Dezembro 2020 vol. 8 num. 4 - XXIV International Conference of the Iberoamerican Society of Digital Graphics

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Pneumatic Structure with Kinetic Sub-system: A Proposal for Extraterrestrial Life

Pneumatic Structure with Kinetic Sub-system: A Proposal for Extraterrestrial Life

Agirbas, Asli ;

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Designing for extraterrestrial life is a very up-to-date issue. However, there are many constraints in this kind of designs. Designs that provide the best solution can only be obtained by identifying these constraints very well. In this study, a design concept was developed for life in Mars by considering various constraints. This design consists of a kinetic system with pneumatic structure. The preliminary scheme of this structure, which was planned to produce as a prototype, was discussed in the scope of this study.

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Palavras-chave: Extraterrestrial architecture, Martian base, Pneumatic structure, Kinetic structures, Algorithmic and parametric design,

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DOI: 10.5151/sigradi2020-55

Referências bibliográficas
  • [1] Abdelmohsen, S., Massoud, P. & Elshafei, A. (2016). Using Tensegrity and Folding to Generate Soft Responsive Architectural Skins. In Proceedings of the 34th eCAADe Conference, University of Oulu, Oulu, Finland, 22-26 August (pp. 529-536).
  • [2] Agirbas, A. (2017). The Use of Simulation for Creating Folding Structures: A Teaching Model. In Proceedings of the 35th eCAADe Conference, Sapienza University of Rome, Rome, Italy, 20-22 September (pp. 325-332).
  • [3] Agirbas, A. (2019). Façade Form-Finding with Swarm Intelligence. Automation in Construction, 99, 140-151.
  • [4] Ahlquist, S., McGee, W. & Sharmin, S. (2017). PneumaKnit: Actuated Architectures Through Wale- and Course-Wise Tubular Knit-Constrained Pneumatic Systems. In Proceedings of the 37th Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA), Cambridge, MA, 2-4 November (pp. 38-51).
  • [5] Baerlecken, D., Swarts, M., Gentry, R. & Wonoto, N. (2012). Bio- Origami: Form Finding and Evaluation of Origami Structures. In Proceedings of the 30th eCAADe Conference, Prague,Czech Republic, 12-14 September (pp. 497-504).
  • [6] Benaroya, H., Bernold, L. & Meng Chua, K. (2002). Engineering, Design and Construction of Lunar Bases. Journal of Aerospace Engineering, 15(2), 33-45.
  • [7] Biloria, N. & Oosterhuis, K. (2005). Envisioning the RESPONSIVE Milieu: An Investigation into Aspects of Ambient Intelligence, Human Machine Symbiosis and Ubiquitous Computing for Developing a Generic Real-time Interactive Spatial Prototype. In Proceedings of the 10th International Conference on Computer-Aided Architectural Design Research in Asia (CAADRIA), New Delhi, India, 28- 30 April (pp. 421-432).
  • [8] Hemmerling, M. (2010). Origamics. In Proceedings of the Arab Society for Computer Aided Architectural Design Conference (ASCAAD), Fez, Morocco, 19-21 October (pp. 89-96). Khoo, C.K., Salim, F. & Burry, J. (2011). Designing Architectural Morphing Skins with Elastic Modular Systems. International Journal of Architectural Computing, 9(4), 397-419.
  • [9] Kozicka, J. (2008). Low-cost Solutions for Martian Base.
  • [10] Advances in Space Research, 41, 129-137.
  • [11] Kozicki, J. & Kozicka, J. (2011). Human Friendly Architectural Design for a Small Martian Base. Advances in Space Research, 48, 1997–2004.
  • [12] Leach, N. (2014). Projecting into Space: International Student Projects. Architectural Design, 84, 96-107.
  • [13] Lee, D. (2013). Self-Organizing Origami Structures. In Proceedings of the 33rd Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA), Cambridge, October 24-26 (pp. 421-422).
  • [14] Lee, D.& Leounis, B. (2011). Digital Origami: Modeling Planar Folding Structures. In ACADIA Regional Conference Proceedings, University of Nebraska Lincoln (pp.25-29).
  • [15] Mather, R.R. & Wilson, J.I.B. (2017). Fabrication of Photovoltaic Textiles. Coatings, 7(5), 63.
  • [16] Morris, M., Ciardullo, C., Lents, K., Montes, J., Yashar, M., Rudakevych, O.,Sono, M. & Sono, Y. (2016). Mars Ice House: Using the Physics of Phase Change in 3D Printing a Habitat with H2O. In 46th International Conference on Environmental Systems, 10-14 July, Vienna, Austria
  • [17] Seguin A.M. (2005). Engaging Space: Extraterrestrial Architecture and the Human Psyche. Acta Astronautica, 56, 980-995.
  • [18] Senagala, M. (2005). Building is a Network for Living in: Toward New Architectures. In Proceedings of the 2005 Annual Conference of the Association for Computer Aided Design in Architecture (ACADIA), Savannah (Georgia) 13-16 October (pp. 36-47).
  • [19] Zuk, W. (1970). Kinetic Architecture. New York, NY: Van Nostrand Reinhold.
  • [20] Zubrin, R. (2014). Colonising the Red Planet: Humans to Mars in Our Time. Architectural Design, 84, 46-53.
  • [21] Wilkinson, S., Musil, J., Dierckx, J., Gallou, I. & De Kestelier X. (2016). Autonomous Additive Construction on Mars. In Earth & Space 2016 Conference - ASCE International Conference on Engineering, Science, Construction and Operations in Challenging Environments.
Como citar:

Agirbas, Asli; "Pneumatic Structure with Kinetic Sub-system: A Proposal for Extraterrestrial Life", p. 400-405 . In: Congreso SIGraDi 2020. São Paulo: Blucher, 2020.
ISSN 2318-6968, DOI 10.5151/sigradi2020-55

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