沖切邊緣特徵對板金沖壓成形邊緣破裂現象影響之研究

Wei-Cheng Lai; 賴威丞

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/81191

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	陳復國(Fuh-Kuo Chen)
dc.contributor.author	Wei-Cheng Lai	en
dc.contributor.author	賴威丞	zh_TW
dc.date.accessioned	2022-11-24T03:35:19Z	-
dc.date.available	2021-09-11
dc.date.available	2022-11-24T03:35:19Z	-
dc.date.copyright	2021-09-11
dc.date.issued	2021
dc.date.submitted	2021-08-31
dc.identifier.citation	M. Mueller. (2016). Timeline: A Path to Lightweight Materials in Cars and Trucks[Online]. Directory：www.energy.gov/eere/articles/timeline-path-lightweight-materials-cars-and-trucks. M. Chen, and D. J. Zhou, “AHSS Forming Simulation for Shear Fracture and Edge Cracking,” Great Designs in Steel Seminar, Livonia, MI, 2007. 富鈞,“先進高強度鋼沖壓成形邊緣破裂現象之研究,” 國立台灣機械工程研究所碩士論文. July. 2020. P. Larour, H. Schauer, J. Lackner and E. Till, “Edge Crack Simulation with the Modular “Smiley” Forming Tool,” International Deep Drawing Research Group Conference, Linz, Austria, 2016. M. F. Shi, and X. Chen, “Prediction of Stretch Flangability Limits of Advanced High Strength Steels using the Hole Expansion Test,” SAE Technical Paper, April 2007. A. Narayanan, D. Diaz-Infante, and T. Altan, (Jul./Aug. 2018). Edge Fracture in Hole Extrusion and Flanging, Part I: The Effect of Process Variables. Stamping Journal. pp. 16-17. H. Kim, J. Shang, J. Dykeman, A. Samant, and C. Hoschouer, “Practical Evaluation and Prediction of Edge Cracking in Forming Advanced High Strength Steels (AHSS),” SAE Technical, March 2017. J. Gu, L. Zoller, and H. Kim, “A New Testing Method to Evaluate Edge Cracking with Considerations of the Shear Clearance and Press Speed,” SAE Technical, Apr. 2020. D. Frometa, A. Lara, L. Grife, T. Dieudonne, P. Dietsch, J. Rehrl, C. Suppan, D. Casellas, and J. Calvo, “Fracture resistance of advanced high-strength steel sheets for automotive applications,” Metallurgical and Materials Transactions A, Feb. 2021. D. Frómeta, S. Parareda, A. Lara, and D. Casellas, “Evaluation of Edge Formability in High Strength Sheets through A Fracture Mechanics Approach,” AIP Conference Proceedings, vol. 2113, no. 1, July 2019. K. Wang, G. Ayoub, A. Ilinich, and G. Kridli, “Effect of Trimming Process Parameters on Sheared Edge Geometry and Stretch Limit: An Experimental Investigation,” Journal of Materials Engineering and Performance, September, 2020. J. Gu, F. Alamos, D. Schoch, J. Bornhorst, and H. Kim,“A Study on Effects of the Press Speed on Sheared Edge Formability,” International Deep Drawing Research Group Conference, 2020. L. Komgrit, and L. Pongsakorn, “FE Simulations and Experimental Analysis of the Blade Angle Effect on Sheared Surface in Trimming Process of Advanced High Strength Steel Sheet,” Arabian Journal for Science and Engineering, May, 2019. S. Thipprakmas, M. Jin, and M. Murakawa, “An Investigation of Material Flow Analysis in Fneblanking Process,” Journal of Materials Processing Technology, 2007. 李炳坤, “370MPa~590MPa熱軋高強度鋼擴孔性研究,” 中國鋼鐵公司產品應用研究室. Apr. 2005. X. Chena, H. Jianga, Z. Cuia, C. Liana, and C. Lu, “Hole Expansion Characteristics of Ultra High Strength Steels,” International Conference on Technology of Plasticity, Oct., 2014. J. N. Hall, J. Coryell, B. Wendt, and D. Adamski, “Case Studies of Edge Fracture of Dual Phase Steel Stampings,” SAE Technical Paper, Jul. 2015. H. Mohrbacher, “Reverse Metallurgical Engineering Towards Sustainable Manufacturing of Vehicles using Nb and Mo Alloyed High Performance Steels,” Advances in Manufacturing, Mar. 2013. B. M. Hance, “Practical Application of the Hole Expansion Test,” SAE Technical Paper, Apr. 2017. Y. Chang, S. Han, X. Li, C. Wang, G. Zheng, and H. Dong, “Effect of Shearing Clearance on Formability of Sheared Edge of the Third-generation Automotive Medium-Mn Steel with Metastable Austenite,” Journal of Materials Processing Technology, pp. 216–227, Apr. 2018. C. R. M. Silva, F. J. G. Silva, and R. M. Gouveia, “Investigations on the Edge Crack Defect in Dual Phase Steel Stamping Process,” Procedia Manufacturing, pp. 737–745, Jun. 2018. X. Chen, C. Hsiung, K. Schmid, and C. Du, “Evaluation of Metal Gainers for Advanced High Strength Steel Flanging,” SAE Technical Paper, 2014. Y. M. Haung, and K. H. Chien, “The Formability Limitation of the Hole Flanging Process,” Journal of Material Processing Technology, 2001. H. Shih, and G. Chen, “Effects of AHSS Sheared Edge Conditions on Crash Energy Absorption in Component Bend Test,” SAE Technical Paper, Apr., 2018. B. Levy, and C. Van Tyne, “Review of the Shearing Process for Sheet Steels and Its Effect on Sheared-edge Stretching,” Journal of materials engineering and performance, vol.21, no.5, pp.1205-1213, 2012. N. Hatanaka, K. Yamaguchi, and N. Takakura, “Finite Element Simulation of the Shearing Mechanism in the Blanking of Sheet Metal,” Journal of Materials Processing Technology, vol.139, pp.64-70, 2003.
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/81191	-
dc.description.abstract	先進高強度鋼由於具有高強度之特性，可使用較少之材料達到相同之安全性，目前已被廣泛應用於汽車結構件，然而先進高強度鋼於沖壓成形時容易產生邊緣破裂。其邊緣破裂難以透過CAE模擬進行預測，且目前預測沖壓板材破裂最準確之成形極限曲線(FLC)也無法有效預測邊緣破裂發生，因此為了解決邊緣破裂現象，本研究主要為探討沖切邊緣之特性以及量化邊緣特徵之分析方法。本論文首先針對影響邊緣特徵與邊緣成形性之相關製程參數，以及實際發生邊緣破裂之載具進行文獻蒐集與整理，所整理之相關製程參數包括沖頭圓角、沖壓速度、沖頭角度、壓料力、板材厚度及材料強度等；而透過已發表之實際產品缺陷歸納出容易產生邊緣破裂成形模式主要有三種，分別為圓孔凸緣(hole ﬂanging)、拉伸翻邊(stretch ﬂanging)以及拉伸彎曲(stretch bending)，並藉由文獻分析，定義以剪斷面(burnish)分布比例作為判斷沖切邊緣特徵之方法。為了探討不同邊緣特徵與邊緣破裂之關聯性，本論文透過一次一因子實驗法及田口實驗法分析上述已整理之相關參數，並比較不同參數間之影響程度。而為建立預測邊緣破裂之CAE模擬，本論文透過上述所歸納之三種成形模式設計出本研究所使用之實際載具造型，首先利用ABAQUS軟體分析各別成形造型之破裂機制，並與先前已探討之基礎載具擴孔實驗進行比較，確認其一致性；接著，由於成形造型之尺寸參數亦會影響邊緣破裂，因此藉由PAM-STAMP軟體探討不同尺寸參數於不同成形造型中之影響程度；最後則為參考上述分析之結果，設計包含此三種成形模式之實際載具，並於PAM-STAMP軟體建立此載具之模擬模型。最後藉由上述之研究結果，設計出可探討邊緣特徵與特性之相關參數的實驗規劃，包含沖孔實驗及圓孔拉伸實驗，未來將可透過本論文之規劃完成實驗驗證，量化邊緣特徵、預測及避免邊緣破裂，並提供模具設計之參考。	zh_TW
dc.description.provenance	Made available in DSpace on 2022-11-24T03:35:19Z (GMT). No. of bitstreams: 1 U0001-0308202110404700.pdf: 9007873 bytes, checksum: febde49de1a6b82c7c7b21baf65134bf (MD5) Previous issue date: 2021	en
dc.description.tableofcontents	目錄 iii 圖目錄 viii 表目錄 xv 第一章緒論 1 1.1 前言 1 1.2 研究動機與目的 4 1.3 研究方法與步驟 7 1.4 文獻回顧 14 1.5 論文總覽 23 第二章影響邊緣特徵之參數模擬分析 24 2.1 定義及量化邊緣特徵 25 2.2 建立CAE沖切實驗模擬 27 2.3 相關參數影響之模擬探討 29 2.3.1 一次一因子實驗法 29 2.3.2 田口實驗法 41 2.4 小結 46 第三章邊緣破裂成形造型之模擬分析 47 3.1 邊緣破裂成形造型之破裂機制 49 3.1.1 Stretch Flanging之破裂機制分析 51 3.1.2 Hole Flanging之破裂機制分析 53 3.1.3 Stretch Bending之破裂機制分析 55 3.2 邊緣破裂成形造型之尺寸參數探討 57 3.2.1 Stretch Flanging之尺寸參數分析 57 3.2.2 Hole Flanging之尺寸參數分析 62 3.2.3 Stretch Bending之尺寸參數分析 65 3.3 小結 68 第四章設計實驗載具及建立模擬模型 69 4.1 實驗載具之設計方向 70 4.2 建立實驗載具之模擬模型 75 第五章邊緣破裂參數之實驗規劃 80 5.1 探討相關參數之實驗規劃 81 5.1.1 沖孔實驗 85 5.1.2 圓孔拉伸實驗 89 5.2 實際實驗規劃 92 5.3 小結 95 第六章結論及未來研究方向 96 參考文獻 98
dc.language.iso	zh-TW
dc.subject	拉伸彎曲	zh_TW
dc.subject	先進高強度鋼	zh_TW
dc.subject	邊緣破裂	zh_TW
dc.subject	邊緣特徵	zh_TW
dc.subject	沖切製程參數	zh_TW
dc.subject	圓孔凸緣	zh_TW
dc.subject	拉伸翻邊	zh_TW
dc.subject	stretch flanging	en
dc.subject	stretch bending	en
dc.subject	advanced high strength steel	en
dc.subject	edge crack	en
dc.subject	edge characteristic	en
dc.subject	the parameter of blanking process	en
dc.subject	hole flanging	en
dc.title	沖切邊緣特徵對板金沖壓成形邊緣破裂現象影響之研究	zh_TW
dc.title	A Study of Blanked Edge Characteristic Effect on Edge Cracking Phenomenon in Sheet Metal Stamping Process	en
dc.date.schoolyear	109-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	洪景華(Hsin-Tsai Liu),黃永茂(Chih-Yang Tseng),劉宏毅,李炳坤
dc.subject.keyword	先進高強度鋼,邊緣破裂,邊緣特徵,沖切製程參數,圓孔凸緣,拉伸翻邊,拉伸彎曲,	zh_TW
dc.subject.keyword	advanced high strength steel,edge crack,edge characteristic,the parameter of blanking process,hole flanging,stretch flanging,stretch bending,	en
dc.relation.page	101
dc.identifier.doi	10.6342/NTU202102025
dc.rights.note	同意授權(限校園內公開)
dc.date.accepted	2021-09-01
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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