進階搜尋


下載電子全文  
系統識別號 U0026-2708201513304300
論文名稱(中文) 應用於女鞋之創新設計
論文名稱(英文) Innovative Female Footwear Design
校院名稱 成功大學
系所名稱(中) 工業設計學系
系所名稱(英) Department of Industrial Design
學年度 103
學期 2
出版年 104
研究生(中文) 林蓮雅
研究生(英文) Lien-Ya Lin
學號 P36021037
學位類別 碩士
語文別 英文
論文頁數 47頁
口試委員 指導教授-陳建旭
口試委員-賴新喜
口試委員-簡聖芬
口試委員-鄧怡莘
中文關鍵字 3D列印  鞋子設計 
英文關鍵字 3D printing  footwear design 
學科別分類
中文摘要 人的足部承受人體全身的重量,並提供行走、跑步、維持平衡的能力,而鞋子正是保護人體足部的重要發明,更能夠透過穿戴合適的或訂製的鞋子來彌補生理先天上的疾病。
鞋子依舊是個穿在腳上的服飾,但現今人對鞋子的「概念」正在改變。總體來看,鞋子的需求變化是基本保護、外觀美化、身分地位象徵、人體工學、科技導入,到現在的客製、訂製化需求。
本研究目的在透過文獻探討、流程觀察與實際製作的方式,嘗試將傳統鞋業製造移植到3D列印的製造程序,並探索直接用普遍的3D列印機,製造出可穿著鞋子的方法,為鞋業開創一全新的服務。此新形態的服務不僅能將製造過程數位化,也能提供使用者雲端服務。此流程的概念不僅僅是讓使用者可以得到一雙屬於自己的鞋子,同時也能將人們對於「得到鞋子」的想法,從「從工廠或銷售商得到一雙完整鞋子」,改變成「自己透過雲端服務,用3D列印機器製造出一組可以組合、創造不同樣式鞋子的零件」。
英文摘要 The different requirements point out the diversity and development of the footwear. Most important, rapid expansion of Internet and shopping online make the attribution in the sales of footwear.
Depends on the digital manufacturing way, 3D printing can bring a new kind of shoes industry which differs from the traditional services. This new industry offer consumers a way to have shoes’ model online and the models are build up according to their own feet. To get the shoes, consumers only need to print and combine the components.
To achieve the new service, this experiment aimed at the women shoes, which has high variety. Researchers explore the possibility of 3D printing digital design and manufacturing, and develop the possibility of new forms of service.
論文目次 摘要 i
SUMMARY ii
ACKNOWLEDGEMENTS iii
TABLE OF CONTENTS iv
LIST OF TABLES vi
LIST OF FIGURES vii
CHAPTER 1 INTRODUCTION 1
1.1 Motivation 1
1.1.1 Importance of footwear for human being 1
1.1.2 Changes of the development and need 1
1.1.3 Changes of the manufacturing method 3
1.2 Research purpose 4
CHAPTER 2 RELATED WORKS 6
2.1 Ergonomics consideration 6
2.1.1 Standing Balance 6
2.1.2 Foot Plantar Pressure 7
2.1.3 Relationship between Size and Fitness 8
2.1.4 Evaluation and Customized Requirement 8
2.2 Manufacturing and Technology 9
2.2.1 3D Scanning 9
2.2.2 3D Printing 10
2.2.3 3D Printing Materials 12
CHAPTER 3 DEVELOPMENT AND INNOVATIVE DESIGN 14
3.1 Pilot study 14
3.1.1 Observation of traditional manufacturing 15
3.1.2 3D printing and traditional manufacturing 16
3.1.3 Prototyping of 3D printing shoes 17
3.2 Innovative shoes design 24
3.2.1 Analysis of the 3D printing shoes 25
3.2.2 Features and advantages of fused filament fabrication (FFF) 25
3.2.3 Concept of the innovative shoes 27
3.2.4 Concept prototyping 27
CHAPTER 4 RESULTS 34
4.1.1 Shoes results 34
4.1.2 Digital data 36
CHAPTER 5 DISCUSSION 38
5.1.1 3D scanning models 38
5.1.2 The supporters and quality of 3D printing 38
5.1.3 Structure and the component 40
5.1.4 Manufacturing process 41
5.1.5 Traditional training and 3D digital skill 41
5.1.6 Limitation 41
CHAPTER 6 CONCLUSION 43
REFERENCES 45
參考文獻 Aden, S. (2013). AMOEBA TRAINER. from http://shameesaden.com
Bogue, R., Loughlin, C., & Loughlin, C. (2014). What future for humans in assembly? Assembly Automation, 34(4).
Cubify. (2015). Sense portable 3D scanner.
Fisher, D., Mündermann, A., Morag, E., & Andriacchi, T. (2004). Gait adaptations to recent footwear history: implication for the treatment of knee osteoarthritis. Paper presented at the 50th Annual Meeting of the Orthopaedic Research Society, San Francisco, CA, Trans Orthop Res Soc.
Goonetilleke, R. S., Luximon, A., & Tsui, K. L. (2000). The Quality of Footwear Fit: What we know, don't know and should know. Paper presented at the Proceedings of the Human Factors and Ergonomics Society Annual Meeting.
Hutmacher, D. W., Schantz T Fau - Zein, I., Zein I Fau - Ng, K. W., Ng Kw Fau - Teoh, S. H., Teoh Sh Fau - Tan, K. C., & Tan, K. C. Mechanical properties and cell cultural response of polycaprolactone scaffolds designed and fabricated via fused deposition modeling. (0021-9304 (Print)).
Kilby, M. C., & Newell, K. M. (2012). Intra-and inter-foot coordination in quiet standing: footwear and posture effects. Gait & posture, 35(3), 511-516.
Kolarik, W. J. (1995). Creating quality: concepts, systems, strategies, and tools: McGraw-Hill.
Lavery, L. A., Vela, S. A., Fleischli, J. G., Armstrong, D. G., & Lavery, D. C. (1997). Reducing plantar pressure in the neuropathic foot: a comparison of footwear. Diabetes care, 20(11), 1706-1710.
Luh, Y.-P., Wang, J.-B., Chang, J.-W., Chang, S.-Y., & Chu, C.-H. (2013). Augmented reality-based design customization of footwear for children. Journal of Intelligent Manufacturing, 24(5), 905-917.
McPoil, T. G. (2000). Athletic footwear: design, performance and selection issues. Journal of Science and Medicine in sport, 3(3), 260-267.
NIKE. (2014). Vapor Laser Talon. from http://www.nike.com/us/en_us/c/us-football/stories/2014-02/vapor-cleats
RepRap. (2014). Fused filament fabrication. from http://reprap.org/wiki/Fused_filament_fabrication
Ritchey, T. (1998). Fritz Zwicky, morphologie and policy analysis. Paper presented at the 16th EURO conference on operational analysis, Brussels.
Rout, N., Zhang, Y. F., Khandual, A., & Luximon, A. (2010). 3D foot scan to custom shoe last. Special Issue of International Journal of Computer and Communication Technology, 1(2-4), 14-18.
Rozema, A., Ulbrecht, J. S., Pammer, S. E., & Cavanagh, P. R. (1996). In-shoe plantar pressures during activities of daily living: implications for therapeutic footwear design. Foot & ankle international, 17(6), 352-359.
Smith, C. J., Machado-Moreira, C. A., Plant, G., Hodder, S., Havenith, G., & Taylor, N. A. (2013). Design data for footwear: sweating distribution on the human foot. International Journal of Clothing Science and Technology, 25(1), 43-58.
SOLS. (2015). SOLS. from http://www.sols.com/
Sudta, P., Kanchan, K., & Chantrapornchai, C. (2012). Children Shoes Suggestion System Using Data Mining. International Journal of Database Theory and Application, 5(1), 21-36.
TaiwanFootwearManufacturersAssociation. (2014). FOOTWEAR EXPORTS FROM TAIWAN R.O.C. IN RECENT 5 YEARS (BY CATEGORY). from http://www.footwear-assn.org.tw/statistics/default.asp
Viswanathan, V., Madhavan, S., Gnanasundaram, S., Gopalakrishna, G., Das, B. N., Rajasekar, S., & Ramachandran, A. (2004). Effectiveness of different types of footwear insoles for the diabetic neuropathic foot A follow-up study. Diabetes care, 27(2), 474-477.
Wang, C.-S. (2010). An analysis and evaluation of fitness for shoe lasts and human feet. Computers in Industry, 61(6), 532-540.
Wantedanalytics. (2015). 3D printing skill demand. from https://www.wantedanalytics.com/analysis/posts/demand-for-3d-printing-skills-soars
Wikipedia. (2014). Selective laser sintering. from http://en.wikipedia.org/wiki/Selective_laser_sintering
Wunderlich, R. E., & Cavanagh, P. R. (2001). Gender differences in adult foot shape: implications for shoe design. Medicine and science in sports and exercise, 33(4), 605-611.
Yu, J., Cheung, J. T.-M., Fan, Y., Zhang, Y., Leung, A. K.-L., & Zhang, M. (2008). Development of a finite element model of female foot for high-heeled shoe design. Clinical Biomechanics, 23, S31-S38.
Zahari, T., Aris, M. A., Zulkifli, A., Mohd Hasnun Ariff, H., & Nina Nadia, S. (2013). A Low Cost 3D Foot Scanner for Custom-Made Sports Shoes. Advanced Materials Research.
論文全文使用權限
  • 同意授權校內瀏覽/列印電子全文服務,於2018-09-08起公開。
  • 同意授權校外瀏覽/列印電子全文服務,於2018-09-08起公開。


  • 如您有疑問,請聯絡圖書館
    聯絡電話:(06)2757575#65773
    聯絡E-mail:etds@email.ncku.edu.tw