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| DC 欄位 | 值 | 語言 |
|---|---|---|
| dc.contributor.advisor | 馬鴻文(Hwong-Wen Ma) | |
| dc.contributor.author | Huie-Lun Hung | en |
| dc.contributor.author | 洪慧倫 | zh_TW |
| dc.date.accessioned | 2021-06-13T01:16:26Z | - |
| dc.date.available | 2007-07-24 | |
| dc.date.copyright | 2007-07-24 | |
| dc.date.issued | 2007 | |
| dc.date.submitted | 2007-07-17 | |
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| dc.identifier.uri | http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/29727 | - |
| dc.description.abstract | 戴奧辛號稱「世紀之毒」,台灣歷年來也有許多戴奧辛中毒及污染事件,對戴奧辛的管理則多琢磨在訂定排放標準以及建立排放清冊,雖然能於源頭減量並掌握每年戴奧辛排放趨勢,但對於戴奧辛的管理還不夠全面性,並且對於戴奧辛在環境中的流佈狀況也未善加瞭解。
本研究使用物質流分析,架構出台灣戴奧辛流佈狀況,並結合不確定性分析,考慮參數的不確定性,提高戴奧辛排放分佈估算的準確性。另外也使用CalTOX多介質模式,瞭解由經濟圈所排放的戴奧辛在環境圈中的分佈狀況。 研究結果顯示,台灣經濟圈戴奧辛整體釋放量為2480.19 g I-TEQ (589.18~8593.50 g I-TEQ),有256.31 g I-TEQ (98.50~628.88 g I-TEQ)經煙道釋放到空氣,2197.46 g I-TEQ (606.15~7084.76 g I-TEQ)儲存在廢棄物,並有21.97 g I-TEQ(6.06~70.85 g I-TEQ)釋放到土壤,以及有2.07E-06 g I-TEQ (1.08E-07~6.28E-06 g I-TEQ)釋放到水體。並且計算貿易食品及境內產品所含戴奧辛量,進口食品為0.57 g I-TEQ(0.29~0.88 g I-TEQ),出口食品為0.74 g I-TEQ(0.09~1.76 g I-TEQ);自給畜產為1.78 g I-TEQ(0.44~3.86 g I-TEQ)。 而戴奧辛排放貢獻量依序為電弧爐(41.42%)、集塵灰回收設施(12.36%)、鑄造廠(12.32%)、事業廢棄物焚化爐(11.0%)、燒結廠(7.30%)。 戴奧辛由經濟圈釋放後的環境宿命,最終以儲存在土壤為主,尤其是根部土壤,佔52.70%的比例,另外在空氣(air)佔0.13%,植物體(leaf)佔1.01 %,植物表皮(cuticle)佔0.98%,表土(ground-soil)佔1.75%,深層土(vadose-zone soil)佔24.74%,表面水(surface water)佔0.01 %,地下水佔5.20 %,底泥(sediment)則佔13.19%。 本研究更進一步做情境假設,以所建立的戴奧辛物質流資料庫為基礎,並根據台灣在2004~2008年間所修改戴奧辛排放標準,可知在活動強度成長10%下,若能確實遵守所修改的戴奧辛排放標準,雖然整體戴奧辛量增加0.71%,但在經由煙道排放的戴奧辛則能有40.27%的減量較果,可知戴奧辛排放標準的修訂具有一定的成效。 | zh_TW |
| dc.description.abstract | Dioxins are persistant organic pollutants in the environment and have diverse toxic occur in living organisms. The events of dioxins toxication and dioxins pollution happened in Taiwan constantly. Although the government sets up the emission standard and emission inventory to control the dioxins, the effective management requires more comprehensive understanding of dioxins flow in the economy and the environment.
The substance flow of dioxins of Taiwan is investigated in this study and the framework of substance flow network is defined. Uncertainty analysis and multimedia model (CalTOX) are combined to increase the accuracy of estimation of the flow in the environment. The results show that dioxins are discharged on average 2480.19 (589.18 ~8593.50) g I-TEQ, including 256.31 (98.50 ~628.88) g I-TEQ to air, 2197.46 (606.15~7084.76) g I-TEQ in the residues, 21.97 (6.06~70.85) g I-TEQ to soil, and 2.07E-06 (1.08E-07~6.28E-06) g I-TEQ to water. Dioxins in the food are also estimated. There are 0.57 (0.29~0.88) g I-TEQ in imported foods, 0.74 (0.09~1.76) g I-TEQ in exported foods, and 1.78 (0.44~3.86) g I-TEQ in the animal husbandry in Taiwan. The contributions of the sources of dioxins discharge in order are electric arc furnaces (41.42%), ferrous foundries (12.32%), industrial waste incineration (11.0%), and sintering plants (7.30%). The fate of most dioxins in the environment is stored in root soil (52.70%); others are in air (0.13%), leaf (1.01%), cuticle (0.98%), ground-soil (1.75%), vadose-zone soil (24.74%), surface water (0.01%), aquifer (5.20%), and sediment (13.19%). The study also conducts a scenario simulation, according to the dioxin emission standard modified from 2004 to 2008 and activity intensities that grow 10%. Although the amount of dioxins increases 0.71%, the dioxins emitted from flue reduces 40.27%. It shows the modification of dioxin emission standard has effect. | en |
| dc.description.provenance | Made available in DSpace on 2021-06-13T01:16:26Z (GMT). No. of bitstreams: 1 ntu-96-R94541205-1.pdf: 2409423 bytes, checksum: a8600b4d28c69c7028810fb6a9441b50 (MD5) Previous issue date: 2007 | en |
| dc.description.tableofcontents | 摘要 I
Abstract III 目錄 V 表目錄 VIII 圖目錄 XI 第一章 前言 1 1.1 研究背景 1 1.1.1 世紀之毒-戴奧辛 1 1.1.2 我國戴奧辛管理方法 5 1.2 研究目的 6 1.3 研究流程圖 8 第二章 文獻回顧 9 2.1 戴奧辛簡介 9 2.1.1 種類與定義 9 2.1.2 物理與化學特性 10 2.1.3 戴奧辛的來源 13 2.1.4 戴奧辛在環境的流布 14 2.1.5 戴奧辛毒理性質及對人體影響 17 2.1.6 毒性計量 18 2.2 戴奧辛推估方式與管制現況 20 2.2.1 戴奧辛排放量推估方式 20 2.2.2 各國對於戴奧辛的管制狀況 23 2.2.3 台灣管制戴奧辛現況 27 2.3 物質流分析簡述 30 2.3.1 物質流分析 30 2.3.2 物質流分析的系統 31 2.3.3 物質流分析的原理 32 2.3.4 物質流分析流程 33 2.3.5 物質流分析於危害性物質管理之應用 34 2.3.6 物質流分析應用於戴奧辛管理 37 2.3.7 物質流分析的限制與展望 40 2.4 不確定性分析 41 2.4.1 定量不確定性分析-蒙地卡羅模擬 41 2.4.2 定性不確定性分析-資料品質指標 42 2.5 小結 43 第三章 研究方法 44 3.1 研究步驟與概要 44 3.2 戴奧辛生命週期 48 3.3 經濟圈內的戴奧辛 49 3.3.1 本土產業活動 49 3.3.1.1 估算方法 51 3.3.1.2 物質流資料庫建構情形 51 3.3.2 貿易活動 57 3.3.3 境內自給自足食品 58 3.3.3.1 毒性當量因子的單位轉換 59 3.4 不確定性分析 59 3.4.1 定性不確定性分析 59 3.4.2 定量不確定性分析 63 3.5 環境圈戴奧辛流布 63 3.6 小結 65 第四章 結果與討論 66 4.1 台灣戴奧辛物質流分析結果 66 4.2 經濟圈戴奧辛物質流細部分析 73 4.2.1 經濟圈整體現況 73 4.2.2 產業活動排放到空氣的排放量、貢獻量與敏感度分析 74 4.2.3 產業活動排放到土壤的排放量、貢獻量與敏感度分析 77 4.2.4 本土產業活動排放到水體的排放量 81 4.2.5 貿易活動與自給畜產的戴奧辛含量 82 4.3 環境圈戴奧辛物質流細部分析 84 4.4 敏感度分析 86 4.5 現有戴奧辛物質流比較與討論 89 4.6 未來台灣戴奧辛物質流推估 95 4.6.1 台灣戴奧辛物質流情境結果 95 4.6.2 情境假設下排放到空氣的排放量、貢獻量與敏感度分析 102 4.6.3 情境假設下環境介質分配量的變化 106 4.6.4 情境假設下的敏感度分析 106 第五章 結論與建議 109 5.1 結論 109 5.2 建議 111 參考文獻 113 附錄A 產業活動排放戴奧辛到空氣 A-1 附錄B 產業活動排放戴奧辛到土壤 B-1 附錄C 貿易活動與自給畜產所含戴奧辛量 C-1 附錄D 環境介質的分佈比例與敏感度分析 D-1 附錄E 情境假設下各排放源的敏感度分析 E-1 附錄F 情境假設下環境介質的敏感度分析 F-1 | |
| dc.language.iso | zh-TW | |
| dc.title | 台灣戴奧辛物質流分析 | zh_TW |
| dc.title | Substance Flow Analysis for Dioxins in Taiwan | en |
| dc.type | Thesis | |
| dc.date.schoolyear | 95-2 | |
| dc.description.degree | 碩士 | |
| dc.contributor.oralexamcommittee | 張慶源(Ching-Yuan Chang),於幼華(Yue-Hwa Yu),張簡國平 | |
| dc.subject.keyword | 戴奧辛,物質流分析,不確定性分析, | zh_TW |
| dc.subject.keyword | dioxin,substance flow analysis,uncertainty analysis, | en |
| dc.relation.page | 118 | |
| dc.rights.note | 有償授權 | |
| dc.date.accepted | 2007-07-19 | |
| 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 | |
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