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完整後設資料紀錄
DC 欄位 | 值 | 語言 |
---|---|---|
dc.contributor.advisor | 蔡曜陽 | |
dc.contributor.author | Jen-Han Tsai | en |
dc.contributor.author | 蔡仁瀚 | zh_TW |
dc.date.accessioned | 2021-06-16T08:45:35Z | - |
dc.date.available | 2013-09-02 | |
dc.date.copyright | 2013-09-02 | |
dc.date.issued | 2013 | |
dc.date.submitted | 2013-08-20 | |
dc.identifier.citation | 1.郭文雄, 複合材料, 高立出版社, 1998.
2.郭文雄, 複合材料纖維學, 全威出版社, 2002. 3.B. W. Rosen, “Tensile failure of fibrous composites” AIAA journal, Vol. 2/11, pp.1985-1991, 1964. 4.A. C. Loos and G. S. Springer, “Curing of epoxy matrix composites”, Journal of composite materials, Vol. 17/2, pp.135-169, 1983. 5.J. M. Tang, W. I. Lee and G. S. Springer, “Effects of cure pressure on resin flow, voids, and mechanical properties”, Journal of composite materials, Vol.21/5, pp. 421-440, 1987. 6.W. Wenger, G. R. Dickson, R. McIlhagger and P. P. Miller, 'The surface-finish characteristics of composite components', Journal of materials processing technology, Vol. 33/4, pp. 439-452, 1992. 7.L. H. Strait, M. L. Karasek, and M. F. Amateau, “Effects of stacking sequence on the impact resistance of carbon fiber reinforced thermoplastic toughened epoxy laminates” , Journal of Composite Materials, Vol.26/12 , pp. 1725-1740, 1992. 8.de Almeida, Sergio Frascino Muller and Zabulon dos Santos Nogueira Neto. “Effect of void content on the strength of composite laminates.” Composite structures, Vol.28/2, pp. 139-148, 1994. 9.P. B. A. U. P. S. Olivier, J. P. Cottu, and B. B. A. U. P. S. Ferret, “Effects of cure cycle pressure and voids on some mechanical properties of carbon/epoxy laminates”, Composites, Vol. 26/7, pp. 509-515, 1995. 10.H. Hamada, N. Oya, K. Yamashita and Z.-I Maekawa, “Tensile strength and its scatter of unidirectional carbon fiber reinforced composites”, Journal of Reinforced Plastics and Composites, Vol. 16/2, pp. 119–130, 1997. 11.Seunghan Shin and Jyongsik Jang, “Fractographical analysis on the mode II delamination in woven carbon fiber reinforced epoxy composites”, Journal of materials science 34.21, pp. 5299-5306, 1999. 12.M. Neitzel, M. Blinzler, K. Edelmann, and F. Hoecker, “Surface quality characterization of textile‐reinforced thermoplastics”, Polymer composites, Vol.21/4, 630-635, 2000. 13.Michelle Leali Costa, Sergio Frascino M. de Almeida and Mirabel Cerqueira Rezende, “The influence of porosity on the interlaminar shear strength of carbon/epoxy and carbon/bismaleimide fabric laminates.” Composites Science and Technology, Vol. 61/14, pp. 2101-2108, 2001. 14.Xinbao Yang, A. Nanni, S. Haug, C. L. Sun, “Strength and modulus degradation of carbon fiber-reinforced polymer laminates from fiber misalignment”, Journal of materials in civil engineering, Vol. 14/4, pp.320-326, 2002. 15.Y. Cao and J. Cameron, “The effect of curing conditions on the properties of silica modified glass fiber reinforced epoxy composite”, Journal of reinforced plastics and composites, Vol. 26/1, 41-50, 2007. 16.M. T. Cann, D. O. Adams and C. L. Schneider, “Characterization of fiber volume fraction gradients in composite laminates”, Journal of composite materials, Vol.42/5, pp. 447-466, 2008. 17.M. L. Herring, J. I. Mardel and B. L. Fox, “The effect of material selection and manufacturing process on the surface finish of carbon fibre composites”, Journal of materials processing technology, Vol. 210/6, pp. 926-940, 2010. 18.王文士,厚積層板碳纖維複合材料撓曲與懸臂樑靜態和動態撓曲行為研究,逢甲大學航太與系統工程學系碩士論文,2011. 19.H. Koushyar, S. Alavi-Soltani, B. Minaie, M. Violette, “Effects of variation in autoclave pressure, temperature, and vacuum-application time on porosity and mechanical properties of a carbon fiber/epoxy composite.” Journal of Composite Materials, Vol.46/16, pp. 1985-2004, 2012. 20.M. B. Roller, “Characterization of the time‐temperature‐viscosity behavior of curing B‐staged epoxy resin”, Polymer Engineering & Science, Vol. 15/6, pp. 406-414, 1975. 21.M. Ivankovic, L. Incarnato, J. M. Kenny and L. Nicolais, “Curing kinetics and chemorheology of epoxy/anhydride system”, Journal of Applied Polymer Science, Vol. 90/11, pp. 3012-3019, 2003. 22.T. Edison, U.S. Patent 223, 898, 1880. 23.R. Bacon and M. M. Tang, Carbonization of Cellulose Fibers I, Carbon, Vol. 2, p211, 1964. 24.R. Bacon and C. T. Moses, “High-Performance Polymers—Their Origin and Development”, R.B. Seymour and G.S. Kirshenbaum, Ed., Elseveir, p 341, 1986. 25.W. Schimpf, Advanced Fiber Technologies, personal communication, 2000. 26.J. B. Donnet and R. C. Bansal, Carbon Fibers, 2nd ed., Marcel Dekker, 1990. 27.Tadayuki Matsumoto, “Mesophase pitch and its carbon fibers”, Pure & Appl. Chem, Vol. 57/11, pp. 1553-1562, 1985. 28.J. V. Milanski and H. Katz, “Handbook of Reinforcement of Plastics”, 1987. 29.D. L. Chung, “Carbon Fiber Composites”, Butterworth-Heinemann: Boston, MA, USA, pp. 3–11, 1994. 30.P. J. Walsh and Zoltek, “Carbon Fibers”, ASM Handbook, Vol. 21, 2001. 31.垣內弘, 環氧樹脂應用實務, 複漢出版社, 1981. 32.馬振基, 高分子複合材料, 正中出版社, 1995. 33.F. L. Matthews, R. D. Rawlings, “Composite Materials: Engineering and Science”, 1994. 34.范光照, 表面粗糙度及其量測, 2010. 35.精密量測,中州技術學院機械與電腦輔助工程系精密量測實驗室. | |
dc.identifier.uri | http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/59030 | - |
dc.description.abstract | 由於纖維強化複合材料的諸多優點使其受到廣泛的使用,除了航太業外還有海上運輸業、汽車、運動用品等工業,以利用複合材料達到減重的目的。在許多實例中表面的特徵是很重要的,因量測時發現表面孔隙率對粗糙度的影響很大,固本實驗利用表面孔隙率當做評斷表面特徵的重要性質。另外纖維體積百分比也是一種纖維強化複合材料性質的評斷指標,複合材料主要承受力量的是強化材也就是纖維,當纖維體積百分率不高時,容易使樹脂承受過多力量而提前斷裂,導致層板受損。在本實驗因編織纖維複合層板的纖維體積含率量測較困難,改利用層板剖面的纖維面積百分比來比較纖維在層板中的含量。
本實驗使用Toray公司所生產,型號T300-3K的碳纖維1x1平織布與Huntsman公司所生產,型號AralditeRLY556的環氧樹脂溶液及AradurR917的硬化劑和DY 070的加速劑,利用手積法將樹脂塗佈於纖維布上,再使用真空袋熱壓法,製作複合材料層板。並對其固化製程中之參數對表面孔隙率及剖面纖維面積百分比進行探討。 實驗結果顯示編織纖維強化複合材料層板表面會有許多孔隙存在於富含樹脂區,固化壓力與升溫速率均會影響表面孔隙率,而最主要的影響變因是升溫速率。較低的升溫速率導致較低的表面孔隙率0.118%,因較高的升溫速率會提高樹脂在凝膠化前產生交聯反應的比率,導致樹脂的黏性上升,流動性減少,無法填補孔隙。較低的升溫速率導致較高的纖維面積百分比76.3%,與前面的論點相同,樹脂在凝膠化就開始交聯反應,導致樹脂的流動性降低並限制在層板間,多餘的樹脂無法因擠壓而被排出。 | zh_TW |
dc.description.abstract | Composite materials are widely used in many applications, not only in the aerospace industry but also in the marine, automotive, sports goods industries. In many examples surface characteristic is critical, or at least important, since it reduces skin friction, drag and fuel consumption, in addition, a good surface appearance is a cosmetic necessity. Besides, fiber volume fraction is an important indicator of composites property. The fiber is used to reinforce material which is the main part in composite to bear the load. While the fiber volume fraction is low, the resin will break with too much loading and hence the composite will be damaged.
The Toray T300-3K and Huntsman AralditeRLY556 epoxy resin, AradurR917 hardener, DY070 accelerator was used and applying hand lay-up process and hot compress vacuum bag to make composite. Then, investigate the influence of curing parameter on the surface characteristic and fiber volume fraction. It shows that there will be many porosity in the resin-rich area of the woven fiber –reinforced composite. The curing pressure and the heating rate both have effect on the surface porosity and heating rate is the most influential factor. The higher heating rate raise the cross-linking rate prior to gel and cause higher viscosity, lower resin flow as a result of surface porosity entrapment. The higher heating rate reduce the fiber volume fraction because of the high cross-linking rate prior to gel, which leads to low resin flow and restricted resin which can’t be squeezed out by compressing in the composite. | en |
dc.description.provenance | Made available in DSpace on 2021-06-16T08:45:35Z (GMT). No. of bitstreams: 1 ntu-102-R00522707-1.pdf: 6381226 bytes, checksum: 4abfdae357959d97c6bed8e351bdefc3 (MD5) Previous issue date: 2013 | en |
dc.description.tableofcontents | 論文審定書 I
誌謝 II 摘要 IV Abstract V 目錄 VI 圖目錄 IX 表目錄 XIII 第一章 緒論 1 1.1 研究背景 1 1.2 論文回顧 2 1.3 研究目的 10 1.4 本文架構 11 第二章 相關背景知識與技術理論 13 2.1 碳纖維 13 2.1.1 PAN碳纖維 15 2.2 環氧樹脂 16 2.2.1 環氧樹脂之特性 16 2.2.2 環氧樹脂的固化反應 16 2.2.3 樹脂性質影響纖維與基材之鍵結強度 18 2.3 複合材料纖維補強理論 18 2.4 纖維與樹脂介面 20 2.4.1 介面接著理論 20 2.5 表面粗糙度理論 24 2.5.1 表面組織定義 24 2.5.2 表面量測相關術語 25 2.5.3 表面粗糙度表現方式 27 第三章 實驗方法與設備 31 3.1 實驗規劃 31 3.2 研究規劃流程圖 32 3.3 實驗方法 33 3.3.1 材料 33 3.3.2 試片製作 34 3.3.3 實驗參數 35 3.3.4 表面孔隙率分析法 37 3.3.5 纖維體積百分率分析法與剖面纖維面積百分比 39 3.4 實驗設備 40 3.4.1 精密電子天秤 40 3.4.2 熱壓機 41 3.4.3 光學顯微鏡 42 3.4.4 金相低速精密切割機 43 3.4.5 表面粗度儀 44 第四章 實驗結果與討論 45 4.1 表面粗糙度量測 45 4.2 表面孔隙率 50 4.2.1 表面形貌觀察 50 4.2.2 表面孔隙率及孔隙於表面分部情形 51 4.2.3 壓力對孔隙率之影響 60 4.2.4 升溫速率對孔隙率之影響 61 4.3 剖面纖維面積百分比 63 第五章 結論與未來展望 71 5.1結論 71 5.2 未來展望 72 參考文獻 73 | |
dc.language.iso | zh-TW | |
dc.title | 固化製程參數對編織碳纖維強化複合材料的表面特徵及纖維體積百分率之影響 | zh_TW |
dc.title | The effect of curing parameter on the surface characteristic and fiber volume fraction of a woven carbon fiber composite | en |
dc.type | Thesis | |
dc.date.schoolyear | 101-2 | |
dc.description.degree | 碩士 | |
dc.contributor.oralexamcommittee | 張仁安,楊申語 | |
dc.subject.keyword | 碳纖維,孔隙,固化,纖維體積百分率, | zh_TW |
dc.subject.keyword | carbon fiber,porosity,cure,fiber volume fraction, | en |
dc.relation.page | 76 | |
dc.rights.note | 有償授權 | |
dc.date.accepted | 2013-08-20 | |
dc.contributor.author-college | 工學院 | zh_TW |
dc.contributor.author-dept | 機械工程學研究所 | zh_TW |
顯示於系所單位: | 機械工程學系 |
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