本論文之研究成果顯示,改良後之CID 3.0 具有比 CID 2.0 更高的阻抗量測性 能以及更好的量測穩定性,而改良分壓公式亦有效地解決虛部阻抗造成的計算誤 差,未來可針對實際應用層面進行改良與研發,如:
1. 架設方法:CID 3.0 之最終目的是用於離岸風機等工業環境的現地檢測,然而 一般實驗室所採用的架設方法為水溶液浸泡,此方法並不適用於現地檢測,因 此未來要如何將CID 3.0 實際架設於檢測現場仍有待考量與克服。
2. 獨立供電:現階段之 CID 3.0 仍是透過 USB 介面由電腦進行有線的電源供應,
若要將CID 3.0 實際架設於檢測現場,則需具備依靠電池獨立供電的能力,且 其運作時的電量消耗應盡量節省,方能維持其進行長時間連續監測。
3. 無線傳輸:現階段之 CID 3.0 仍是透過 USB 介面與電腦進行有線的數據傳輸,
由於離岸風機屬於海上無人結構物,若要將CID 3.0 實際架設於檢測現場,則 需具備無線傳輸數據資料的功能,此功能不需將數據遠端傳輸至陸地,僅需將 數據無線傳輸至離岸風機的監控系統,便可透過風機的電纜等設備傳送回陸 地。
4. 內部儲存:現階段之 CID 3.0 不具備內部儲存功能,因此每一次量測都要進行 數據傳輸,若要將CID 3.0 實際架設於檢測現場,考慮到無線傳輸往往需要較 多的電量消耗,可能導致電池供電的使用時間縮短,若CID 3.0 具有內部儲存 空間,則可待量測數據收集達一定數量再進行回傳,以達到省電的效果。
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