Bridging the Technologies for LED Lighting
Š  2013 Eaton. All rights reserved.
Eaton’s Cooper Lighting Rick Gottlieb Specification Sales Manager Architectural Exterior 727.781.4451 Richardagottlieb@eaton.com 1121 Highway 74 South Peachtree City, GA 30269 1 Credit Hour HSW CEU © 2012 Eaton Corporation. All rights reserved.
Market Influences
3
Solid State Lighting
Electronics
• Efficiency (Energy Savings) • Reliability • Robustness • Lifetime Costs
Lighting
• Flexibility of Design
4
LED Fundamentals
5
Typical Lighting-class LED Package Substrate/Lead Frame Air, RI = 1.0
Lens (glass, silicone), RI ~1.4
Encapsulant RI ~1.5 Wire bond Reflector
Phosphor ESD protection LED chip RI~2.2
6
LED: Theory of Operation • LEDs consist of several layers of semiconductor material • Light is generated in the PN junction with applied current • Monochromatic light • Color depends on materials used • Primary materials:
→ Red/Orange/Amber → Green/blue
AlInGaP InGaN
7
LED Device Materials 10
Better
AlInGaP
InGaN
AlGaAs
1
Luminous Intensity GaP:N
0.1
GaAsP
GaAsP
SiC
Worse
0.01 400
450
500
550
600
650
700
Wavelength (nm)
Color: Ultra-violet
Blue
Green
© 2013 Eaton. All rights reserved.
Yellow
Orange
Red
Infra-Red
How do I get white light?
9
Producing White Light with LEDs RGB (Red, Green, Blue)
Blue + Yellow Phosphor
Blue Peak
Yellow Phosphor
10
Typical Lighting-class LED Package Substrate/Lead Frame Air, RI = 1.0
Lens (glass, silicone), RI ~1.4
Encapsulant RI ~1.5 Wire bond Reflector
Phosphor ESD protection LED chip RI~2.2
11
Drive Current, Why has increased? Lumileds Rebel 16 stud bumps 1mm2
Lumileds Rebel ES 25 stud bumps 1.5mm2
Lumileds Tx 36 stud bumps 2mm2
12
Drive Current, What is it?
Watts=Volts x Amps Vf (forward voltage) of an LED chip increases with drive current
Luxeon Tx
Drive Current
Vf (Forward Voltage
350mA
2.71V*
700mA
2.80V*
1000mA
2.86V*
*Varies by chip but this is an good representation example 13
Drive Current, What is it? Watts=Volts x Amps Watts=Vf x Drive Current Luxeon TX Drive Current
Watts
Lumen Output
Efficacy LPW
Vf
350mA
2.71V
.95
147
155
700mA
2.80V
1.96
269
137
1050mA
2.86V
3.00
360
136
14
Drive Current, What is it? Luxeon TX Drive Current
Vf
Watts
HP Lumen Output
350mA
2.71V
.95
147
155
700mA
2.80V
1.96
269
137
1050mA
2.86V
3.00
360
136
Honda Accord @ 55 MPH = 36 MPG
MPG Efficacy LPW
Honda Accord @ 87 MPH = 26 MPG
15
LED – Basic Value Proposition • • • • • • • • • • •
Life - Very Long Operating Life (>100K hours) Lumen Maintenance – 90% @60K hours @40C Power - Energy Efficient (source 130 LPW) Size – Relative small package size Uniformity – Led can give superior control over light Directional- Directed light for increased system efficiency Durability - Solid State, vibration proof Dimmable - Fully dimmable without color variation Rise Time - Instant on (<100ms), full color, 100% light Cool Source – No IR heat Environment – no Mercury 16
“ LIFE “
17
IES LM-80-08 • Measuring Lumen Maintenance of LED Light Sources • Approved method for measuring lumen depreciation of solid-state (LED) light sources, arrays and modules • Does not cover measurement of luminaires • Does not define or provide methods for estimation of life. • 55C, 85C and 3rd LED mfg selected temperature • 6000 hours min testing period. 10K preferred. • Minimum at least every 1000 hours
Consistent way to measure life-time 18
TM-21 – Use the latest data • Initial data variability (i.e. “hump”) is difficult for models to evaluate (0-1000 hr) • Later data exhibits more characteristic decay curve of interest • Non-chip decay (encapsulant, etc.) occurs early and with varying effects on decay curve • Later decay is chip-driven and relatively consistent with exponential curve • Verification with long duration data sets(>10,000hr) shows better model to reality fit with last 5,000 hours of 10,000 hour data • For 6,000 hours of data (LM-80 minimum) and up to 10,000 hours: Use last 5,000 hours • For > 10,000 hours: Use the last ½ of the collected data
19
LM-80 Challenge Directly from TM-21 report
Unless you plan on installing a liquid nitrogen tank donâ&#x20AC;&#x2122;t expect to replicate LM-80 result directly. 20
TM-21 – Use the latest data
© 2013 Eaton. All rights reserved.
TM-21 – Use the latest data
© 2013 Eaton. All rights reserved.
LED – Basic Value Proposition • • • • • • • • • •
Life - Very Long Operating Life (>100K hours) Lumen Maintenance – 90% @60K hours Power - Energy Efficient (source 130 LPW) Size – Relative small package size Directional- Directed light for increased system efficiency Durability - Solid State, vibration proof Dimmable - Fully dimmable without color variation Rise Time - Instant on (<100ms), full color, 100% light Cool Source – No IR heat Environment – no Mercury
23
LED – Basic Value Proposition • • • • • • • • • • •
Life - Very Long Operating Life (>100K hours) Lumen Maintenance – 90% @60K hours @40C Power - Energy Efficient (source 130 LPW) Size – Relative small package size Uniformity – Led can give superior control over light Directional- Directed light for increased system efficiency Durability - Solid State, vibration proof Dimmable - Fully dimmable without color variation Rise Time - Instant on (<100ms), full color, 100% light Cool Source – No IR heat Environment – no Mercury 24
Efficiency: LED vs. Traditional Sources
25
Lumens / Watt
Efficiency: LED vs. Traditional Sources
© 2013 Eaton, All Rights Reserved.
LED – Basic Value Proposition • • • • • • • • • • •
Life - Very Long Operating Life (>100K hours) Lumen Maintenance – 90% @60K hours @40C Power - Energy Efficient (source 130 LPW) Size – Relative small package size Uniformity – Led can give superior control over light Directional- Directed light for increased system efficiency Durability - Solid State, vibration proof Dimmable - Fully dimmable without color variation Rise Time - Instant on (<100ms), full color, 100% light Cool Source – No IR heat Environment – no Mercury 27
Lens Technology The optical system uses the lens to refract light and a reflector to shape the distribution of light.
28
LED – Basic Value Proposition • • • • • • • • • • •
Life - Very Long Operating Life (>100K hours) Lumen Maintenance – 90% @60K hours @40C Power - Energy Efficient (source 130 LPW) Size – Relative small package size Uniformity – Led can give superior control over light Directional- Directed light for increased system efficiency Durability - Solid State, vibration proof Dimmable - Fully dimmable without color variation Rise Time - Instant on (<100ms), full color, 100% light Cool Source – No IR heat Environment – no Mercury 29
Average vs. Minimum Light Levels
Please educate your clients to change their specifications/ requirements from Average FC/Lux to Minimum Maintained FC/Lux
© 2013 Eaton. All rights reserved.
‹#›
Uniformity Rules
© 2013 Eaton. All rights reserved.
‹#›
Uniformity Rules
© 2013 Eaton. All rights reserved.
‹#›
Uniformity Rules
© 2013 Eaton. All rights reserved.
‹#›
Uniformity Rules
© 2013 Eaton. All rights reserved.
‹#›
Uniformity Rules
© 2013 Eaton. All rights reserved.
‹#›
Uniformity Rules
© 2013 Eaton. All rights reserved.
‹#›
Uniformity Rules
->4.5 lux min: for Uniformity; 3:1 ratio
© 2013 Eaton. All rights reserved.
‹#›
Uniformity Rules • Result Summary •
->4.5 lux min: for Uniformity; 3:1 ratio
© 2013 Eaton. All rights reserved.
‹#›
LED – Basic Value Proposition • • • • • • • • • • •
Life - Very Long Operating Life (>100K hours) Lumen Maintenance – 90% @60K hours @40C Power - Energy Efficient (source 130 LPW) Size – Relative small package size Uniformity – Led can give superior control over light Directional- Directed light for increased system efficiency Durability - Solid State, vibration proof Dimmable - Fully dimmable without color variation Rise Time - Instant on (<100ms), full color, 100% light Cool Source – No IR heat Environment – no Mercury 39
Controls • On/off • Occupancy sensors • Time Clocks
• Building automation • Battery packs
Control increases energy savings and “life” 40
LED – Basic Value Proposition • • • • • • • • • • •
Life - Very Long Operating Life (>100K hours) Lumen Maintenance – 90% @60K hours @40C Power - Energy Efficient (source 130 LPW) Size – Relative small package size Uniformity – Led can give superior control over light Directional- Directed light for increased system efficiency Durability - Solid State, vibration proof Dimmable - Fully dimmable without color variation Rise Time - Instant on (<100ms), full color, 100% light Cool Source – No IR heat Environment – no Mercury 41
What role does heat play?
42
What Determines Life?
Heat = Life An LED driven at 1A with a Ts (case temperature) of 85C will outlive the same LED driven at 530mA with a Tc of 90C
Life = Ts Drive Current = Efficiency
43
Is 3 Watts a Lot of Heat?
@ 1A drive current = 3 watts
= 1800 watts
44
Is 3 Watts a Lot of Heat? T8 48’ 32 watt lamp Surface area = 2πr2 + 2πrL r=12.7mm L=1219.2 Surface area ≈ 98,300mm2 Watts per mm2 .0003 If the T8 ran at 1.50 watts per mm2 it would consume ≈ 147,500 watts.
Luxeon Tx = 3 watts Surface area = 2mm2 Watts per mm2 1.5 45
Heat and Life
46
Heat and Life
47
Thermal Management Ambient temperature ratings >25째C (40째C preferred)
Reduce Maintenance Costs, Go Green with LED 48
LED – Basic Value Proposition • • • • • • • • • • •
Life - Very Long Operating Life (>100K hours) Lumen Maintenance – 90% @60K hours @40C Power - Energy Efficient (source 130 LPW) Size – Relative small package size Uniformity – Led can give superior control over light Directional- Directed light for increased system efficiency Durability - Solid State, vibration proof Dimmable - Fully dimmable without color variation Rise Time - Instant on (<100ms), full color, 100% light Cool Source – No IR heat Environment – no Mercury 49
LED to MH Comparison 250 Watt MH Talon (295 watts) SL4 optic (segmented) • 25 feet mounting height • .70 LLF • Scale 25’ • 20,500 Lumens
80’x 40’
107 Watt LED Galleon SL4 optic (2) 1A LightSquares • 25 feet mounting height • .91 LLF • Scale 25’ • 9,976 Lumens
100’x 50’
74 Watt LED Galleon SL4 optic (2) .7A LightSquares • 25 feet mounting height • .91 LLF • Scale 25’ • 7,292 Lumens
80’x 40’
Red = .20 Footcandles Green = .5 Footcandles Blue = 1 Footcanles
12
Industrial HID Options for Retro-fit
© 2015 Eaton. All rights reserved.
‹#›
Industrial HID Options for Retro-fit
© 2015 Eaton. All rights reserved.
‹#›
Fluorescent to LED Options for Retro-fit
© 2015 Eaton. All rights reserved.
‹#›
Parking Garage HID Options for Retro-fit
Lumens 17500 8000 6600 Wa0age 205 77 58 Annual $ @.10/ kWh (24hrs/ day) $ 179.58 $ 67.45 $ 50.81 Lamp Life 15000 L90 @ 60K L90 @ 60K Failure Rate 50% <1% <1% Annual $ Saved Energy $112.13 $128.77 Annual Maint Savings $58 $58 © 2015 Eaton. All rights reserved.
‹#›
HID │LED Equivalency HID 250W (290W)
vs.
LED 107W
250W MH (290w)
22,000 lms
2 Square 1A
9,575
~70% optic eff.
15,400 lms
All ready included
9,575
Street Side (65%)
10,010 lms
Street Side (89%)
8,841
0.7 LLF
7,007 lms
0.91 LLF
8,045 lms
55
LED Fixture Comparison When 20,000 lumens = 30,000 lumens XYz [1A, 4000K]
vs.
ECL [1A, 4000K] 99.4 LPW
72.2 LPW
Fixture Watts = 428W
30,916 lms
Fixture Watts = 213W
21,164 lms
Street Side = 66.5%
20,644 lms
Street Side = 82.9%
17,548 lms
Design Lumens 0.82 LLD * 0.95 LDD =
0.96 LLD * 0.95 LDD =
0.779 LLF [Light Loss Factor] 16,082 lms
0.912 LLF[Light Loss Factor]. 16,004 lms 56
Cost of Ownership • The life cycle cost of ownership of a lighting system must be considered when performing a ROI calculation: • • • •
upfront costs energy savings maintenance savings cradle to cradle design (recyclability)
57
58