MR16 Reference Design

CLD-AP76 Rev 0D
Application Note
Cree® XLamp® XP-E LED MR16 Reference Design
Table of Contents
Introduction
Introduction..................................................................................... 1
It is a challenge to design an efficient, high‑lumen, small form
Design approach/objectives.......................................................... 2
factor, solid-state luminaire at a reasonable cost. The limited
The 6-step methodology................................................................. 2
space of an MR16 lamp means that designing the optical,
1.Define lighting requirements.................................................. 2
thermal, and electrical components to achieve the desired
2.Define design goals................................................................. 4
requirements is not easy.
3.Estimate efficiencies of the optical, thermal & electrical
systems.................................................................................... 4
4.Calculate the number of LEDs................................................ 9
5.Consider all design possibilities........................................... 10
6.Complete the final steps: implementation and analysis..... 10
Conclusions................................................................................... 15
This application note details the design of an MR16 lamp using
Cree’s XLamp® XP-E LED. The goal of this design is to develop
a replacement 20-W MR16 lamp meeting the ENERGY STAR®
requirements. In this reference design we used simulation and
prototype creation to build a replacement for the traditional
20-W MR16 halogen bulb. Building on Cree’s reference designs
of prototype MR16 replacement lamps using XLamp MT-G and
XM-L EasyWhite® (EZW) LEDs1, this design provides another
possibility to create an LED-based MR16 lamp that exceeds the
www.cree.com/Xlamp
performance of existing halogen MR16 bulbs.
1
Cree XLamp MT-G LED MR16 Reference Design
Cree XLamp XM-L EZW LED MR16 Reference Design
Reliance on any of the information provided in this Application Note is at the user’s sole risk. Cree and its affiliates make no warranties or representations about, nor assume
any liability with respect to, the information in this document or any LED-based lamp or luminaire made in accordance with this reference design, including without limitation
that the lamps or luminaires will not infringe the intellectual property rights of Cree or a third party. Luminaire manufacturers who base product designs in whole or part on
any Cree Application Note or Reference Design are solely responsible for the compliance of their products with all applicable laws and industry requirements.
Copyright © 2011-20116 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree®, XLamp® and
EasyWhite® are registered trademarks and the Cree logo is a trademark of Cree, Inc. ENERGY STAR® is a registered trademark of the U.S. Environmental
Protection Agency. Other trademarks, product, and company names are the property of their respective owners and do not imply specific product and/
or vendor endorsement, sponsorship or association. For product specifications, please see the data sheets available at www.cree.com. For warranty
information, please contact Cree Sales at [email protected].
Cree, Inc.
4600 Silicon Drive
Durham, NC 27703
USA Tel: +1.919.313.5300
1
XLamp ® XP-E LED MR16 Reference Design
Design approach/objectives
In the “LED Luminaire Design Guide”, Cree advocates a 6-step framework for creating LED luminaires. All Cree reference designs use this
framework, and the design guide’s summary table is reproduced below.
Table 1: Cree 6-step framework
Step
Explanation
1. Define lighting requirements
•
The design goals can be based either on an existing fixture or on the application’s lighting requirements.
2. Define design goals
•
•
Specify design goals, which will be based on the application’s lighting requirements.
Specify any other goals that will influence the design, such as special optical or environmental requirements.
3. Estimate efficiencies of the optical, thermal
& electrical systems
•
•
•
Design goals will place constraints on the optical, thermal and electrical systems.
Good estimations of efficiencies of each system can be made based on these constraints.
The combination of lighting goals and system efficiencies will drive the number of LEDs needed in the luminaire.
4. Calculate the number of LEDs needed
•
Based on the design goals and estimated losses, the designer can calculate the number of LEDs to meet the design
goals.
5. Consider all design possibilities and
choose the best
•
•
With any design, there are many ways to achieve the goals.
LED lighting is a new field; assumptions that work for conventional lighting sources may not apply.
6. Complete final steps
•
•
•
•
•
Complete circuit board layout.
Test design choices by building a prototype luminaire.
Make sure the design achieves all the design goals.
Use the prototype to further refine the luminaire design.
Record observations and ideas for improvement.
The 6-step methodology
The major goal for this project was to create a 20-W equivalent XLamp XP-E LED-based MR16 lamp. It is meant to be a plug-in replacement
for any MR16 fixture and operate with the existing low voltage power supply.
1. Define lighting requirements
Table 2 shows a ranked list of desirable characteristics to address in an MR16 reference design.
Table 2: Ranked design criteria for MR16 replacement lamp
Importance
Characteristic
Units
Critical
Light intensity
center beam candle power (CBCP) candelas (cd)
Nominal beam angle
angle (degrees)
Electrical power
watts (W)
Luminous flux
lumens (lm)
Form factor
Important
Price
$
Lifetime
hours
Operating temperatures
˚C
Operating humidity
% RH
Correlated Color Temperature (CCT)
K
Color Rendering Index (CRI)
100-point scale
Manufacturability
Ease of installation
Copyright © 2011-20116 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree®, XLamp® and EasyWhite® are registered trademarks and the Cree logo is a
trademark of Cree, Inc. ENERGY STAR® is a registered trademark of the U.S. Environmental Protection Agency. Other trademarks, product, and company names are the property of their respective owners and
do not imply specific product and/or vendor endorsement, sponsorship or association. For product specifications, please see the data sheets available at www.cree.com. For warranty information, please
contact Cree Sales at [email protected].
2
XLamp ® XP-E LED MR16 Reference Design
As a comparison, photometric testing of several halogen MR16 lamps provides basic benchmark data.2
Table 3: Halogen MR16 comparison data
Luminaire Power
(W)
Luminous Flux
(lm)
CBCP
(cd)
Efficacy
(lm/W)
MR16 A
20
2802
420
13.6
36
2900
MR16 B
20
254
455
12
30
2780
MR16 C
20
260
950
12.6
22
2780
Source
Beam Angle
(˚)
CCT
(K)
The following table summarizes the ENERGY STAR requirements for all integral LED lamps.3
Table 4: ENERGY STAR requirements for integral LED lamps
Characteristic
Requirement
CCT
Lamp must have one of the following designated CCTs (per ANSI C78.377-2008) consistent with the 7-step chromaticity
quadrangles and Duv tolerances below.
Nominal Target CCT (K)
Target Duv
CCT (K) and tolerance
and tolerance
2700
2725 + 145
0.000 + 0.006
3000
3045 + 1750
000 + 0.006
3500
3465 + 2450
000 + 0.006
4000
3985 + 2750
001 + 0.006
Color maintenance
The change of chromaticity over the minimum lumen maintenance test period (6,000 hours) shall be within 0.007 on the CIE
1976 (u’, v’) diagram.
CRI
Minimum CRI (Ra) of 80. R9 value must be greater than 0.
Dimming
Lamps may be dimmable or non-dimmable. Product packaging must clearly indicate whether the lamp is dimmable or not
dimmable. Manufacturers qualifying dimmable products must maintain a web page providing dimmer compatibility information.
Warranty
3-year warranty
Allowable lamp bases
Must be a lamp base listed by ANSI.
Power factor (PF)
Lamp power < 5 W and low voltage lamps: no minimum PF
Lamp power > 5 W: PF > 0.70
Minimum operating temperature
-20°C or below
LED operating frequency
≥ 120 Hz
Note: This performance characteristic addresses problems with visible flicker due to low frequency operation and applies to
steady-state as well as dimmed operation.
Dimming operation shall meet the requirement at all light output levels.
Electromagnetic and radio frequency
interference
Must meet appropriate FCC requirements for consumer use (FCC 47 CFR Part 15)
Audible noise
Class A sound rating
Transient protection
Power supply shall comply with IEEE C62.41-1991, Class A operation. The line transient shall consist of seven strikes of a
100 kHz ring wave, 2.5 kV level, for both common mode and differential mode.
Operating voltage
Lamp shall operate at rated nominal voltage of 120, 240 or 277 VAC, or at 12 or 24 VAC or VDC.
The following table summarizes ENERGY STAR requirements for MR16 lamps.4
2
Measured in an integrating sphere at Cree’s facility in Santa Barbara, California
3
ENERGY STAR Program Requirements for Integral Lamps, Eligibility Criteria, Version 1.4, Table 4
4
Ibid, Table 7C
Copyright © 2011-20116 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree®, XLamp® and EasyWhite® are registered trademarks and the Cree logo is a
trademark of Cree, Inc. ENERGY STAR® is a registered trademark of the U.S. Environmental Protection Agency. Other trademarks, product, and company names are the property of their respective owners and
do not imply specific product and/or vendor endorsement, sponsorship or association. For product specifications, please see the data sheets available at www.cree.com. For warranty information, please
contact Cree Sales at [email protected].
3
XLamp ® XP-E LED MR16 Reference Design
Table 5: ENERGY STAR requirements for MR16 lamps
Characteristic
Requirement
Definition
Directional lamp means a lamp having at least 80% light output within a solid angle
of ∏ sr (corresponding to a cone with angle of 120˚.
Minimum luminous efficacy
Lamp diameter < 20/8 inch: 40 lm/W
Lamp diameter < 20/8 inch: 45 lm/W
Color spacial uniformity
The variation of chromaticity within the beam angle shall be within 0.006 from the
weighted average point on the CIE 1976 (u’, v’) diagram.
Maximum lamp diameter
Not to exceed target lamp diameter as per ANSI C78.21-2003.
Maximum overall length (MOL)
Not to exceed MOL for target lamp as per ANSI C78.21-2003.
Minimum center beam intensity
473 cd - determined from the ENERGY STAR® Integral LED Lamp Center Beam
Intensity Benchmark Tool (ed. 7/6/2010)
Lumen maintenance
L70 > 25,000 hours
Rapid-cycle stress test
Cycle times must be 2 minutes on, 2 minutes off. Lamp will be cycled once for every
2 hours of required minimum L70 life.
2. Define design goals
The design goals for this project as derived from the information above:
Table 6: Design goals
Characteristic
Light output
Unit
Minimum Goal
Target Goal
lm
210
> 210
Illuminance profile
Identical
Power
W
<< 10
Beam angle
˚
36
36
cd
473
> 473
CBCP
3.5
Luminaire efficacy
lm/W
> 50
60
Lifetime
hours
50,000
50,000
K
3000
3000
CCT
CRI
Maximum ambient temperature
˚C
> 80
80
30
40
3. Estimate efficiencies of the optical, thermal & electrical systems
Component Efficiency
Considering efficiency, stability, cost, availability of secondary optics, color rendering and LM-80 availability, two LEDs from the XP family
became candidates: the XLamp XP-E and XP-G LEDs, highlighted in yellow in Figure 1. The XP-E has a slight advantage due to its lower
cost.
Copyright © 2011-20116 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree®, XLamp® and EasyWhite® are registered trademarks and the Cree logo is a
trademark of Cree, Inc. ENERGY STAR® is a registered trademark of the U.S. Environmental Protection Agency. Other trademarks, product, and company names are the property of their respective owners and
do not imply specific product and/or vendor endorsement, sponsorship or association. For product specifications, please see the data sheets available at www.cree.com. For warranty information, please
contact Cree Sales at [email protected].
4
XLamp ® XP-E LED MR16 Reference Design
Figure 1: Binning comparison(left: XP-E, right: XP-G)
Cree chose to work with the XPEWHT-H1-0000-00AE7, highlighted in yellow in Figure 2, in this reference design.
Figure 2: XP-E color, bin and order code
The XLamp XP-E LED has completed LM-80 testing, fulfilling ENERGY STAR’s requirement. The XP-E has been in volume production for
over two years and has become the workhorse of many LED luminaires. It is a reliable choice for an MR16 retrofit lamp.
Thermal Requirements
Despite the XLamp XP-E LED’s efficacy advantage over conventional incandescent and fluorescent lighting, as much as 80% of the input
power is converted to heat. This heat needs to be dissipated efficiently to ensure LED and luminaire lumen maintenance and reliability. For
a 4-W MR16 luminaire, there are many existing market thermal solutions from which to choose. For this reference design, Cree selected
Copyright © 2011-20116 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree®, XLamp® and EasyWhite® are registered trademarks and the Cree logo is a
trademark of Cree, Inc. ENERGY STAR® is a registered trademark of the U.S. Environmental Protection Agency. Other trademarks, product, and company names are the property of their respective owners and
do not imply specific product and/or vendor endorsement, sponsorship or association. For product specifications, please see the data sheets available at www.cree.com. For warranty information, please
contact Cree Sales at [email protected].
5
XLamp ® XP-E LED MR16 Reference Design
an existing well-designed machined aluminum heat sink with good workmanship. Our simulations and actual test results confirmed this
as a good choice for this project.
Figure 3: Machined aluminum heat sink
Cree performed thermal simulation5 on the design with 3 XP-E LEDs running at both 350 mA and 700 mA and found the estimated
solder point temperature to be 53 ˚C. Figure 4 shows the thermal simulation of the solder point temperature. Figure 5 shows the thermal
simulation of the airflow, in the form of convection currents, around the XP-E MR16 lamp.
Figure 4: Thermal simulation of temperature of XP-E MR16
Figure 5: Thermal simulation of airflow around XP-E MR16
Figure 6 shows the thermocouple attached to the XP-E MR16 lamp to record the solder point temperature. Figure 7 shows the measurement
in progress and the temperature reading. The steady-state measurement of 60˚C is a reasonable match to the thermal simulation.
5
Cree used NIKA EFD Pro V8.2 with Pro E Wildfire
Copyright © 2011-20116 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree®, XLamp® and EasyWhite® are registered trademarks and the Cree logo is a
trademark of Cree, Inc. ENERGY STAR® is a registered trademark of the U.S. Environmental Protection Agency. Other trademarks, product, and company names are the property of their respective owners and
do not imply specific product and/or vendor endorsement, sponsorship or association. For product specifications, please see the data sheets available at www.cree.com. For warranty information, please
contact Cree Sales at [email protected].
6
XLamp ® XP-E LED MR16 Reference Design
Figure 6: Thermocouple attached to XP-E LED
Figure 7: XP-E MR16 solder point temperature measurement
Based on Cree’s experience with the XLamp XP-E LED and the L70 lifetime projection shown in Figure 8, we expect this design to attain
both an ENERGY STAR compliant L70 rating of 25,000 hours and meet the target design goal of an L70 rating of 50,000 hours.
Current
Ta/Tsp (ºC)
L70 (hours)
350 mA
85
96,294
400 mA*
85
90,234*
500 mA*
85
79,234*
600 mA*
85
69,575*
700 mA
85
61,094
* Interpolated values
Figure 8: XP-E L70 lifetime estimate
Driver Electronics
Considering the traditional MR16 power requirement and for ease of retrofit, we chose to use a GU5.3 bi-pin connector with 12 VDC
and 12 VAC power input. The LEDs were connected in series to achieve a higher overall Vf for better driver efficiency and to provide the
constant drive current required by the LEDs to achieve consistent light output.
To meet the challenge of fitting a high-efficiency driver into the compact space of an MR16 lamp base, a non-dimmable driver with simple
circuit design6 was used, shown in Figure 9.
6
Driver from Shen Zhen IPOWER Electronic Technology Co., Ltd.
Copyright © 2011-20116 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree®, XLamp® and EasyWhite® are registered trademarks and the Cree logo is a
trademark of Cree, Inc. ENERGY STAR® is a registered trademark of the U.S. Environmental Protection Agency. Other trademarks, product, and company names are the property of their respective owners and
do not imply specific product and/or vendor endorsement, sponsorship or association. For product specifications, please see the data sheets available at www.cree.com. For warranty information, please
contact Cree Sales at [email protected].
7
XLamp ® XP-E LED MR16 Reference Design






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




 ℃
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
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﹣
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





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




Figure 9: Figure 10: XP-E MR16 driver circuit design
Figure 10 shows the XP-E MR16 driver and GU5.3 connector.
Figure 10: XPE-MR16 driver and GU5.3 connector
Secondary Optics
Cree’s XLamp XP-E LED has been in volume production since 2009 and
many market-ready optics designs are available. Considering efficiency,
TIR
beam angle, size and repeatability, Cree chose to use Total Internal
Refraction (TIR) optics for this application.
Figure 11: Example TIR optics
Copyright © 2011-20116 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree®, XLamp® and EasyWhite® are registered trademarks and the Cree logo is a
trademark of Cree, Inc. ENERGY STAR® is a registered trademark of the U.S. Environmental Protection Agency. Other trademarks, product, and company names are the property of their respective owners and
do not imply specific product and/or vendor endorsement, sponsorship or association. For product specifications, please see the data sheets available at www.cree.com. For warranty information, please
contact Cree Sales at [email protected].
8
XLamp ® XP-E LED MR16 Reference Design
A well-designed TIR optic provides high optical efficiency, a narrow beam
angle and good color mixing. As shown in Figure 12, some designs use
surface texture or “mini-pillows” on the lens surface for color mixing to
improve the color uniformity of the light beam.
Figure 12: Example “mini-pillow” TIR optic
Cree Proprietary — CONFIDENTIAL
Figure 13 shows the secondary optics for the XP-E MR16.
Figure 13: Secondary TIR optics for XP-E MR16
4. Calculate the number of LEDs
The XLamp XP-E LED offers various efficacies depending on color temperature, bin and drive conditions. Based on the electrical data
and optical output from Cree’s Product Characterization Tool (PCT), we chose to work with the Q2 flux bin at 3000K CCT, highlighted in
yellow in Figure 14 below, to give a close color point to a halogen bulb. The PCT data indicate that an MR16 lamp containing 3 XP-E LEDs
is capable of meeting the design goals.
Copyright © 2011-20116 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree®, XLamp® and EasyWhite® are registered trademarks and the Cree logo is a
trademark of Cree, Inc. ENERGY STAR® is a registered trademark of the U.S. Environmental Protection Agency. Other trademarks, product, and company names are the property of their respective owners and
do not imply specific product and/or vendor endorsement, sponsorship or association. For product specifications, please see the data sheets available at www.cree.com. For warranty information, please
contact Cree Sales at [email protected].
9
XLamp ® XP-E LED MR16 Reference Design
Compare:
System:
SYS # LED
11 SYS lm tot 13 SYS W
Target Lumens :
Current Display Range:
12 SYS lm/W 15
Optical Efficiency:
210
LED 1
Model
Q2 [87.4]
5
87.4
Q2 [87.4]
Price
$
SYS # LED SYS lm tot
10
233
3.09
75.4
10
7
236.6
3.28
72.1
7
5
218.5
3.14
69.6
5
4
213.2
3.19
66.8
4
4
250
3.87
64.6
4
3
213.9
3.41
62.7
3
3
239.1
3.96
60.4
3
3
263.1
4.5
58.5
3
3
285.6
5.04
56.7
3
3
307.2
5.59
55
2
2
218.6
4.09
53.4
2
2
231.4
4.45
52
2
2
243.6
4.83
50.4
2
2
254.8
5.19
49.1
2
2
265.6
5.55
47.9
2
2
275.6
5.91
46.6
2
2
284.8
6.28
45.4
2
2
293.2
6.64
44.2
2
2
301.2
6.98
43.2
2
#N/A
#N/A
#N/A
#N/A
2
#N/A Cree’s
#N/A
#N/ACharacterization
#N/A
2 Tool
14:
Product
#N/A
#N/A
#N/A
#N/A
2
$
-
Tsp (ºC)
2.0
LED Multiple
SYS W
55
x1
1
SYS lm/W
LED 3
Model
Cree XLamp
22XP-G {CW/NW/WW}
Flux
0.100
0.150
0.200
0.250
0.300
0.350
0.400
0.450
0.500
0.550
0.600
0.650
0.700
0.750
0.800
0.850
0.900
0.950
1.000
1.100
1.200
Figure
1.300
Price
3
94%
LED 2
Model
Cree XLamp
20XP-E {CW/NW/WW}
Current (A)
Flux
Medium (0.1A - 2.0A)
Electrical Efficiency:
90%
3
-
SYS # LED SYS lm tot
Flux
87.4
Tsp (ºC)
2.0
LED Multiple
SYS W
215
2.87
225.4
3.05
213
2.98
210.8
3.02
250.4
3.66
216.6
3.26
244.5
3.77
271.8
4.28
298.5
4.82
216.2
3.55
233
3.94
249.2
4.3
265
4.66
280
5.04
294.8
5.4
308.8
5.81
322.8
6.19
335.8
6.57
348.6
6.96
372.8
7.74
395 XLamp
8.51XP
with
415.2
9.3
Price
55
x1
1
(none)
1
$
1
LED Multiple
SYS lm/W
74.9
73.9
71.5
69.8
68.4
66.4
64.9
63.5
61.9
60.9
59.1
58
56.9
55.6
54.6
53.1
52.1
51.1
50.1
48.2
46.4data
LED
44.6
#N/A
#N/A
#N/A
#N/A
#N/A
#N/A
#N/A
#N/A
#N/A
#N/A
#N/A
#N/A
#N/A
#N/A
#N/A
#N/A
#N/A
#N/A
#N/A
#N/A
#N/A
#N/A
#N/A
#N/A
#N/A
#N/A
#N/A
#N/A
#N/A
#N/A
#N/A
#N/A
#N/A
#N/A
#N/A
#N/A
#N/A
#N/A
#N/A
#N/A
#N/A
#N/A
#N/A
#N/A
5. Consider all design possibilities
Due to the vast quantity of LED-based MR16 designs and parts available in the market, our team tried a number of combinations of heat
sinks, optics, and driver solutions and finally chose to use an MR16 kit from Shenzhen Zhongke Lianhe Super-Conduction Technology Co.
An optic, metal core printed circuit board (MCPCB), heat sink and GU5.3 plug are included in this kit.
6. Complete the final steps: implementation and analysis
With the methodology above, we determined a suitable combination of XLamp XP-E LEDs, components and drive conditions. This section
illustrates the techniques Cree used to create an MR16 replacement based on the design and compares the results with our goal, to create
a 20-W XP-E MR16 replacement lamp.
Prototyping Details
1. We verified the component dimensions to ensure a correct fit.
Copyright © 2011-20116 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree®, XLamp® and EasyWhite® are registered trademarks and the Cree logo is a
trademark of Cree, Inc. ENERGY STAR® is a registered trademark of the U.S. Environmental Protection Agency. Other trademarks, product, and company names are the property of their respective owners and
do not imply specific product and/or vendor endorsement, sponsorship or association. For product specifications, please see the data sheets available at www.cree.com. For warranty information, please
contact Cree Sales at [email protected].
10
XLamp ® XP-E LED MR16 Reference Design
Figure 15: XP-E MR16 components
2. Following the recommendations in the XP LED Family Soldering & Handling Application Note, we reflow soldered the XP-E LEDs onto
the MCPCB with an appropriate solder paste and reflow profile and cleaned the flux residue with isopropyl alcohol.
3. We applied a thin layer of thermal conductive compound to the back of the MCPCB and secured the MCPCB to the heat sink with
screws.
4. We inserted the driver into the GU5.3 plug end and soldered the DC output wires to the corresponding terminals on the MCPCB.
5. We connected the GU5.3 plug end to the heat sink and secured it with screws. We verified that the MCPCB and plug end were secure.
6. We inserted the TIR optics, ensuring proper alignment to the LEDs. Depending on the type of TIR optics and their design, various
securing options can be used including self locking, additional locking ring, or adhesive.
7. We tested the completed assembly with 12 VDC.
Results
Optical Results
Optical testing of the XLamp XP-E LED MR16 shows this reference design meets the target specifications. Contour plots of color and
luminance distribution of the reference design7 are shown below in Figure 16 and Figure 17. These demonstrate that the TIR optics evenly
distribute the light from the 3 XP-E LEDs and produce smooth light without hotspots.
7
Plots were taken with Radiant Imaging’s imaging photometer.
Copyright © 2011-20116 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree®, XLamp® and EasyWhite® are registered trademarks and the Cree logo is a
trademark of Cree, Inc. ENERGY STAR® is a registered trademark of the U.S. Environmental Protection Agency. Other trademarks, product, and company names are the property of their respective owners and
do not imply specific product and/or vendor endorsement, sponsorship or association. For product specifications, please see the data sheets available at www.cree.com. For warranty information, please
contact Cree Sales at [email protected].
11
XLamp ® XP-E LED MR16 Reference Design
Figure 16: Contour plot of CCT color distribution (oval shape is a result of off-axis camera placement)
Figure 17: Contour plot of luminance distribution (oval shape is a result of off-axis camera placement)
Copyright © 2011-20116 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree®, XLamp® and EasyWhite® are registered trademarks and the Cree logo is a
trademark of Cree, Inc. ENERGY STAR® is a registered trademark of the U.S. Environmental Protection Agency. Other trademarks, product, and company names are the property of their respective owners and
do not imply specific product and/or vendor endorsement, sponsorship or association. For product specifications, please see the data sheets available at www.cree.com. For warranty information, please
contact Cree Sales at [email protected].
12
XLamp ® XP-E LED MR16 Reference Design
As shown in Figure 18 and Figure 19, the XLamp XP-E LED MR16 lamp far field distribution pattern betters that of two halogen MR16
bulbs.
162
156
150
144
138
132
126
120
114
-180
180
-174-168
168 174
600.00
-162
-156
-150
-144
500.00
-138
-132
400.00
-126
-120
300.00
-114
-108
200.00
108
102
-102
100.00
96
-96
-90
0.00
90
-84
84
-78
78
-72
72
66
60
54
48
42
36
30
24
18 12
6
0
-66
-60
-54
-48
-42
-36
-30
XPE 20W MR16
-24
-18
Halogen MR16 - A
-12
-6
Halogen MR16 - B
Figure 18: Goniometric intensity polar plot comparison of 20-W equivalent XP-E MR16
600
550
XPE 20W MR16
500
Halogen MR16 - A
Lum Intensity (Cd)
450
Halogen MR16 - B
400
350
300
250
200
150
100
50
0
1
-90 -80 -70 -60 -50 -40 -30 -20 -10 0
10 20 30 40 50 60 70 80 90
Angle (deg)
Figure 19: Measured luminous intensity comparison of 20-W equivalent XP-E MR16
Copyright © 2011-20116 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree®, XLamp® and EasyWhite® are registered trademarks and the Cree logo is a
trademark of Cree, Inc. ENERGY STAR® is a registered trademark of the U.S. Environmental Protection Agency. Other trademarks, product, and company names are the property of their respective owners and
do not imply specific product and/or vendor endorsement, sponsorship or association. For product specifications, please see the data sheets available at www.cree.com. For warranty information, please
contact Cree Sales at [email protected].
13
XLamp ® XP-E LED MR16 Reference Design
Table 7 shows the illuminance of the XLamp XP-E LED MR16 lamp at various distances from the light source. The beam angle is 35
degrees.
Table 7: XP-E MR16 illuminance
Height
Illuminance
Diameter
1m
3.2 ft
47.3 fc
508.6 lx
63.1 cm
2.1 ft
2m
6.6 ft
11.8 fc
127.2 lx
126.1 cm
4.1 ft
3m
9.8 ft
5.2 fc
56.5 lx
189.2 cm
6.2 ft
4.m
13.1 ft
3.0 fc
31.8 lx
252.2 cm
8.3 ft
5m
16.4 ft
1.9 fc
20.4 lx
315.3 cm
10.3 ft
6m
19.7 ft
1.3 fc
14.1 lx
378.4 cm
12.4 ft
7m
23.0 ft
.9 fc
10.3 lx
441.4 cm
14.5 ft
8m
26.2 ft
.7 fc
8.0 lx
504.5 cm
16.6 ft
9m
29.5 ft
.6 fc
6.3 lx
567.5 cm
18.6 ft
10 m
32.8 ft
.5 fc
5.1 lx
630.6 cm
20.7 ft
Table 8 summarizes the results and shows that the XP-E MR16 lamp generally meets the design goals and betters the performance of
comparison halogen fixtures.
Table 8: XLamp XP-E LED MR16 test results
Characteristic
Unit
Result
Target Goal
Light output (10 min. on time)
lm
209
> 210
Power
W
3.6
3.5
degrees
36
36
Cd
508
> 473
Efficacy
lm/W
58
60
Lifetime
hours
50,000
50,000
K
3000
3000
> 80
80
30
40
Beam angle
CBCP
CCT
CRI
Maximum ambient temperature
˚C
Copyright © 2011-20116 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree®, XLamp® and EasyWhite® are registered trademarks and the Cree logo is a
trademark of Cree, Inc. ENERGY STAR® is a registered trademark of the U.S. Environmental Protection Agency. Other trademarks, product, and company names are the property of their respective owners and
do not imply specific product and/or vendor endorsement, sponsorship or association. For product specifications, please see the data sheets available at www.cree.com. For warranty information, please
contact Cree Sales at [email protected].
14
XLamp ® XP-E LED MR16 Reference Design
Conclusions
The intent of this design is to demonstrate that Cree’s high-power XLamp XP-E LED can be easily incorporated into a MR16 retrofit lamp
meeting the ENERGY STAR requirements. Testing of the prototype shows that this goal has been met. Despite the “plug and play” nature
of this design, there are many improvements a committed design team with appropriate resources can make, such as a simpler and
cheaper heat sink and a dimmable power supply. This design shows the level of performance that can be achieved with the Cree XLamp
XP-E LED but should not be interpreted as the only way that a good XP-E LED-based MR16 lamp can be designed.
Reliance on any of the information provided in this Application Note is at the user’s sole risk. Cree and its affiliates make no warranties or representations about, nor assume any
liability with respect to, the information in this document or any LED-based lamp or luminaire made in accordance with this reference design, including without limitation that
the lamps or luminaires will not infringe the intellectual property rights of Cree or a third party. Luminaire manufacturers who base product designs in whole or part on any Cree
Application Note or Reference Design are solely responsible for the compliance of their products with all applicable laws and industry requirements.
Copyright © 2011-20116 Cree, Inc. All rights reserved. The information in this document is subject to change without notice. Cree®, XLamp® and EasyWhite® are registered trademarks and the Cree logo is a
trademark of Cree, Inc. ENERGY STAR® is a registered trademark of the U.S. Environmental Protection Agency. Other trademarks, product, and company names are the property of their respective owners and
do not imply specific product and/or vendor endorsement, sponsorship or association. For product specifications, please see the data sheets available at www.cree.com. For warranty information, please
contact Cree Sales at [email protected].
15