廢棄物投入產出評估台灣推動二次銅循環再利用之研究

Meng-I Liao; 廖孟儀

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/54876

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	馬鴻文(Hwong-Wen Ma)
dc.contributor.author	Meng-I Liao	en
dc.contributor.author	廖孟儀	zh_TW
dc.date.accessioned	2021-06-16T03:40:28Z	-
dc.date.available	2017-03-16
dc.date.copyright	2015-03-16
dc.date.issued	2015
dc.date.submitted	2015-02-13
dc.identifier.citation	Egilmez, G., Kucukvar, M., Tatari, O., 2013. Sustainability assessment of U.S. manufacturing sectors: an economic input output-based frontier approach. J Clean Prod 53, 91-102. Hendrickson, C., Horvath, A., Joshi, S. and Lave, L., 1998. Peer Reviewed: Economic Input–Output Models for Environmental Life-Cycle Assessment. Environmental Science & Technology, 32(7): 184A-191A. Hendrickson, C.T., Lave, L.B. and Matthews, H.S., 2006. Environmental life cycle assessment of goods and services: an input-output approach. Resources for the Future. Huang, Y.A., Weber, C.L. and Matthews, H.S., 2009. Categorization of Scope 3 Emissions for Streamlined Enterprise Carbon Footprinting. Environmental Science & Technology, 43(22): 8509-8515. International Copper Study Group., 2014. The world copper factbook 2014. International institute for sustainable development., 2010. Sustainable Development and the Global Copper Supply Chain: International research team report. Jiang, Q., Li, T., Liu, Z., Zhang, H., Ren, K., 2014. Life Cycle Assessment of an Engine with Input-Output Based Hybrid Analysis Method. J Clean Prod 78, 131-138. Joshi, S., 1999. Product environmental life-cycle assessment using input-output techniques. J Ind Ecol 3, 95–120. Kagawa, S., Nakamura, S., Inamura, H., Yamada, M., 2007. Measuring spatial repercussion effects of regional waste management. Resources, Conservation and Recycling 51, 141-174. Kondo, Y., Nakamura, S., 2004. Evaluating alternative life-cycle strategies for electrical appliances by the waste input-output model. Int J Life Cycle Ass 9, 236-246. Kucukvar, M., Egilmez, G., Tatari, O., 2014. Sustainability assessment of U.S. final consumption and investments: triple-bottom-line input–output analysis. J Clean Prod 81, 234-243. Lave, L.B., Cobas-Flores, E., Hendrickson, C.T. and McMichael, F.C., 1995. Using input-output analysis to estimate economy-wide discharges. Environmental Science & Technology, 29(9): 420A-426A. Lenzen, M., 2001. A Generalized Input–Output Multiplier Calculus for Australia. Economic Systems Research 13, 65-92. Leontief, W., 1970. Environmental repercussions and the economic structure: An input output approach. Rev Econ Stat 52, 262–271. Li, S., 2012. The Research on Quantitative Evaluation of Circular Economy Based on Waste Input-Output Analysis. Procedia Environmental Sciences 12, Part A, 65-71. Liao, M. I., Chen, P. C., Ma, H. W., Nakamura, S., 2015. Identification of the driving force of waste generation using a high-resolution wasteinput-output table. Acceptance,J Clean Prod. Lin, C., 2009. Hybrid input–output analysis of wastewater treatment and environmental impacts: A case study for the Tokyo Metropolis. Ecological Economics 68 (7):2096-2105. Matsubae, K., Nakajima, K., Nakamura, S., Nagasaka, T., 2011. Impact of the Recovery of Secondary Ferrous Materials from Alternative ELV Treatment Methods on CO2 Emission: A Waste Input Output Analysis. IsijInt 51, 151-157. Nakajima, K., Nakamura, S., 2006. Material flow analysis of metals based on the waste input-output model (WIO-MFA model): Application to material cycle of iron and steel. J Jpn I Met 70, 618-621. Nakajima, K., Nansai, K., Matsubae, K., Kondo, Y., Kagawa, S., Inaba, R., Nakamura, S., Nagasaka, T., 2011. Identifying the Substance Flow of Metals Embedded in Japanese International Trade by Use of Waste Input-Output Material Flow Analysis (WIO-MFA) Model. IsijInt 51, 1934-1939. Nakajima, K., Ohno, H., Kondo, Y., Matsubae, K., Takeda, O., Miki, T., Nakamura, S., Nagasaka, T., 2013. Simultaneous Material Flow Analysis of Nickel, Chromium, and Molybdenum Used in Alloy Steel by Means of Input–Output Analysis. Environ. Sci. Technol.47, 4653-4660. Nakamura, S., Kondo, Y., 2002a.Input-Output Analysis of Waste Management. J Ind Ecol 6, 39-63. Nakamura, S., Kondo, Y., 2002b.Recycling, landfill consumption, and CO2 emission: analysis by waste input–output model. J Mater Cycles Waste Manag 4, 2-11. Nakamura, S., Kondo, Y., 2006. A waste input-output life-cycle cost analysis of the recycling of end-of-life electrical home appliances. Ecological Economics 57, 494-506. Nakamura, S., Kondo, Y., 2009.Waste input-output analysis: Concepts and Application to Industrial Ecology. Springer Netherlands. Nakamura, S., Kondo, Y., Matsubae, K., Nakajima, K., Tasaki, T., Nagasaka, T., 2012. Quality and Dilution Losses in the Recycling of Ferrous Materials from End-of-Life Passenger Cars: Input-Output Analysis under Explicit Consideration of Scrap Quality. Environ. Sci. Technol. 46, 9266-9273. Nakamura, S., Nakajima, K., 2005. Waste input-output material flow analysis of metals in the Japanese economy. Mater Trans 46, 2550-2553. Nakamura, S., Nakajima, K., 2006. Waste input-output material flow analysis and its application to quantity metals. J Jpn I Met 70, 505-510. Nakamura, S., Nakajima, K., Kondo, Y., Nagasaka, T., 2007. The waste input-output approach to materials flow analysis - Concepts and application to base metals. J Ind Ecol 11, 50-63. Nakamura, S., Nakajima, K., Yoshizawa, Y., Matsubae-Yokoyama, K., Nagasaka, T., 2009. Analyzing Polyvinyl Chloride in Japan With the Waste Input-Output Material Flow Analysis Model. J Ind Ecol 13, 706-717. Oguchi, Masahiro, Shinsuke Murakami, Hirofumi Sakanakura, Akiko Kida, and Takashi Kameya. 2011. A preliminary categorization of end-of-life electrical and electronic equipment as secondary metal resources. Waste Management 31 (9–10):2150-2160. Seppala, J., Maenpaa, I., Koskela, S., Mattila, T., Nissinen, A., Katajajuuri, J.-M., Harma, T., Korhonen, M.-R., Saarinen, M., Virtanen, Y., 2011. An assessment of greenhouse gas emissions and material flows caused by the Finnish economy using the ENVIMAT model. J Clean Prod 19, 1833-1841. Takase, K., Kondo, Y., Washizu, A., 2005. An Analysis of Sustainable Consumption by the Waste Input-Output Model. J IndEcol 9, 201-219. Xu, Y., Zhang, T., 2009. A new approach to modeling waste in physical input–output analysis. Ecological Economics 68, 2475-2478. Yokoyama, K., Kagawa S., 2007. A simple dynamic waste input output analysis: Theory and its application to Japanese Economy. 16th International conference on input-output techniques. Istanbul, Turkey. Yokoyama, K., Onda, T., Nagasaka, T., 2006.Environmental assessment of “landfill mining” by using dynamic extension of waste input-output analysis. J Life Cycle Ass Japan. 2, 73-79 王俊傑, 2008. 台灣產業環境衝擊關聯分析與永續消費型態探討, 臺灣大學, 台北市, 147 pp. 行政院主計處, 2006. 產業關聯編製報告李佳禾, 2013. 投入產出方法分析電子電機產業含鉛廢棄物質直接及間接流布, 臺灣大學, 台北市, 87 pp. 李高朝, 2005. 實用產業關聯分析精義, 行政院經濟建設委員會李賦屏、周永生、黃斌與尹杰. 2011. 銅論, 科學出版社, 北京林知以, 2012.銅元素都市代謝－以台北市為例, 臺灣大學, 台北市, 112 pp. 姜金龍、徐金城、吳玉萍, 2006. 再生銅的生命週期評價,蘭州理工大學學報, 第32卷, 第3期, pp.4-6 陳秋龍, 2001. 鋼鐵業之生命週期盤查分析－投入產出生命週期評估模型之應用, 國立台北大學, 台北, 79 pp. 黃盈庭, 2000. 投入產出分析應用於生命週期評估-台灣地區水泥範例研究, 成功大學, 台南市, 80 pp. 蔡敏行、張祖恩、鄭智和與蔡尚林, 2013. 建構國內二次銅資源循環體系之探討, 礦冶期刊, 第57卷, 第1期, pp.22-37 環保署, 2008. 事業廢棄物查核與輔導及清理管理技術整合應用專案工作計畫,事業廢棄物行業製程稽查參考手冊-銅鑄造業環保署, 2008. 辦理特定有害事業廢棄物戴奧辛含量與流向調查專案工作計畫環保署, 2013. 污泥處理現況檢討及因應策略薛乃綺, 2010. 非鐵金屬特輯-銅金屬篇, 2010. 財團法人金屬工業研究發展中心詹尚文, 2009. 國內工業廢棄物處理成本效益分析探討-以印刷電路板業含銅污泥為例, 國立台北大學, 台北, 77 pp. 胡紹華, 2012.銅資源、冶煉、再生現狀與未來趨勢- 國內銅資源再生體系之建構, http://serc.ncku.edu.tw/ATDP/plan1_services_04_01.html 莊宜剛、姚慧怡, 2012. 台灣發展銅冶煉的未來契機, 永續產業發展季刊, 第59期, pp.72-79
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/54876	-
dc.description.abstract	台灣隸屬銅資源高消費的國家之一，在國內缺乏生產高品位電解銅技術能力之情況下，每年必須向國外高價購買含銅品位較高的電解銅，以滿足國內企業界之需求。國內產官學界正著手進行建構二次銅資源循環體系之計畫，希望建構二次銅資源循環體系以降低對進口電解銅之依賴。為探討二次銅資源循環與經濟活動相互間之關係，本研究建構二次銅廢棄物投入產出模型，此模型包含產業關聯矩陣、廢棄物處理部門矩陣、各產業廢棄物排放矩陣、廢棄物排放與廢棄物處理關聯矩陣等四大類矩陣，將這些矩陣整合為一個正方形矩陣，計算產業關聯分析矩陣，透過此模型可以清楚掌握各產業部門(動脈產業)與廢棄物處理部門(靜脈產業)之經濟活動與廢棄物流動的關係。研究進一步結合價格向量，建構二次銅廢棄物投入產出價格模型，評估各產業部門在二次銅資源循環體系建立後成本變動之情形。二次銅廢棄物投入產出價格模型用以評估滿足最終需求之直接成本與間接成本之總和，對於產業關聯程度較高之資源與物質，此模型可以反映相關產業價格變動後所帶動之成本變化。本研究初步擬定三種情境方案包括：維持現況，未正式設置電解精煉廠與濕式浸漬廠(情境1)、設置40000噸電解精煉廠與3000噸濕式浸漬廠(情境2)與設置60000噸電解精煉廠與6000噸濕式浸漬廠(情境3)等，分析各產業部門於此三種情境下之單位生產成本。情境分析之結果顯示，在增設電解精煉部門與濕式浸漬部門之情況下，產業關聯表中52部門之單位生產成本變動幅度大多小於1%，唯污染整治部門之單位生產成本出現降幅超過2%之現象，由於增設電解精煉部門與濕式浸漬部門意味著產業結構之調整，再利用部門之擴增代表產業結構朝靜脈產業擴增的方向調整時，可以促進資源循環，也可使傳統污染整治部門之成本下降。本研究以2010年電解銅進口之平均價格23.48萬元/公噸為基準，比較高品位電解銅之國內單位生產成本與外購之單位成本，結果顯示，國內自行生產高品位電解銅之成本較國外進口電解銅之成本為高。本研究為廢棄物管理者提供一個新的思維，協助廢棄物管理者從整體產業結構調整之角度，分析二次銅資源循環再利用之可行性，由於目前環保署事業廢棄物申報與管理資訊系統受限於權責範圍，較難呈現廢棄物成為再利用資源與產品之實際流向與流量。若要確實掌握各類廢棄物之去向，建議環保主關機關所建立之廢棄物處理類別應與再利用產品之製程連結，如此較能清晰判定廢棄物轉化為再利用產品之實際流向，藉以提升廢棄物再利用資料的數據品質，亦可提高二次銅廢棄物投入產出價格模型推估之精確度。	zh_TW
dc.description.abstract	Taiwan is characterized by high consumption of copper metal, which requires the import of expensive copper annually to meet the needs of the domestic industries. The industries, government agencies and academia are embarking to establish the secondary copper resource recycling system to reduce the rely of import copper resources. The objective of this study is to construct a secondary copper waste input-output model and further to establish a secondary copper waste input-output price model to estimate the unit process cost of individual industries. The waste input-output (WIO) analysis provides an extended function to consider the entire life cycle of a product. This article illuminates the diagnostic features of the secondary copper waste input-output model and provides useful insights for linking the WIO and supply chain analysis approaching sustainable consumption and production.	en
dc.description.provenance	Made available in DSpace on 2021-06-16T03:40:28Z (GMT). No. of bitstreams: 1 ntu-104-D93541007-1.pdf: 1499583 bytes, checksum: 6cbf42361b1a8698fec03a7e21fa605e (MD5) Previous issue date: 2015	en
dc.description.tableofcontents	第一章緒論 1 1.1 研究背景 1 1.2研究目的和意義 3 1.3主要研究內容與研究方法 3 第二章文獻回顧 5 2.1銅資源產業現況 5 2.2二次銅定義與資源現況 13 2.3二次銅資源再利用技術 20 2.4投入產出基本原理 26 2.5投入產出生命週期評估 28 2.6廢棄物投入產出 30 第三章研究方法 36 3.1投入產出模型矩陣 36 3.2投入產出生命週期評估模型 38 3.3廢棄物投入產出模型矩陣 40 3.4廢棄物投入產出價格模型矩陣 42 第四章二次銅廢棄物投入產出分析 48 4.1二次銅廢棄物投入產出模型矩陣表之建置 48 4.2產業部門之中間投入產出 50 4.3二次銅廢棄物處理部門之建立 51 4.4產業部門之含銅廢棄物產生量與再利用量 58 4.5廢棄物處理部門之含銅廢棄物產生量與再利用量 70 4.6最終需求部門之相關廢棄物產生量 74 4.7廢棄物處理分配係數矩陣 76 4.8二次銅廢棄物投入產出關聯分析計算之係數矩陣推估 77 4.9二次銅廢棄物投入產出價格模型計算 92 第五章二次銅資源循環體系情境分析 96 5.1二次銅資源循環體系情境一 97 5.2二次銅資源循環體系情境二 103 5.3二次銅資源循環體系情境三 112 第六章結論與建議 133 6.1結論 133 6.2建議 135 參考文獻 136
dc.language.iso	zh-TW
dc.title	廢棄物投入產出評估台灣推動二次銅循環再利用之研究	zh_TW
dc.title	Study on secondary copper resource recycling and reuse by Waste Input-Output Model	en
dc.type	Thesis
dc.date.schoolyear	103-1
dc.description.degree	博士
dc.contributor.oralexamcommittee	張慶源(Ching-Yuan Chang),李公哲(Kung-Cheh Li),於幼華(Yue-Hwa Yu),鄒倫(Leon Tzou)
dc.subject.keyword	廢棄物投入產出,廢棄物投入產出價格模型,二次銅,二次銅廢棄物投入產出,電解精煉部門,	zh_TW
dc.subject.keyword	Waste Input-Output Analysis,Waste Input-Output Price Model,Secondary copper,Secondary copper Waste Input-Output Model,The Sector of Electrolytic Refining,	en
dc.relation.page	140
dc.rights.note	有償授權
dc.date.accepted	2015-02-13
dc.contributor.author-college	工學院	zh_TW
dc.contributor.author-dept	環境工程學研究所	zh_TW
顯示於系所單位：	環境工程學研究所

文件中的檔案：

檔案	大小	格式
ntu-104-1.pdf 目前未授權公開取用	1.46 MB	Adobe PDF

顯示文件簡單紀錄

系統中的文件，除了特別指名其著作權條款之外，均受到著作權保護，並且保留所有的權利。