下載/瀏覽

Download Report

Transcript 下載/瀏覽 

High Efficiency Uniform LED Surface
Light Source
Chih-Chieh Kang, Jeng-Feng Lin, Yu-Chang Wu, ShihCheng Yeh, Tai-Rong Chen
Department of Electrooptical Engineering, Southern
Taiwan University, Yung-Kang, Tainan, Taiwan, 71005
R.O.C.
Abstract
• A novel LED uniform surface light structure is
devised for the use of lighting, especially for a
large-size edge-type backlight unit (BLU). Two
kinds of embodiments are proposed in this
work. Simulation results demonstrate their
high efficiency and high uniformity in terms of
light extraction and illuminance performance,
respectively.
Background
• Going green is the market trend.
• Concept of using “empty cavity” as a light-guiding
mechanism was proposed more than a decade ago
for small-size LED backlight unit (BLU) .
• As the size and thickness of a BLU are becoming
larger and thinner, the optical design of existing
structures become difficult and complicated.
• Novel design is needed
Prior Works
• Y. Nakamura and E. Furuya, “ Liquid
Crystal Display Device Backlit by
LED’s Coupled to Printed Circuit
Board,” US Patent No. 5453855,
(1995).
• S. Sakai, A. Mori, K. Ishiguchi, K.
Kobauashi, T. Kokogawa, T.
Sakamoto, and T. Yoneda, “A Thin
LED Backlight System with High
Efficiency for Backlighting 22-in. TFTLCDs,” SID Symposium Digest 37,
1218-1221, (2004)
• C. P. Hung, W. S. Chen, J. H. Lin, and
W. Y. Li, “Novel Design for LED Lens
and Backlight System,” Proceedings
of IDMC 2007, Taiwan, 476-479,
(2007)
Optical Design Principle
• Bullet-shape LEDs with high-directivity intensity
profile.
• One central bump and several pairs of side slant
structures on the bottom reflection surface for
illuminace uniformity by light modulation.
• Improve illumiance uniformity by a diffusion plate.
• Reverse prism layer structure to greatly enhance
luminance performance.
Optical Designs
(a) only a diffusion plate
(b) a diffusion plate with a reverse prism layer structure
High-Directivity LED
• For exampe
Nichia NSPW500B
Radiation pattern
Bottom Reflection Surface with
Bumpy Structures
• Illuminace uniformity improvement
• Enhancement of light extraction efficiency
BLU implemented is of 62.6 × 234× 15.9 mm
Optical Simulation (a)
• only a diffusion plate ontop of the “empty cavity”
No diffusion plate presents
Light extraction efficiency = 91%
Optical simulation (a)
• only a diffusion plate ontop of the “empty cavity”
Diffusion plate presents
Light extraction efficiency = 77%
Illuminance uniformity = 72%
Reverse Prism Layer Structure
• Redirect the light rays toward the direction of
normal viewing angle
• Enhancement of light extraction efficiency
Refocusing Effect of Reverse Prism
Layer Structure
Light rays emitting
from LEDs on the
left side modulated
by the left side slant
structure
Light rays emitting
from LEDs on the
right side
modulated by the
central bump
Optical Simulation (b)
• A reverse prism layer structure ontop of the “empty cavity”
No diffusion plate presents
Light extraction efficiency = 94%
Optical simulation (b)
• A diffusion plate with a reverse prism layer structure
ontop of the “empty cavity”
Light extraction efficiency = 89%
Illuminance uniformity = 60%
Conclusion
• We can highly increase the light extraction efficiency
up to be 90% that is comparable to some direct-type
LED BLUs .
• Our second devised embodiment can greatly
increase the luminance performance by the
implementation of the reverse prism layer structure
as well as the manipulation the transmittance of a
diffusion plate.
• More work is needed on optimizing optical design in
order to improve the uniformity on both illuminance
and luminance.