附著力及平均側向附著力,均大於O2 plasma 改質之平均正向附著 力與平均側向附著力,因為機械粗化表面粗糙度較大,鍍膜與基 材之附著較密合。而單看同一表面改質製程,試片加熱的溫度越 高,鍍膜附著力也會隨之略微提升。
6. 依據其綜合比較的結果,機械粗化表面改質在抗腐蝕性與機械性 質方面均優於O2 plasma 表面改質,但在導電性方面較不理想,因 此若能提升薄膜之導電性問題,則機械粗化表面改質將較適合用 於質子交換膜燃料電池之雙極板的製備流程。
7. 本研究主要在提供新的質子交換膜燃料電池之雙極板製備方法,
未來還可利用不同的機械粗化製程來進行試驗。另外因質子交換 膜燃料電池主要的工作溫度範圍在室溫至100℃之間,因此基材的 材質除了可以使用 PMMA(硬質料)之外,還可以選用軟性基材設 計不同規格及用途之雙極板。
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