機械手臂輔助互承性木構築實現從設計到製造一體化流程

The Robotic-arm-Assisted Reciprocal Wood Tectonics for the Integrated Process from Design to Build

10.53106/101632122022060120010

沈揚庭(Yang-Ting Shen)；蕭瑋廷(Wei-Ting Hsiao)；顏嘉慶(Chia-Ching Yen)

設計為建造 ； 互承結構 ； 機械手臂 ； 數位製造 ； 自動化組裝 ； Design for Build ； Reciprocal Structure ； Robotic Arm ； Digital Fabrication ； Automatic Assembly

建築學報

120_S期：建築設計教學及設計教育專刊Ⅳ（2022 / 06 / 30）

53 - 68

繁體中文

智慧營建在現今面臨少子化與缺工的社會現象，以及工程日趨複雜與高度整合的趨勢下，已成為先進國家戮力發展的戰略性目標。在智慧營建的框架下，本研究企圖發展一套機械手臂輔助互承性木構築，以探討並實證「設計為建造」從設計到製造一體化流程。本研究以雙曲拋物面互承性木構涼亭設計專案對機械手臂輔助數位構築進行技術實證。機械手臂輔助互承性木構築的工法分成三大階段：1.設計階段的成形查找、互承佈署與實體生成、2.製造階段的虛實流程整合設計、以及3.建造階段的自動化組裝。設計階段透過參數化設計軟體及其支援性運算程式，可以實現可調式性的成形查找到最佳化的互承性結構佈署，再透過實際材料斷片尺寸進行實體的製造模型生成；進入到製造階段，透過機械手臂的路徑生成程式，可以運用視覺化的數位雙生模型及其模擬，產生虛實流程整合設計，實現對於木材角料構件的精準加工和客製化製造；最終運用機械手臂的空間定位特性對組裝構件進行空間放樣與目標區定位，達到對複雜空間構件的自動化的組裝。總結來說，本研究發展並實證透過機械手臂輔助互承性木構築的找形設計、數位製造、自動組裝三階段的一體化流程。

The smart construction has become the strategic goal among developed countries due to the trend of declining birthrate rate and lack of workers. Under the frame of smart construction, this research develops the robotic-arm-assisted reciprocal wood tectonics to demonstrate the complete process from design to build. We found the hyperbolic paraboloid reciprocal pavilion project and use robotic arm to assist the construction process. There are three tectonic construction phases including 1. Design phase: the forming finding and reciprocal frame deployment, 2. Fabrication phase: the integrated design process from virtual to real, and 3. Construction phase: the automatic assembly. In conclusion, our research demonstrates the complete robotic-arm-assisted reciprocal wood tectonics based on form finding design, digital fabrication, and automatic assembly.

1. 沈揚庭, Y. T.,盧沛文, P. W.(2017)。以韌性城市概念發展智慧建築皮層的主動調適控制系統。建築學報，99，123-137。
   連結：
2. Boje, C.,Guerriero, A.,Kubicki, S.,Rezgui, Y.(2020).Towards a semantic Construction Digital Twin: Directions for future research.Automation in Construction,114,103179.
3. Chen, K.,Lu, W.,Peng, Y.,Rowlinson, S.,Huang, G. Q.(2015).Bridging BIM and building: From a literature review to an integrated conceptual framework.International Journal of Project Management,33(6),1405-1416.
4. Eastman, C. M.,Jeong, Y. S.,Sacks, R.,Kaner, I.(2010).Exchange model and exchange object concepts for implementation of national BIM standards.Journal of Computing in Civil Engineering,24(1),25-34.
5. Fralix, M. T.(2001).From mass production to mass customization.Journal of Textile and Apparel, Technology and Management,1(2),1-7.
6. Fraser, H.(2015).The wild reindeer viewing pavilion, Tverrfjellhytta, Norway: sign off.Leading Architecture & Design,50.
7. Gershenfeld, N.(2012).How to make almost anything: The digital fabrication revolution.Foreign Aff.,91,43.
8. Godthelp, T. S.,Jorissen, A. J.,Habraken, A. P.,Roelofs, R.(2019).The timber Reciprocal Frame Designer: free form design to production.Proceedings of IASS Annual Symposia,2019(15),1-8.
9. Goedert, J. D.,Meadati, P.(2008).Integrating construction process documentation into building information modeling.Journal of Construction Engineering and Management,134(7),509-516.
10. He, R.,Li, M.,Gan, V. J.,Ma, J.(2021).BIM-enabled computerized design and digital fabrication of industrialized buildings: A case study.Journal of Cleaner Production,278,123505.
11. Hildner,Claudia(2020).Hildner & Claudia (2020). Hauchdünngeschalt: Future Tree in Esslingen im Kanton Zürich..
12. Huang, J.,Krawczyk, R. J.,Schipporeit, G.(2006).Huang, J., Krawczyk, R. J., & Schipporeit, G. (2006). Integrating Mass Customization with Prefabricated Housing..
13. Jodidio, P.,Köper, K. B.,Bosser, J.(2011).Serpentine Gallery Pavilions.Cologne:Taschen.
14. Kamari, A.,Laustsen, C.,Peterson, S.,Kirkegaard, P. H.(2018).A BIM-based decision support system for the evaluation of holistic renovation scenarios.Journal of Information Technology in Construction (ITcon),23(18),354-380.
15. Khajavi, S. H.,Motlagh, N. H.,Jaribion, A.,Werner, L. C.,Holmström, J.(2019).Digital twin: vision, benefits, boundaries, and creation for buildings.IEEE access,7,147406-147419.
16. Kolarevic, B.(2001).Kolarevic, B. (2001). Digital fabrication: manufacturing architecture in the information age..
17. Larsen, O. P.(2007).Reciprocal Frame Architecture.Routledge.
18. Monizza, G. P.,Rauch, E.,Matt, D. T.(2017).Parametric and generative design techniques for mass-customization in building industry: a case study for glued-laminated timber.Procedia CIRP,60,392-397.
19. Parvin, A.(2013).Architecture (and the other 99%): open‐source architecture and design commons.Architectural design,83(6),90-95.
20. Pine, B. J.(1993).Mass Customization.Boston:Harvard business school press.
21. Rosen, R.,Von Wichert, G.,Lo, G.,Bettenhausen, K. D.(2015).About the importance of autonomy and digital twins for the future of manufacturing.IFAC-PapersOnLine,48(3),567-572.
22. Sass, L.(2007).Synthesis of design production with integrated digital fabrication.Automation in Construction,16(3),298-310.
23. Sass, L.,Botha, M.(2006).The instant house: a model of design production with digital fabrication.International Journal of Architectural Computing,4(4),109-123.
24. Shen, Y. T.,Lu, P. W.(2016).Development of Kinetic Facade Units with BIM-Based Active Control System for the Adaptive Building Energy Performance Service.CAADRIA 2016: Living Systems and Micro-Utopias - Towards Continuous Designing
25. Singh, V.,Gu, N.,Wang, X.(2011).A theoretical framework of a BIM-based multi-disciplinary collaboration platform.Automation in Construction,20(2),134-144.
26. 石井和紘(1992)。清和文楽館〔設計・石井和紘建築研究所〕─歴史・地方・木造・重源。建築文化，548，171-186。
27. 沈揚庭, Y. T(2020)。數位智造工坊（RAC-Coon）：成大建築的數位轉型之路。成大建築簡訊，94，1-7。
28. 沈揚庭, Y. T.,鄭博仁, B. R.,李承哲, C. Z.,許佳傑, J. J.,王彥鈞, Y. J.,李怡瑩, Y. Y.,孫子皓, Z. H.(2018)。建築放送台：邁向群眾的建築社會實踐。建築學報，102，33-42。
29. 覃池泉, C. Q.,王寶珍, B. Z.(2008)。虹橋結構類型初探。中國水運：下半月，6，195-196。

1. 蕭瑋廷,沈揚庭(2022)。機器人建造：發展基於離散設計下機械手臂金屬彎折應用於自體站立牆體工法。建築學報，122，73-88。
2. (2024)。基於機械手臂木構築的建築設計教育方法與實踐。建築學報，127_S期：建築教學實踐及教育專刊，47-65。