论文信息 - TOWARDS FUNCTIONAL ARCHITECTURAL DECOMPOSITION OF CONSTRAINED LAYER INFLATABLE SYSTEMS

TOWARDS FUNCTIONAL ARCHITECTURAL DECOMPOSITION OF CONSTRAINED LAYER INFLATABLE SYSTEMS

Abstract Pneumatically activated systems enable myriad types of highly functional inflatables employing a wide range of architectural approaches affecting their form and function, making systematic conceptual design difficult. A new architectural class of pneumatically activated systems, constrained layer inflatable systems, consists of hierarchically architected flat layers of thin airtight bladders that are internally and/or externally constrained to generate a variety of functionalities. The highly hierarchical architectural structure of constrained layer inflatable systems coincides with the hierarchy of produced functions, providing an opportunity for the development of a functional architectural decomposition, capturing the inherent relationship between architectural and functional hierarchies. The basis of the approach is conveyed through the design of an example constrained layer inflatable system. This approach empowers the systematic understanding of the interrelated architectural and functional breakdown of constrained layer inflatable systems, enabling designers to iteratively analyze, synthesize, and re-synthesize the components of the system improving existing designs and exploring new concepts.

[1] R. Gurt. Design and analysis of reinforced rubber membranes for inflatable dams , 2015 .

[2] J. Veneman,et al. Varstiff , an innovative variable stiffness material , applied in a Wheelchair Positioning , 2015 .

[3] Ryo Takahashi,et al. PneuModule: Using Inflatable Pin Arrays for Reconfigurable Physical Controls on Pressure-Sensitive Touch Surfaces , 2020, CHI.

[4] Nobuhiro Takahashi,et al. ClaytricSurface: an interactive surface with dynamic softness control capability , 2012, SIGGRAPH '12.

[5] Exoskin : pneumatically augmenting inelastic materials for texture changing interfaces , 2015 .

[6] Ali Sadeghi,et al. Preliminary Experimental Study on Variable Stiffness Structures Based on Textile Jamming for Wearable Robotics , 2018 .

[7] Erik Seedhouse. Bigelow Expandable Activity Module , 2015 .

[8] Hiroshi Ishii,et al. Jamming user interfaces: programmable particle stiffness and sensing for malleable and shape-changing devices , 2012, UIST.

[9] Pedro M Reis,et al. Smart Morphable Surfaces for Aerodynamic Drag Control , 2014, Advanced materials.

[10] R. E. Freeland,et al. Large Inflatable Deployable Antenna Flight Experiment Results , 1997 .

[11] Erik Seedhouse,et al. Bigelow Aerospace: Colonizing Space One Module at a Time , 2014 .

[12] Louis H. Sullivan,et al. The Tall Office Building Artistically Considered , 2012 .