. et al., Evaluating Potential Spectral Impacts of Various Artificial Lights on Melatonin Suppression, Photosynthesis, and Star Visibility. PLOS ONE, 2013, DOI: 10.1371/journal.pone.0067798
13. http://lighting.com/light-pollution-wildlife.htm. Turning Night Into Day: Light Pollution’s Impacts on Wildlife
14. Haim, Abraham; Shanas, Uri; Zubidad, Abed El Salam; Scantelbury, Michael (January 2005). "Seasonality and Seasons Out of Time—The Thermoregulatory Effects of Light Interference". Chronobiology International. 22 (1): 59–66. doi:10.1081/CBI-200038144. ISSN 0742-0528. PMID 15865321. S2CID 10616727.
15. Liu, Jennifer A.; Meléndez-Fernández, O. Hecmarie; Bumgarner, Jacob R.; Nelson, Randy J. (2022-05-01). "Effects of light pollution on photoperiod-driven seasonality". Hormones and Behavior. 141: 105150. doi:10.1016/j.yhbeh.2022.105150. ISSN 0018-506X. PMC 10137835. PMID 35304351.
16. Zubidat, Abed Elsalam; Ben-Shlomo, Rachel; Haim, Abraham (January 2007). "Thermoregulatory and Endocrine Responses to Light Pulses in Short-Day Acclimated Social Voles ( Microtus socialis )". Chronobiology International. 24 (2): 269–288. doi:10.1080/07420520701284675. ISSN 0742-0528. PMID 17453847. S2CID 25682181.
17. ANSES, the French Agency for Food, Environmental and Occupational Health & Safety, September 2013
18. Rogers, Adam (29 November 2022). "The Great Purpling -". Business Insider. Retrieved 12 April 2023.
19. da Silva, Susana (4 October 2022). "Why thousands of city street lights are turning purple". CBC News. Retrieved 12 April 2023.
20. Fox, Greg (13 March 2023). "FDOT makes progress in replacing defective purple streetlights". WESH. Retrieved 12 April 2023.
21. Maloney, Damon; Nelson, Jim. "Cleveland streetlights malfunction, cause strobe effect". WOIO Cleveland 19 News. Retrieved 12 April 2023.
22. "Street lights become strobe lights after partial power outage". CNN/WBNG. 4 February 2019. Retrieved 12 April 2023.
23. "Calgary seizure sufferer worries flickering LED street light will break down again". CBC News. 27 January 2017. Retrieved 12 April 2023.
24. Preciado, Ou; Manzano, Er (October 2018). "Spectral characteristics of road surfaces and eye transmittance: Effects on energy efficiency of road lighting at mesopic levels". Lighting Research & Technology. 50 (6): 842–861. doi:10.1177/1477153517718227. ISSN 1477-1535. S2CID 116821441.
25. Bullough, Jd; Brons, Ja; Qi, R.; Rea, Ms (September 2008). "Predicting discomfort glare from outdoor lighting installations". Lighting Research & Technology. 40 (3): 225–242. doi:10.1177/1477153508094048. ISSN 1477-1535. S2CID 109408921.
26. de Boer, J. B.; Schreuder, D. A. (June 1967). "Glare as a Criterion for Quality in Street Lighting". Lighting Research and Technology. 32 (2 IEStrans): 117–135. doi:10.1177/147715356703200205. ISSN 1477-1535. S2CID 106634429.
27. Cox, A. J.; DeWeerd, Alan J.; Linden, Jennifer (2002-05-13). "An experiment to measure Mie and Rayleigh total scattering cross sections". American Journal of Physics. 70 (6): 620–625. doi:10.1119/1.1466815. ISSN 0002-9505.
28. van Bommel, Wout (2015). "Road Lighting". SpringerLink. doi:10.1007/978-3-319-11466-8. ISBN 978-3-319-11465-1.
29. University of Haifa study by Professor Abraham Haim, director of the Israeli Center for Interdisciplinary Studies in Chronobiology Sept 2012
30. "Exposure to 'white' light LEDs appears to suppress body's production of melatonin more than certain other lights, research suggests". www.sciencedaily.com. Retrieved 4 October 2016.
31. Dr. Celia Sanchez Ramos, The Effect of Light-Emitting Diode (LED) on eyesight, Complutense University Madrid, 2013
32. "LED lights can damage your eyes". The Hindu. 15 May 2013. Retrieved 4 October 2016.
33. "Do White LEDs Disrupt our Biological Clocks?". www.insidescience.org. 19 June 2012. Retrieved 4 October 2016.
34. Tim Whitaker (15 November 2010). "Light and human health: LED risks highlighted". LEDs Magazine. Archived from the original on 23 November 2010.
35. "In response to the internally-solicited request entitled "Health effects of lighting systems using light-emitting diodes (LEDs)"" (PDF). ANSES. 2010-10-19. Retrieved 2022-09-20.

External links

• U.S. Department of Energy reports on municipal LED lighting pilot projects: Solid-State Lighting GATEWAY Demonstration Results