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A.B.Suma , Eindhoven University of Technology, Eindhoven

Tutorial 1. 3D Adaptable Building Skin An Invention for Freedom in Shape of Facades. Divyesh Kumar R.S.Jayakrishnan. A.B.Suma , Eindhoven University of Technology, Eindhoven. ABSTRACT. To develop a principle on which a façade element can be deformed in shape

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A.B.Suma , Eindhoven University of Technology, Eindhoven

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  1. Tutorial 1 3D Adaptable Building Skin An Invention for Freedom in Shape of Facades Divyesh Kumar R.S.Jayakrishnan A.B.Suma , Eindhoven University of Technology, Eindhoven

  2. ABSTRACT • To develop a principle on which a façade element can be deformed in shape • Flexible structure with cables, small bars and inflatable tubes, which together form a woven pattern • By studying the structure of the human skin, a pattern was discovered and translated into a constructive principle • This principle will create many new possibilities in architectural design

  3. HUMAN SKIN • Discovery of a structural pattern which can be used for façade elements • Human skin is very elastic and deformable • Dermis is the structural layer and absorbs all the deformations

  4. HUMAN SKIN • Structural behavior in the dermis is determined by a cooperation of elastin fibers, collagen fibers and the extracellular matrix • Elastin fibers take care of the elasticity • Collagen fibers take care of the ultimate strength and finite strain • Extracellular matrix consists of a dense mass of fluids which keeps the fibers in the dermis layer in place

  5. HUMAN SKIN • When deformation occurs, the elastin fibers are tensioned first • They will stretch till the collagen fibers are straightened and the tension forces will be taken by the collagen fibers • An analogy was developed for a constructive façade element

  6. TRANSLATION TO FAÇADE ELEMENT • The constructive façade element must be easily manufactured, constructed and maintained at low cost • The chaotic skin structure was schematized to a regular pattern • A hexagonal structure which is made up of small bars connected by cables

  7. TRANSLATION TO FAÇADE ELEMENT • In the open spaces of the structure, inflatable tubes are placed which • will establish the cooperation between all the structure elements • The cross sections are never directly mutually joined • Façade element with elasticity and freedom of deformation

  8. TRANSLATION TO FAÇADE ELEMENT • Grey arrows will keep the red horizontal bars in place • Horizontal deformation is possible by the elastic properties of the blue • cables • When the deformation becomes so large that the red curved cables are stretched, the system has reached its finite strain

  9. TRANSLATION TO FAÇADE ELEMENT • Inflatable tubes represent the properties of the extracellular matrix by • their resistance in pressure • The steel cables, rigid pipes and springs represent the cooperation of the • collagen and elastin fibers • The rigid pipes are hollow so the steel cables can slide through them • At the end supports each cable is hold by a spring which limits the ability to deform

  10. APPLICATION:A PHYSICAL STUDY • A scale model has been produced • Hexagonal framework along 3 axis is entangled perpendicularly.

  11. APPLICATION:A PHYSICAL STUDY • Hollow corridors give the opportunity to place the inflatable tubes in layers.

  12. DYNAMIC CHARACTER : Tensile Structure • Can be deformed into convex and concave surfaces by varying the tension in the cables Lifts up Depression

  13. DYNAMIC CHARACTER : Tensile Structure Tension force applied to elevate the skin facade Tension force applied to depress the skin facade

  14. DYNAMIC CHARACTER : Inflatable Tubes • Can be deformed by varying the pressure of inflatable tubes Pressure increased

  15. Feasibility? • Research work in going on to investigate the structural behaviour. • To meet the commercial market, the sectional geometry is set to 318 mm thickness and a span of 1950 mm in two orthogonal surface directions • Structural elements like inflatable tubes, steel cables and springs will be investigated and adjusted to the desirable behaviour.

  16. Conclusion: Architectural Advantages • Elements with adaptable shape lead to great freedom in architectural design • express different characters both inwards and outwards • Possible shapes on the façade are 2D and 3D waves, walking bulges, logos of firms,pictures, expression of scenes, text and names etc. • Rooms and halls can grow or shrink and adapt to its internal circumstances

  17. Conclusion: Architectural Advantages A corridor can adapt to passing people. The width of the corridor with a plan width of two meters expands from 1.40 meter to 2.60 meters.

  18. Conclusion: Architectural Advantages The façade consists almost entirely of stagnant air; the best thermal isolator.

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