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姓名	陳柏春(Chung-po Chen)  查詢紙本館藏	畢業系所	能源工程研究所
論文名稱	不同流道設計之透明質子交換膜燃料電池陰極水生成現象探討 (Location of droplet formation and water distribution for the various types of flow field designs of PEMFC)
相關論文	★ 定開孔率下流道設計與疏水流場對質子交換膜燃料電池之性能影響 ★ 熱風循環烘箱熱傳特性研究 ★ 以陽極處理製備奈米結構之氧化鐵光觸媒薄膜應用在光電化學產氫 ★ 規則多孔碳應用在燃料電池陰極觸媒擔體之研究 ★ 鉑錫/多孔碳觸媒應用於燃料電池陰極反應之研究 ★ 腐蝕特性對金屬多孔材質子交換膜燃料電池性能影響之研究 ★ 碎形理論應用在質子交換膜燃料電池中氣體擴散層熱傳導係數之研究 ★ 中溫固態氧化物燃料電池複合系統分析 ★ 中文質子傳輸型固態氧化物燃料電池陽極之研究 ★ 鋯摻雜鋇鈰釔氧化物微結構與電化學特性之研究 ★ 發展應用脈衝雷射沉積製備奈米顆粒堆疊多孔觸媒層與滴塗聚苯並咪唑介面層製作高溫型質子交換膜燃料電池 ★ 直接甲醇燃料電池氣體擴散層之研究 ★ 鋰離子電池陰極材料LiCoO2粉體尺寸與形貌對電池性能的影響 ★ 多孔性碳材應用於質子交換膜燃料電池觸媒層之研究 ★ 多孔材應用於質子交換膜燃料電池散熱之研究 ★ 質子交換膜燃料電池發泡材流道與傳統流道之模擬分析
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摘要(中)	本實驗藉由實驗方法，利用燃料電池測試系統及以Gore 5621為主體之膜電極組來進行單電池實驗測試分析，研究中我們主要針對在固定開孔率條件下探測不同流場設計對電池特性之影響；在實驗設定上分別探討電池內部自發性生成液態水、改變陰極流速對電池性能影響、陰極加濕與否及電池瞬間負載變化之暫態行為。 由實驗結果可以發現，單蛇、指叉及雙指叉型流道因不同流道設計下，其內部生成水區域分布亦有所差異，其中以雙指叉流道設計擁有均勻性分布而電池性能亦較佳。於電池溫度60oC陰陽極加濕溫度90oC設定條件下，改變陰極流速對於此三種流道設計之電池放電過程皆有性能提升現象。於低溫系統下探討陰極加濕對於單蛇型與雙指叉型流道放電效應具有增進效果，但於指叉型流道卻因本流場設計上在氣流導通方面無前兩者有效分布導致電池性能上無明顯差異。最後於電池暫態切換反應下，可以發現雙指叉型流道擁有較佳的電流增益值，相對地於電位轉換所需切換時間亦較遲緩。由此上結論可知，於此三種流道設計上雙指叉型流道擁有較佳的電池性能特性，原因歸為此流場設計可獲得較均勻之反應氣體分布及具有良好的對流質傳模式。
摘要(英)	The purpose of this study is to investigate the effect of flow field design on the performance of PEMFC with fixed open ratio flow fields. Gore 5621 is used in this work. Experiments include the visualization of the droplets formation from cell reaction, effects of cathode flow rate on the water formation and transport, and the transient response of the cell to sudden load change. The results show that the location of droplet formation and water distribution are different for the various types of flow field designs. The double inter-digitated flow field (DIFF) has the most uniform water distribution and best cell performance among the three flow field designs. For cell temperature of 60oC and humidification temperature of 90oC, cell performances of all three flow fields are enhanced by increasing the cathode flow rate. For low cell temperature cases, cathodic humidification increases cell performance for serpentine flow field (SFF) and DIFF, but not for the interdigitated flow field (IFF). For the transient analysis, results show that DIFF has better current gain but longer response time. In summary, the cell performance of DIFF is the best of the three flow field designs due to more uniform reactant gas distribution and the convective mass transfer effect.
關鍵字(中)	★ 質子交換膜 ★ 燃料電池 ★ 流道設計 ★ 暫態行為 ★ 流道可視化	關鍵字(英)	★ PEM ★ Fuel cell ★ Flow field ★ Visualization ★ Transient
論文目次	摘要 I ABSTRACT II 誌謝 III 目錄 IV 圖目錄 VII 表目錄 XII 第一章 緒論 1 1.1 前言 1 1.2 質子交換膜燃料電池主要元件分析 2 1.2.1 質子交換膜 2 1.2.2 觸媒層 3 1.2.3 氣體擴散層 4 1.2.4 流道板(雙極板) 5 1.3 質子交換膜燃料電池發電原理與極化現象 6 1.4 研究動機與方向 8 第二章 文獻回顧 10 2.1 流場設計 10 2.2 水傳輸現象 12 2.2.1 使用CCD攝影機流場觀測部份 15 2.2.2 使用NEUTRON顯像技術流場觀測部份 20 2.2.3 其它流場相關文獻探討 23 第三章 實驗設備與方法 26 3.1 流道板加工 26 3.2 實驗架設方式 27 3.2.1 電池組裝 27 3.2.2 燃料電池測試平台 28 3.3 實驗流程 29 3.3.1 活化程序 29 3.3.2 實驗設定 30 第四章 結果與討論 31 4.1 電池自發性生成水現象 31 4.2 陰極氣體流量對電池性能影響 38 4.3 陰極加濕與未加濕效果影響 43 4.4 電池暫態切換時域響應 44 第五章 結論與未來方向建議 49 5.1 結論 49 5.2 未來研究方向建議 50 參考文獻 52 附錄一 59
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指導教授	曾重仁(Chung-jen Tseng)	審核日期	2008-7-22
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