本研究蒐集國內外有關於異質材料接合的文獻資料，並參考國內業界施工的技術，設計出混合式接頭的異質接合試片，且透過拉伸與彎曲實驗，確認FRP-金屬異質接合的機械特性。
本研究採用多款結構膠設計出混合接頭，並探討不同結構膠對金屬的界面強度，從中選擇較合適的搭配方式，使結構膠可以發揮最大的功用，進而獲得較佳的FRP-金屬接合強度。
研究結果指出於FRP接合面使用高破壞變形之聚酯結構膠，而金屬接合面使用高強度之環氧結構膠，可以使結構膠與接合面緊密接合，此時高破壞變形之結構膠可以完全發揮其機械特性。
因此，異質接合若選擇適當的接頭型式與黏合方式，便能使FRP-金屬具有較佳的接合強度。

In this study, domestic and foreign research on heterogeneous materials and manufacture methods were collected, and refer the technologies implemented by domestic industries, in order to design heterogeneous bond test specimens with a hybrid joint. Next, tensile and bending test were conducted to confirm the mechanical properties of FRP–metal heterogeneous material bonding.
Various types of structural adhesives were used to design hybrid joints. Subsequently, the effects of the adhesives on the interfacial strength of the metals were investigated to confirm the appropriate matching method, which enabled the structural adhesives to prove maximum capability and obtain higher FRP–metal bond strength.
The study results showed that when polyester structural adhesives with high elongation at break are applied at the FRP bond surface and high strength epoxy structural adhesives are applied at the metal bond surface, the adhesives bond tightly with the surfaces. In particular, the mechanical properties of the structural adhesives with high elongation at break are fully exhibited.
Therefore, for heterogeneous material bonding, the selection of the appropriate joint type and adhesive method enables FRP–metal to demonstrate higher bond strength.

致謝 I
摘要 II
Abstract III
目錄 IV
圖目錄 VI
表目錄 VIII
第一章 緒論 1
1.1 研究動機 1
1.2 文獻回顧 3
1.3 論文架構 7
第二章 研究方法 8
2.1 接合型式 8
2.2 膠合法 9
2.3 膠體破壞模式 11
2.4 表面處理工法 12
第三章 實驗方法 13
3.1 材料與工法 14
3.2 試片設計 18
3.3 試片命名 22
3.4 試驗測定條件 24
第四章 結果與討論 26
4.1 彎曲系列結果 26
4.1.1 B-OL試片 26
4.1.2 B-PA試片 27
4.1.3 B-AV試片 28
4.1.4 B-M試片 29
4.1.5 彎曲系列討論 29
4.2 剪切系列結果 31
4.2.1 SA-PA試片 31
4.2.2 SA-M試片 32
4.2.3 SA-AV試片 34
4.2.4 Adhesive系列討論 35
4.2.5 SH-M試片 37
4.2.6 SH-AV試片 39
4.2.7 Hybrid系列討論 40
4.3 SH-AV改良式試片 41
4.3.1 試片設計 41
4.3.2 試驗結果 42
第五章 結論 45
5.1 論文結論 45
5.2 後續研究建議 46
參考文獻 47

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