彩色濾光片噴塗研究

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姓名

張皓翔(Hao-Hsiang Chang) 查詢紙本館藏

畢業系所

機械工程學系

論文名稱

彩色濾光片噴塗研究
(The Study of Ink-Jet Coating in Color Filter.)

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至系統瀏覽論文 ( 永不開放)

摘要(中)

本論文的主要研究重點在於開發出一種陣列式多孔壓電噴頭模組，並經由實驗測試其可行性與穩定性，找出噴頭模組可噴出液體的視窗範圍。本次研究所用的壓電材料型號為PZT5H，長寬高為100mm×10mm×1mm；驅動電壓源則使用國科會精密儀器發展中心所研發的可調高壓信號產生器，其可產生最高輸出電壓200
+/-V ptp，並配合外接信號產生器，以產生1萬Hz以上的頻率輸出；噴墨液體固定為5cP的標準黏度液(矽油)；噴孔數量30孔，大小則為50μm ～200μm之間。實驗參數固定以最高的輸出電壓，搭配1Hz～20kHz的高低頻率，並觀察在以上的條件下，此噴頭模組是否具有可行性。在歷經一連串的重複實驗後，本論文找出在頻率介於1Hz~20kHz之間，噴頭模組具有將液體噴出的能力，進而分析噴出後液體的物理狀態，證明本研究所開發出的壓電噴頭模組其可行性相當高。

關鍵字(中)

★ 壓電噴頭
★ 噴墨
★ 彩色濾光片

關鍵字(英)

★ piezoelectric inkjet
★ inkjet
★ color filter

論文目次

目錄
摘要.....................................................Ⅰ
目錄.....................................................Ⅱ
表目錄...................................................Ⅵ
圖目錄...................................................Ⅶ
第一章緒論........................................... 1
1-1 前言.................................................1
1-2 噴墨列印技術之演進...................................2
1-2-1 噴墨種類與原理.....................................2
1-2-2 文獻回顧...........................................5
1-3 噴墨技術之應用.......................................9
1-3-1 焊錫凸塊..........................................10
1-3-2 電路基板配線......................................10
1-3-3 高分子微型光學透鏡................................10
1-3-4 微泵燃油噴射......................................11
1-3-5 生醫工程..........................................11
1-3-6 奈米尺度超精密加工................................11
1-3-7 微熱點冷卻........................................12
1-3-8 有機發光二極體平面顯示器（PLED）................. 12
1-3-9 彩色濾光片........................................13
1-4 彩色濾光片塗佈技術之演進............................13
1-5 研究動機與目的......................................16
1-6 研究概要............................................16
第二章多孔壓電噴頭模組製作方法.......................18
2-1 多孔壓電噴頭模組製作簡介............................18
2-2 壓電材料接線步驟....................................18
2-3 微型噴孔薄鋼片製作方法..............................20
2-4 噴頭模組製作流程....................................20
第三章實驗設備與步驟.................................23
3-1 實驗設備............................................23
3-1-1 多孔陣列式噴頭模組................................23
3-1-2 影像擷取系統......................................25
3-1-3 噴頭模組驅動系統..................................26
3-2 實驗步驟............................................26
3-2-1 噴頭模組組裝......................................27
3-2-2 溶液的填充........................................27
3-2-3 輸入電壓脈衝訊號..................................27
3-2-4 觀察液體有無噴出現象..............................28
3-2-5 噴出影像擷取......................................28
3-2-6 影像分析..........................................28
3-2-7 微型噴孔片的更換..................................29
第四章實驗結果與討論................................ 30
4-1 多孔陣列式壓電噴頭模組製程改善......................30
4-1-1 上蓋板的變更......................................30
4-1-2 防漏透明塑膠墊的改善..............................31
4-1-3 供液系統的討論....................................31
4-1-4 玻璃纖維 (PCB) 板的改善...........................32
4-1-5 壓電材料的短路現象................................32
4-1-6 微型噴孔片的替換..................................33
4-2 可以噴出液體的頻率視窗..............................33
4-2-1 T40μm Φ100μm 單孔可噴出視窗.......................33
4-2-2 T40μm Φ200μm 單孔可噴出視窗.......................33
4-2-3 T30μm Φ100μm 30孔可噴出視窗.......................34
4-2-4 T30μm Φ50μm 30孔可噴出視窗........................34
4-3 影像擷取分析........................................35
4-3-1 CCD 影像擷取分析..................................35
4-3-2 高速攝影機影像擷取分析............................36
第五章結論與未來發展.................................37
參考文獻................................................38
附表....................................................43
附圖....................................................46

參考文獻

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指導教授

周復初(Fu-Chu Chou)

審核日期

2005-7-12

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