 |
|
|
|
以作者查詢圖書館館藏 、以作者查詢臺灣博碩士 、以作者查詢全國書目 、勘誤回報 、線上人數:20 、訪客IP:3.144.6.236
姓名 葉隆興(Long-Sing Ye) 查詢紙本館藏 畢業系所 機械工程學系 論文名稱 高功率發光二極體於自然對流環境下之熱流場分析
(Thermal-Fluid analysis of HBLEDs under the natural convection)相關論文 檔案 [Endnote RIS 格式]
[相關文章]
[文章引用]
[完整記錄]
[館藏目錄]
至系統瀏覽論文 ( 永不開放)
摘要(中) 能源短缺及溫室效應等議題,是世界各國在目前甚至是未來的五十年內所需面臨的問題。其中,傳統照明光源(白熾燈、日光燈)直接或間接造成了能源消耗。相較之下,在LED能達到150 lm/W的前提下預估可有效的降低這些問題。然而,材料匹配與應用、電路配置與電力之供應以及封裝材料散熱結構設計等等都直接的阻礙了此目標,其中又以散熱問題最為嚴重。因此,有效的熱管理是必要的。
本研究藉由熱阻量測系統的建立再配合數值分析軟體的應用,針對高功率LED在不同的操作條件下進行實驗及模擬分析,進而找出較適當的基板結構設計及操作條件,以降低整體熱阻及接面溫度。由數值方法模擬出之元件外部熱流場可得知,因特殊的幾何結構、輸入功率(大於1W)及自然對流環境,使得元件擺置角度角度於水平MCPCB基板朝下時,LED元件上方有二次流動的現象產生。當元件擺置角度於垂直方向時的自由流速較水平方向增加近2倍的流動速率,接面溫度及熱阻分別約降低4℃及2.4℃/W,又由於基板結構的改變(切槽及開孔設計),使得LED基板在水平擺置角度時,接面溫度及熱阻分別約降低4℃及4℃/W,而模擬與實驗結果比對後之準確率達90%。另外,本研究完成標準熱阻量測系統之建立,並與業界量測結果比對後有約有98%的相似率,並透過實驗方式歸納出適用於LED之對流熱傳係數估算經驗公式,期望本研究能作為日後設計時參考指標與努力方向。摘要(英) In the 21st century, lack of energy or greenhouse effect has become one of top ten problems not only in global but also in many countries for next 50 years in which light is one of main reason that takes a high number of total energy consumption with traditional light equipments like fluorescent lamp and incandescent bulb etc…. When LEDs is invented, it has been used in many fields of living and industry in order to replace for foregoing light since it runs with high efficiency and save more energy. By the advanced technique at moment, it can be expected to reach over 150lumens/W, and as a result it reaches to the luminous efficiency. Because of this, it is essential to study the heat problems as well as the effective of thermal management for white light LEDs.
In this study, the Measurement System of Thermal Resistance and Numerical Analysis Module have been done via experiment and simulation analysis in which focus on the high power LEDs at different work conditions in order to find out better MCPCB structure design and operated condition, that for the purpose of reduce the thermal resistance and junction temperature.
In numerical simulation of the LED device outside thermal-fluid field, there is phenomenon of secondary flow that emerges above LED device when keep the horizontal downward of MCPCB, the velocity of free flow in the vertical angle orientation of device increased nearly 2 times of the efficiency than the horizontal, and the junction temperature as well as the total thermal resistance reduce around by 4℃ and 2.4℃/W respectively. In addition, due to the change of the structure of the substrate(slice, via…), junction temperature as well as the total thermal resistance reduce around by 4℃ and 4℃/W respectively. Simulation results are accurate more than 90% if compare to the experimental results. On the other hand, in this study the Standard Measurement System of Thermal Resistance has been finished that results are similar and closed to 98%compare with the industry and define the thermal convection coefficient correlation module of LED device by experiment data. These results may give the directions for LED’s design in the future.關鍵字(中) ★ 電子封裝散熱
★ 熱流數值分析
★ 有限元素法
★ LED熱阻量測關鍵字(英) ★ Thermal-Fluid Analysis
★ FEM
★ Rth Measurement論文目次 摘要 Ⅰ
Abstract Ⅱ
致謝 Ⅳ
目錄 Ⅴ
圖目錄 Ⅷ
表目錄 XII
符號說明 XIII
第一章 緒論
1-1 前言 1
1-2 LED簡介 2
1-2.1 LED發展 2
1-2.2 LED發光原理 2
1-2.3 LED的優點 3
1-2.4 LED的應用與分類 5
1-3 文獻回顧 5
1-4 研究動機與目的 8
第二章 熱傳遞原理
2-1 熱傳遞基本原理 18
2-1.1 熱傳導原理 18
2-1.2熱對流原理 18
2-2 自然對流基本原理 19
2-3對流熱傳係數估算 19
第三章 熱阻抗量測實驗
3-1 實驗目的 24
3-2 熱阻定義 24
3-3測試環境與量測之規範 26
3-4 實驗器材及設備 26
3-5 實驗試件 27
3-6 實驗原理 28
3-7 實驗方法及步驟 28
第四章 有限元素數值模擬分析
4-1 有限元素法 39
4-2 分析流程 40
4-2.1物理模型及問題描述 40
4-2.2 問題求解及相關假設 41
4-2.3 統御方程式與邊界條件 42
4-2.4 各項材料性質與模型參數設定 43
4-2.5 收斂條件 44
4-2.6 幾何網格之建立及測試 45
第五章 結果與討論
5-1 LED接面溫度與熱阻量 55
5-1.1 設備準確性驗證 55
5-1.2 不同擺置角度與輸入功率之影響 56
5-1.3 實驗流程注意事項 57
5-2 數值模擬分析 57
5-2.1 LED模型準確性驗證 58
5-2.2 LED元件擺置角度變化對熱流場之影響 58
5-2.3 LED輸入功率變化對熱流場之影響 59
5-2.4 LED MCPCB幾何變化對熱流場之影響 60
5-3 實驗與模擬結果之比對 62
5-3.1 元件擺置角度變化 62
5-3.2 輸入功率變化 62
5-3.3 MCPCB結構變化 62
5-3.4 各式熱對流係數預估比較 63
第六章 結論 83
參考文獻 87參考文獻 1.Nichia Inc., www.nichia.co.jp
2.Jeong Park and Chin C. Lee, “An Electrical Model With
Junction Temperature for Light-Emitting Diodes and the
Impact on Conversion Efficiency”, IEEE Electron Device
Letters, vol. 26, no. 5, pp. 308~310, 2005.
3.小山稔,奧野保男,柏原鳳一郎著,柏瑞芳譯,“發光二極體及
其應用”,工業技術研究院工業材料研究所,1991。
4.江文瑞,“台灣可見光二極體上游產業的競爭策略”,義守大學
管理研究所碩士論文,2004。
5.湯鈞汶,“LED照明應用”,工業材料雜誌,208期,pp. 142,
2004。
6.Lumileds Lighting, U.S. LLC., “Luxeon K2-Star Technical
Datasheet”, www.lumileds.com,2006.
7.Lumileds Lighting, U.S. LLC., “Luxeon Emitter Technical
Datasheet”, www.lumileds.com,2005.
8.Lumileds Lighting, U.S. LLC., “Luxeon Star Technical
Datasheet”, www.lumileds.com, 2005.
9.OIDA, “Light Emitting Diodes (LEDs) for General
Illumination” , An OIDA Technology Roadmap Update 2002.
10.Mehmet Arika, Charles Beckerb, Stanton Weaverb, and
James Pertroskic., “Thermal Management of LEDs:
Package to Syatem”, Third International Conference on
Solid State Lighting, SPIE Vol. 5187,2004.
11.鄭健宏,“高功率LED之熱場模擬與結構分析”,中央大學機械
工程研究所碩士論文,2005。
12.McAdams, W.H., Heat Transmission, 3rd ed., McGraw-Hill,
New York, 1954.
13.Coulson and Richardson, Chemical Engineering, vol. 1,
4th ed., Pergamon Press, 1990.
14.Morgan, V.T., “The Overall Convection Heat Transfer
from Smooth Circular Cylinders,” in T.F. Irvine and
J.P. Hartnett, Eds., Advance in Heat Transfer, Vol. 11,
Academic Press, New York, 1975, pp. 199-264.
15.Churchill, S.W., and H. H. S. Chu, “Correlating
Equations for Laminar and Turbulent Free Convection
form a Horizontal Cylinder,” Int. J. Heat Mass
Transfer, 18, 1049, 1975.
16.Churchill, S.W., “Free Convection Around Immersed
Bodies,” in E.U. Schlunder, Ed.-in-Chief, Heat
Exchange Design Handbook, Section 2.5.7, Hemisphere
Publishing, New York, 1983.
17.Enchao Yu and Yogendra K. Joshi, “Natura; Convection
Air Cooling of Electronic Components in Partially Open
Compact Horizontal Enclosures ”, IEEE TRANSACTIONS ON
COMPONENTS AND PACKAGING TECHNOLOGIES, VOL. 23, NO.1 /
MARCH 2000.
18.Jeong Park and Chin C. Lee, “An Electrical Model With
Junction Temperature for Light-Emitting Diodes and the
Impact on Conversion Efficiency”, IEEE Electron Device
Letters, vol. 26, no. 5, pp. 308~310, 2005.
19.Nadarajah Narendran and Yimin Gu, “Life of LED-Based
White Light Sources”, IEEE/OSA Journal of Display
Technology, vol. 1, no. 1, pp. 167~171, 2005.
20.Eugene Hong and Nadarajah Narendran, “A Method for
Projecting Useful Life of LED Lighting Systems”, Third
International Conference on Solid State Lighting,
Proceedings of SPIE, vol. 5187, pp. 93~99, 2004.
21.J. P. Holman, “Heat Transfer”, The McGraw-Hill
Companies, Inc., Eighth Edition , 2000
22.F. P. Incropera, D. P. DeWitt, “Fundamentals of Heat
and Mass Transfer”, John Wiley & Sons, Inc., Fourth
Edition, N. Y., 1996.
23.Gordon N. Ellison, “THERMAL COMPUTATIONS FOR
ELECTRONIC WQUIPMENT”, TAI TA BOOK COMPANY, Sep. 1986.
24.John Sofia, “Fundamentals of thermal Resistance
Measurement” Analysis Tech, 1995.
25.EIA/JEDEC Standard EIA/JESD51, “Integrated Circutis
Thermal Test Method Environment Conditions Natural
Convection (Still Air)”, Electronic Industried
Association, Engineering Department, Arlington, VA,
1995.
26.Applied Finite Element Analysis 2nd, Larry J. Segerlind
John Wiley & Sons, 1984.
27.Introduction to Finite Elements in Engineering 3nd,
TIRUPATHI R. CHANDRUPATLA., ASHOK D. BELEGNDU, Prentice
Hall, 2002.
28.黃清白,“覆晶直接粘著之熱傳模擬方法的探討”,電腦與通
訊,70期,pp. 22,1998。
29.吳望一”流體力學”歐亞書局,1989.
30.Frank M. White, “Viscous Fluid Flow Second Edition”,
McGRAW-HILL INTERNATION EDITIONS Mechanical Engineering
Series , 1991.
31.Benjamin Gebhart, “HEAT CONDUCTION AND MASS
DIFFUSION”, McGRAW-HILL, INTERNATION EDITIONS
Mechanical Engineering Series , 1993.
32.Lumileds Lighting, U.S. LLC., “Thermal Design Using
Luxeon Power Light Sources”, www.lumileds.com,2006.指導教授 陳志臣(Jyh-Chen Chen) 審核日期 2007-7-10 推文 plurk
funp
live
udn
HD
myshare
netvibes
friend
youpush
delicious
baidu
網路書籤 Google bookmarks
del.icio.us
hemidemi
facebook
twitter
google
reddit