生質廢棄物再利用生成高附加價值材料及能源回收技術之研發(III)-有機污泥轉換能源及其衍生殘餘物製備新型抗菌輕質化材料之應用評估(III);Organic Sludge-To-Energy and Derived Residues Converted to Innovative Anti-Fugal Lightweight Building Materials

NCUIR > Engineering College > Graduate Institute of Environmental Engineering > Research Project > Item 987654321/82438

Please use this identifier to cite or link to this item: http://ir.lib.ncu.edu.tw/handle/987654321/82438

Title:	生質廢棄物再利用生成高附加價值材料及能源回收技術之研發(III)-有機污泥轉換能源及其衍生殘餘物製備新型抗菌輕質化材料之應用評估(III);Organic Sludge-To-Energy and Derived Residues Converted to Innovative Anti-Fugal Lightweight Building Materials
Authors:	江康鈺;林居慶
Contributors:	國立中央大學環境工程研究所
Keywords:	有機污泥;氣化;高壓蒸氣技術;輕質化材料;organic sludge;gasification;autoclaving;lightweight material.
Date:	2020-01-13
Issue Date:	2020-01-13 14:53:32 (UTC+8)
Publisher:	科技部
Abstract:	有鑑於建立整合型有機污泥資源/能源再利用研究之重要性，本研究主要包括(1)建立多元化有機污泥共同氣化處理之應用與評估，評估共同氣化轉換能源及提升產能效率之應用性；(2)開發污泥殘餘物再利用為新型綠色材料之新穎技術，及其新型材料之功能特性評估；(3)建立新穎技術與新型材料之環境安全與減碳效益(碳足跡)之應用評估等重要內容。其中多元化有機污泥共同氣化處理之應用與評估，主要針對現階段產生數量較為龐大之漿紙污泥、染整污泥及工業區廢水污泥等為研究對象，探討前述有機污泥共同氣化轉換能源之可行性，並期進一步建立提升產能效率之方法、操作參數與質能平衡分析等重要資訊。此外，本研究嘗試規劃未來可行之整合型有機污泥能源轉換之應用技術，其中考量規劃重點除共同氣化轉換能源效益外，亦包括能源轉後殘餘物(residue)製備為新型抗菌輕質化材料、能源轉換過程二氧化碳減量效益，以及應用過程之環境安全與生態毒性等評估項目。 ;Recognizing the importance of integrated organic sludge converted to resources and energy, the objectives of this study were to: (1) establish feasibility assessment of co-gasified of multiple organic sludge and enhancement of energy yield; (2) develop the innovative lightweight materials manufactured from residues and assessment of the environmental safety and carbon emission reduction. In this project, we focus on the sludges produced from wastewater treatment plant of paper-mill, dyeing and finishing and industrial park which are generated a lot of amounts every year in Taiwan. This project investigates the information of enhanced energy conversion efficiency, optimum operation parameters, and mass and energy balance in co-gasification of various organic sludge. Meanwhile, residues produced from organic sludge gasification were also considered as raw materials for manufacturing the innovative anti-fungal lightweight materials. The assessment of carbon dioxide reduction, environmental safety and ecological toxicity in anti-fungal lightweight materials manufacturing were also discussed in this project.
Relation:	財團法人國家實驗研究院科技政策研究與資訊中心
Appears in Collections:	[Graduate Institute of Environmental Engineering ] Research Project

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