感壓膠測試系統之建立與其力學特性之研究

Yi-Hung Wu; 吳奕鴻

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/29230

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	王安邦(An-Bang Wang)
dc.contributor.author	Yi-Hung Wu	en
dc.contributor.author	吳奕鴻	zh_TW
dc.date.accessioned	2021-06-13T01:03:06Z	-
dc.date.available	2014-08-08
dc.date.copyright	2011-08-08
dc.date.issued	2011
dc.date.submitted	2011-08-04
dc.identifier.citation	1. 楊嘉慧, 讓破鏡也能重圓的黏著劑, in 科學人. 2. 劉大佼, 淺談膠帶, in 科學發展2003: 台灣. p. 26. 3. Test methods for Pressure Sensitive Adhesive Tapes, 1996, Pressure Sensitive Tape Council. 4. Dahlquist, C.A. in Proceedings of the Nottingham Conference on Adhesion. 1966. MacLaren and Sons, London. 5. Dillard, D.A. and A.V. Pocius, The Mechanics of Adhesion. First ed. Adhesion Science and Engineering. Vol. 1. 2002: ELSEVIER. 6. Ferry, J.D., Viscoelastic Properties fo Polymers. 3rd ed1980: John Wiley & Sons, Inc. 7. Schramm, G., A Practical Approach to Rheology and Rheometry. 2nd ed1998, Karlsruhe, Federal Republic of Germany: Gebrueder HAAKE GmbH. 8. Nase, J., Debonding of Viscoelastic Materials: From a Viscous Liquid to a Soft Elastic Solid, 2009. 9. Nase, J., A. Lindner, and C. Creton, Pattern formation during deformation of a confined viscoelastic layer: From a viscous liquid to a soft elastic solid. Physical Review Letters, 2008. 101(7). 10. Duncan, B., S. Abbott, and R. Roberts, Adhesive tack. , in Measurement Good Practice Guide No. 26 1999, The UK's National Measurement Institute. 11. Chaudhury, M. and A.V. Pocius, Surfaces, Chemistry and Applications. First ed. Adhesion Science and Engineering. Vol. 2. 2002: ELSEVIER. 2020. 12. Creton, C., Materials Science of Pressure-Sensitive Adhesives, in Materials Science and Technology: A Comprehensive Treatment, H.E.H. Meijer, Editor 1997, VCH: Weinheim. p. 707. 13. Dahlquist, C.A., Pressure-Sensitive Adhesives, in Treatise on Adhesion and Adhesives, R.L. Patrick, Editor 1969, Marcel Dekker, Inc.: New York. p. 219-260. 14. F. H. Hammond, J., Polyken Probe Tack Tester, in ASTM Special Technical Publication No.3601964, ASTM: Atlantic City, N. J. p. 123. 15. Zosel, A., ADHESION AND TACK OF POLYMERS - INFLUENCE OF MECHANICAL-PROPERTIES AND SURFACE TENSIONS. Colloid and Polymer Science, 1985. 263(7): p. 541-553. 16. Zosel, A., ADHESIVE FAILURE AND DEFORMATION-BEHAVIOR OF POLYMERS. Journal of Adhesion, 1989. 30(1-4): p. 135-149. 17. Lakrout, H., P. Sergot, and C. Creton, Direct observation of cavitation and fibrillation in a probe tack experiment on model acrylic Pressure-Sensitive-Adhesives. Journal of Adhesion, 1999. 69(3-4): p. 307-359. 18. Yamaguchi, T., K. Koike, and M. Doi, In situ observation of stereoscopic shapes of cavities in soft adhesives. Epl, 2007. 77(6). 19. Nase, J., et al., Measurement of the receding contact angle at the interface between a viscoelastic material and a rigid surface. Soft Matter, 2010. 6(12): p. 2685-2691. 20. Chuang, H.K., C. Chiu, and R. Paniagua, Avery Adhesive Test yields more performance data than traditional probe. Adhesives Age, 1997. 40(10): p. 18-23. 21. Roger F. Merrill, J. and H.R. Courtney, Acrylate Microsphere-surfaced Sheet Material, 1974, Minnesota Mining and Manufacturing Company. 22. Mazurek, M.H., R.K. Galkiewicz, and G.M. Benson, Pressure-Sensitive Adhesives Having Microstructured Surfaces, 2007, 3M Innovative Properties Company: US. 23. Kasahara, H., K. Kawashita, and Y. Urahama, Adhesive Product and Transferring Insturment, 2006, Kokuyo S&T Co., Ltd. 24. Autumn, K., et al., Adhesive force of a single gecko foot-hair. Nature, 2000. 405(6787): p. 681-685. 25. Autumn, K., et al., Evidence for van der Waals adhesion in gecko setae. Proceedings of the National Academy of Sciences of the United States of America, 2002. 99(19): p. 12252-12256. 26. Geim, A.K., et al., Microfabricated adhesive mimicking gecko foot-hair. Nature Materials, 2003. 2(7): p. 461-463. 27. Varenberg, M., et al., Effect of real contact geometry on adhesion. Applied Physics Letters, 2006. 89(12): p. 3. 28. Greiner, C., A. del Campo, and E. Arzt, Adhesion of bioinspired micropatterned surfaces: Effects of pillar radius, aspect ratio, and preload. Langmuir, 2007. 23(7): p. 3495-3502. 29. Majumder, A., A. Ghatak, and A. Sharma, Microfluidic adhesion induced by subsurface microstructures. Science, 2007. 318(5848): p. 258-261. 30. Davies, J., et al., A practical approach to the development of a synthetic Gecko tape. International Journal of Adhesion and Adhesives, 2009. 29(4): p. 380-390. 31. Greiner, C., R. Spolenak, and E. Arzt, Adhesion design maps for fibrillar adhesives: The effect of shape. Acta Biomaterialia, 2009. 5(2): p. 597-606. 32. Liu, J.Z., C.Y. Hui, and A. Jagota, Effect of Fibril Arrangement on Crack Trapping in a Film-Terminated Fibrillar Interface. Journal of Polymer Science Part B-Polymer Physics, 2009. 47(23): p. 2368-2384. 33. Jeong, H.E., M.K. Kwak, and K.Y. Suh, Stretchable, Adhesion-Tunable Dry Adhesive by Surface Wrinkling. Langmuir, 2010. 26(4): p. 2223-2226. 34. Spolenak, R., et al., Effects of contact shape on the scaling of biological attachments. Proceedings of the Royal Society of London Series a-Mathematical Physical and Engineering Sciences, 2005. 461(2054): p. 305-319. 35. del Campo, A., C. Greiner, and E. Arzt, Contact shape controls adhesion of bioinspired fibrillar surfaces. Langmuir, 2007. 23(20): p. 10235-10243. 36. Noderer, W.L., et al., Enhanced adhesion and compliance of film-terminated fibrillar surfaces. Proceedings of the Royal Society a-Mathematical Physical and Engineering Sciences, 2007. 463(2086): p. 2631-2654. 37. Lee, J., et al., Gecko-Inspired Combined Lamellar and Nanofibrillar Array for Adhesion on Nonplanar Surface. Langmuir, 2009. 25(21): p. 12449-12453. 38. Murphy, M.P., B. Aksak, and M. Sitti, Gecko-inspired Directional and Controllable Adhesion. Small, 2009. 5(2): p. 170-175. 39. Zhao, B.X., et al., Role of Tilted Adhesion Fibrils (Setae) in the Adhesion and Locomotion of Gecko-like Systems. Journal of Physical Chemistry B, 2009. 113(12): p. 3615-3621. 40. Jeong, H.E., et al., Effect of leaning angle of gecko-inspired slanted polymer nanohairs on dry adhesion. Applied Physics Letters, 2010. 96(4). 41. Sarkar, J., A. Sharma, and V. Shenoy, Adhesion and Debonding of Soft Elastic Films on Rough and Patterned Surfaces. Journal of Adhesion, 2005. 81(3/4): p. 271-295. 42. Autumn, K. and A.M. Peattie, Mechanisms of adhesion in geckos. Integrative and Comparative Biology, 2002. 42(6): p. 1081-1090. 43. Creton, C. and H. Lakrout, Micromechanics of flat-probe adhesion tests of soft viscoelastic polymer films. Journal of Polymer Science Part B-Polymer Physics, 2000. 38(7): p. 965-979. 44. Lindsey, G.H., TRIAXIAL FRACTURE STUDIES. Journal of Applied Physics, 1967. 38(12): p. 4843-&. 45. Lindsey, G.H., et al., THE TRIAXIAL TENSION FAILURE OF VISCOELASTIC MATERIALS, 1963. 46. Crosby, A.J., et al., Deformation and failure modes of adhesively bonded elastic layers. Journal of Applied Physics, 2000. 88(5): p. 2956-2966. 47. Saffman, P.G. and G. Taylor, THE PENETRATION OF A FLUID INTO A POROUS MEDIUM OR HELE-SHAW CELL CONTAINING A MORE VISCOUS LIQUID. Proceedings of the Royal Society of London Series a-Mathematical and Physical Sciences, 1958. 245(1242): p. 312-&. 48. Ben Amar, M. and D. Bonn, Fingering instabilities in adhesive failure. Physica D-Nonlinear Phenomena, 2005. 209(1-4): p. 1-16. 49. Shull, K.R. and C. Creton, Deformation behavior of thin, compliant layers under tensile loading conditions. Journal of Polymer Science Part B-Polymer Physics, 2004. 42(22): p. 4023-4043. 50. Chikina, I. and C. Gay, Cavitation in adhesives. Physical Review Letters, 2000. 85(21): p. 4546-4549. 51. Gent, A.N. and P.B. Lindley, INTERNAL RUPTURE OF BONDED RUBBER CYLINDERS IN TENSION. Proceedings of the Royal Society of London Series a-Mathematical and Physical Sciences, 1959. 249(1257): p. 195-205. 52. Cho, K. and A.N. Gent, CAVITATION IN MODEL ELASTOMERIC COMPOSITES. Journal of Materials Science, 1988. 23(1): p. 141-144. 53. Zosel, A., The effect of bond formation on the tack of polymers. Journal of Adhesion Science and Technology, 1997. 11(11): p. 1447-1457. 54. Zosel, A., The effect of fibrilation on the tack of pressure sensitive adhesives. International Journal of Adhesion and Adhesives, 1998. 18(4): p. 265-271. 55. Creton, C. and L. Leibler, How does tack depend on time of contact and contact pressure? Journal of Polymer Science Part B-Polymer Physics, 1996. 34(3): p. 545-554. 56. Novikov, M.B., et al., Stress relaxation during bond formation and adhesion of pressure-sensitive adhesives. Journal of Adhesion, 2008. 84(2): p. 164-190. 57. Chiche, A., P. Pareige, and C. Creton, Role of surface roughness in controlling the adhesion of a soft adhesive on a hard surface. Comptes Rendus De L Academie Des Sciences Serie Iv Physique Astrophysique, 2000. 1(9): p. 1197-1204. 58. Peykova, Y., et al., The effect of surface roughness on adhesive properties of acrylate copolymers. International Journal of Adhesion and Adhesives, 2010. 30(4): p. 245-254. 59. Chiche, A., J. Dollhofer, and C. Creton, Cavity growth in soft adhesives. European Physical Journal E, 2005. 17(4): p. 389-401. 60. Josse, G., et al., Measuring interfacial adhesion between a soft viscoelastic layer and a rigid surface using a probe method. Journal of Adhesion, 2004. 80(1-2): p. 87-118. 61. 潘柏廷, 精微圖案毛細管塗佈之研究, in 應用力學研究所 2010, 台灣大學: 台北. 62. Ganghoffer, J.F. and A.N. Gent, ADHESION OF A RIGID PUNCH TO A THIN ELASTIC LAYER. Journal of Adhesion, 1995. 48(1-4): p. 75-84. 63. Dollhofer, J., et al., Surface energy effects for cavity growth and nucleation in an incompressible neo-Hookean material - modeling and experiment. International Journal of Solids and Structures, 2004. 41(22-23): p. 6111-6127. 64. Tirumkudulu, M., W.B. Russel, and T.J. Huang, Measuring the 'tack' of waterborne adhesives. Journal of Rheology, 2003. 47(6): p. 1399-1415. 65. Tirumkudulu, M., W.B. Russel, and T.J. Huang, On the measurement of 'tack' for adhesives. Physics of Fluids, 2003. 15(6): p. 1588-1605.
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/29230	-
dc.description.abstract	本研究建立起一套重複性良好的探棒式測試方法，用來探討感壓膠的黏性測試。此測試方法作動機制簡單，有別於剝離測試法(peel testing method)，探棒式測試法排除了膠體背板(adhesive carrier)的影響，可直接量測到感壓膠本身的特性。有別於一般使用金屬材質的探棒，本研究使用矽晶圓製作探棒，可將表面粗糙度所造成的影響減至最小，並有相當好的表面平整度，減少接觸膠面時的不平整現象。為測試本系統可用性，在實驗中探討了影響實驗的參數：膠體厚度、剝離速度、接觸時間等，這些實驗結果與文獻比較皆有相同的趨勢發展。使用探棒式測試感壓膠時，在剝離的過程中會有孔穴(cavity)的出現，這些孔穴是隨機的出現，無法定量的控制其產生的位子及個數。在本研究中首先使用PMMA顆粒作為人工缺陷點，進而成功地誘導出單一孔穴，觀察其發展情況；另外也發現人工缺陷點在不同的探棒接觸位置，所得到的最大應力值σ1p也會有所不同，此乃探棒接觸膠面產生的應力分佈場所致，影響應力分佈場的參數為探棒半徑與膠體厚度的比值α (= a/h0)。實驗中使用不同探棒半徑與不同膠體厚度，進行人工缺陷點誘導孔穴實驗時，實驗結果發現相同α值條件下所得之無因次化最大應力	zh_TW
dc.description.abstract	A probe tack testing system was built in this study. Unlike peel testing, the probe tack testing eliminates the effect of adhesive carrier. It can measure the characteristics of PSA purely. In this study, the probes were made by silicon wafer instead of stainless steel with the benefits of good surface roughness and flatness. The experimental parameters such as thickness of adhesive, debonding velocity and dwell time are discussed in the research to test the reliability of this system. Besides, in order to study the growth of cavity, a method of generating single cavity was first proposed. A PMMA particle was introduced as an artificial defect to induce the formation of the single cavity. Furthermore, it was observed that the peak stress σ1p was correlated with the location of particle on adhesive surface. The experiments with different probe diameters (a) and adhesive thickness (h0) were tested. Under the same α, the normalized peak stress was the same for different probe diameter and adhesive thickness. The results show that the dimensionless term α (= a/h0) dominated the debonding mechanism. Moreover, the effects of probe geometry were discussed. The circular, annular and rectangular probes made of silicon wafer were used. Some had same contact area, the others had same contact perimeter. The results showed that peak stress was affected not only contact area but contact perimeter. Also, the parameter hydraulic diameter Dh was used for annular and rectangular probes to make a good correlation with peak stress	en
dc.description.provenance	Made available in DSpace on 2021-06-13T01:03:06Z (GMT). No. of bitstreams: 1 ntu-100-R97543013-1.pdf: 20122647 bytes, checksum: 81f28bb6478afe6ba06f3fc65cf5c0a3 (MD5) Previous issue date: 2011	en
dc.description.tableofcontents	口試委員會審定書 I 誌謝 II 摘要 IV Abstract V 圖目錄 IX 表目錄 XV 符號說明 XVI 第一章緒論 1 1.1 前言 1 1.2 感壓膠(Pressure Sensitive Adhesives) 1 1.2.1 感壓膠定義 1 1.2.2感壓膠的流變特性 2 1.3 文獻回顧 8 1.3.1 感壓膠帶標準測試方法回顧 8 1.3.2 幾何形狀於黏性的影響(Effect of geometry) 16 1.4 研究動機 18 第二章探棒式測試之作動機制 19 2.1 測試原理 19 2.2 應力分佈場(Stress distribution) 22 2.3 剝離機制 24 2.3.1 指狀破壞(fingering) 25 2.3.2 孔穴破壞(cavitation) 27 2.4 實驗參數之影響 28 2.4.1 接觸壓力(Contact pressure) 28 2.4.2 接觸時間(Contact time, or dwell time) 29 2.4.3 剝離速度(Debonding velocity) 31 2.4.4 表面性質(Surface properties) 32 第三章實驗設備架構與方法 35 3.1 黏性測試系統 35 3.1.1 實驗材料 36 3.1.2 測試探棒 38 3.2.3 荷重計 (Load cell) 42 3.2.4 直流訊號放大器(DC Amplifier) 43 3.2.5 位移平台 (Moving stage) 44 3.2.6 載玻片(Glass slide) 45 3.2.7 試片固定座(Sample fixture) 46 3.2.8 光學尺 (Linear scale) 46 3.3 資料與影像擷取系統 48 3.3.1 類比攝影機及鏡頭 48 3.3.2 資料擷取卡 49 3.3.3 影像擷取卡 49 3.3.4 程式介面 49 3.3.5 UV感壓膠固化系統(UV Curing System) 50 3.4 實驗方法 52 3.4.1 黏性測試樣本製備 52 3.4.2 載玻片與探棒之清潔 52 3.4.3 影像處理 53 3.4.4 黏性測試實驗步驟 54 3.4.5 感壓膠塗佈流程 54 第四章實驗設備架設結果 56 4.1 荷重計校正 56 4.2 黏性測試系統初探 56 4.3 不平整度分析 59 4.4 膠體變形量 62 4.5 剝離破壞機制比較 66 第五章實驗結果與討論 67 5.1 感壓膠塗佈結果 67 5.1.1 水溶型感壓膠(Water-based PSA)塗佈 67 5.1.2 UV感壓膠(UV-PSA)塗佈 70 5.1.3 溶劑型感壓膠(Solvent-based PSA)塗佈 71 5.1.4 毛細管塗佈感壓膠問題探討 72 5.1.5 圖案塗佈即時固化 73 5.1.7塗佈速度與間距參數探討 80 5.2 黏性測試參數實驗結果 83 5.2.1 剝離速度 83 5.2.2 接觸時間(Dwell time) 86 5.2.3 膠體厚度 93 5.3 孔穴與氣泡於黏性測試的影響 99 5.3.1 孔穴對最大應力值的影響 99 5.3.2 氣泡對σ1p的影響 101 5.3.3 孔穴發生在探棒不同位置的影響 102 5.3.4 實驗操作溫度之影響 116 5.4 探棒幾何形狀對黏性的影響 118 5.4.1 相同接觸面積 118 5.4.2 相同接觸周長 126 5.4.3 探棒幾何形狀影響之綜合討論 133 5.5 理論模型分析 135 5.6 牛頓流體(Newtonian fluid) 138 第六章結論與建議 141 6.1 結論 141 6.2 建議 142 參考文獻 143
dc.language.iso	zh-TW
dc.title	感壓膠測試系統之建立與其力學特性之研究	zh_TW
dc.title	The Establishment and Mechanism Study of Pressure Sensitive Adhesive Testing System	en
dc.type	Thesis
dc.date.schoolyear	99-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	吳光鐘,高啟林,徐通墀,莊孝根
dc.subject.keyword	探棒式測試法,非圓形幾何探棒,孔穴,人工缺陷點,	zh_TW
dc.subject.keyword	Probe Tack Testing,non-circular probe,cavity,artificial defect,	en
dc.relation.page	148
dc.rights.note	有償授權
dc.date.accepted	2011-08-04
dc.contributor.author-college	工學院	zh_TW
dc.contributor.author-dept	應用力學研究所	zh_TW
顯示於系所單位：	應用力學研究所

文件中的檔案：

檔案	大小	格式
ntu-100-1.pdf 未授權公開取用	19.65 MB	Adobe PDF

顯示文件簡單紀錄

系統中的文件，除了特別指名其著作權條款之外，均受到著作權保護，並且保留所有的權利。