本次實驗成功運用氣相層析儀分離技術結合微哨偵測器和自動 進樣裝置進行氫氣即時監測,有效地分離出混合氣體中的氫氣,數據 分析後可得到氫氣總生成量並進行其生成速率與防鏽程度的探討,實 驗經由 30 ℃、40 ℃和 50 ℃鏽化反應可得 50 ℃下飽和沒食子酸洗下 氫氣生成速率最快、防銹效果較優且耗時最短,此研究方法有利於爾 後進行其他配方的測量和防鏽探討!以提供一個既簡單又快速的分 析技術來尋找較佳的酸洗配方。
此新型自動化氣體偵測器使用上方便簡易,待測物不需要複雜的 前處理過程,而微哨偵測器也具備近乎無耗損、無殘留、環保可多次 重複使用的優點,樣品更不僅僅是這次實驗所測量的氫氣氣體,只要 是待測氣體具有相對應的分離管柱即可進行複雜樣品的分離與測 量!
未來發展方面,本實驗室也正著手開發微型化攜帶式微哨偵測器,
如圖 5-1 所示,希望能成為有效且簡易的氣體感測器。
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圖 5-1 攜帶型微行氣哨偵測器實際圖
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研討會發表
參與會議:第二十三屆台灣化學感測器科技研討會 會議時間:中華民國 107 年 6 月 2 日
主辦單位:國立臺灣師範大學理學院 科技與工程學院 生命科學 專業學院 光電科技研究所/化學系、社團法人台灣化學感測器科 技協會、社團法人中華民國微系統暨奈米科技協會
題目:利用氣相層析/微哨偵測系統同步監測鐵在酸洗防鏽處理
過程中產生的氫氣濃度變化並探討其反應速率對防鏽程度的影響
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