本研究主要探討使用真空樹脂轉注成型工法，將光纖光柵感測器埋設於玻璃纖維積層板中，並藉由拉伸試驗獲得光纖光柵感測器頻譜飄移量對應變的關係，後續將其應用在FRP硬化過程中的收縮應變的量測。
本研究使用真空樹脂轉注成形工法製作埋設光纖光柵感測器試片，利用光學頻譜分析儀紀錄實驗過程中光纖光柵感測器頻譜波長之變化，本研究發現光纖光柵感測器在樹脂放熱過中波長會往長波長飄移，在樹脂降溫冷卻時波長會往短波長飄移。
將埋設光纖光柵感測器之試片進行拉伸試驗，並搭配應變規量測其拉伸應變，本研究得到光纖光柵感測器埋設於玻璃纖維時其波長及應變之計算公式，並利用此計算公式進一步計算出樹脂造成的收縮應變。

This research mainly discusses the use of vacuum resin transfer molding to embed the fiber grating sensor in the glass fiber laminate. Through the tensile test to get the relationship between the optical fiber grating sensor spectral drift and the strain. And apply it to the measurement of shrinkage strain during FRP hardening.
In this study, we used vacuum resin transfer molding method to make embedded fiber grating sensor specimen, and use optical spectrum analyzer to record the change of spectrum wavelength of fiber grating sensor during the experiment. We found that the fiber grating sensor will shift to long wave lengths when the resin is heat release, and the wavelengths will shift to short wavelengths when the resin cools down.
We use tensile test on glass fiber specimen with embed fiber grating sensors, and measure the tensile strain with strain gauge. We get the calculation formula of the wave length and strain of the fiber grating sensor when it is embedded in the glass fiber. We use this calculation formula to further calculate the shrinkage strain caused by the resin.

摘 要 I
ABSTRACT II
誌 謝 III
目 錄 IV
圖 目 錄 VI
表 目 錄 IX
符 號 表 X
第一章 緒論 1
1.1研究動機 1
1.2文獻回顧 1
1.3論文架構 4
第二章 光纖光柵感測器 5
2.1 光纖之結構 5
2.2 光纖光柵感測器種類 5
2.2.1 以感測元件分類光纖光柵感測器 5
2.2.2 以解調方式分類光纖光柵感測器 6
2.3 光纖光柵感測器 6
2.4 光纖熔接技術 9
2.5 光纖光柵感測器的應用 13
2.6光纖尺寸設計 16
第三章 實驗方法 18
3.1光纖光柵感測器結合VARTM之製程 18
3.1.1試片製作 20
3.1.2試片尺寸設計 29
3.2光纖光柵感測器直接浸泡樹脂 32
3.3 拉伸試驗 36
第四章 實驗結果 40
4.1埋設光纖光柵感測器實驗結果 40
4.2光纖光柵感測器浸泡樹脂實驗結果 49
4.2.1光纖光柵感測器浸泡150克樹脂實驗結果 49
4.2.2光纖光柵感測器浸泡300克樹脂實驗結果 50
4.3拉伸試驗結果 52
4.3.1光纖光柵感測器黏貼於試片表面之拉伸試驗結果 52
4.3.2光纖光柵感測器埋設於試片之拉伸試驗結果 56
4.4光纖光柵感測器埋設於試片之收縮應變 60
第五章 研究結論與未來展望 62
5.1 結論 62
5.2未來展望 63
參考文獻 64

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