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完整後設資料紀錄
DC 欄位 | 值 | 語言 |
---|---|---|
dc.contributor.advisor | 詹穎雯 | |
dc.contributor.author | Ke-Ling Shih | en |
dc.contributor.author | 施克陵 | zh_TW |
dc.date.accessioned | 2021-06-17T04:27:42Z | - |
dc.date.available | 2019-08-16 | |
dc.date.copyright | 2018-08-16 | |
dc.date.issued | 2018 | |
dc.date.submitted | 2018-08-13 | |
dc.identifier.citation | [1]Sayahi, F. 2016. Plastic shrinkage cracking in concrete(Doctoral dissertation).
[2]Kellerman, J. and Crosswell, S. 2009. Fulton’s concrete technology. Midrand, South Africa: Cement & Concrete Institute. [3]Slowik, V., Schmidt, M. & Fritzsch, R. 2008. Capillary Pressure in fresh cement-based materials and identification of the air entry value. Cement & Concrete Composites, 30: 557-565. [4]Slowik, V., Schmidt, M. & Villmann, B. 2010. Capillary shrinkage cracking – experiments and numerical simulation. [5]Maritz, J.-L., 2012. An Investigation on the Use of Low Volume - Fibre Reinforced Concrete for Controlling Plastic Shrinkage Cracking, Stellenbosch: Thesis presented in fulfilment of the requirements for the degree Master of Science in Engineering at Stellenbosch University. [6]Combrinck, R., 2011. Plastic shrinkage cracking in conventional and low volume fibre reinforced concrete, Stellenbosch: Thesis presented in partial fulfilment of the requirements for the degree Master of Science in Engineering at the University of Stellenbosch. [7]Dippenaar, J.D., 2015, The tensile properties of early age concrete and the experimental apparatus required for its determination, MEng (Research) Thesis, Stellenbosch University. [8]Illston, J. & Domone, P., 2001. Construction materials: their nature and behaviour. New York: CRC Press. [9]Wittmann, F.H. 1976. On the Action of Capillary Pressure in Fresh Concrete. Cement and Concrete Research, 6(1):49-56. [10]Doa, V. T. N., Dux, P. F., Morris, P. H. & O'Moore, L. O., 2010. Plastic shrinkage cracking of concrete. Australian Journal of Structural Engineering, pp. 207-214. [11]Powers, T. C., 1968. The Properties of Fresh Concrete. New York: John Wiley & Sons. Inc. [12]Owens, G., 2012. Fundamentals of concrete. 2nd ed. Midrand: Cement & Concrete Institute. [13]Combrinck, R. & Boshoff, W. P., 2012a. Influence of restraint on the early age cracking of concrete. Guimarães, BEFIB2012. [14]Kronlof, A., Markku, L., & Sipari, P. 1995. Experimental study on the basic phenomena of shrinkage and cracking of fresh mortar. Cement and Concrete Research, 25:1747-1754. [15]Uno, P. J., 1998. Plastic Shrinkage Cracking and Evaporation Formulas. ACI Materials Journal, 95(4), pp. 365-375. [16]Mehta, P. K. & Monteiro, P., 2014. Concrete: microstructure, properties, and materials. Fourth edition. New York: McGraw-Hill Professional 2014. [17]Kwak, H. G. & Ha, S. J., 2006. Plastic shrinkage cracking in concrete slabs. Part II: numerical. Magazine of Concrete Research, 58(8), pp. 517-532. [18]Addis, Brian. 1998. Fundamentals of Concrete. Midrand: Cement and Concrete Institute. [19]Hannant, D. J., 1978. Fibre Cements and Fibre Concretes. New York: John Wiley & Sons. [20]Daniel, J.I., (ACI 544.1R-96). 2001. Report on Fiber Reinforced Concrete. American Concrete Institute. [21]Wongtanakitcharoen, T. 2005. Effect of Randomly Distributed Fibres on Plastic Shrinkage Cracking of Cement Composites. Michigan: The University of Michigan. (PHD-thesis). [22]Forrester, R.G. 2004, “Crypsystem” Treatment Process Enhances Polypropylene Fibre Reinforcement Performance in Shotcrete and Concrete: Magaliesburg: Omega Consulting Services. [23]Golding. 1959. Polymers and Resins. D. Van Nostrand Co. [24]Halse, Y. Koerner, R.M. and Lord, A.E. 1987. Effect of High Levels of Alkalinity on Geotextiles. Geotextiles and Geomembranes, 5: 261-282. [25]Zeiml, M., Leithner, D., Lackner, R. & Mang, H.A. 2006. How do polypropylene fibres improve the spalling behaviour of in-situ concrete?. Cement and Concrete Research, 36:929-942. [26]Johnston, C.D. 2001. Fiber-Reinforced Cements and Concretes. New York: Taylor & Francis. [27]Banthia, N., (ACI 544). 2005. State of the Art Report on Synthetic Fibre-Reinforced Concrete. American Concrete Institute. [28]Pelisser, F. 2010. Effect of the addition of synthetic fibers to concrete thin slabs on plastic shrinkage cracking. Construction and Building Materials, 24: 2171 – 2176. [29]Bagherzadeh, R., Sadeghi, A. and Latifi, M. 2011. Utilizing polypropylene fibers to improve physical and mechanical properties of concrete. Textile Research Journal, 00 (00) 1-9. [30]Banthia, N. and Gupta, R. 2006. Influence of polypropylene fiber geometry on plastic shrinkage cracking in concrete. Cement and Concrete Research, 36: 1263-1267. [31]Qi, C., 2003. Quantitative assessment of plastic Shrinkage cracking and its effect on the corrosion of steel reinforcement. PhD thesis. Indiana, United States of America: Purdue University. [32]Abdulrahman, A. 1995. Effects of low volume fractions of polypropylene fiber on the plastic shrinkage cracking. The fourth Saudi engineering conference. 1995. [33]WP Boshoff. December 2012, Plastic Shrinkage Cracking of Concrete Part 2: Commentary. [34]ASTM C1579 , Standard Test Method for Evaluating Plastic Shrinkage Cracking of Restrained Fiber Reinforced Concrete (Using a Steel Form Insert). [35]CNS 1176 , Method of slump test for concrete. [36]ASTM C232 , Standard Test Method for Bleeding of Concrete. [37]ASTM C403 , Standard Test Method for Time of Setting of Concrete Mixture by Penetration Resistance. [38]Ma, Y., Tan, M. and Wu, K. 2002. Effect of different geometric polypropylene fibers on plastic shrinkage cracking of cement mortars. Materials and Structures, 35: 165-169, April. [39]Kronlof, A., Markku, L., & Sipari, P. 1995. Experimental study on the basic phenomena of shrinkage and cracking of fresh mortar. Cement and Concrete Research, 25:1747-1754. | |
dc.identifier.uri | http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/70415 | - |
dc.description.abstract | 新拌混凝土於澆置的數小時內會發生塑性收縮,而此種收縮會導致裂縫的產生,亦即塑性收縮裂縫。通常較容易發生在表面積比體積大很多的混凝土表面,而該裂縫的產生容易使有害物質侵入混凝土中,侵蝕混凝土以及加速內部鋼筋的腐蝕,影響混凝土結構的美觀、耐久性、使用性以及力學性質。而影響塑性收縮裂縫發生的因素有很多種,包括混凝土的配比、泌水量、初凝時間、環境條件以及束制條件等等,而這些因素之間會互相影響,因此塑性收縮裂縫的發生機制其實是複雜的。
為了防範塑性收縮裂縫的發生,通常使用的方法為灑水養護,讓混凝土表面保持濕潤的狀態,避免表面顆粒間的毛細管壓力上升,導致塑性收縮裂縫的發生。而添加高分子纖維於混凝土中也是另一種預防的方式,利用纖維與混凝土漿體間的介面剪切黏結應力,提高混凝土於塑性狀態下的抗拉強度,減少塑性收縮裂縫的形成。隨著環保意識抬頭,將回收材料製作成高分子纖維並應用於混凝土中,未來會逐漸地朝這個方向進行,而本研究將針對高分子纖維對於塑性收縮裂縫面積之間的關係進行探討。 本研究進行了泌水試驗、蒸發量的量測、初終凝試驗以及塑性收縮裂縫試驗,探討不同水灰比、環境條件以及束制條件對混凝土塑性收縮裂縫的影響,並選擇適當的條件進行低纖維體積取代率混凝土的塑性收縮裂縫試驗。利用上述所有的試驗結果求出塑性收縮裂縫風險值,並將該數值與最終塑性收縮裂縫面積套入塑性收縮裂縫模型中,比較混凝土塑性收縮裂縫的嚴重程度。 最後將本研究所使用的高分子纖維種類所拌合出來的纖維混凝土其最終塑性收縮裂縫面積與塑性收縮裂縫風險值與一般混凝土的數值進行比較。最終得到本研究所使用的高分子纖維其於不同體積取代率下的纖維折減值,並應用於塑性收縮裂縫風險值的公式中。 | zh_TW |
dc.description.abstract | Plastic shrinkage occurs within several hours after casting and this type of shrinkage causes early age cracking which is known as plastic shrinkage cracking. Concrete with a large surface area compared to its volume are usually tend to form plastic shrinkage cracking. Aggressive substance may enter the cracks, which accelerate the deterioration of concrete and it also induces the exposure of reinforcement causing it to corrode faster. These phenomena will have an impact on the aesthetic value, durability, serviceability and mechanical properties of the concrete structures. There are many factors influencing plastic shrinkage cracking such as mix proportion of concrete, bleeding, initial setting time, environment conditions and restraint. These factors influence each other and change continuously with time, so they complicate the mechanism of plastic shrinkage cracking.
To prevent plastic shrinkage cracking, curing the concrete surface directly after casting is a method that usually adopted. It can keep the surface of concrete wet and avoid capillary pressure to build up causing plastic shrinkage cracking. Adding plastic fibers into concrete is another preventive method. The interfacial shear bond stress between fibers and concrete paste is used to increase the tensile strength of concrete under plastic state and reduce the formation of plastic shrinkage cracking. As the awareness of environmental protection rises, plastic fibers made of recycled materials are applied to concrete, which will gradually proceed in the future. This study will discuss the relationship between plastic fibers and plastic shrinkage cracking area. In this study, the bleeding test, the measurement of evaporation, the setting time test and the plastic shrinkage cracking test were carried out to investigate the effects on the plastic shrinkage cracking of concrete with different water-cement ratios, environmental conditions and restraints. The appropriate conditions were selected to carry out the plastic shrinkage cracking test of concrete with low volume of fibers. The crack prediction value was obtained by using all the above test results, and the value as well as the final crack area were put into the crack prediction model to compare the severity of plastic shrinkage cracking. Finally, the final crack area and the crack prediction values of fiber concrete mixed with the plastic fibers used in this study are compared to the values of general concrete. The fiber risk reduction values of plastic fibers used in this study with different volume substitution were obtained and applied to the equation of crack prediction value. | en |
dc.description.provenance | Made available in DSpace on 2021-06-17T04:27:42Z (GMT). No. of bitstreams: 1 ntu-107-R05521244-1.pdf: 5148301 bytes, checksum: 18c463ac5be04d45239433b8a0442227 (MD5) Previous issue date: 2018 | en |
dc.description.tableofcontents | 誌謝 i
摘要 ii Abstract iii 表目錄 ix 圖目錄 x 第一章、 緒論 1 1.1. 研究動機與目的 1 1.2. 研究範圍與內容 1 1.3. 研究流程圖 2 第二章、 文獻回顧 3 2.1. 塑性收縮裂縫介紹 3 2.2. 塑性收縮裂縫發生機制 4 2.2.1 毛細管壓力 6 2.2.2 空氣進入 7 2.2.3 束制 8 2.2.4 機制概觀 9 2.3. 影響塑性收縮裂縫因素 12 2.3.1 蒸發率 12 2.3.2 泌水 13 2.3.3 初凝以及終凝時間 14 2.3.4 混凝土粒料 17 2.3.5 化學摻料 18 2.4. 塑性收縮裂縫發展模型 20 2.4.1 累積蒸發量(Cumulative evaporation) 20 2.4.2 累積泌水量(Cumulative bleeding) 20 2.4.3 乾燥時間點(Drying time) 21 2.4.4 毛細管壓力(Capillary pressure) 21 2.4.5 空氣進入(Air entry) 21 2.4.6 初凝(Initial set) 21 2.4.7 終凝(Final set) 22 2.4.8 裂縫面積(Crack area) 22 2.5. 低纖維體積取代率混凝土 22 2.5.1 典型的纖維種類和性質 22 2.5.2 優點 24 2.5.3 控制塑性收縮裂縫的機理 24 2.5.4 影響塑性收縮裂縫的纖維特性 25 2.5.5 纖維對於泌水的影響 30 2.6. 塑性收縮裂縫預測模型 32 2.6.1 模型介紹 32 2.6.2 纖維風險折減值 35 第三章、 實驗計畫 37 3.1. 試驗說明 37 3.2. 試驗材料 37 3.2.1 水泥 37 3.2.2 粗粒料 39 3.2.3 細粒料 40 3.2.4 纖維 40 3.2.5 化學摻料 41 3.3. 試驗配比與環境 42 3.4. 試驗量測 44 3.4.1 風速 44 3.4.2 蒸發 44 3.4.3 混凝土溫度 44 3.4.4 裂縫 45 3.5. 試體製作程序 46 3.6. 塑性收縮裂縫試驗 47 3.6.1 試驗說明 47 3.6.2 試驗模具 47 3.6.3 試驗方法 50 3.6.4 試驗儀器 50 3.7. 坍度試驗 53 3.7.1 試驗說明 53 3.7.2 試驗方法 53 3.8. 泌水試驗 55 3.8.1 試驗說明 55 3.8.2 試驗方法 55 3.9. 初凝以及終凝試驗 56 3.9.1 試驗說明 56 3.9.2 試驗方法 56 第四章、 實驗結果與分析 58 4.1. 前言 58 4.2. 影響塑性收縮裂縫的因素 58 4.2.1 水灰比與塑性收縮裂縫關係的結果 58 4.2.2 環境條件與塑性收縮裂縫關係的結果 59 4.2.3 添加束制與塑性收縮裂縫關係的結果 61 4.3. 纖維與混凝土泌水的關係 62 4.3.1 纖維直徑 63 4.3.2 纖維種類 66 4.3.3 纖維體積取代率 69 4.4. 纖維與塑性收縮裂縫的關係 71 4.4.1 纖維直徑 71 4.4.2 纖維種類 72 4.4.3 纖維體積取代率 73 4.5. 塑性收縮裂縫模型 74 4.5.2 低纖維體積取代率混凝土之裂縫結果於塑性收縮裂縫模型中 75 4.5.3 纖維體積取代率與纖維風險折減值 79 第五章、 結論與建議 82 5.1. 結論 82 5.2. 建議 84 參考文獻 85 附錄A 試驗結果 89 | |
dc.language.iso | zh-TW | |
dc.title | 探討高分子纖維抑制混凝土塑性收縮裂縫之效果 | zh_TW |
dc.title | An Investigation into the effect of plastic fibre on plastic shrinkage cracking of concrete | en |
dc.type | Thesis | |
dc.date.schoolyear | 106-2 | |
dc.description.degree | 碩士 | |
dc.contributor.oralexamcommittee | 廖文正,楊仲家 | |
dc.subject.keyword | 高分子纖維,塑性收縮裂縫,低纖維體積取代率混凝土,介面剪切黏結應力,纖維風險折減值, | zh_TW |
dc.subject.keyword | plastic fiber,plastic shrinkage cracking,low volume fiber reinforcement concrete,interfacial shear bond stress,fiber risk reduction, | en |
dc.relation.page | 98 | |
dc.identifier.doi | 10.6342/NTU201803225 | |
dc.rights.note | 有償授權 | |
dc.date.accepted | 2018-08-14 | |
dc.contributor.author-college | 工學院 | zh_TW |
dc.contributor.author-dept | 土木工程學研究所 | zh_TW |
顯示於系所單位: | 土木工程學系 |
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