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研究生: 陳紀廷
Chi-ting Chen
論文名稱: 點承與摩擦基樁負摩擦力之模型試驗
A study of negative skin friction developing in point bearing pile and friction pile
指導教授: 黃俊鴻
Jyun-hong Huang
口試委員:
學位類別: 碩士
Master
系所名稱: 工學院 - 土木工程學系
Department of Civil Engineering
畢業學年度: 96
語文別: 中文
論文頁數: 133
中文關鍵詞: 模型試驗中立點樁基礎負摩擦力
外文關鍵詞: negative skin friction, piles, downdrag, neutral plane, model test
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    • 本研究利用中央大學自行設計之基樁負摩擦力量測系統,探討樁體在工作載重條件下,因鄰近地表覆土壓力增加而形成之土層壓密,所造成樁身承受負摩擦力之現象。並變化點承土層之性質,以模擬點承樁與摩擦樁之負摩擦力發展情形。試驗過程以循環加載方式逐步增加及減少覆土壓力,並利用樁體各深度黏貼之應變計電阻值的變化,可得知樁身軸力分佈情形進而推算樁表面單位面積摩擦力隨深度的變化、下拉荷載隨壓密時間的發展情形,以及負摩擦力因土體回漲而減少的情形;並以樁頂、土表沉陷量配合壓密理論來推估樁、土相對位移與摩擦力之間的關係。由試驗結果得知,點承樁所受下拉荷載遠大於摩擦樁,承載砂層在樁體產生有限沉陷時即可發揮承載效果以承受下拉力與工作載重;而摩擦樁試驗中,由於樁體產生較大沉陷量,而拉高中立點位置,使負摩擦力影響範圍減少。由於摩擦樁受下拉力造成的軸力增量遠小於點承樁之情形,故建議在需求承載力不高時,可藉由摩擦樁設計方式,減少因下拉力而提昇的樁身強度要求,所造成的工程成本的增加。

    Negative skin friction is one of the most common problems in the design of pile foundations in soft soils, which is governed by soil slip behavior at the pile-soil interface, and highly depends on friction coefficient of interface, surface loading, and axial load. The research designed two types of long-term model pile tests under working load situation, point bearing pile and friction pile, to discuss the mechanism of negative skin friction in different kinds of end bearing layers when its surrounding ground consolidated in multi-stage, which is cyclically added on the ground surface. From the research results, the neutral plane of point bearing pile appears at about 85-90% of the compressible layer, and the incremental axial force of pile rises to 50kg when the surcharge increases to 1kg/cm2. In case of friction pile, the settlement of pile is larger than the one of point bearing pile. The neutral plane obviously moves downward as the surcharge and compact time increases, the location of which ranges between 30 to 50% of the pile length. The incremental axial force of pile rises to 14kg when the surcharge increases to 1kg/cm2. Due to negative skin friction highly developing in point bearing pile, it is suggested to adopt fiction pile for lowering construction cost when the construction only needs low demand of bearing capacity.

    摘要 ·················································· I ABSTRACT ··············································II 目錄··················································III 圖目錄··················································V 表目錄··················································X 第一章 緒論·············································1 1.1 前言················································1 1.2 研究動機與目的 ······································2 1.3 研究方法與流程 ······································3 1.4 論文架構············································3 第二章 文獻回顧·········································4 2.1 基樁與土壤間之摩擦性質····························· 4 2.2 負摩擦力發生之機制·································11 2.3 基樁負摩擦力之估計·································14 2.3.1 中立點位置·······································14 2.3.2 單樁負摩擦力之推求·······························16 2.4 基樁負摩擦力之研究回顧·····························23 2.4.1 現場量測法·······································23 2.4.2 室內模型試驗法···································25 2.4.3 數值分析法·······································29 第三章 單樁負摩擦力模型試驗····························33 3.1 試驗規劃與設計·····································33 3.2 試驗土樣···········································33 3.3 試驗儀器與相關設備·································35 3.3.1 移動式霣降機·····································35 3.3.2 大型壓密儀與模型試驗箱···························36 3.3.3 模型計測樁·······································40 3.3.4 荷載施加設備·····································45 3.4 各式感應器之校正···································52 3.5 試驗方法···········································56 3.5.1 試體製作·········································56 3.5.2 模型樁之負摩擦力試驗·····························61 3.5.3 土體性質之相關試驗·······························63 第四章 試驗結果與分析··································67 4.1 模型樁貫樁及靜置過程之受力反應·····················67 4.2 施加覆土應力下之土壤壓密沉陷行為···················71 4.3 點承樁試驗施加覆土應力下土壤壓密與負摩擦力發展·····73 4.3.1 各階壓密對點承樁軸力之影響·······················78 4.3.2 各階壓密對點承樁表面摩擦力之影響·················86 4.3.3 循環試驗對於點承樁軸力分佈之影響·················91 4.4 摩擦樁施加覆土應力下之土壤壓密與負摩擦力發展·······94 4.4.1 各階壓密對摩擦樁軸力之影響·······················98 4.4.2 各階壓密對摩擦樁表面摩擦力之影響················104 4.4.3 循環加壓解壓對於摩擦樁軸力之影響················108 4.5 承載機制對負摩擦力發展的影響······················111 第五章 結論與建議·····································113 5.1 結論··············································113 5.2 建議··············································115 參考文獻··············································116

    1.毛懿夫,「基樁負摩擦力之實驗研究」,碩士論文,國立中央大學土木工程學系,中壢(1987)。
    2.王韋舜,「基樁抗壓與抗拉極限承載力之差異」,碩士論文,國立中央大學土木工程學系,中壢(2004)。
    3.王維漢,「單樁負摩擦力之行為研究」,碩士論文,國立中央大學土木工程學系,中壢(1997)。
    4.王獻增,「台北盆地黏性土壤不排水剪力強度之研究」,碩士論文,國立中央大學土木工程學系,中壢(2000)。
    5.謝依航,「基樁負摩擦力之模型試驗」,碩士論文,國立中央大學土木工程學系,中壢(2006)。
    6.林杏性,「黏性土壤與不同材質基樁間之摩擦特性」,碩士論文,國立中央大學土木工程學系,中壢(1992)。
    7.內政部營建署,「建築技術規則建築構造篇基礎構造設計規範」,中華民國建築學會,第24~25頁,(1988)。
    8.日本鋼管樁協會,「表面負摩擦力之作用」,鋼管樁協會報告第二號(1978)。
    9.張惠文、廖新興、陳國隆,「黏性土壤與剛材間之摩擦特性」,中華民國第十四屆全國力學會議,中壢,第841~850頁,(1990)
    10.梁能,「基樁軸向承載之依時行為」,博士論文,國立中央大學土木工程學系,中壢(2003)。
    11.譚志豪,「黏土壓縮與壓密行為之研究」,博士論文,國立中央大學土木工程學系,中壢(2002)。
    12.蔡雅惠,「降水引致單樁基礎負摩擦力行為之有限元素分析」,碩士論文,國立中央大學土木工程學系,中壢(2001)。
    13.楊麗文、陳敏雄、張瑞佳、謝百鍾,「以現地試驗調查中和地區黏土之工性質」,地工技術雜誌,第36期,第20~32頁,(1991)。
    14.歐晉德,「基樁負摩擦力」,地工技術雜誌,第18期,第24~33頁,(1987)。
    15.廖新興,「黏性土壤中鑽掘樁之摩擦特性」,博士論文,國立中央大學土木工程學系,中壢(1995)。
    16.盧玉璜,「黏性土層中基樁之摩擦行為」,碩士論文,國立中央大學土木工程學系,中壢(1993)。
    17.Alonso, E.E., Josa, A., and Ledesma, A., “Negative Skin Friction on Pile:A simplified Analysis and Prediction Procedure.” Geptechnique, Vol.34, No.3, pp.341~357 (1984).
    18.Azzous, A.S., Baligh, M.M., and Whittle, A.J., “Shaft Resistance of Piles in Clay” Journal of Geotechnical Engineering, ASCE, Vol.116, No.2, pp.205~221 (1990).
    19.Baligh, M.M., and Vivatrat, V., “A Manual on Prediction of Pile Downdrag on End Bearing Piles” National Technical Information Service ,Source Data: u7616 (1975).
    20.Bjerrum, L., Johannesson, I.J., and Eido, O., “Reduction of Skin Friction on Steel Piles to Rock” Proceedings of the 10th International Conference on Soil Mechanics and Foundation Engineering, Vol.2, pp.27~34 (1969).
    21.Bowles, J.E., Foundation Analysis and design, 4th Edition, Mc Graw-Hill Book Company, pp.745~753, pp.843~848 (1988).
    22.Comodromos, E.M., and Bareka, S.V., “Evaluation of Negative Skin Friction Effects in Pile Foundations Using 3D Nonlinear Analysis” Computers and Geotechnics, Vol.32, No.3, pp.210~221 (2005).
    23.Endo, M., Minou, K., and Shibata, T., “Negative skin Friction Acting on Steel Pipe Piles in Clay” Proceedings of the 8th International Conference on Soil Mechanics and Foundation Engineering, Vol.2, paper 85~92 (1969).
    24.Fellenius, B.H., “Unified design of piles and pile groups.” Transportation Research Board, Washington, TRB Record 1169, pp.75~82(1989) .
    25.Fellenius, B.H., and Broms, B.B., “Negative Skin Friction for Long Piles Driven in Clay” Proceedings of the 7th International Conference on Soil Mechanics and Foundation Engineering, Vol.2, paper 93~97 (1969).
    26.Fellenius, B.H., “Results from long-term measurement in piles of drag load and downdrag” Canadian Geotechnical Journal, Vol.43, pp.409~430 (2006).
    27.Fellenius, B.H., Harris, D., and Anderson, D.G.“Static loading test on a 45 m long pipe pile in Sandpoint, Idaho” Canadian Geotechnical Journal, Vol.41, pp.613~628 (2004).
    28.Indraratna, B., Balasubramanian, A.S., Phamvan, P., and Wong, Y.K., “Development of Negative Skin Friction on Driven Piles in Soft Bankok Clay” Canadian Geotechnical Journal, Vol.29, pp.393~404 (1992).
    29.Johannessen, I.J., and Bjerrum, L., “Measurement of the Compression of a Steel Pile to Rock due to Settlement of Surrounding Clay” Proceedings of the 6th International Conference on Soil Mechanics and Foundation Engineering, Vol.2, pp.261~264 (1965).
    30.Jeong, S., Lee, J., and Lee, C.J., ”Slip Effect at the Pile-Soil Interface on Dragload” Computers and Geotechnics, Vol.31, No.2, pp.115~126 (2004).
    31.Kerisel, J., “Old Structures in Relation to Soil Condition” Geotechnique, Vol.25, No.3, pp.433~483 (1976).
    32.Leung, C.F., Liao, B.K., Chow, Y.K., and Kog, Y.C., ”Behavior of Pile Subject to Negative Skin Friction and Axial Load” Soils and Foundations, Vol.44, No.6, pp.17~26 (2004).
    33.Lim, C.H., Chow, Y.K., and Karunaratne, G.P., ”Negative Skin Friction on Single Piles in a Layered Half-Space” International Journal for Numerical and Analytical Methods in Geomechanics, Vol.17, No.9, pp.625~645 (1993).
    34.Meyerhof, G.G., ”Bearing Capacity and Settlement of Pile Foundation” Journal of Geotechnical Engineering, ASCE, Vol.102, No.3, pp.195~228 (1976).
    35.Parry, R.H., and Swain, C.W., “ Effective Stress Methods of Calculating Skin Friction on Driven Piles in Soft Clay” Ground Engineering, Vol.10, pp.24~26 (1977).
    36.Potyondy, J.G., “Skin Friction between Various Soil and Construction Materials” Geotechnical, Vol.11, No.4, pp.339~353 (1961).
    37.Poulos, H.G., “Pile Behaviour-Theory and Application” Geotechnique, Vol.39, No.3, pp.365~415 (1989).
    38.Poulos, H.G., and Davis, E.H., Pile Foundation Analysis and Design, Series in Geotechnical Engineering, (1975).
    39.Poulos, H.G.and Davis, E.H., “Prediction of Downdrag Force in End-Bearing Piles” Journal of Geotechnical Engineering, ASCE, Vol.101, No.2, pp.189~204 (1975).
    40.Shibata, T., Sekiguchi, H., and Yukitomo H., “Model Test and Analysis of Negative Skin Friction Acting on Piles” Soils and Foundation, Vol.22, No.2, pp.29~39 (1982).
    41.Tomlinson, M. J., “Some Effects of Pile Driving on Skin Friction,” Behavior of Piles, London, Institute of Civil Engineering, pp.107-114(1971).
    42.Wong, K.S.and Teh, C.I., “Negative Skin Friction on Piles in Layered Soil Deposits” Journal of Geotechnical Engineering, Vol.121, No.6, pp.457~465 (1995).

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