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論文中文名稱:GFRP模板於鋼筋混凝土牆構件之應用與數值分析之研究 [以論文名稱查詢館藏系統]
論文英文名稱:A Study of GFRP Formworks Applying in Reinforced Concrete Members and Numerical Analysis [以論文名稱查詢館藏系統]
院校名稱:臺北科技大學
學院名稱:工程學院
系所名稱:土木工程系土木與防災碩士班
畢業學年度:106
畢業學期:第二學期
出版年度:107
中文姓名:林祐任
英文姓名:Yu-Jen Lin
研究生學號:105428045
學位類別:碩士
語文別:中文
口試日期:2018/06/30
論文頁數:106
指導教授中文名:李有豐
指導教授英文名:Yeou-Fong Li
口試委員中文名:陳清泉;邱佑宗;徐增興;李有豐
口試委員英文名:Yeou-Fong Li
中文關鍵詞:纖維強化高分子複合材料牆模板有限元素分析
英文關鍵詞:Fiber reinforced plasticsWall formworkFinite element analysis
論文中文摘要:本論文利用強度高、質量輕且耐候性佳之玻璃纖維強化高分子複合材料(Glass Fiber Reinforcement Plastic, GFRP)來取代傳統模板工程中所使用之材料,並進行系統牆模板之設計、分析及現地試驗驗證。本研究是先以不同規格之GFRP格柵透過力學試驗及數值分析,選擇較適宜之構件規格,作為GFRP模板於RC牆構件現地試驗之材料。並將試驗所得之參數代入有限元素分析軟體中,模擬現地實驗之分析,分析結果再與現地試驗結果進行比較,得到GFRP複合材料應用於模板可達到變位小的需求,以驗證本研究GFRP模板於RC牆構件之可行性。最後,為了使本研究之GFRP模板能應用在不同條件下,如挑高樓層設計等,改變模板之高度及橫桿和對鎖之配置,並將結果製成表格,以供土木工程人員應用時之參考。
論文英文摘要:This thesis uses Glass Fiber Reinforcement Plastic (GFRP), which has higher strength, lighter weight, and better resistance to weather compare to the traditional materials, in formworks in engineering. This study simulates the design of wall formworks and compares analyzed results with results from in-situ tests using GFRP composite materials. The approach for the study was conducting an experiment on the mechanical behavior and FEM numerical analysis using different sizes of GFRP grids and choosing the most compatible dimensions for applying GFRP formworks to the construction of RC walls. To ensure feasibility of the RC wall, experimental parameters in FEM software were used to simulate the actual cases and compared to experimental results.The application of GFRP composite material to the formwork can achieve the requirement of small displacement. Finally, in order to apply GFRP formworks under different conditions, such as designing for high stories, the height of formworks along with the location of locks and supports were changed accordingly. Tables with the results from these different conditions were made for future civil engineers to reference.
論文目次:摘要 i
ABSTRACT ii
誌謝 iv
目錄 v
表目錄 vii
圖目錄 ix
第一章 緒論 1
1.1 研究背景 1
1.2 研究動機 2
1.3 研究內容及流程 2
第二章 文獻回顧 5
2.1 GFRP複合材料相關研究 5
2.2 GFRP格柵現有施工案例 23
第三章 GFRP牆模板構件試驗與分析 28
3.1 FRP材料介紹及特性 28
3.1.1 FRP材料介紹 28
3.1.2 GFRP格柵 31
3.1.3 GFRP薄板 32
3.1.4 環氧樹脂 33
3.2 試驗規劃 34
3.2.1 試驗設備 34
3.2.2 GFRP構件選擇與先行測試 36
3.3 GFRP格柵試驗與分析 43
3.4 GFRP構件試驗及分析小結 55
第四章 GFRP牆模板現地試驗與分析 56
4.1 GFRP牆模板現地試驗規劃 56
4.1.1一單元GFRP牆模板製作 56
4.1.2 GFRP牆模板施作規劃 61
4.2 GFRP牆模板現地試驗 62
4.3 牆模板等值E值分析 72
4.3.1 牆模板先行試驗 72
4.3.2 牆模板試驗分析 74
4.3.3 等值E值牆模板分析 76
4.4 GFRP牆模板現地試驗分析 80
4.4.1使用元素介紹 81
4.4.2 現地試驗分析 81
4.5 GFRP牆模板現地試驗與分析小結 88
第五章 GFRP牆模板之設計與分析 89
5.1設計變因 89
5.2設計牆板分析 90
5.3小結 101
第六章 結論 102
參考文獻 104
論文參考文獻:1. Bank, L., Malla, A., Oliva, M., Russell, J., Bentur, A. and Shapira, A., “A model specification for fiber reinforced non-participating permanent formwork panels for concrete bridge deck construction,” Construction and Building Materials, Vol. 23, pp. 2664-2677 (2009).
2. Cottone, A. and Giambanco, G., “Minimum bond length and size effects in FRP–substrate bonded joints,” Engineering Fracture Mechanics, Vol. 76, pp. 1957-1976 (2009).
3. Correia, J., Almeida, N. and Figueira, J., “Recycling of FRP composites: reusing fine GFRP waste in concrete mixtures,” Journal of Cleaner Production, Vol. 19, pp. 1745-1753 (2011).
4. Correia, J., Gomes, M., Pires, J. and Branco, F., “Mechanical behaviour of pultruded glass fibre reinforced polymer composites at elevated temperature: Experiments and model assessment,” Composite Structures, Vol. 98, pp. 303-313 (2013).
5. Fang, H., Xu, X., Liu, W., Qi, Y., Bai, Y., Zhang, B. and Hui, D., “Flexural behavior of composite concrete slabs reinforced by FRP grid facesheets,” Composites Part B, Vol.92, pp. 46-62 (2015).
6. Ferdous, W., Bai, Y., Almutairi, A., Satasivam, S. and Jeske, J., “Modular assembly of water-retaining walls using GFRP hollow profiles:components and connection performances,”Composite Structures, ELSEVIER, (2018).
7. Gai, X., Darby, A., Ibell, T., Evernden, M. and Orr, J., Permanent Participating FRP Formwork for Concrete Floor Slabs, Ph.D. Thesis, University of Bath, Britain (2011).
8. Goyal, R., Mukherjee, A. and Goyal, S., “An investigation on bond between FRP stay-in-place formwork and concrete,” Construction and Building Materials, Vol. 113, pp. 741-751 (2016).
9. Guermazi, N., Tarjem, A., Ksouri, I. and Ayedi, H., “On the durability of FRP composites for aircraft structures in hygrothermal conditioning,” Composites Part B, Vol. 85, pp. 294-304 (2016).
10. Liang, R. and Hota, G., Developments in Fiber-Reinforced Polymer (FRP) Composites for Civil Engineering, Woodhead Publishing, USA (2013)
11. Kim, G., Pilakoutas, K. and Waldron,P., “Development of thin FRP reinforced GFRC permanent formwork systems,” Construction and Building Materials, Vol. 22, pp. 2250-2259 (2008).
12. Kumar, P., Patnaik, A. and Chaudhary, S., “A review on application of structural adhesives in concrete and steel–concrete composite and factors influencing the performance of composite connections,” International Journal of Adhesion and Adhesives, Vol. 77, pp. 1-14 (2017).
13. Norris,T. and Chen, An., “Development of insulated FRP-confined Precast Concrete Sandwich panel with side and top confining plates and dry bond,” Composite Structures, Vol. 152, pp. 400-454 (2016).
14. Russo, S., Ghadimi, B., Lawania, K. and Rosano, M., “Residual strength testing in pultruded FRP material under a variety of temperature cycles and values,” Composite Structures, Vol. 133, pp. 458-475 (2015).
15. Shao, Y. “Characterization of a Pultruded FRP Sheet Pile for Waterfront Retaining Structures,” Journal of Materials in Civil Engineering, Vol. 18, pp. 626-623 (2006).
16. Schober, K., Harte, A., Kliger, R., Jockwer, R., Xu, Q. and Chen, J., “FRP reinforcement of timber structures,” Construction and Building Materials, Vol. 97, pp. 106-118 (2015).
17. Sousa, J., Correia, J., Firmo, J., Cabral-Fonseca, S. and Gonilha, J., “Effects of thermal cycles on adhesively bonded joints between pultruded GFRP adherends,” Composite Structures, (2018).
18. Wattick, J. and Chen, A., “Development of a prototype fiber Reinforced Polymer – Concrete Filled wall panel,” Engineering Structures, Vol. 147, pp. 297-308 (2017).
19. Zhang, B., Masmoudi, R. and Benmokrane, B., “Behaviour of one-way concrete slabs reinforced with CFRP grid reinforcements,” Construction and Building Materials, Vol. 18, pp. 625-635 (2004).
20. Zhang, W., Huang, J., Li, Z. and Huang, C., “An experimental study on the lateral pressure of fresh concrete in formwork,” Construction and Building Materials, Vol. 111, pp. 450-460 (2016).
21. 甘淑婷,混編纖維複合梁構件之三點抗彎實驗及力學行為探討,碩士論文,國立臺北科技大學,臺北(2011)。
22. 陳彥鈞,玻璃纖維強化高分子複合材料I型梁-版系統力學行為之研究,碩士論文,國立臺北科技大學,臺北(2012)。
23. 李有豐,FRP複合材料於土木與建築工程之應用,臺灣區複合材料工業同業公會,臺北(2012)
24. 郭育汝,模組化GFRP防洪板設計與應用,碩士論文,國立臺北科技大學,臺北(2016)
25. 陳敬棋,GFRP模板應用於鋼筋混凝土柱構件之可行性研究,碩士論文,國立臺北科技大學,臺北(2016)
26. https://www.ilosh.gov.tw/menu/1188/1204/sdsp021t0116-%E6%A8%A1%E6%9D%BF%E6%94%AF%E6%92%90%E7%B5%84%E7%AB%8B%E5%8F%8A%E6%8B%86%E9%99%A4%E4%BD%9C%E6%A5%AD/
27. https://kknews.cc/home/l6zmyye.html
28. http://www.appledaily.com.tw/appledaily/article/property/20150831/36751159//
29. http://www.iaa.ncku.edu.tw/~young/pccl/faq.html
30. http://www.hican.com.tw/product-detail-573442.html
31. http://www.twce.org.tw/info/%E6%8A%80%E5%B8%AB%E5%A0%B1/387-2-2.htm
論文全文使用權限:同意授權於2018-08-13起公開