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研究生: 李炳仁
Lee, Ping-Jen
論文名稱: 熱管製作與熱沉鑄造之實驗研究與數值分析
Experimental and Numerical Studies of Heat-Pipe Manufacturing Technology and Heat-Sink Casting Method
指導教授: 趙隆山
Chao, Long-Sun
學位類別: 碩士
Master
系所名稱: 工學院 - 工程科學系碩士在職專班
Department of Engineering Science (on the job class)
論文出版年: 2004
畢業學年度: 92
語文別: 中文
論文頁數: 118
中文關鍵詞: 熱管鑄造
外文關鍵詞: heat pipe, casting method
相關次數: 點閱:89下載:3
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    •   本文主要是探討含熱管熱沉之鑄造方法與熱管之製作技術、鑄造式與嵌入式熱沉之熱反應和熱阻的比較、自製熱管與市售熱管作之熱反應比較。在研究中,建立簡易之暫態熱反應實驗方法,可以檢測熱管之效能,本文以改良鑄造方法成功地製造出含熱管之熱沉,而不損壞熱管之效率,與嵌入式熱沉比較,具有較佳之熱反應與相對很低之熱阻。於熱管之製作過程中,熱管之溫度與真空度有重要之關係,可以作為熱管製作之重要指標,不過本研究所製作之熱管的效能尚不如市售熱管。最後使用FIDAP軟體來作熱沉與熱管的熱傳分析,藉由暫態熱反應之溫度與時間關係圖,以試誤法來反推熱管的等效熱傳導係數。

      This paper is to study (1) the casting method of the connection between heat sink and heat pipe, (2) the thermal response and the thermal resistance for the heat sinks with heat pipe of casting and insert types, (3) the thermal response of self-made and commercial heat pipes. In the study, a simple experimental method of thermal response is built and it can be used to inspect the efficiency of a heat pipe. An improved method is developed to cast the heat sink with heat pipe, which can prevent the heat pipe from burning out and then lose its function. The thermal response and the thermal resistance of casting-type heat sink with heat pipe are superior to those of insert one. In the process of heat-pipe fabrication, there exists a critical relation between the temperature and the vacuum pressure of a heat pipe, which can be applied as an important index for making a heat pipe. However, the self-made heat pipe in this research is inferior to the commercial one. Finally, the package FIDAP is used in simulating the heat conduction of the heat sink and heat pipe. The equivalent heat conduction coefficient of heat pipe can be obtained with the trial and error method by comparing the computing temperatures with experimentally measured ones.

    總目錄 頁數 摘要.................................................. I 英文摘要............................................. II 誌謝................................................ III 目錄................................................. IV 表目錄............................................... IX 圖目錄................................................ X 符號表.............................................. XIV 第一章 導論........................................... 1 1-1前言............................................. 1 1-2文獻回顧......................................... 3 1-3研究目的......................................... 6 第二章 實驗設備與方法.................................. 8 2-1實驗設備介紹.................................... 8 2-2扣具壓力....................................... 15 2-2-1實驗方法與步驟............................ 16 2-3熱管與銅管之比較............................... 17 2-3-1實驗方法與步驟............................ 17 2-4熱管之製作與比較............................... 18 2-4-1實驗方法與步驟............................ 18 2-5含熱管之熱沉的鑄造方式......................... 19 2-5-1鑄造之實驗方法與步驟...................... 21 2-5-2鑄造熱沉與熱管之檢驗...................... 23 2-6鑄造式與嵌入式熱沉之比較....................... 24 2-6-1鑄造式與嵌入式熱沉之暫態熱反應比較........ 25 2-6-2鑄造式與嵌入式熱沉之熱阻比較.............. 26 2-7熱管兩端均有熱沉之鑄造式與嵌入式比較........... 28 第三章 熱管數值模擬分析.............................. 30 3-1理論模式....................................... 30 3-2數值方法....................................... 31 3-3熱管之等效熱傳導係數........................... 32 第四章 結果與討論.................................... 33 4-1扣具壓力....................................... 33 4-2熱管與銅管之比較................................ 34 4-2-1熱管的暫態熱反應之研究..................... 34 4-2-2熱管的模擬熱傳導係數之研究................. 34 4-3熱管之製作與比較............................... 35 4-3-1自製熱管的製作與暫態熱反應比較............. 35 4-3-2市售熱管與自製熱管的數值模擬分析........... 37 4-4含熱管熱沉之鑄造................................ 37 4-5 鑄造式熱沉與嵌入式熱沉之熱阻比較............... 41 4-5-1一端有熱沉的接觸熱阻....................... 41 4-5-2兩端有熱沉的接觸熱阻....................... 43 4-6 鑄造式與嵌入式熱沉之暫態熱反應比較............. 45 4-7熱沉與熱管之數值熱傳分析........................ 45 第五章 結論.......................................... 47 參考文獻............................................. 49

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