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研究生: 李佳育
Lee, Chia-Yu
論文名稱: 產業/社區之能源流分析技術與生態化鏈結機制研究
Energy Flow Analysis among Industries and Communities and Study the Mechanism of Forming Energy-based Eco-industrial Networks
指導教授: 林達昌
Lin, Ta-Chang
學位類別: 碩士
Master
系所名稱: 工學院 - 環境工程學系
Department of Environmental Engineering
論文出版年: 2012
畢業學年度: 100
語文別: 英文
論文頁數: 65
中文關鍵詞: 生態化鏈結鋼鐵業能源
外文關鍵詞: eco-industrial networks, iron and steel industry, energy
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    • 本研究擬探討如何有效整合工業區之能源流,且推動區內之能源鏈結機制,建構能源循環利用產業網路,進而有效提升能源使用率與降低廢棄物產量,為永續產業提供參考方案。本研究顯示鋼鐵業在台灣地區所造成之二氧化碳排放量、能源之使用量均占大宗,因此如何提高鋼鐵業之能源使用效率乃是當前重要課題。另外,對工業蒸汽鏈結機制之研究,結果顯示,藉由該鏈結系統所能減少之能源消耗及二氧化碳排放量均有一定規模,在節能及減碳方面皆有不錯之效果,甚至能對廠方提供額外之利潤,若能推廣至其他工業區及產業,相信能進一步提升能源使用效率,減少二氧化碳排放量,以達成建構生態化工業區之目標。

    This research investigates how to integrate the energy flow of industrial park, the energy linkage mechanism, establish the energy re-circulation networks and how to elevate the efficiency of energy usage. They are important issues for the establishment of sustainable industries. The iron and steel industry consumes large amounts of energy and the CO2 emission is also tremendous in Taiwan. Improving the energy efficiency of iron and steel industry is an important work at present. The eco-industrial networks studied in this study successfully reduce the energy consumptions and CO2 emissions. In addition, it also brings some additional incomes to the case mill. It is believed that the goal of improving energy efficiency and reduction of CO2 emission will be accomplished while this system being applied to other industrial parks.

    摘要 I Abstract II 誌謝 IV Table of contents V List of tables VII List of figures VIII Chapter 1 Introduction 1 Chapter 2 Literature review 4 2.1. Energy consumption and pollution emission in Taiwan 4 2.1.1. Energy use of industrial sector in Taiwan 4 2.1.2. Emissions of CO2 in Taiwan 6 2.2. Iron and steel industry in Taiwan 11 2.2.1. The scale of steel industry in Taiwan 11 2.2.2. History of steel industry in Taiwan 13 2.3. Processing routes and equipment 19 2.3.1. Steel making process 19 2.3.2. Cogeneration system 23 2.3.3. Energy saving equipment and technology in steel mill A 24 2.4. Related research 26 2.4.1. Variables affecting SEC in iron and steel industry 26 2.4.2. Other examples in the world 27 2.4.3. Potential in Taiwan 28 2.4.4. Technology about energy saving and efficiency 29 2.5. Eco-industrial park 31 2.5.1. What is eco-industrial park 31 2.5.2. Examples of eco-industrial park 33 2.6. Waste management plants 35 Chapter 3 Material and methods 36 3.1. Information collection 36 3.2. Data calculation 37 3.3. Evaluation 37 Chapter 4 Result and discussion 39 4.1. Analysis of energy consumption 39 4.1.1. energy consumption of case steel mill A 39 4.1.2. Energy consumption of case petro-chemical mill B 43 4.2. Cost from energy consumption 46 4.3. Emission of CO2 48 4.3.1. CO2 emission of steel mill A 48 4.3.1. CO2 emission of case petro-chemical mill B 49 4.4. Steam connection system of the industrial park 51 4.4.1 Present steam connection 51 4.4.2 Possible steam connection with waste management plant 54 4.5. Energy saving in case steel mill A 57 4.5.1 Reduction of CO2 and profit of steam network 57 Chapter 5 Conclusion and suggestion 59 5.1. Conclusions 59 5.2. Suggestions 61 Reference 62

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