五軸同步3D列印機無需輔助支架於高複雜度物件積層製造之應用

Lung-Chuan Hsu; 許隆銓

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/67228

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DC 欄位	值	語言
dc.contributor.advisor	羅仁權(Ren-Chyuan Luo)
dc.contributor.author	Lung-Chuan Hsu	en
dc.contributor.author	許隆銓	zh_TW
dc.date.accessioned	2021-06-17T01:24:19Z	-
dc.date.available	2020-09-02
dc.date.copyright	2020-09-02
dc.date.issued	2020
dc.date.submitted	2020-08-18
dc.identifier.citation	[1]T. D. Ngo, A. Kashani, G. Imbalzano, K. T. Nguyen and D. Hui, “Additive manufacturing (3D printing): A review of materials, methods, applications and challenges,” Composites Part B: Engineering, 143, Feb. 2018, pp.172-196. [2]E. Peed and N. Lee,” Open Source 3D Printing, History of,” Encyclopedia of Computer Graphics and Games, Springer, Cham, Nov. 2019. [3]L. Gaget, “Comparison between 3D printing and traditional manufacturing processes for plastics,” sculpteo, https://www.sculpteo.com/blog/2019/07/16/comparison-between-3d-printing-and-traditional-manufacturing-processes-for-plastics-3 [Online, accessed 11-June-2020] [4]K. Grutle, “5-axis 3D printer,” M.S. thesis, Dept. Inform., Univ. Oslo, Oslo, Norway, 2015. [5]C. Wu, C. Dai, G. Fang, Y. Liu and C. C. L. Wang, “RoboFDM: A robotic system for support-free fabrication using FDM,” 2017 IEEE International Conference on Robotics and Automation (ICRA), Singapore, 2017, pp. 1175-1180. [6]C. Dai, C. Wang, C. C. L. Wu, S. Lefebvre, G. Fang, and Y. J. Liu, “Support-free volume printing by multi-axis motion,” ACM Transactions on Graphics (TOG), Vol. 37, Aug. 2018, pp. 1-14. [7]K. Hu, S. Jin and C. C. Wang, “Support slimming for single material based additive manufacturing,” Computer-Aided Design, vol.65, 2015, pp.1-10. [8]R. S. Rodrigues, J. F. Morgado and A. J. Gomes, “Part‐based mesh segmentation: a survey,” In Computer Graphics Forum, vol. 37, no. 6, Sep. 2018, pp. 235-274. [9]B. Redwood, “How does part orientation affect a 3D Print? ,” 3D HUBS. https://www.3dhubs.com/knowledge-base/how-does-part-orientation-affect-3d-print#author [Online, accessed 15-Octorber-2019] [10]P. K. Tseng,” Hybrid Additive and Subtractive 3D Printing Process for Multi-Heterogeneous Objects Fabrication,” M.S. thesis, Jul. 2017. [11]“Types of 3D printers or 3D printing technologies overview,” 3dprintingfromscratch. http: / / 3dprintingfromscratch .com/common/types-of-3d-printers-or-3d-printing-technologies-overview/ [Online, accessed 27-Octorber-2018] [12]R. Pires,” SLA vs DLP: The Differences - Simply Explained,” ALL3DP, https://all3dp.com/2/dlp-vs-sla-3d-printing-technologies-shootout/ [Online, accessed 1-February-2020] [13]“Additive manufacturing - Learn about the different kinds of additive manufacturing,” https://scanandmake.com/additive-manufacturing [Online, accessed 20-March-2020] [14]I. Gibson, D. W. Rosen and B. Stucker,” Additive manufacturing technologies,” Springer, New York, NY, Vol. 17, 2014. [15]L. Carolo, “5-Axis 3D Printer: The Latest Advancements,” ALL3DP, https://all3dp.com/2/5-axis-3d-printer-the-latest-advancements/ [Online, accessed 1-June-2020] [16]J. Ruan, T. E. Sparks, A. Panackal, F. W. Liou, K. Eiamsa-Ard, K. Slattery, H. N. Chou and M. Kinsella, “Automated slicing for a multiaxis metal deposition system,” Journal of Manufacturing Science and Engineering, vol. 129, Arp. 2007, pp.303-310. [17]X. Wei, S. Qiu, L. Zhu, R. Feng, Y. Tian, J. Xi and Y. Zheng, “Toward Support-Free 3D Printing: A Skeletal Approach for Partitioning Models,” in IEEE Transactions on Visualization and Computer Graphics, vol. 24, no. 10, 1 Oct. 2018, pp. 2799-2812. [18]J. Vanek, J. A. G. Galicia and B. Benes, “Clever support: Efficient support structure generation for digital fabrication,” In Computer graphics forum, vol. 33, no. 5, Aug. 2014, pp. 117-125. [19]C. Dai, C. C. L. Wang, C. Wu, S. Lefebvre, G. Fang and Y. J. Liu, “Support-free volume printing by multi-axis motion.” ACM Transactions on Graphics (TOG), vol.37, no.4, 2018, pp.1-14. [20]A. K. Jadoon, C. Wu, Y. Liu, Y. He and C. C. L. Wang, “Interactive Partitioning of 3D Models into Printable Parts,” in IEEE Computer Graphics and Applications, vol. 38, no. 4, Jul./Aug. 2018, pp. 38-53. [21]K. Xu, L. Chen and K. Tang, “Support-Free Layered Process Planning Toward 3 + 2-Axis Additive Manufacturing,” in IEEE Transactions on Automation Science and Engineering, vol. 16, no. 2, April 2019, pp. 838-850. [22]R. S. V. Rodrigues, J. F. Morgado and A. J. Gomes, “Part‐based mesh segmentation: a survey,” In Computer Graphics Forum, vol. 37, no. 6, Sep. 2018, pp. 235-274. [23]C. Wu, C. Dai, G. Fang, Y. J. Liu and C. C. L. Wang, 'General Support-Effective Decomposition for Multi-Directional 3-D Printing,” Automation Science and Engineering IEEE Transactions on, vol. 17, no. 2, 2020, pp. 599-610. [24]H. Peng, F. Guimbretière, J. McCann and S. Hudson, “A 3D printer for interactive electromagnetic devices,” Proceedings of the 29th Annual Symposium on User Interface Software and Technology, Oct. 2016, pp. 553-562. [25]P. Alexandrea, “Zurich students build a six-axis 3D printer,” 3Dnatives, https://www.3dnatives.com/en/6-axis-3dprinter230320174/ [Online, accessed 23-Augest-2019] [26]S. Keating and N. Oxman, “Compound fabrication: A multi-functional robotic platform for digital design and fabrication,” Robotics and Computer-Integrated Manufacturing, vol. 29, no. 6, Dec. 2013, pp.439-448. [27]Y. Huang, J. Zhang, X. Hu, G. Song, Z. Liu, L. Yu and L. Liu, “FrameFab: Robotic Fabrication of Frame Shapes,” ACM Trans. Graph., Vol. 35, No. 6, Article 224, November 2016, pp. 1-11. [28]B. Redwood, “How does part orientation affect a 3D Print? ,” 3D HUBS. https://www.3dhubs.com/knowledge-base/how-does-part-orientation-affect-3d-print#author [Online, accessed 15-Octobor-2019] [29]O. S. Carneiro, A. F. Silva and R. Gomes, “Fused deposition modeling with polypropylene,” International Journal of Materials Design, June 2015, pp. 768-776. [30]A. W. Fatimatuzahraa, B. Farahaina and W. A. Y. Yusoff, “The effect of employing different raster orientations on the mechanical properties and microstructure of Fused Deposition Modeling parts,” 2011 IEEE Symposium on Business, Engineering and Industrial Applications (ISBEIA), Langkawi, 2011, pp. 22-27. [31]H. Zhang, L. Cai, M. Golub, Y. Zhang, X. Yang, K. Schlarman, and J. Zhang, “Tensile, Creep, and Fatigue Behaviors of 3D-Printed Acrylonitrile Butadiene Styrene,” Journal of Materials Engineering and Performance, vol.27, January 2018, pp. 57-62. [32]J. T. Belter and A. M. Dollar, “Strengthening of 3D Printed Fused Deposition Manufactured Parts Using the Fill Compositing Technique,” PloS one, April 2015. [33]A. Avdeev, A. Shvets, I. Gushchin, I. Torubarov, A. Drobotov, A. Makarov, A. Plontnikov, and Y. Serdobintsev, “Strength Increasing Additive Manufacturing Fused Filament Fabrication Technology, Based on Spiral Toolpath Material Deposition,” Machines, vol.7, September 2019. [34]W. S. Yerazunis, J. C. Barnwell III, and D. N. Nikovski, “Strengthening ABS, Nylon and Polyester 3D Printed Parts by Stress Tensor Aligned Deposition Paths and Five-Axis Printing,' Proceedings of the Solid Freeform Fabrication Symposium, AT T Conference Center, Austin, Texas. Vol. 10, August 2016. [35]R. C. Luo, Y. W. Perng and P. Tseng, “3D printing process for multi-heterogeneous objects fabrication,” 2017 IEEE/SICE International Symposium on System Integration (SII), Taipei, 2017, pp. 95-101. [36]P. Li, G. Zhu, S. Gong, Y. Huang and L. Yue, “Synchronization control of dual-drive system in gantry-type machine tools based on disturbance observer,” 2016 12th IEEE/ASME International Conference on Mechatronic and Embedded Systems and Applications (MESA), Auckland, 2016, pp. 1-7. [37]R. C. Luo and Y. W. Perng, “Adaptive Skew Force Free Model-Based Synchronous Control and Tool Center Point Calibration for a Hybrid 6-DoF Gantry-Robot Machine,” in IEEE/ASME Transactions on Mechatronics, vol. 25, no. 2, April 2020, pp. 964-976. [38]T. R. Kramer, F. M. Proctor and E. R. Messina, “The NIST RS274NGC Interpreter - Version 3,” NIST Interagency/Internal Report (NISTIR), Aug. 2000. [39]Cura homepage. Ultimaker. URL: https://ultimaker.com/software/ultimaker-cura [Online, accessed 14-November-2018]. [40]E. W. Weisstein, “Sphere point picking,” In Series MathWorld—A Wolfram Web Resource [Online, accessed 1-May-2020]. [41]B. T. Lowerre, “The harpy speech recognition system,” Ph.D. dissertation, Carnegie Mellon University, Pittsburgh, PA, USA, 1976. [42]C. M. Wilt, J. T. Thayer and W. Ruml, “A comparison of greedy search algorithms,” In third annual symposium on combinatorial search, Aug. 2010. [43]C. Wu, Y. J. Liu and C. C. Wang, “Learning to Accelerate Decomposition for Multi-Directional 3D Printing.” arXiv preprint arXiv:2004.03450, Mar. 17, 2020. [44]R. C. Luo, L. C. Hsu, T. J. Hsiao and Y. W. Perng, “3D Digital Manufacturing via Synchronous 5-Axes Printing for Strengthening Printing Parts,” in IEEE Access, vol. 8, pp. 126083-126091, 2020. [45]D. Farbman and C. McCoy, “Materials testing of 3D printed ABS and PLA samples to guide mechanical design,” in ASME 2016 11th International Manufacturing Science and Engineering Conference, Blacksburg, Jun. 2016, pp. 1-11. [46]“Standard Test Method for Tensile Properties of Plastics.” ASTM International, https://www.astm.org/Standards/D638 [Online, accessed 14-January-2020]. [47]M. Fernandez-Vicente, W. Calle, S. Ferrandiz, and A. Conejero, “Effect of infill parameters on tensile mechanical behavior in desktop 3D printing,” 3D printing and additive manufacturing, vol.3, no.3, Sep. 2016, pp.183-192. [48]“Specifications Of AG-Xplus Table-Top Type,” Shimadzu.com., https://shimadzu.com.au/specifications-ag-xplus-table-top-type [Online, accessed 14-January-2020]. [49]F. Wulle, D. Coupek, F. Schäffner, F. Verl, F. Oberhofer, and T. Maier, “Workpiece and machine design in additive manufacturing for multi-axis fused deposition modeling,” Procedia CIRP, vol.60, 2017, pp.229-234. [50]B. Akhoundi, A. H. Behravesh, and A. B. Saed, “An Innovative Design Approach in Three-dimensional Printing of Continuous Fiber–Reinforced Thermoplastic Composites via Fused Deposition Modeling Process: In-melt Simultaneous Impregnation,” Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture, vol.234, no. 1–2, Jan. 2020, pp.243-259. [51]B. Akhoundi, A. H. Behravesh, and A. B. Saed, “Improving Mechanical Properties of Continuous fiber-reinforced thermoplastic Composites produced by FDM 3D Printer,” Journal of Reinforced Plastics and Composites, vol. 38, no. 3, Feb. 2019, pp. 99-116.
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/67228	-
dc.description.abstract	近年來，數位製造技術受到了學術界和工業界的極大關注，它可以製造幾何形狀複雜的物件，且具有客製化製造與多種材料選擇的優點。熔融沈積成型（Fused Deposition Modeling）和光固化成型（Stereolithography Apparatus）是數位製造中較為廣泛使用的兩個技術，因為此兩種技術在成本和品質之間有取得很好的平衡，其中熔融沈積成型（FDM）是3D列印眾多方法中最受歡迎的一種技術，也是本論文中所使用與探討的積層製造技術，但是熔融沈積成型（FDM）技術採用逐層方式堆疊製造，其中在製造過程中需要為懸空的部分添加支撐結構以防止列印失敗，支撐結構的添加減慢了列印的速度，亦增加列印材料之費用，並會在成品表面上留下痕跡，這會使得在去除支撐材時損壞成品的表面品質。由於打印方式是逐層疊加的，因此列印模型的強度在垂直於層的方向上受到限制，特別是當外力從不同方向施加時，層與層之間不良的粘合性成為抵抗外力的弱點。本文中所提出的演算法在我們台大智慧機器人及自動化實驗室開發的五軸同步3D列印機上進行實驗，並克服了以上敘述的兩個問題。為了克服支撐結構的問題，在硬體和軟體方面有各種相關的研究成果，近年來各種機器人製造系統被引入積層製造中，本文中的五軸同步3D列印機是龍門式設備，可以實現多軸3D列印。將給定的模型基於幾何性質進行分割，形成數個子零件，每個子零件可以達到無支架需求的列印，而每個子物件的G-code則透過切層軟體獲得，後續本論文中所提出的五軸列印軌跡生成演算法，用來獲得完整的五軸同步3D列印的G-code，我們成功地透過各種實體模型來展示無支撐列印的結果。對於強度不足的問題，我們提出了基於表面列印軌跡的同步五軸列印演算法。五軸列印具有不同方向列印的功能，因此與僅在固定方向上進行列印相比，列印物件的強度可透過表面列印被大大提升，用於破壞性實驗的測試樣品成功地於五軸同步表面列印中完成，最後透過三點彎曲試驗和拉伸試驗的破壞性實驗，對列印的樣品進行強度分析，並顯示出表面列印可以提高列印模型的強度。	zh_TW
dc.description.abstract	Digital manufacturing technologies have received significant attention from both academia and industry in recent years. It can produce geometrically complex objects directly from 3D model data. Manufacturing customization and the use of various materials are the advantages of digital manufacturing. Fused Deposition Modeling (FDM) and Stereolithography Apparatus (SLA) are two widely used approaches in digital manufacturing because they achieve a very good balance between the cost and quality. FDM is the most popular one among the numerous methods of 3D printing. In this thesis, we use FDM basic principle to conduct additive manufacturing (AM) process. However, FDM technology is in layer-by-layer manner, where supporting structures need to be added for overhanging areas during the manufacturing process. The addition of supporting structures, not only increases material costs but also slows down the speed of fabrication and introduces artifacts onto the finished surface, which can damage the actual product upon removing the supporting material. The strength of the printed models is restricted in the direction of perpendicular to the layers since the printing style is in layer by layer fashion. The poor adhesion between the layers becomes a weakness to resist external force, especially when the force exerted from different directions. In this thesis, the algorithms are proposed to solve these two issues and implemented under the five axes synchronous 3D printing machine developed in our NTU Intelligent Robotics and Automation Lab. For overcoming the issue of supporting structures, there are various researches to improve in the aspects of hardware and software. Various robotic fabrication systems have been introduced in recent years. The developed five axes synchronous 3D printing machine is a gantry-type equipment to conduct multi-axis synchronous 3D printing in our experiment. A geometry-based decomposition method is used to divide a given model into several sub-components. Each sub-component can be printed under self-support, which means that the sub-component can be printed without supporting structures. The G-code format of each sub-component is obtained by slicing software separately. An algorithm of five axes printing trajectory generation is proposed to combine the G-code of each sub-component. The five axes printing trajectory is implemented in synchronous five axes printing machine to demonstrate the results of printing without supporting structures. Algorithms for synchronous five axes printing based on the surface printing trajectory have been proposed to overcome the lack of strength issue. Five axes printing can achieve the goal of printing in different orientations so that the strength of the printed parts is greatly enhanced in comparison with the printing in a fixed direction only. The five axes synchronous 3D printing has been successfully demonstrated with physical object printing. The strength analysis of printed parts is also performed under the three-point bending test and the tensile test to show the evidential results of improving the strength of the printed object models.	en
dc.description.provenance	Made available in DSpace on 2021-06-17T01:24:19Z (GMT). No. of bitstreams: 1 U0001-1608202015553000.pdf: 9853627 bytes, checksum: b82b9e5e96cd1312d6b515cdb1db6882 (MD5) Previous issue date: 2020	en
dc.description.tableofcontents	誌謝 i 中文摘要 ii ABSTRACT iii CONTENTS v LIST OF FIGURES viii LIST OF TABLES xiii Chapter 1 Introduction 1 1.1 Introduction 1 1.2 Motivation and Objectives 2 1.3 Background 4 1.3.1 Additive Manufacturing 4 1.3.2 Subtractive Manufacturing 10 1.3.3 Commercial Multi Axes Equipment 12 1.4 Previous Works 13 1.4.1 Decomposition Model Ways 13 1.4.2 Multi Axes Printing Styles 14 1.4.3 The Strength of Printed Object Issues 15 1.5 Thesis Organization 16 Chapter 2 The Hardware and Software 17 2.1 Hardware 17 2.1.1 Mechanism Design 17 2.1.2 Robot Coordinate System 18 2.1.3 The Coordinate System of Five-Axis Synchronous Motion 3D Printing Machine 20 2.1.4 System Structure 23 2.2 Software 30 2.2.1 STL (STereoLithography) Format 30 2.2.2 Off Format 31 2.2.3 Slicing Software 32 2.2.4 Direct Numerical Control (DNC) 33 2.3 Materials 34 2.3.1 PLA (Polylactic Acid) 34 2.3.2 ABS (Acrylonitrile Butadiene Styrene) 35 2.3.3 PLA vs. ABS 36 Chapter 3 Five Axes Printing Trajectory Generation 37 3.1 System Structure 37 3.2 Model Decomposition Method 39 3.3 Slicing Process 43 3.4 Printing Sequence Generation 44 Chapter 4 Surface Processing 53 4.1 System Structure 53 4.2 Pretreatment 54 4.3 Surface Trajectory Generation 54 4.4 Combination 61 Chapter 5 Implementation and Experimental Results with Discussions 62 5.1 Calibration of Rotational Pivot of Machine 62 5.2 Synchronous Five Axes Printing without Supporting Structure 66 5.2.1 Stanford Bunny 66 5.2.2 Kitten 69 5.2.3 Curved Tube 71 5.2.4 The Component of Robot Arm Shell Mechanism 74 5.2.5 The Cooperation on Material Usage and Printing Time 76 5.3 Surface Processing 79 5.4 Supporting Free Printing and Surface Processing 90 Chapter 6 Contributions, Conclusions and Future Works 93 6.1 Contributions 93 6.2 Conclusions 93 6.3 Future Works 95 REFERENCE 97
dc.language.iso	en
dc.subject	數位製造	zh_TW
dc.subject	熔融沈積成型	zh_TW
dc.subject	5軸同步3D列印機	zh_TW
dc.subject	列印軌跡生成與規劃	zh_TW
dc.subject	五軸3D列印無須輔助支架	zh_TW
dc.subject	3D Printing without Supporting Structure	en
dc.subject	Digital Manufacturing	en
dc.subject	Fused Deposition Modeling	en
dc.subject	Tool Path Generation and Planning	en
dc.subject	Five-Axis Synchronous Motion 3D Printing Machine	en
dc.title	五軸同步3D列印機無需輔助支架於高複雜度物件積層製造之應用	zh_TW
dc.title	Five-Axis Synchronous Motion 3D Printing Machine for Additive Manufacturing of Complex Objects without Supporting Structure	en
dc.type	Thesis
dc.date.schoolyear	108-2
dc.description.degree	碩士
dc.contributor.author-orcid	0000-0002-4471-3585
dc.contributor.oralexamcommittee	張帆人(Fan-ren Chang),王富正(Fu-Cheng Wang)
dc.subject.keyword	數位製造,熔融沈積成型,5軸同步3D列印機,列印軌跡生成與規劃,五軸3D列印無須輔助支架,	zh_TW
dc.subject.keyword	Digital Manufacturing,Fused Deposition Modeling,Tool Path Generation and Planning,Five-Axis Synchronous Motion 3D Printing Machine,3D Printing without Supporting Structure,	en
dc.relation.page	103
dc.identifier.doi	10.6342/NTU202003584
dc.rights.note	有償授權
dc.date.accepted	2020-08-19
dc.contributor.author-college	電機資訊學院	zh_TW
dc.contributor.author-dept	電機工程學研究所	zh_TW
顯示於系所單位：	電機工程學系

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