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Challenges and traps of assessing life cycle costs of lighting
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Transcript of Challenges and traps of assessing life cycle costs of lighting
IEA SHC Task 50 Fukuola, Japan 29 September 2014
Challenges and traps of assessing Life Cycle Cost analysis (LCC) Prof Marc Fontoynont, Lærke Andersen Danish Building Research Institute Aalborg University in Copenhagen Denmark
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IEA SHC Task 50 Fukuola, Japan 29 September 2014
« Lighting retrofit issue is mainly a decision process cocerning possible benefits to change, before their end of life, the lighting installations » Tasks: 1) to identify the « low hanging fruits » 2) To identify the winning schemes
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IEA SHC Task 50 Fukuola, Japan 29 September 2014
What are are the Life Cycle Costs (LCC) of major lighting schemes?
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Industrial buillding
Office building School Store
OLD (15 – 30 yrs)
New (2014-2015)
Looking for « low hanging fruits » and best solutions
Industrial buillding
Office building School Store
OLD (15 – 30 yrs)
New (2014-2015)
Looking for « low hanging fruits » and best solutions / Daylighting and controls
Occupancy sensor
Daylight sensor
Daylight sensor
Insufficient daylight, aging roof monitors, steady
electrical lighting
Individual shadings, on-off and clock controls
Manually controlled shading and lamps.
Manual switches, or clock driven
Roof monitors with improved performance and sunlight
control. Daylight responsive sensors
Sensors and intelligent managemen tof sunbeams.
Roof monitors with improved performance and sunlight
control. Daylight responsive sensors
Automatic controls of shading, override, clocks
IEA SHC Task 50 SBi January 2014
Cumulated costs for good fluorescent lights
Garage 5600 hr/yr 1.5 W/m2 Office hallways 2400 hr/yr 2.5 W/m2
Office 3500 hr/yr 10 W/m2 Commercial 4000 hr/yr 16 W/m2
SUM – 127 Euro/m2 SUM – 96.6 Euro/m2
SUM – 832 Euro/m2 SUM – 516.2 Euro/m2
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Change ofelectronic ballast
Investment with allcomponents
Change oflighttubes
Electricity Price
Installation price
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64,0
IEA SHC Task 50 SBi January 2014
Lighting cost storyboard for ”good” fluorescent lights
Garage 5600 hr/yr 1.5 W/m2 Office hallways 2400 hr/yr 2.5 W/m2
Office 3500 hr/yr 10 W/m2 Commercial 4000 hr/yr 16 W/m2
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Electricity Price Change of electronic ballast Investment with all components Change of lighttubes Installation price
IEA SHC Task 50 SBi January 2014
Change from fluorescent 15 W/m2 to SSL
Benefit in all cases, but one can wait until 2025 until performing change to SSL: it may be useful to wait until prices of SSL drops significantly after 2020 or 2025)
2014 2025
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Years
Office 3500hrs 15 W/m2 1.scenario - Change to SSL after 14 yrs 3xFL=SL 1.scenario - Change to SSL after 25 yrs 3xFL=SL
2.scenario -Change to SSL after 25 yrs - 2XFL=SL 3. scenario - Change to SSL after 25 yrs SL=FL
Investor _ Industrial building (Processing)
Typical installation to replace Approx 15 to 30 years old
Typical new generation installation
Double fluorescent with cheap reflector Suspended HP sodium
Suspended HID
Typical illuminance_500 lux Typical power density_30 W/m2
Linear LED tubes Suspended LED
Typical illuminance_ 750 lux Typical power density_15 W/m2
Investment cost (incl. Installation) - LED (15 W/m2) _21 €/m2
Based on: Typical operating hours_ 4000 hours/yr Typical lifespan of products (LED/SSL)_60000 hrs/yr For industrial building 10 m2 is thought for every luminaire Installation_ 60 min_ 40 E/hr_ 10m2/luminaire LED /SSL 5W/m2_ the same price as a 6 W/m2 fluorescent lamp. Price for LED (15 W/m2) defined based on this and taking the difference in power density into consideration.
Investor _ Office building
Typical installation to replace Approx 15 to 30 years old
Typical new generation installation
60 X 60 recessed luminaire Circular compact fluorescent downlighters
Typical illuminance_500 lux (designed) 350 lux (service) Typical power density_15W/m2 and 10 W/m2
Single T5 luminaires, prismatic Rails with LED spots (Suspended direct indirect)
Stand alone luiminaires
Typical illuminance_500 lux (desk space) 350 lux(floor space) Typical power density_5 W/m2
Investment cost (incl. Installation) - Fluorescent (6 W/m2) _ 57 €/m2 - LED/SSL (5 W/m2) _57 €/m2
Based on: Typical operating hours_ 3500 hours/yr Typical lifespan of products (fluorescent)_ 15000 hrs/yr for fluorescent tubes, 50000 hrs/yr for ballast and 25 yrs for fixtures. Typical lifespan of products (LED/SSL)_60000 hrs/yr For office 6 m2 is thought for every luminaire Installation_ 60 min_ 40 E/hr_ 6m2/luminaire LED /SSL 5W/m2_ the same price as a 6 W/m2 fluorescent lamp.
Investor _ Schools
Typical installation to replace Approx 15 to 30 years old
Typical new generation installation
2 x 1,20 T8 low price ptics
Typical illuminance _ 300 lux Typical power density_ 10 W/m2
Single T5 luminaires, continuous Suspended direct indirect (3 tubes)
Typical illuminance_500 lux Typical power density_ 6 W/m2
Investment cost (incl. Installation) - Fluorescent (6W/m2)_ 68 €/m2
Based on: Typical operating hours_ 1500 hours/yr Typical lifespan of products (fluorescent)_ 15000 hrs/yr for fluorescent tubes, 50000 hrs/yr for ballast and 25 yrs for fixtures. For schools 5 m2 is thought for every luminaire Installation_ 60 min_ 40 E/hr_ 5m2/luminaire
Investor _Store
Typical installation to replace Approx 15 to 30 years old
Typical new generation installation
Double fluorescent Suspended HID
Typical illuminance_ 750 lux Typical power density_20 W/m2
Linear LED tubes Suspended LED
Typical illuminance_ 750 lux Typical power density_12 W/m2
Investment cost (incl. Installation) - LED (12 W/m2) _28 €/m2
Based on: Typical operating hours_ 4000 hours/yr Typical lifespan of products (LED/SSL)_60000 hrs/yr For commercial 6 m2 is thought for every luminaire Installation_ 60 min_ 40 E/hr_ 6m2/luminaire LED /SSL 5W/m2_ the same price as a 6 W/m2 fluorescent lamp. Price for LED (12 W/m2) defined based on this and taking the difference in power density into consideration.
Retrofit: roof openings
Typical installation to replace Approx 15 to 30 years old
Typical new generation installation
No daylighting or poor daylighting
Typical illuminance 0 – 100 lx
1.40 m x 1.40 m Roof apertures 10% of roof area , DF = 2 to 2.5 %
Diffuse horizontal illuminance of 16 000 lx exceeded 50 % of daylight hours with 10% of roof area.
Investment/installation and maintenance cost Retrofit: 2200 € to install a 1.4 x 1.4 m (2m2 ) roof monitor in an existing building ( less than 1500€ if new) . Investment is 110€/m2.
Based on: Roof top area = 10% of floor area for DF average 2%, and > 50% electricity savings during daylight hours. Investment cost 110€$/m2 for retrofit
Retrofit: lighting controls
Installation with manual / clock control Fluorescent with Daylight sensors On –off or dimming ( HF ballast or LEDs)
Operation 2000 to 8000 hrs /yr.
Savings can reach 50% of lighting electricity
Investment/installation and maintenance cost on top of an industrial luminaire single tube 120€ extra
Based on: 1.5 m , 35 W Single T5 no diimming 130 € , with dimming ( 0-10 v, DALI) : 250€ Typical savings per year 1500 hrs x 6 W/m2 = 9 Kwh/m2.yr value 1,35€/m2
Investment, per m2 : one luminaire per 10 m2: 12 €/m2
Occupancy sensor
Daylight sensor
Retrofit: improved shading / redirecting shading devices
Textile shading Louvre system, with controllable angles
Operation when daylight is glary, leading to possible unnecessary us of electricity 200 to 800 hrs /yr.
Possibility to adjust teh right level of daylight indoor, and, with specifiv louver design, tio bring daylight
deeper into interiors.
Benefit: some extra saving in lighting electricity ( above 200 hrs per year in area located between 3 an6 meter from facade) and reduction of glare
Based on: Investment : 200 € /m2 of facade, 40€/m2 of floor Savings: maximum 0.5 cts / m2 per year
Actor Investment Costs Life
Installation costs Installation simplicity
Maintenance costs Cleaning simplicity Failures
Energy consumption Controls to reduce consumption
Lighting quality Comfort Flexibility
Investor /owner *** ** ***
Installer **
User Maintenance ** *** ***
Concerns by actors : how to promote lighting retrofit? Where are the benefits
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Early finding statements 1. There are many “low hanging fruits” in lighting leading to return on investments
below 3 years), and often increasing lighting quality
2. These low hanging fruits are found mainly in industrial buildings and stores where lighting is independent from ceiling systems
3. In office buildings and schools, it is essential to estimate possible schedule of ceiling refurbishment, to conduct lighting retrofit at the same time.
1. Anticipating retrofitting a lighting installation can be justified if cost of new
(high efficiency) luminaires remains low: for example if SSL costs are close from fluorescent luminaires
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Early finding statements ( Cont’d)
5. In offices, hybrid task ambient strategies, with electric power densities around 4W/m2 are the most energy efficient solutions, and can be easily implemented
6. Other benefits should dominate: added rental value, lighting quality, lower maintenance
7. Market seems to move to disposable luminaires (life below 60 000 hrs) with maintenance limited to simple cleaning
8. Evolution of ceiling systems may also lead to reduction of life of ceiling components.
9. Daylighting measures can dimish electric lighting by 50%, bur without possibbilities of return on investment related to these savings only
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Questions to lighting industry and professionals
Is the energy saving model the dominant argument for investing in new lighting, or is it a secondary one? Is there a growing interest , in Japan, for retrofitting lighting before the end of life Will a technological gap modify