DSpace collection: 研究計畫 https://ir.lib.ncu.edu.tw/handle/987654321/24100 The collection's search engine Search the Channel s https://ir.lib.ncu.edu.tw/simple-search 鹼液吸收CO2製備碳酸鹽的生命週期評估和技術經濟分析;Life-Cycle Assessment and Techno-Economic Analysis of Co2 Capture by Alkaline Solution for Carbonate Production https://ir.lib.ncu.edu.tw/handle/987654321/99100 title: 鹼液吸收CO2製備碳酸鹽的生命週期評估和技術經濟分析;Life-Cycle Assessment and Techno-Economic Analysis of Co2 Capture by Alkaline Solution for Carbonate Production abstract: 使用鹼性溶液吸收加速碳酸化係具有應用潛力之二氧化碳(CO2)捕獲與再利用技術。本研究優化鹼液吸收碳酸化程序於碳捕集再利用,並使用生命週期評估和技術經濟分析進行各項情境的技術驗證。預期的目標有評估鹼液吸收碳酸化程序關鍵操作參數的碳捕獲績效,從CO2捕集到礦化的系統邊界界定與成本敏感度建模,以量化環境衝擊與經濟成本。 <br> 硫自營性脫硝技術開發-模型廠驗證與智慧優化( I );The Development of Sulfur-Based Autotrophic Denitrification Technology – a Pilot Study and Intelligent Optimization( I ) https://ir.lib.ncu.edu.tw/handle/987654321/99098 title: 硫自營性脫硝技術開發-模型廠驗證與智慧優化( I );The Development of Sulfur-Based Autotrophic Denitrification Technology – a Pilot Study and Intelligent Optimization( I ) abstract: 本計畫預期將對社會、經濟及產業發展帶來多重正面影響。首先,在社會面向,有助於強化水資源循環再利用與污染控制,減少硝酸鹽氮對水體與人體健康的潛在風險,提升民眾生活品質與環境安全。經濟層面,本技術可降低工業廢水處理成本,提升水回收率,對缺水地區尤其具備節水效益與經濟誘因,協助企業符合放流水法規之餘兼顧營運效率。於產業發展方面,本研究結合智慧控制與低碳處理技術,具高度創新與應用潛力,可加速國內水處理產業升級,強化我國在環境工程與綠色科技領域之國際競爭力,並促進產學合作與高階技術人才培育。 <br> 還原態硫生物脫硝之膨脹床反應系統研究(II);A Study of Reduced Sulfur-Based Denitrification Process in Expanded-Bed Bioreactor (II) https://ir.lib.ncu.edu.tw/handle/987654321/97039 title: 還原態硫生物脫硝之膨脹床反應系統研究(II);A Study of Reduced Sulfur-Based Denitrification Process in Expanded-Bed Bioreactor (II) abstract: 本研究之成果將開創一套硫自營脫硝膨脹床模組化系統,預期達成降低操作成本、人力需求、環境永續之目標,並且克服傳統異營性脫硝之缺點,如需添加額外碳源、污泥產量高、CO2溫室氣體排放等問題。此外,此系統亦能為低C/N比之廢水、高NO3−廢水及再生水廠之RO濃排水提供一良好的處理方案,從而使RO膜組之回收率不再因濃排水問題而受限。對於學術方面,將掌握元素硫自營脫硝之反應模式與最佳系統操作參數,以及硫生物擔體之製作方針與材料特性。此項技術之開發不僅能於國際上提昇技術競爭力,亦有助於應用於國內外相關水處理產業。 <br> 開發電漿結合觸媒之混合系統用於甲烷乾式重整產生液態產物之效率探討;Development of a Hybrid System Combining Plasma and Catalysis for Dry Reforming of Methane to Generate Liquid Products( I ) https://ir.lib.ncu.edu.tw/handle/987654321/97037 title: 開發電漿結合觸媒之混合系統用於甲烷乾式重整產生液態產物之效率探討;Development of a Hybrid System Combining Plasma and Catalysis for Dry Reforming of Methane to Generate Liquid Products( I ) abstract: This technology will have an impact on energy transition, science advancement; economic and industrial impact as well as social impact. (1) Environmental sustainability: This hybrid system fosters environmental sustainability (mitigating GHGs via CH4 and CO2 conversion, supporting a circular carbon economy, and aligning with Taiwan's net-zero 2050 goal). (2) Energy transition: Producing alternative fuels and advancing low-carbon technologies), (3) Scientific advancements: Bridging disciplines, establishing research foundations, and developing novel methodologies. (4) Economic and industrial impact: Producing valuable chemicals, offering cost-competitive alternatives, and enabling industrial integration. (5) Societal impact: contributing to climate goals, highlighting engineering innovation, and providing training. <br>