The movement to light-emitting diode (LED) lighting systems worldwide is accelerating quickly as energy savings and reduction in hazardous materials increase in importance. Government regulations and rapidly lowering prices help to further this trend. Today's strong drive is to replace light bulbs of common outputs (60 W, 75 W, and 100 W) without resorting to compact fluorescent (CFL) bulbs containing mercury while maintaining the standard industry bulb size and shape referred to as A19. For many bulb designs, this A19 size and shape restriction forces a small heat sink which is barely capable of dissipating heat for 60 W equivalent LED bulbs with natural convection for today's LED efficacies. 75 W and 100 W equivalent bulbs require larger sizes, some method of forced cooling, or some unusual liquid cooling system; generally none of these approaches are desirable for light bulbs from a consumer point of view. Thus, there is interest in developing natural convection cooled A19 light bulb designs for LEDs that cool far more effectively than today's current designs. Current A19 size heat sink designs typically have thermal resistances of 5–7 °C/W. This paper presents designs utilizing the effects of chimney cooling, well developed for other fields that reduce heat sink resistances by significant amounts while meeting all other requirements for bulb system design. Numerical studies and test data show performance of 3–4 °C/W for various orientations including methods for keeping the chimney partially active in horizontal orientations. Significant parameters are also studied with effects upon performance. The simulations are in good agreement with the experimental data. Such chimney-based designs are shown to enable 75 W and 100 W equivalent LED light bulb designs critical for faster penetration of LED systems into general lighting applications.

References

1.
European Commission on Energy Efficiency, 2008, “
Phasing Out Incandescent Bulbs in the EU
,” http://ec.europa.eu/energy/efficiency/ecodesign/doc/committee/2008_12_08_technical_briefing_household_lamps.pdf
2.
Energy Independence and Security Act of 2007,
2007
, “
U.S. Public Law 110-140
,” retrieved Dec. 19, 2013, http://www.gpo.gov/fdsys/pkg/PLAW-110publ140/content-detail.html
3.
ANSI,
2003
, “American National Standard for Electric Lamps—A, G, PS and Similar Shapes With E26 Medium Screw Bases,”
American National Standards Institute
, Washington, DC, Standard No. ANSI C78.20-2003.
4.
U.S. Environmental Protection Agency
,
2012
, “
ENERGY STAR® Program Requirements Product Specification for Lamps (Light Bulbs), Version 1 Draft 2
,” retrieved July 6, 2014, http://energystar.gov/products/specs/node/273
5.
Ellenbaas
,
W.
,
1942
, “
The Dissipation of Heat by Free Convection From the Inner Surface of Vertical Tubes of Different Shapes of Cross Section
,”
Physica
,
9
(
8
), pp.
865
874
.10.1016/S0031-8914(42)80062-2
6.
Ellenbaas
,
W.
,
1942
, “
Heat Dissipation of Parallel Plates by Free Convection
,”
Physica
,
9
(
1
), pp.
1
28
.10.1016/S0031-8914(42)90053-3
7.
Karki
,
K. C.
, and
Patankar
,
S. V.
,
1987
, “
Cooling of a Vertical Shrouded Fin Array by Natural Convection: A Numerical Study
,”
ASME J. Heat Transfer
,
109
(
3
), pp.
671
676
.10.1115/1.3248140
8.
Petrie
,
T. W.
,
Bajabir
,
A. A.
,
Petrie
,
D. J.
, and
Kroll
,
J. W.
,
1988
, “
Predicting Temperatures of Stacked Heat Sinks With a Shroud
,”
ASME J. Heat Transfer
,
110
(
3
), pp.
802
807
.10.1115/1.3250568
9.
Acharya
,
S.
, and
Patankar
,
S. V.
,
1981
, “
Laminar Mixed Convection in a Shrouded Fin Array
,”
ASME J. Heat Transfer
,
103
(
3
), pp.
559
565
.10.1115/1.3244502
10.
Sparrow
,
E. M.
, and
Kadle
,
D. S.
,
1986
, “
Effect of Tip-to-Shroud Clearance on Turbulent Heat Transfer From a Shrouded, Longitudinal Fin Array
,”
ASME J. Heat Transfer
,
108
(
3
), pp.
519
524
.10.1115/1.3246965
11.
Kitamura
,
Y.
, and
Ishizuka
,
M.
,
2004
, “
Chimney Effect on Natural Air Cooling of Electronics Equipment Under Inclination
,”
ASME J. Electron. Packag.
,
126
(
4
), pp.
423
428
.10.1115/1.1827256
12.
Andreozzi
,
A.
,
Buonomo
,
B.
, and
Manca
,
O.
,
2005
, “
Numerical Simulation of Transient Natural Convection in a Channel-Chimney System
,”
ASME
Paper No. HT2005-72628.10.1115/HT2005-72628
13.
De Mey
,
D.
,
Wójcik
,
M.
,
Pilarski
,
J.
,
Lasota
,
M.
,
Banaszczyk
,
J.
,
Vermeersch
,
B.
,
Napieralski
,
A.
, and
De Paepe
,
M.
,
2009
, “
Chimney Effect on Natural Convection Cooling of a Transistor Mounted on a Cooling Fin
,”
ASME J. Electron. Packag.
,
131
(
1
), p.
014501
.10.1115/1.3068307
14.
Panthalookaran
,
V.
,
2010
, “
CFD-Assisted Optimization of Chimneylike Flows to Cool an Electronic Device
,”
ASME J. Electron. Packag.
,
132
(
3
), p.
031007
.10.1115/1.4002009
15.
Mulay
,
V.
,
Agonafer
,
D.
,
Irwin
,
G.
, and
Patell
,
D.
,
2009
, “
Effective Thermal Management of Data Centers Using Efficient Cabinet Designs
,”
ASME
Paper No. InterPACK2009-89351.10.1115/InterPACK2009-89351
16.
Avallone
,
E. A.
, and
Baumeister
,
T.
, III
,
1987
,
Marks' Standard Handbook for Mechanical Engineers
, 9th ed.,
McGraw-Hill
,
New York
, pp.
9
27
.
17.
Treurniet
,
T.
, and
Bosschaart
,
K. J.
,
2011
, “
Method for Heat Flux Measurement on LED Light Engines
,”
27th IEEE Semiconductor Thermal Measurement and Management Symposium
(
SEMI-THERM
), San Jose, CA, Mar. 20–24, pp.
292
296
.10.1109/STHERM.2011.5767213
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