爐石添加量對超微粒水泥漿體基礎物理性質影響之研究

Ming-Hsien Hsu; 徐名顯

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/29192

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	范正成
dc.contributor.author	Ming-Hsien Hsu	en
dc.contributor.author	徐名顯	zh_TW
dc.date.accessioned	2021-06-13T01:02:39Z	-
dc.date.available	2007-07-27
dc.date.copyright	2007-07-27
dc.date.issued	2007
dc.date.submitted	2007-07-23
dc.identifier.citation	1.米倉亮三、廖洪鈞、林英堂 (2002)，“恆久性灌漿材料與其灌漿砂土之動態行為“　地工技術,第93期5-12頁。 2.林任峰(2005)，“超細水泥漿液滲透灌漿模式之研究”，碩士論文，台北科技大學土木與防災研究所。 3.倪至寬、林任峰(2006)，“超細水泥漿液滲透灌漿之研究”, 臺北科技大學學報, 95年09號。 4.徐尉凱(2002)，“應用蒸氣養護與微波加熱技術於新拌混凝土之可行性研究”，碩士論文，朝陽科技大學營建工程系。 5.黃亦敏、李維峰、林平全、張東源 (2002)，“高細度地質改良材料研發與案例應用分析“　地工技術，第93期13-22頁。 6.黃兆龍(1985)，”固態廢料處理研究方案之二-爐石在混凝土的應用”，財團法人台灣營建研究中心。 7.黃建霖、范正成、楊文仁(2007)，”超微細水泥灌漿材料於砂性粉土層之應用“　地工技術，第111期71-82頁。 8.陳信州(1994)，”水泥混凝土添加爐石提高早期強度策略之研究”，碩士論文，國立中央大學土木工程研究所。 9.陳清泉、陳振川(1987)，”爐石為水泥熟料與填加料對混凝土特性影響之文獻及國外現況調查研究”，財團法人台灣營建研究中心研究報告，TR 76004。 10.傅國柱(2002)，“還原碴取代部份水泥之研究 ”，碩士論文，中央大學土木工程研究所。 11.劉澤融(2000)，“工業廢水污泥灰渣特性及其再利用於水泥砂漿之研究 ”，碩士論文，中央大學環境工程研究所。 12.Brachman, R. W., Martin C. D. Gilliss, S. A.(2004), “Grout Field Trials in Outwash Sands”, Canadian Geotechnical Journal, Vol. 41, pp. 1-11. 13.Breitsprecher, G., Toth, P. Stefan (2003) “Underpinning of a pier by microfine cement grouting and compensation grouting”Geotechnical Special Publication, n 120 I, 2003, pp. 740-751 14.Clarke, W. J., Millard, D . B. Maan Helal, A. M. (1992) “Ultrafine cement Tests and Dam Test Grouting” Grouting, Soil Improvement and Geosynthetics ASCE, Geotechnical Special Publication No. 30, pp. 626-637. 15.Chengzhi, Z., Aiqin, W. and Mingshu, T. (1996), “The Filling Role of PozzolanicMaterial”, Cement and Concrete Research, Vol. 26, No. 6, pp.943-947. 16.Guan, Xuemao; Hu, Shuguang; Guan, Binjun(2002)”Research on properties of microfine cement-based material for grouting”Proceedings in Mining Science and Safety Technology, March, 2002, pp. 582-587 17.Heenan, D., and Naudts, A.(2000).”Advanced Grouting Program at Penn Forest Dam Results in Reduced Construction Costs and High Quality Product. ”Geotechnical News. June. pp. 43-48 18.Helal, M., Krizek, R. J. (1992)，“Preferred orientation of pore structure in cement-grouted sand ” Grouting, Soil Improvement and Geosynthetics ASCE, Geotechnical Special Publication No. 30,pp. 526-540. 19.Hu, S., Guan, X., Ding, Q. (2002)，“Research on optimizing components of microfine high-performance composite cementitious materals” Cement and concrete Research,Vol 32, pp. 1871-1875 20.Ilker, B. T., Veysel, B. E.(2003)，“lnfuence of concrete properties on bleeding and evaporation” Cement and Concrete Research, v 34 , n 2, pp.275-281. 21.Krizek, R. J., Liao, H. J., Borden, R. H. (1992)，“Mechanical Properties of Microfine Cement/Sodium Silicate Grouted sand ” Grouting, Soil Improvement and Geosynthetics ASCE, Geotechnical Special Publication No. 30, pp. 688-699. 22.Liao, H. J. , Borden, R. H., Krizek, R. J. (1992)，“Microfine Cement/Sodium Silicate Grout” Grouting, Soil Improvement and Geosynthetics ASCE, Geotechnical Special Publication No. 30, pp. 676-687. 23.Lois, G. S., Krizek, R. J. (2006)，“ Hydrocarbon Residuals and Containment in Microfine Cement Grouted Sand” Journal of Materials in Civil Engineering, Vol18, No2, ASCE/MARCH/APRIL 2006.pp. 214-228 24.Lois, G. S., Krizek, R. J. (1992)，“Effects of mixing on rheological properties of microfine cement grout” Grouting, Soil Improvement and Geosynthetics ASCE, Geotechnical Special Publication No. 30, pp. 512-525. 25.Naudts, A., Landry, E., “New On-site Wet Milling Technology for the Preparation of Ultrafine Cement-based Grouts ” 26.Paoli, D., Bosco, B., Granata, R., Bruce, D.A. (1992)，“Fundamental Observations on Cement Based Grouts (2) : Microfine Cements and The Cemill Process” Grouting, Soil Improvement and Geosynthetics ASCE, Geotechnical Special Publication No. 30,pp. 486-499. 27.Perret, S., D. Palardy, G. Ballivy, (2000)，“Rheological Behavior and Setting Time of Microfine Cement-Based Grouts”ACI MATERIALS JOURNAL/ July-August 2000, pp. 472-477 28.Perret, S., Khayat, K.H., Gagnon, E., Rhazi, J. (2002)，“ Repair of 130-Year Old Masonry Bridge using High-Performance Cement Grout” JOURNAL OF BRIDGE ENGINEERING, Vol7 No.1, JANUARY 1, 2002. ASCE, ISSN, pp 31-38 29.Schwarz, L. G., Krizek, R. J.(2000) “Evolving morphology of early age microfine cement grout”Geotechnical Special Publication, n 104, 2000, pp. 181-199 30.Thiessen team (2000)“ The Development of Colloidal Mixer Based CRF Systems ” Reschke ,A.E. The Development of Colloidal Mixer Based CRF Systems (present at MINEFILL｀98, Brisbane,Australia,1988)Rev. Aug. 2000.
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/29192	-
dc.description.abstract	本研究旨在探討不同之爐石添加量對超微粒水泥漿體性質之影響。本研究藉由不同爐石添加量以及不同水灰比進行各項試驗，以推求爐石對漿體所造成之影響。試驗內容包括砂漿的單壓、抗彎、抗剪強度試驗以及淨漿穩定性和流動度試驗。試驗結果顯示添加爐石有助於漿體之單壓、抗彎以及抗剪強度，但添加量存在一最佳配比，而最佳配比依水灰比不同會落在不同範圍內，水灰比低於2時爐石添加量以50-70%為最佳，當水灰比介於3-5時則為40-50%。漿體中爐石含量多寡亦會影響漿體之穩定性及流動性，爐石含量越多時，漿體會有越高之穩定性及越差之流動性。而值得注意的是添加爐石對於水灰比介於3-5之漿體的晚期強度提升有較明顯之幫助，這也顯示了在不同水灰比的情況下，添加爐石對漿體亦會產生不同程度之影響。	zh_TW
dc.description.abstract	The object of this study is to investigate the effects of slag content on the basic physical properties of microfine cement grout. Different ratios of slag content and different water to cement ratios (w/c) were used to evaluate the effects of slag content on the grout. The experiments included compressive strength, flexural strength, shear strength of sand grouts, stability and fluidity of net grouts. It was found that compressive strength, flexural strength and shear strength of sand grout increase with slag content. However, there exists an optimum formulation for a specific w/c. while the w/c is less than 2, the optimum slag content ranges from 50% to 70%; while w/c is between 3 to 5, the optimum slag content ranges from 40% to 50%. It was also found that the stability and the fluidity of net grout are affected by slag content. The higher the slag content, The higher the stability and the lower the fluidity. It is noticeable that while w/c ranges from 3 to 5, long term strength of the grout increases significantly because of the existing of slag in the grout, i.e. while w/c are different, the grouts are affected differently because of the slag added to the grouts.	en
dc.description.provenance	Made available in DSpace on 2021-06-13T01:02:39Z (GMT). No. of bitstreams: 1 ntu-96-R94622033-1.pdf: 4694463 bytes, checksum: 4998d2589312f24c6058c794268f8e0c (MD5) Previous issue date: 2007	en
dc.description.tableofcontents	誌謝......................................................i 中文摘要.................................................ii 英文摘要................................................iii 圖目錄...................................................vi 表目錄.................................................viii 第一章　研究動機與目的....................................1 1.1 研究動機..............................................1 1.2 研究目的..............................................2 第二章　文獻回顧..........................................4 2.1 超微粒水泥之發展......................................4 2.2 基本材料性質及應用....................................5 2.3 研磨攪拌技術方面.....................................10 2.4 配比成分影響.........................................12 2.5 卜作嵐效應方面.......................................16 第三章研究方法.........................................20 3.1砂漿單壓及抗彎試驗....................................20 3.1.1試驗材料及設備......................................20 3.1.2試驗流程............................................26 3.2砂漿抗剪試驗..........................................29 3.2.1試驗材料及設備......................................29 3.2.2試驗流程............................................31 3.3淨漿穩定性試驗........................................35 3.3.1試驗材料及設備......................................35 3.3.2試驗流程............................................36 3.4淨漿流動性試驗........................................37 3.4.1試驗材料及設備......................................37 3.4.2試驗流程............................................37 第四章結果與討論.......................................40 4.1砂漿單壓強度..........................................40 4.1.1以水灰比做為控制變因................................40 4.1.2以爐石添加量做為控制變因............................49 4.2砂漿抗彎強度..........................................52 4.2.1以水灰比做為控制變因................................52 4.2.2以爐石添加量做為控制變因............................59 4.3砂漿抗彎強度..........................................59 4.3.1以水灰比做為控制變因................................60 4.3.2以爐石添加量做為控制變因............................61 4.4淨漿穩定性............................................62 4.4.1以水灰比做為控制變因................................62 4.4.2以爐石添加量做為控制變因............................65 4.5淨漿流動度............................................68 4.6綜合比較..............................................69 第五章結論與建議 ......................................72 5.1 結論.................................................72 5.2 後續建議.............................................73 參考文獻.................................................75 附錄.....................................................78
dc.language.iso	zh-TW
dc.subject	穩定性	zh_TW
dc.subject	抗剪強度	zh_TW
dc.subject	抗彎強度	zh_TW
dc.subject	單壓強度	zh_TW
dc.subject	爐石	zh_TW
dc.subject	超微粒水泥	zh_TW
dc.subject	流動性	zh_TW
dc.subject	fluidity	en
dc.subject	stability	en
dc.subject	shear strength	en
dc.subject	flexural strength	en
dc.subject	compressive strength	en
dc.subject	slag	en
dc.subject	microfine cement	en
dc.title	爐石添加量對超微粒水泥漿體基礎物理性質影響之研究	zh_TW
dc.title	Effects of Slag Content on the Basic Physical Properties of Microfine Cement Grout	en
dc.type	Thesis
dc.date.schoolyear	95-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	王藝峰,陳榮河,林炳森
dc.subject.keyword	超微粒水泥,爐石,單壓強度,抗彎強度,抗剪強度,穩定性,流動性,	zh_TW
dc.subject.keyword	microfine cement,slag,compressive strength,flexural strength,shear strength,stability,fluidity,	en
dc.relation.page	77
dc.rights.note	有償授權
dc.date.accepted	2007-07-25
dc.contributor.author-college	生物資源暨農學院	zh_TW
dc.contributor.author-dept	生物環境系統工程學研究所	zh_TW
顯示於系所單位：	生物環境系統工程學系

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