請用此 Handle URI 來引用此文件:
http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/68083
完整後設資料紀錄
DC 欄位 | 值 | 語言 |
---|---|---|
dc.contributor.advisor | 駱尚廉(Shang-Lien Lo) | |
dc.contributor.author | Chih-Jung Yeh | en |
dc.contributor.author | 葉致榮 | zh_TW |
dc.date.accessioned | 2021-06-17T02:12:20Z | - |
dc.date.available | 2020-08-21 | |
dc.date.copyright | 2020-08-21 | |
dc.date.issued | 2020 | |
dc.date.submitted | 2020-08-17 | |
dc.identifier.citation | Abbas, A.A., Jingsong, G., Ping, L.Z, Ya, P.Y., Al-Rekabi, W.S., 2009. Review on landfill leachate treatment. Journal of Applied Sciences Research, 5, 534-545. Abou-Gamra, Z.M., 2016. Kinetic and thermodynamic studies for oxidation of rosaniline hydrochloride dye by persulfate in ambient temperatures. Desalination and Water Treatment, 57, 8809-8814. Al-Yaqout, A.F., Hamoda, M.F., 2003. Evaluation of landfill leachate in arid climate—a case study. Environment International, 29, 593-600. Appleton, T.J., Colder, R.I., Kingman, S.W., Lowndes, I.S., Read, A.G., 2005. Microwave technology for energy-efficient processing of waste. Applied Energy, 81, 85-113. Bashir, M.J., Aziz, H.A., Yusoff, M.S., 2011. New sequential treatment for mature landfill leachate by cationic/anionic and anionic/cationic processes: optimization and comparative study. Journal of Hazardous Materials, 186, 92–102. Berlin, A.A., 1986. Kinetics of radical-chain decomposition of persulfate in aqueous solution of organic compounds. Kinetics and Catalysis, 27, 34-39. Bi, X., Wang, P., Jiang, H., 2008. Catalytic activity of CuOn–La2O3 /γ-Al2O3 for microwave assisted ClO2 catalytic oxidation of phenol wastewater. Journal of Hazardous Materials, 154, 543-549. Bi, X., Wang, P., Jiao, C., Caoa, H., 2009. Degradation of remazol golden yellow dye wastewater in microwave enhanced ClO2 catalytic oxidation process. Journal of Hazardous Materials, 168, 895-900. Box, G.E., Wilson, K.B., 1951. On the experimental attainment of optimum conditions. Journal of the royal statistical society: Series b (Methodological), 13, 1-38. CEM Corp., 2016. Microwave chemistry: how it all works. Retrieved January, 8, 2017, from http://cem.com/e107/page130.html Chen, P.H., 1996. Assessment of leachates from sanitary landfill: Impact of age, rainfall, and treatment. Environment International, 22, 225-237. Chian, E.S.K., DeWalle, F.B., 1977. Characterization of soluble organic matter in leachate. Environmental Science Technology, 11, 158-163. Chou, Y.C., Lo, S.L., Kuo, J., Yeh, C.J., 2013. Derivative mechanisms of organic acids in microwave oxidation of landfill leachate. Journal of hazardous materials, 254, 293-300. Chou, Y.C., Lo, S.L., Kuo, J., Yeh, C.J., 2015. Microwave-enhanced persulfate oxidation to treat mature landfill leachate. Journal of hazardous materials, 284, 83-91. Chys, M., Oloibiri, V.A., Audenaert, W.T., Demeestere, K., Van Hulle, S.W., 2015. Ozonation of biologically treated landfill leachate: efficiency and insights in organic conversions. Chemical Engineering Journal, 277, 104-111. Czitrom, V., 1999. One-factor-at-a-time versus designed experiments. The American Statistician, 53, 126-131. Deng, Y., Englehardt, J.D., 2007. Electrochemical oxidation for landfill leachate treatment. Waste Management, 27, 380-388. Erkan, N., Ayranci, G., Ayranci, E., 2009. A kinetic study of oxidation development in sunflower oil under microwave heating: Effect of natural antioxidants. Food Research International, 42, 1171-1177. Fernandes, A., Makoś, P., Boczkaj, G., 2018. Treatment of bitumen post oxidative effluents by sulfate radicals based advanced oxidation processes (S-AOPs) under alkaline pH conditions. Journal of Cleaner Production, 195, 374-384. Ferreira, S.L.C., Bruns, R.E., Ferreira, H.S., Matos, G.D., David, J.M., Brandao, G.C., Silva da E.G.P., Portugal L.A., Reis dos P.S., Souza A.S., Santos dos W.N.L., 2007. Box-Behnken design: an alternative for the optimization of analytical methods. Analytica chimica acta, 597, 179-186. Fisher, R.A., 1936. Design of experiments. Br Med J, 1, 554-554. Garaj-Vrhovac, V., Horvat, D., Koren, Z., 1990. The effect of microwave radiation on the cell genome. Mutation Research Letters, 243, 87-93. Go, A.W., Sutanto, S., Tran-Nguyen, P.L., Ismadji, S., Gunawan, S., Ju, Y.H., 2014. Biodiesel production under subcritical solvent condition using subcritical water treated whole Jatropha curcas seed kernels and possible use of hydrolysates to grow Yarrowia lipolytica. Fuel, 120, 46-52. Hamada, M., Wu, C.J., 1992. Analysis of designed experiments with complex aliasing. Journal of Quality Technology, 24, 130-137. Haque, K.E., 1999. Microwave energy for mineral treatment processes-a brief review. International Journal of Mineral Processing, 57, 1-24. Hodge, J.E., Osman, E.M., 1976. Principles of Food Science Part 1. Food Chemistry. by 0.R. Fennema, Marcel Dekker Inc., New York, Basel, 140-187. House, D.A., 1962. Kinetics and mechanism of oxidations by peroxydisurfate. Chemical Reviews, 62, 185-203. Huang, C.P., Dong, C., Tang, Z., 1993. Advanced chemical oxidation: its present role and potential future in hazarous waste treatment. Waste Management, 13, 361-377. Huang, K.C., Couttenye, R.A., Hoag, G.E., 2002. Kinetics of heat-assisted persulfate oxidation of methyl tert-butyl ether (MTBE). Chemosphere, 49, 413-420. Yusoff, M.S., Aziz, H.A., Zamri, M.F.M.A., Abdullah, A.Z., Basri, N.E.A., 2018. Floc behavior and removal mechanisms of cross-linked Durio zibethinus seed starch as a natural flocculant for landfill leachate coagulation-flocculation treatment. Waste Management, 74, 362-372. Jiang, S.J., Liu, Z.Y., 2002. The meaning of UV254 as an organic matter monitoring parameter in water supply wastewater treatment. Journal of Chongqing Jianzhu University, 24, 61-65. Kirmizakis, P., Tsamoutsoglou, C., Kayan, B., Kalderis, D., 2014. Subcritical water treatment of landfill leachate: Application of response surface methodology. Journal of environmental management, 146, 9-15. Kuhn, M., 2016. Desirability: function optimization and ranking via desirability functions. R package v.2.1. Retrieved July 25, 2020, from http://CRAN.R-project.org/package=desirability Kolthoff, I.M., Miller, I.K., 1951. The Chemistry of Persulfate.I.The kinetics and mechanism of the decomposition of the Persulfate ion in aqueous medium. Journal of the American Chemical Society, 73, 3055-3059. Labuza, T.P., 1971. Kinetics of lipid oxidation in foods. Critical Reviews in Food Science Technology, 2, 355-405. Latimer, W.M., 1952. The oxidation states of the elements and their potentials in aqueous solution. Prentice Hall Inc., New York, 78. Lee, Y.C., Lo, S.L., Chiueh, P.T., Chang, D.G., 2009. Efficient decomposition of perfluorocarboxylic acids in aqueous solution using microwave-induced persulfate. Water Research, 43, 2811-2816. Leenheer, J.A., Nanny, M.A., Mcintyre, C., 2003. Terpenoids as Major Precursors of Dissolved Organic Matter in Landfill Leachates, Surface Water, and Groundwater. Environmental Sceince Technology, 37, 2323-2331. Liang, Z., Liu, J.X., Li, J., 2009. Decomposition and mineralization of aquatic humic substances (AHS) in treating landfill leachate using the Anammox process. Chemosphere, 74, 1315-1320. Lin, L., Chan, G.Y.S., Jiang, B.L., Lan, C.Y., 2007. Use of ammoniacal nitrogen tolerant microalgae in landfill leachate treatment. Waste Management, 27, 1376-1382. Lin, L., Chen, J., Xu, Z., Yuan, S., Cao, M., Liu, H., Lu, X., 2009. Removal of ammonia nitrogen in wastewater by microwave radiation: A pilot-scale study. Journal of Hazardous Materials, 168, 862-867. Lin, L., Yuan, S., Chen, J., Xu, Z., Lu, X., 2009. Removal of ammonia nitrogen in wastewater by microwave radiation. Journal of Hazardous Materials, 161, 1063-1068. Ling, S.J., Sanny, J., Moebs, W., 2018. University Physics Volume 2: OpenStax. Rice University, Houston, TX, USA, 370-372. Monteagudo J.M., Durán A., González R., Expósito A.J., 2015. In situ chemical oxidation of carbamazepine solutions using persulfate simultaneously activated by heat energy, UV light, Fe2+ ions, and H2O2. Applied Catalysis B: Environmental, 176, 120-129. Montgomery, D.C. (2012). Design and analysis of experiments (8th Ed.). John Wiley Sons, Inc., Hoboken, New Jersey, USA, 21-22. Murray, P.M., Bellany, F., Benhamou, L., Bučar, D.K., Tabor, A.B., Sheppard, T.D., 2016. The application of design of experiments (DoE) reaction optimisation and solvent selection in the development of new synthetic chemistry. Organic Biomolecular Chemistry, 14, 2373-2384. Nayak, A.K., Pal, A., 2018. Rapid and high-performance adsorptive removal of hazardous acridine orange from aqueous environment using Abelmoschus esculentus seed powder: single-and multi-parameter optimization studies. Journal of environmental management, 217, 573-591. Orozco, A., Ahmad, M., Rooney, D., Walker, G., 2007. Dilute acid hydrolysis of cellulose and cellulosic bio-waste using a microwave reactor system. Process Safety and Environmental Protection, 85, 446-449. Quan, X., Zhang, Y., Chen, S., Zhao, Y., Yang, F., 2007. Generation of hydroxyl radical in aqueous solution by microwave energy using activated carbon as catalyst and its potential in removal of persistent organic substances. Journal of Molecular Catalysis A: Chemical, 263, 216-222. Quitain, A.T., Faisal, M., Kang, K., Daimon, H., Fujie, K., 2002. Low-molecular-weight carboxylic acids produced from hydrothermal treatment of organic wastes. Journal of Hazardous Materials, 93, 209-220. Ravera, M., Buico, A., Gosetti, F., Cassino, C., Musso, D., Osella, D., 2009. Oxidative degradation of 1,5-naphthalenedisulfonic acid in aqueous solutions by microwave irradiation in the presence of H2O2. Chemosphere, 74, 1309-1314. Robinson, T., 2007. Membrane bioreactors: Nanotechnology improves landfill leachate quality. Filtration Separation, 44, 38-39. Rosal, R., Rodríguez, A., Perdigón-Melón, J.A., Petre, A., García-Calvo, E., 2009. Oxidation of dissolved organic matter in the effluent of a sewage treatment plant using ozone combined with hydrogen peroxide (O3/H2O2). Chemical Engineering Journal, 149, 311–318. Saleem, M., Spagni, A., Alibardi, L., Bertucco, A., Lavagnolo, M.C., 2018. Assessment of dynamic membrane filtration for biological treatment of old landfill leachate. Journal of environmental management, 213, 27-35. Schoeman, J.J., Steyn, A., Makgae, M., 2005. Evaluation of electrodialysis for the treatment of an industrial solid waste leachate. Desalination, 186, 273-289. Silveira, J.E., Zazo, J.A., Pliego, G., Bidóia, E.D., Moraes, P.B., 2015. Electrochemical oxidation of landfill leachate in a flow reactor: optimization using response surface methodology. Environmental Science and Pollution Research, 22, 5831-5841. Smith, H.E. 1998. Chiroptical properties of the benzene chromophore. A method for the determination of the absolute configurations of benzene compounds by application of the benzene sector and benzene chirality rules. Chemical reviews, 98, 1709-1740. Taguchi, G., 1986. Introduction to quality engineering: designing quality into products and processes. Asian Productivity Organization, Tokyo. Tatsi, A.A., Zouboulis, A.I., 2002. A field investigation of the quantity and quality of leachate from a municipal solid waste landfill in a Mediterranean climate (Thessaloniki, Greece). Advances in Environmental Research, 6, 207-219. Tizaou, C., Bouselmi, L., Mansouri, L., Ghrabi, A., 2007. Landfill leachate treatment with ozone and ozone/hydrogen peroxide systems. Journal of Hazardous Materials, 140, 316-324. Wang, S., Wu, X., Wang, Y., Li, Q., Tao, M., 2008. Removal of organic matter and ammonia nitrogen from landfill leachate by ultrasound. Ultrasonics Sonochemistry, 15, 933-937. Weissman, S.A., Anderson, N.G., 2015. Design of experiments (DoE) and process optimization. A review of recent publications. Organic Process Research Development, 19, 1605-1633. Witt, O.N. 1876. Zur kenntniss des baues und der bildung färbender kohlenstoffverbindungen. Berichte der deutschen chemischen Gesellschaft, 9, 522-527. Woodward, R.B. 1941. Structure and the absorption spectra of α, β-unsaturated ketones. Journal of the American Chemical Society, 63, 1123-1126. Wu, C.Y., Lui, W.B., Peng, J., 2018. Optimization of extrusion variables and maleic anhydride content on biopolymer blends based on poly (hydroxybutyrate-co-hydroxyvalerate)/poly (vinyl acetate) with tapioca starch. Polymers, 10, 827. Yang, Y., Wang, P., Shi, S., Liu, Y., 2009. Microwave enhanced Fenton-like process for the treatment of high concentration pharmaceutical wastewater. Journal of Hazardous Materials, 168, 238-245. Yasuhara, A., Shiraishi, H., Nishikawa, M., 1997. Determination of organic components in leachate from hazardous waste disposal sites in Japan by gas chromatography-mass specrtrometry. Journal of Chromatography A, 774, 321-332. Yeşilyurt, M., Çolak, S., Çalban, T., Genel, Y., 2005. Determination of the optimum conditions for the dissolution of colemanite in H3PO4 solutions. Industrial engineering chemistry research, 44, 3761-3765. Yusoff, M.S., Aziz, H.A., Zamri, M.F.M.A., Abdullah, A.Z., Basri, N.E.A., 2018. Floc behavior and removal mechanisms of cross-linked Durio zibethinus seed starch as a natural flocculant for landfill leachate coagulation-flocculation treatment. Waste Management, 74, 362-372. 行政院環境保護署一般廢棄物管理清理管理網頁(民107年7月19日),檢自https://www.epa.gov.tw/Page/16FAB5046B4F80FC (Aug. 16, 2020) 行政院環境保護署環境資料庫(民109年3月5日),營運中公有垃圾掩埋場資料,檢自https://erdb.epa.gov.tw/DataRepository/Facilities/PublicWasteOrgData.aspx (Aug. 16, 2020) 李公哲、林正芳(2001),垃圾衛生掩埋場滲出水處理流程之研究,環保月刊,1(2),124-135。 林李旺(2014),突破品質水準-實驗設計與田口方法之實務應用,新北市:全華圖書股份有限公司。 劉國華、陳瑾惠、王園園、齊魯、王洪臣(2020),改性污泥基吸附劑深度處理出水有機物的研究,環境科學學報,40(4),1196-1203。 | |
dc.identifier.uri | http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/68083 | - |
dc.description.abstract | 臺灣的垃圾掩埋場滲出水,因色度、臭味及其處理技術、效果和成本等,而經常受到社會的關注。垃圾滲出水一般以物理及生物等處理方式均無法有效去除,本研究以非傳統式之高級氧化處理程序-微波(MW)技術,結合過硫酸鹽(PS)氧化劑進行滲出水處理。研究中探討三個實驗因子:MW功率設置、PS濃度及MW反應時間(T),對三個目標參數:總有機碳(TOC)、色度及UV254處理效果之影響。另外,本研究首先利用田口(Taguchi)方法L16正交陣列(OA)設計,結合訊噪比(S/N)方法及變異數分析(ANOVA),對微波氧化程序(MOP)進行滲出水處理實驗,探討各項操作參數對處理效果的影響;另外再以反應曲面方法(RSM)中的Box-Behnken (BBD)設計,進一步來達成最適實驗之設計及整體參數最佳化。 本研究在田口方法中求得最佳條件為:在550 W、20 mM及130 min時,TOC去除率為80%,色度去除率為96%;在775W、20 mM及130 min時,UV254去除率為55%。實驗因子的顯著性排名為:對於TOC的去除率,MW > PS > T;對於色度的去除率,PS > MW > T;對於UV254的去除率,MW > PS > T;可見在田口方法設計階段,MW之設置對MOP影響顯著。田口方法和ANOVA在最佳條件下預測的目標參數去除率與確認實驗所得之實際結果相似。接著摒除不顯著之水準,進一步的在RSM方法中進行二次迴歸模型建置,並使用ANOVA得出預測相關係數以及每個參數與測試參數之間的關係,其中等值線圖(2D)和反應曲面圖(3D)可顯示去除三個參數的最佳操作條件,而初始PS濃度對所有三個參數的去除影響最大。研究分析在個別的最佳操作條件下,TOC、色度及UV254的最高去除率分別為79.5%、100%及68.4%;而在整體最佳操作條件下,TOC、色度及UV254操作條件分別為447.7 W、20.0 mM及116.3 min,去除率分別為78.8%、100%及66.4%;在RSM設計階段PS則為顯著性因子。 田口方法應用在滲出水處理程序上,有容易及可快速找出最佳操作條件且較易理解之優點,但對中間反應過程變化較無描述;而反應曲面法針對處理之參數條件變化有較細微的分析,但相對理解或描述上略有難度,二者各有其優缺點。本研究結合此二種方法對微波加熱催化過硫酸鹽處理垃圾滲出水之處理程序加以探討,達成去除目標參數的目的。 | zh_TW |
dc.description.abstract | Landfill leachate issue in Taiwan was often to be concerned about for its treatment technology, effects, and costs. In this study, an experimental study using microwave oxidation process (MOP) to treat leachate was designed and optimized using Taguchi L16 orthogonal array (OA) design, coupled with the signal-to-noise (S/N) ratio method and the analysis of variance (ANOVA) method and compare the relationships in them. To go a step further, the experiment were optimized via response surface methodology (RSM) with a Box-Behnken design (BBD). Three experimental factors, microwave (MW) power settings, persulfate (PS) concetrations, and MW reaction time (T), as well as three target parameters, total organic carbon (TOC), color, and UV254, were studied. In the Taguchi method, the optimal conditions were found to be: 550 W, 20 mM, and 130 min for TOC removals of 80% and color removals of 96%; 775W, 20 mM, and 130 min for UV254 removals of 55%. The ranking of significance of experimental factors were: MW > PS > T for TOC removals, PS > MW > T for color removals, and MW > PS > T for UV254 removals. The quality loss function values were used to compare the quality loss situation among different experimental conditions in the Taguchi OA design. The predicted removals of target parameters under the optimal conditions by Taguchi method and ANOVA were similar to the actual results from the confirmation experimental runs. Further analysis in RSM design, the construction of second-order polynomial model, and ANOVA was used to derive the prediction correlation coefficient and the relationship of each factor on the test parameters. The contour-line plots and surface plots revealed the optimal operating conditions for removals of three parameters. The initial PS concentration had the most significant effect on the removals of all three parameters. The highest removals of 79.5%, 100%, and 68.4% for TOC, color, and UV254 attained under separate optimal operating conditions, respectively. The optimal operating conditions for TOC, color, and UV254 removals as a whole were derived to be 447.7 W, 20.0 mM, and 116.3 min with removals of 78.8%, 100%, and 66.4%, respectively. | en |
dc.description.provenance | Made available in DSpace on 2021-06-17T02:12:20Z (GMT). No. of bitstreams: 1 U0001-1708202017012400.pdf: 2213568 bytes, checksum: a22af9c51bb56373db006a614f0d35f3 (MD5) Previous issue date: 2020 | en |
dc.description.tableofcontents | 口試委員會審定書............................................................................................................i 誌謝……………………………………………………………………………………...ii 摘要……………………………………………………………...……………….......…iii ABSTRACT…………………………………………………………..…………………v 總目錄…………………………………………………………...………………….…vii 圖目錄…………………….…………………………………….…………...….………xi 表目錄………………………………………………………………........…….….......xiii 第一章 緒論………………………………………………………………….……….1 1.1 前言…………………………………………………………….……………1 1.2 研究目的……………………………………………………….……………3 1.3 研究內容……………………………………………………….……………4 第二章 文獻回顧………………………...……………………………….…………..6 2.1 掩埋場滲出水水質特性…………………………………………….………6 2.2 滲出水相關之高級處理技術…………………….………………….………7 2.3 過硫酸鹽特性及處理技術…………………………………...………….........7 2.4 微波技術………………………………………………………………..…....10 2.4.1 微波簡介…………………………………………………….......……10 2.4.2 微波加熱原理………………………………………………………13 2.4.3 熱效應及非熱效應…………………………………………………14 2.4.4 微波技術在工業領域之應用………………………………..……..17 2.5 實驗設計…………………………………………………………………...20 2.5.1 實驗設計簡介及步驟………………………………………………20 2.5.2 田口實驗設計法……………………………………………………23 2.5.3 田口方法直交表配置及訊噪比……………………………..……..25 2.5.4 反應曲面法……………………………...……………..….....……..27 第三章 實驗材料設備及分析方法……………………………….…...……………32 3.1 研究架構………………………………………………………………...…32 3.2 研究場址滲出水水質特性…………………………………...……………34 3.3 實驗試劑與設備…………………………………………..……………….37 3.3.1 實驗試劑………………………………………………...………….37 3.3.2 實驗設備………………………………………………...………….37 3.3.3 實驗軟體………………………………………..……….………….37 3.3.4 水樣前處理………………………………………..………………..38 3.4 實驗步驟及參數分析方法…………………………...……………………38 3.4.1 實驗步驟………………………………………………...………….38 3.4.2 參數分析方法…………………………………………...………….38 3.5 實驗統計相關公式………………………………………....……....……...40 3.5.1 田口方法相關公式…………………………………………………40 3.5.2 反應曲面法相關公式………………….......…………………………42 第四章 結果與討論……………………………………....………………......……. 45 4.1 過硫酸鹽背景實驗….. ……………………………………………………45 4.2 田口直交表建置及實驗結果……….. ……………………………...….…49 4.3 去除參數的OOC及實驗因子影響排序……….......………………....…..…52 4.3.1 去除TOC之OOC及實驗因子影響排序………….....…………....…52 4.3.2 去除色度之OOC及實驗因子影響排序………….....………...…..…55 4.3.3 去除UV254之OOC及實驗因子影響排序………........…………...…59 4.3.4 去除參數因子影響排序分析 ……………………...…….....….......…63 4.4 田口法預測分析及損失函數結果………………....……..…….....…....…67 4.4.1 田口法預測及確認實驗結果........…………………..…….....…....…67 4.4.2 損失函數結果 …………………..………....……………….…...….…69 4.5 ANOVA分析及貢獻度百分比…………………………………….…....…69 4.5.1 ANOVA分析及預測結果…………………………..……....…....…69 4.5.2 貢獻度百分比分析…………..………....………….......…….…..…72 4.5.3 目標參數之去除………....…………....…………...……....……….73 4.6 田口法之交互作用分析………....………...…....…………...…....…………73 4.6.1 TOC之交互作用分析……….... ………....……………....…………74 4.6.2 色度之交互作用分析………..……....……...………......……………75 4.6.3 UV254之交互作用分析………....……………....…...…....………76 4.7 反應曲面法之設置及分析....……………………...……………...……....…76 4.7.1 反應曲面法之設置及RSM模型建置…………………………......…78 4.7.2 標準化殘差常態機率圖分析....………………………………....…82 4.7.3 RSM之ANOVA分析....…………...................................................83 4.7.4 RSM之等值線分析....…………........................................................86 4.7.5 RSM之反應曲面分析....…………................................................…91 4.8 RSM之最佳化分析....…………………………….....……………….....…95 4.12.1 RSM之個別最佳化分析....……………...……………..……....…96 4.12.2 RSM之整體最佳化分析....……………...…………………......…97 4.12.3 RSM之最佳化操作條件驗證....……………….....…………....…98 4.13 田口法與RSM之比較....…………………………………..…...................101 第五章 結論與建議....………………………………………………..…..……....104 5.1 結論....………………………………………………………..…….…....104 5.2 建議....………………………………………………………….……....…105 參考文獻…………………………………………………...….………..………..…106 附錄………………………………………………….....................….………..……114 | |
dc.language.iso | zh-TW | |
dc.title | 以實驗設計法探討微波輔助過硫酸鹽氧化垃圾滲出水之最佳化研究 | zh_TW |
dc.title | Optimization of Landfill Leachate Treatment by Microwave-assisted Persulfate Oxidation using Experimental Design Method | en |
dc.type | Thesis | |
dc.date.schoolyear | 108-2 | |
dc.description.degree | 博士 | |
dc.contributor.oralexamcommittee | 李育明(Yuh-Ming Lee),張添晉(Tien-Chin Chang),蔣本基(Pen-Chi Chiang),林正芳(Cheng-Fang Lin) | |
dc.subject.keyword | 垃圾滲出水,微波氧化,過硫酸鹽,田口方法,反應曲面法,變異數分析, | zh_TW |
dc.subject.keyword | Landfill leachate,Microwave oxidation,Persulfate,Taguchi method,RSM,ANOVA, | en |
dc.relation.page | 123 | |
dc.identifier.doi | 10.6342/NTU202003809 | |
dc.rights.note | 有償授權 | |
dc.date.accepted | 2020-08-18 | |
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 | |
---|---|---|---|
U0001-1708202017012400.pdf 目前未授權公開取用 | 2.16 MB | Adobe PDF |
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。