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研究生:潘時正
研究生(外文):Shih-Cheng Pan
論文名稱:下水污泥灰渣特性及應用於水泥砂漿之研究
論文名稱(外文):The Characteristics of Sewage Sludge Ash and Its Applications in Cement Mortar
指導教授:曾迪華曾迪華引用關係
指導教授(外文):Dyi-Hwa Tseng
學位類別:博士
校院名稱:國立中央大學
系所名稱:環境工程研究所
學門:工程學門
學類:環境工程學類
論文種類:學術論文
論文出版年:2002
畢業學年度:90
語文別:英文
論文頁數:254
中文關鍵詞:下水污泥灰渣水泥砂漿卜作嵐活性工作性抗壓強度
外文關鍵詞:compressive strengthworkabilitypozzolanic activitycement mortarsewage sludge ash
相關次數:
  • 被引用被引用:27
  • 點閱點閱:307
  • 評分評分:
  • 下載下載:0
  • 收藏至我的研究室書目清單書目收藏:1
封面
摘 要
目 錄
圖目錄
表目錄
第一章 前言
1-1研究緣起
1-2研究目的與內容
第二章 文獻回顧
2-1下水污泥處理處置與資源化
2-2下水污泥灰渣特性
2-3水泥與混凝土基本原理
2-4卜作嵐材料基本原理
2-5下水污泥灰渣應用於水泥混凝土
2-6卜作嵐材料改良技術
第三章 研究方法
3-1研究材料
3-2試驗與分析方法
3-3實驗計畫
第四章 下水污泥灰渣特性
4-1下水污泥基本性質
4-2下水污泥灰渣物理性質
4-3下水污泥灰渣化學性質
4-4下水污泥灰渣卜作嵐性質
4-5含石灰污泥灰渣性質
4-6本章總結
第五章 下水污泥灰渣再利用於水泥砂漿
5-1下水污泥灰渣取代砂漿骨材
5-2下水污泥灰渣取代砂漿水泥
5-3本章總結
第六章 下水污泥灰渣砂漿之改良
6-1下水污泥灰渣高溫灼燒處理
6-2下水污泥灰渣機械研磨處理
6-3化學摻料應用於污泥灰渣砂漿
6-4本章總結
第七章 結論與建議
7-1結論
7-2建議
參考文獻
參考標準方法與規範
中英文名詞對照
附錄
Akhter, H., Cartledge, F.K., Roy, A., and Tittlebaum, M.E., “A study of the effects of nickel chloride and calcium chloride on hydration of portland cement”, Cement Concrete Research, Vol.23, No.4, pp.833-842 (1993).Alleman, J.E., and Berman, N.A., “Constructive sludge management: biobrick,” J. Environmental Engineering, ASCE, Vol.110, No.2, pp.301-311 (1984).Alleman, J.E., Bryan, E.H., Stumm, T.A., Marlow, W.W., and Hocevar, R.C., “Sludge-amended brick production: applicability for metal-laden residues”, Water Science Technology, Vol.22, No.12, pp.309-317 (1990).Al Sayed, M.H., Madany, I.M., and Buali, A.R.M., “Use of sewage sludge ash in asphaltic paving mixes in hot regions”, Construction Building Materials, Vol.9, No.1, pp.19-23 (1995).Anderson, M., Skerratt, R.G., Thomas, J., and Clay, S.D., “Case study involving using fluidised bed incinerator sludge ash as a partial clay substitute in brick manufacture”, Water Science Technology, Vol.34, No.3-4, pp.507-515 (1996).Aziz, A., Lawrence, C.C.K., “Potential utilization of sewage sludge”, Water Science Technology, Vol.22, No.12, pp.277-285 (1990).Balashov, S.V., and Boronin, A.M., “Sewage-sludge isolates decomposing sulfoaromatic compounds”, Microbiology, Vol.65, No.5, pp.549-552 (1996).Bhatty, J.I., and Reid, K.J., “Compressive strength of municipal sludge ash mortars”, ACI Materials J., Vol.86, No.4, pp.394-400 (1989).Biernacki, J.J., Williams, P.J., and Stutzman, P.E., “Kinetics of reaction of calcium hydroxide and fly ash”, ACI Materials J., Vol.98, No.4, pp.340-349 (2001).Biricik, H., Akoz, F., Berktay, I., and Tulgar, A.N., “Study of pozzolanic properties of wheat straw ash”, Cement Concrete Research, Vol.29, No.1, pp.637-643 (1999).Bonen, D., and Sarkar, S.L., “The superplasticizer adsorption capacity of cement pastes, pore solution composition, and parameters affecting flow loss”, Cement Concrete Research, Vol.25, No.7, pp.1423-1434 (1995).Bonen, D., and Khayat, K.H., “Characterization and pozzolanic properties of silica fume stored in an open pond”, Cement Concrete Research, Vol.25, No.2, pp.395-407 (1995).Bridle, T., “Fuel first”, Water Quality International, No.4, pp.20-21 (1997).Brough, A.R., Dobson, C.M., Richardson, I.G., and Groves, G.W., “A study of the pozzolanic reaction by solid-state 29Si nuclear magnetic resonance using selective isotopic enrichment”, J. Materials Science, Vol.30, pp.1671-1678 (1995).Carette, G.G., and Malhotra, V. M., “Characterization of Canadian fly ashes and their relative performance in concrete”, Canadian J. Civil Engineering, Vol.14, No.5, pp.667-682 (1987).Cargill, G.D., Cook, E.J., and Richard, S., “Biosolids marketing,” Water Environment Technology, Vol.9, No.9, pp.87-91 (1997).Chan, M.Y., and Ouyang, C.F., “Feasibility study of two sewage sludge slag as fine aggregate”, Proceeding of Sludge Management Entering the 3rd Millenium, Taipei, pp.440-449 (2001).Chatterji, S., Discussion of “Mercury porosimetry an inappropriate method for the measurement of pore size distributions in cement-based materials” by S. Diamond, Cement Concrete Research, Vol.31, No.11, pp.1657-1658 (2001).Chen, H.M., and Ouyang, C.F., “The characteristics of melting process on sewage sludge cake”, Proceeding of Sludge Management Entering the 3rd Millenium, Taipei, pp.223-229 (2001).Cheremisinoff, P. N., Sludge Management and Disposal, Prentice-Hall, Inc., New Jersey (1994).Cheriaf, M., Rocha, C., and Pera, J., “Pozzolanic properties of pulverized coal combustion bottom ash”, Cement Concrete Research, Vol.29, No.1, pp.1387-1391 (1999).Clark, S.M., Morisson, G.R., and Shi, W.D., “The use of scanning transmission X-ray microscopy for the real-time study of cement hydration”, Cement and Concrete Research, Vol.29, No.8, pp.1099-1102 (1999).Cong, X., Gong, S., Darwin, D., and McCabe, S.L., “Role of silica fume in compressive strength of cement paste, mortar, and concrete”, ACI Materials J., Vol.89, No.4, pp.375-387 (1992).Cook, R.A., and Hover, K.C., “Mercury porosimetry of cement-based materials and associated correction factors”, ACI Materials J., Vol.90, No.2, pp.152-161 (1993).Day, R.L., and Shi, C., “Influence of the fineness of pozzolan on the strength of lime natural-pozzolan cement pastes”, Cement Concrete Research, Vol.24, No.8, pp.1485-1491 (1994).Demirbas, A., Karslioglu, S., and Ayas, A., “Utilization of lignite ash in concrete mixture”, Cement Concrete Research, Vol.25, No.8, pp.1610-1614 (1995).Diamond, S., “Mercury porosimetry an inappropriate method for the measurement of pore size distributions in cement-based materials”, Cement Concrete Research, Vol.30, No.10, pp.1517-1525 (2000).Eaton, A.D., Clesceri, L.S., and Greenberg, A.E., (Ed.), Standard Methods for the Examination of Water and Wastewater, 19th Ed., APHA, AWWA, WEF (1995).El-Didamony, H., Sharara, A.M., Helmy, I.M., and Adb El-Aleem, S., “Hydration characteristics of b-C2S in the presence of some accelerators”, Cement Concrete Research, Vol.26, No.8, pp.1117-1187 (1996).Erdodgu, K., and Turker, P., “Effect of fly ash particle size on strength of portland cement fly ash mortars”, Cement Concrete Research, Vol.28, No.9, pp.1217-1222 (1998).Escalante, J.I., Mendoza, G., Mancha, H., Lopez, J., and Vargas, G., “Pozzolanic properties of a geothermal silica waste material”, Cement Concrete Research, Vol.29, No.8, pp.623-625 (1999).Gagne, R., Boisvert, A., and Pigeon, M., “Effect of superplasticizer dosage on mechanical properties, permeability, and freeze-thaw durability of high-strength concretes with and without silica fume”, ACI Materials J., Vol. 93, No.2, pp.111-120 (1996).Galle, C., “Effect of drying on cement-based materials pore structure as identified by mercury intrusion porosimetry a comparative study between oven-, vacuum-, and free-drying”, Cement Concrete Research, Vol.31, No.10, pp.1467-1525 (2001).Gartner, E.M., Kurtis, K.E., and Monteiro, P.J.M., “Porposed mechanism of C-S-H growth tested by soft X-ray microscopy”, Cement and Concrete Research, Vol.30, No.5, pp.817-822 (2000). Groves, G.W., and Richardson, I.G., “Microcrystalline calcium hydroxide in pozzolanic cement pastes”, Cement Concrete Research, Vol.24, No.6, pp.1191-1196 (1994).Grzeszczyk, S., and Lipowski, G., “Effect of content and particle size distribution of high-calcium fly ash on the rheological properties of cement pastes”, Cement Concrete Research, Vol.27, No.6, pp.907-916 (1997).Hauser, A., Eggenberger, U., and Peters, T., “Origin and characterisation of fly ashes from cellulose industries containing high proportions of free lime and anhydrite”, Cement Concrete Research, Vol.29, No.10, pp.1569-1573 (1999).He, C., Osbaeck, B., and Makovicky, E., “Pozzolanic reactions of six principal clay minerals: activation, reactivity assessments and technology effects”, Cement Concrete Research, Vol.25, No.8, pp.1691-1702 (1995).He, C., Makovicky, E., and Osback, B., “Thermal treatment and pozzolanic activity of sepiolite”, Applied Clay Science, Vol.10, No.6, pp.341-349 (1996).He, C., Makovicky, E., and Osback, B., “Thermal treatment and pozzolanic activity of Na-and Ca-montmorillonite”, Applied Clay Science, Vol.10, No.2, pp.351-368 (1996).Hiraoka, M., “Advanced sludge thermal processes in Japan”, Water Science Technology, Vol.30, No.8, pp.139-148 (1994).Hsuan, Y., “Thermogravimetric analyzer for geosynthetic materials”, Geotechnical Fabrics Report, No.11, pp.18-21 (1991).Jenkins, R., and Snyder, R.L., Introduction to X-ray Powder Diffractometry, John Wiley & Sons, Inc., New York (1996).Jennings, H.M., “A model for the microstructure of calcium silicate hydrate in cement paste”, Cement Concrete Research, Vol.30, No.1, pp.101-106 (2000).Jeyaseelan, S., and Qing, L.G., “Development of adsorbent/catalyst from municipal wastewater sludge”, Water Science Technology, Vol.34, No.3-4, pp.499-505 (1996).Katz, A., “Microscopic study of alkali-activated fly ash”, Cement Concrete Research, Vol.28, No.2, pp.197-208 (1998).Khanbilvardi, R., and Afahari, S., “Sludge ash as fine aggregate for concrete mix”, J. Environmental Engineering, ASCE, Vol.121, No.9, pp.633-638 (1994).Kovacs, R., “Effect of the hydration products on the properties of fly ash cements”, Cement Concrete Research, Vol.5, No.1, pp.73-82 (1975).Kovler, K., “Setting and hardening of gypsum-portland cement-silica fume blends, Part 1: temperature and setting expansion”, Cement Concrete Research, Vol.28, No.3, pp.423-437 (1998).Lilkov, V., and Stoitchkov, V., “Effect of the “Pozzolit” active mineral admixture on the properties of cement mortars and concretes”, Cement Concrete Research, Vol.26, No.7, pp.1073-1081 (1996).Lin, D.F., and Weng, C.H., “Use of sewage sludge ash as brick material”, J. Environmental Engineering, ASCE, Vol.127, No.10, pp.922-927 (2001).Loretto, M.H., Electron Beam Analysis of Materials, 2nd Ed., Chapman & Hall, London (1994).Lue-Hing, C., Zenz, D.R., and Kuchenrither, R. (Ed.), Municipal Sewage Sludge Management, Technomic Publishing, Lancaster, Pennsylvania (1992).Macias, A., and Goni, S., “Characterization of admixture as plasticizer or superplasticizer by deflocculation test”, ACI Materials J., Vol.96, No.1, pp40-46 (1999).Matthews, P. (Ed.), A Global Atlas of Wastewater Sludge and Biosolids Use and Disposal, International Association on Water Quality, London (1996).McCarter, W.J., and Tran, D., “Monitoring pozzolanic activity by direct activation with calcium hydroxide”, Construction Building Materials, Vol.10, No.3, pp.179-184 (1996).Mehta, P.K., Concrete, Structure, Properties, and Materials, Prentice-Hall, Inc., New Jersey (1986).Metcalf & Eddy, Inc., Wastewater Engineering Treatment, Disposal, and Reuse, McGraw-Hill, Inc., New York (1991).Mindess, S., and Young, J.F., Concrete, Prentice-Hall, Inc., New Jersey (1981).Monzo, J., Paya, J., and Peris-Mora, E., “A preliminary study on fly ash granulometric influence on mortar strength”, Cement Concrete Research, Vol.24, No.4, pp.791-796 (1994).Monzo, J., Paya, J., Borrachero, M.V., and Corcoles, A., “Use of sewage ash (SSA) - cement admixtures in mortars”, Cement Concrete Research, Vol.26, No.9, pp.1389-1398 (1996).Monzo, J., Paya, J., Borrachero, M.V., and Peris-Mora, E., “Mechanical behavior of mortars containing sewage sludge ash (SSA) and portland cements with different tricalcium aluminate content”, Cement Concrete Research, Vol.29, No.1, pp.87-94 (1999).National Research Council, Use of Reclaimed Water and Sludge in Food Crop Production, National Academy Press, Washington, D.C. (1996).Oriol, M., and Pera, J., “Pozzolanic activity of metakaolin under microwave treatment”, Cement Concrete Research, Vol.25, No.2, pp.265-270 (1995).Paya, J., Monzo, J., Borrachero, M.V., and Peris-Mora, E., “Mechanical treatments of fly ash. Part I: physico-chemical characterization of ground fly ashes”, Cement Concrete Research, Vol.25, No.7, pp.1469-1479 (1995)Paya, J., Monzo, J., Borrachero, M.V., Peris-Mora, E., and Gonzalez-Lopez, E., “Mechanical treatments of fly ash. Part II: particle morphologies in ground fly ash (GFA) and workability of GFA-cement mortars”, Cement Concrete Research, Vol.26, No.2, pp.225-235 (1996).Paya, J., Monzo, J., Borrachero, M.V., Peris, E., and Gonzalez-Lopez, E., “Mechanical treatment of fly ash. Part Ⅲ: studies on strength development of ground fly ash (GFA)-cement mortars”, Cement Concrete Research, Vol.27, No.9, pp.1365-1377 (1997).Paya, J., Monzo, J., Borrachero, M.V., Peris, E., and Amahjour, F., “Thermogravimetric methods for determining carbon content in fly ashes”, Cement Concrete Research, Vol.28, No.5, pp.675-686 (1998).Paya, J., Borrachero, M.V., Monzo, J., and Bonilla, M., “Properties of portland cement mortars incorporating high amounts of oil-fuel ashes”, Waste Management, Vol.19, No.1, pp.1-7 (1999).Paya, J., Monzo, J., Borrachero, M.V., Mellado, A., and Ordonez, L.M., “Determination of amorphous silica in rice husk ash by a rapid analytical method”, Cement Concrete Research, Vol.31, No.2, pp.227-231 (2001).Pera, J., Boumaza, R., and Ambroise, J., “Development of a pozzolanic pigment from red mud”, Cement Concrete Research, Vol.27, No.10, pp.1513-1522 (1997).Pera, J., and Amrouz, A., “Development of highly reactive metakaolin from paper sludge”, Cement Basic Material, Vol.7, No.3, pp.49-56 (1998).Peris-Mora, E., Paya, J., and Monzo, J., “Influence of different sized fractions of a fly ash on workability of mortars”, Cement Concrete Research, Vol.23, No.4, pp.917-924 (1993).Punkki, J., Golaszewski, J., and Gjorv, O.E., “Workability loss of high-strength concrete”, ACI Materials J., Vol.93, No.5, pp.427- 431 (1996).Ramachandran, V.S., “Alkali-aggregate expansion inhibition admixtures”, Cement Concrete Composites, Vol.20, No.1, pp.149-161 (1998).Ranganath, R.V., Bhattacharjee, B., and Krishnamoorthy, S., “Influence of size fraction of ponded ash on its pozzolanic activity”, Cement Concrete Research, Vol.28, No.5, pp.749-761 (1998).Richardson, I.G., “The nature of C-S-H in hardened cements”, Cement Concrete Research, Vol.29, No.8, pp.1131-1147 (1999).Richardson, I.G., “The nature of hydration products in hardened cement pastes”, Cement Concrete Composites, Vol.22, No.2, pp.97-113 (2000).Salvador, S., “Pozzolanic properties of flash-calcined kaolinite: a comparative study with soak-calcined products”, Cement Concrete Research, Vol.25, No.1, pp.102-112 (1995).Sanchez de Rojas, M.I., and Frias, M., “The pozzolanic activity of different materials, its influence on the hydration heat in mortars”, Cement Concrete Research, Vol.26, No.2, pp.203-213 (1996).Sharara, A.M., El-Didamony, H., Ebied, E., and El-Aleem, A., “Hydration characteristics of b-C2S in the presence of some pozzolanic materials”, Cement Concrete Research, Vol.24, No.5, pp.966-974 (1994).Sharma, R.C., Jain, N.K., and Ghosh, S.N., “Semi-theoretical method for the assessment of reactivity of fly ashes”, Cement Concrete Research, Vol.23, No.1, pp.41-45 (1993).Shi, C., “Pozzolanic reaction and microstructure of chemical activated lime-fly ash pastes”, ACI Materials J., Vol.95, No.5, pp.537-545 (1998).Shi, C., and Day, R.L., “Chemical activation of blend cements made with lime and natural pozzolans”, Cement Concrete Research, Vol.23, No.6, pp.1389-1396 (1993).Shi, C., and Day, R.L., “Acceleration of the reactivity of fly ash by chemical activation”, Cement Concrete Research, Vol.25, No.1, pp.15-21 (1995).Shi, C., and Day, R.L., “Pozzolanic reaction in the presence of chemical activators, Part I. Reaction kinetics”, Cement Concrete Research, Vol.30, No.1, pp.51-58 (2000).Shi, C., and Day, R.L., “Pozzolanic reaction in the presence of chemical activators, Part II. Reaction products and mechanism”, Cement Concrete Research, Vol.30, No.4, pp.607-613 (2000).Singh, M., and Garg, M., “Cementitious binder from fly ash and other industrial wastes”, Cement and Concrete Research, Vol.29, No.1, pp.309-314 (1999).Slanicka, S., “The influence of fly ash on the strength of concrete”, Cement Concrete Research, Vol.21, No.2-3, pp.285-296 (1991).Smith, P.G., “Thermal treatment and ultimate disposal of sewage sludge in Japan”, J. Institution of Water and Environmental Management, Vol.6, No.6, pp.653-658 (1992).Sopper, W.E., Municipal Sludge Use in Land Reclamation, Lewis Publishers, Boca Raton, Florida (1993).Storeven, P., Bui, D.D., and Sabuni, E., “Ash of vegetable waste used for economic production of low to high strength hydraulic binders”, Fuel, Vol.78, No.7, pp.153-159 (1999).Stumm, W., and Morgan, J.J., Aquatic Chemistry, 2nd Ed., John Wiley & Sons, New York (1981).Tamai, M., Yoshida, K., and Kuromatsu, A., “Reduction in environmental load with eco-cement and porous concrete”, Proceeding of International Conference on Cleaner Production and Sustainable Development ’99, Taipei, pp.20-33 (1999).Tanaka, I., Suzuki, N., Ono, Y., and Koishi, M., “Fluidity of spherical cement and mechanism for creating high fluidity”, Cement Concrete Research, Vol.28, No.1, pp.63-74 (1998).Tashiro, C., Ikeda, K., and Inoue, Y., “Evaluation of pozzolanic activity by the electric resistance measurement method”, Cement Concrete Research, Vol.24, No.6, pp.1133-1139 (1994).Tattersall, G.H., and Banfill, P.F.G., The Rheology of Fresh Concrete, Pitman Publishing Inc., Marshfield, Massachusetts (1983).Tay, J.H., “Sludge ash as filler for portland cement concrete”, J. Environmental Engineering, ASCE, Vol.113, No.2, pp.345-351 (1987).Tay, J.H., “Bricks manufactured from sludge,” J. Environmental Engineering, ASCE, Vol.113, No.2, pp.278-284 (1987).Tay, J.H., and Show, K.Y., “Reuse of wastewater sludge in manufacturing non-conventional construction materials - an innovative approach to ultimate sludge disposal”, Water Science and Technology, Vol.26, No.5-6, pp.1165-1174 (1992).Tay, J.H., and Show, K.Y., “The use of lime-blended sludge for production of cementitious material”, Water Environment Research, Vol.64, No.1, pp.6-12 (1992).Tay, J.H., and Show, K.Y., “Municipal wastewater sludge as cementitious and blended cement materials,” Cement Concrete Composites, Vol.16, pp.39-48 (1994).Tay, J.H., and Yip, W.K., “Sludge ash as lightweight concrete material”, J. Environmental Engineering, ASCE, Vol.115, No.1, pp.56-64 (1989).Tay, J.H., Yip, W.K., and Show, K.Y., “Clay-blended sludge as lightweight aggregate concrete material”, J. Environmental Engineering, ASCE, Vol.117, No.6, pp.834-844 (1991).Torrents, J.M., Roncero, J., and Gettu, R., “Utilization of impedance spectroscopy for studying the retarding effect of a superplasticizer on the setting of cement”, Cement Concrete Research, Vol.28, No.9, pp.1325-1333 (1998).Trauner, E.J., “Sludge ash bricks fired to above and bellow ash-vitrifying temperature”, J. Environmental Engineering, ASCE, Vol.119, No.3, pp.506-519 (1993).U.S. EPA, Land Application of Biosolids Process Design Manual, U.S. Environmental Protection Agency, Cincinnati, Ohio (1996).Vaananen, P., “Fuel, methane gas and fertilisers from sludge”, Asian Water, Vol.14, No.1, pp.32-34 (1998).Wasserman, R., and Bentur, A., “Effect of lightweight fly ash aggregate microstructure on the strength of concrete”, Cement Concrete Research, Vol.27, No.4, pp.525-537 (1997).Wild, S., Discussion of “Mercury porosimetry an inappropriate method for the measurement of pore size distributions in cement-based materials” by S. Diamond, Cement Concrete Research, Vol.31, No.11, pp.1653-1654 (2001).Wild, S., and Khatib, J.M., “Portlandite consumption in metakaolin cement pastes and mortars”, Cement Concrete Research, Vol.27, No.1, pp.137-146 (1997).Xu, G.J.Z., and Watt, D.F., and Hudec, P.P., “Effectiveness of mineral admixtures in reducing ASR expansion”, Cement Concrete Research, Vol.25, No.6, pp.1225-1236 (1995).Yan, P., and You, Y., “Studies of the binder of fly ash-fluorgypsum-cement”, Cement Concrete Research, Vol.28, No.1, pp.135-140 (1998).Yu, Q., Sawayama, K., Sugita, S., Shoya, M., and Isojima, Y., “The reaction between rice husk ash and Ca(OH)2 solution and the nature of its product”, Cement Concrete Research, Vol.29, No.3, pp.37-43 (1999).Zanni, H., Cheyrezy, M., and Maret, V., “Investigation of hydration and pozzolanic reaction in reactive powder concrete (RPC) using 29Si NMR”, Cement Concrete Research, Vol.26, No.1, pp.93-100 (1996).Zhang, M.H., and Malhorta, V.M., “Characteristics of a thermally activated alumino-silicate pozzolanic material and its use in concrete”, Cement Concrete Research, Vol.24, No.5, pp.966-974 (1994).Zhang, C., Wang, A., and Tang, M., “The filling role of pozzolanic material”, Cement Concrete Research, Vol.26, No.6, pp.943-947 (1996).張鎮南、黃俊雄、林世祥,「應用臭氧回收廢棄污泥含碳有機物質之研究」,第10屆下水道技術研討會論文集,台北,pp.95-102 (2000)。詹孟贇、李釗、歐陽嶠暉,「都市下水污泥熔渣細骨材利用可行性之研究」,第十屆廢棄物處理技術研討會論文集,pp.54-63 (1995)。陳立俊、張立、梁鉅銘、林文台、楊哲人、鄭晃忠,材料電子顯微鏡學,修訂版,行政院國家科學委員會精密儀器發展中心,新竹 (1994)。邱承美,儀器分析原理,科文出版社,台北 (1981)。戴岳志、李建賢,「加速推動下水道建設執行對策」,第11屆下水道及水環境再生研討會論文集,台北,pp.1-14 (2001)。黃兆龍,混凝土配比設計與控制,詹氏書局,台北 (2000)。江康鈺、張今濃、黃煌竣,「下水污泥堆肥資源化過程重金屬分佈特性之研究」,第11屆下水道及水環境再生研討會論文集,台北,pp.211-221 (2001)。江康鈺、林鶴年、游世達、嚴浩哲、黃俊傑、林莞慧、王鯤生,「利用堆肥資源化技術處理下水污泥之可行性研究」,第9屆下水道技術研討會論文集,台北,pp.277-290 (1999)。李釗、江少鋒、郭文田,「垃圾焚化灰渣作為混凝土細骨材之可行性研究」,中國環境工程學刊,Vol.7,No.3,pp.289-296 (1997)。林登峰、傅國柱、翁誌煌、曾志晏、邱玟韶,「家庭廢水污泥與黏土燒製成磚之資源化研究」,第9屆下水道技術研討會論文集,台北,pp.291-304 (1999)。林仁益、沈永年、黃兆龍,「29Si NMR解析水灰比、養護溫度與水泥漿體水化行為之相關性」,中國土木水利學刊,Vol.3,pp.255-265 (1991)。林益厚,「內政部營建署署長致詞」,第10屆下水道技術研討會論文集,台北 (2000)。羅鈞瑋、張鎮南、黃俊雄,「應用化學方式加速污泥水解以回收有機成份之研究」,第9屆下水道技術研討會論文集,台北,pp.223-238 (1999)。歐陽嶠暉、許鎮龍、藍文忠,「都市污水處理廠之污泥處理與資源化再利用之研究」,第8屆下水道技術研討會論文集,台北,pp.19-33 (1998)。沈君山、李怡嚴,固態與核子物理,科學圖書社,台北 (1972)。沈得縣、黃兆龍,「高爐熟料與飛灰對新拌水泥漿體水化機理影響之研究」,中國土木水利工程學刊,Vol.3,No.4,pp.333-338 (1991)。田中和博、佐藤和明,「日本下水污泥處理處置及利用近況」,第7屆下水道技術研討會論文集,中壢,pp.17-31 (1996)。蔡攀鰲,土木材料試驗,三民書局,台北 (1986)。曾迪華、葉俊宏,都市污水廠污泥脫水性和燃燒值改良之研究,中央大學土木工程研究所,中壢 (1985)。曾迪華、葉仁博,以機械脫水和自然乾燥法進行污泥脫水性和燃燒值改良之研究,中央大學土木工程研究所,中壢 (1987)。王鯤生、張毓舜、林凱隆、黃尊謙,「下水污泥焚化灰渣組成對燒結材料特性之影響」,第9屆下水道技術研討會論文集,台北,pp.211-222 (1999)。王鯤生、余岳峰、蔡振球、楊志政,「下水污泥焚化灰燒成輕質骨材之條件控制因子探討」,第10屆下水道技術研討會論文集,台北,pp.119-127 (2000)。王鯤生、楊志政、蔡振球、胡趙原,「下水污泥灰矽晶相調質之輕質化燒結特性研究」,第11屆下水道及水環境再生研討會論文集,台北,pp.187-194 (2001)。尾花博,「新資源再利用體系-環保水泥」,87年廢棄物處理與資源回收國際研討會論文集,台北 (1998)。 參考標準方法與規範ASTM C 109/C 109M-98, Standard Test Methods for Compressive Strength of Hydraulic Cement Mortars (Using 2-in or [50-mm] Cube Specimens), American Society for Testing and Materials.ASTM C 136-01, Standard Test Method for Sieve Analysis of Fine and Coarse Aggregates, American Society for Testing and Materials.ASTM C 150-89, Standard Specifications for Portland Cement, American Society for Testing and Materials.ASTM C 187-98, Standard Test Method for Normal Consistency of Hydraulic Cement, American Society for Testing and Materials.ASTM C 188-89, Standard Test Method for Density of Hydraulic Cement, American Society for Testing and Materials.ASTM C 191-01a, Standard Test Method for Time of Setting of Hydraulic Cement by Vicat Needle, American Society for Testing and Materials.ASTM C 204-91a, Standard Test Method for Fineness of Hydraulic Cement by Air Permeability Apparatus, American Society for Testing and Materials.ASTM C 230-97, Standard Specification for Flow Table for Use in Tests of Hydraulic Cement, American Society for Testing and Materials.ASTM C 311-98, Standard Test Methods for Sampling and Testing Fly Ash or Natural Pozzolan for Use as a Mineral Admixture in Portland-Cement Concrete, American Society for Testing and Materials.ASTM C 311-90, Standard Test Methods for Sampling and Testing Fly Ash or Natural Pozzolan for Use as a Mineral Admixture in Portland-Cement Concrete, American Society for Testing and Materials.ASTM C 332-99, Standard Specification for Lightweight Aggregates for Insulating Concrete, American Society for Testing and Materials.ASTM C 494/C 494M-99ae, Standard Specification for Chemical Admixtures for Concrete e, American Society for Testing and Materials.ASTM C 618-98, Standard Specifications for Coal Fly Ash and Raw or Calcined Natural Pozzolan for Use as a Mineral Admixture in Concrete, American Society for Testing and Materials.ASTM C 778-00, Standard Specification for Standard Sand, American Society for Testing and Materials.ASTM D 4404-84, Standard test method for determination of pore volume and pore size distribution of soil and rock by mercury intrusion porosimetry, American Society for Testing and Materials.ASTM E 12-70, Standard Definitions of Terms Relating to Density and Specific Gravity of Solids, Liquids, and Gases, American Society for Testing and Materials.BS 812: Part 3:1975, Testing Aggregates. Methods for Determination of Mechanical Properties, British Standards Institution.BS 3892: Part 1:1997, Pulverised-Fuel Ash-Cementitious Component in Concrete, British Standards Institution.CNS-61,「卜特蘭水泥」,經濟部標準檢驗局。CNS-3036,「卜特蘭水泥混凝土用飛灰及天然或煆燒卜作嵐攙和物」,經濟部標準檢驗局。NIEA R201.10T,「事業廢棄物毒性特性溶出程序」,行政院環境保護署。
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