Smart Textiles as hybrid interactive materials A responsive behaviour towards transformable surfaces
Youssef, M. (2017). Smart Textiles as hybrid interactive materials A responsive behaviour towards transformable surfaces. EKB Journal Management System, 7(2), 215-226. doi: 10.12816/0046567
Mai M. Youssef. "Smart Textiles as hybrid interactive materials A responsive behaviour towards transformable surfaces". EKB Journal Management System, 7, 2, 2017, 215-226. doi: 10.12816/0046567
Youssef, M. (2017). 'Smart Textiles as hybrid interactive materials A responsive behaviour towards transformable surfaces', EKB Journal Management System, 7(2), pp. 215-226. doi: 10.12816/0046567
Youssef, M. Smart Textiles as hybrid interactive materials A responsive behaviour towards transformable surfaces. EKB Journal Management System, 2017; 7(2): 215-226. doi: 10.12816/0046567

Smart Textiles as hybrid interactive materials A responsive behaviour towards transformable surfaces

International Design Journal
Article 19, Volume 7, Issue 2 - Serial Number 22, April 2017, Page 215-226  XML PDF (1.36 MB)
Document Type: Original Article
DOI: 10.12816/0046567
View on SCiNiTO View on SCiNiTO
Author
Mai M. Youssef
Teaching Assistant, Faculty of Fine Arts, Alexandria University, Alexandria, Egypt
Abstract
Finding ingenious solutions in interior spaces is the result of capability and scalability of the designer in reshaping the interior's contents through the use of the materials in the contexts of perception and interpretation. This approach extended to include the concepts of contextual variation into computed responses and ubiquitous integration into architecture. They are also known as Hybrid materials functionally when integrated with high performance intelligent embedded systems as adaptive system property changing or energy exchanging building system energy-saving control through the adaptation of patterns within the digital phase modelling. These materials mimic living organisms in terms of behaviour, in reaction to various environmental impacts and they are known as active, responsive or adaptive materials due to their metamorphic ability to adapt and self-assemble to the environmental surroundings and the requirements of the inhabitants of interior spaces. This research aims to create a framework that provides a strategy for the adaptation of responsive patterns to generate manipulative surfaces of topological richness in spatial variation to enhance environmental performance through passive design. This paper focuses on expressing the interior's identity through computational design and smart materials_ smart textiles in particular_ in a dynamic potential that reflects the diversity of form due to the impact of the emergence of modern trends in design. It changed the shape of interior spaces and gave it incipient interactive responsive properties. Computer design and digital fabrication techniques replaced static forms with living, interactive spaces through smart textile to alter their shape and function. As conclusion, these hybrid formations in design added a new functional dimension. Therefore, the smart materials and responsive proprieties have directly influenced the process of design and architecture, whether it's in the effectiveness of the design or the process of the fabrication and manufacturing of various structures.
Keywords
Generative Patterns; Digital Fabrication; Smart Textiles; Embedded Systems; Smart Materials; Responsive; Hybrid Behavior
References

[1].  Addington DM, Schodek DL. Smart materials and new technologies: for the architecture and design professions: Routledge; 2005.

[2].  Vyas D, Poelman W, Nijholt A, De Bruijn A, editors. Smart material interfaces: a new form of physical interaction. CHI'12 Extended Abstracts on Human Factors in Computing Systems; 2012: ACM.

[3].  Gould P. Textiles gain intelligence. Materials today. 2003;6(10):38-43.

[4].  Noor-Evans F, Incentives KR, Stingelin N. Nanotechnology innovation for future development in the textile industry. New Product Development in Textiles: Innovation and Production. 2011:109.

[5].  Kuusisto TK. Textile in Architecture. 2010.

[6].  Joshi M. The impact of nanotechnology on polyesters, polyamides and other textiles. Polyesters and Polyamides. 2008:354.

[7].  Engin M, Demirel A, Engin EZ, Fedakar M. Recent developments and trends in biomedical sensors. Measurement. 2005;37(2):173-88.

[8].  Khaldi W. Thermochromic laminates and methods for controlling the temperature of a structure. Google Patents; 2002.

[9].  Heynen H. Architecture and modernity: a critique: MIT press; 1999.

[10]. Shen J. Development and evaluation of phototherapy device made of luminous polymer optical fiber fabrics: The Hong Kong Polytechnic University; 2013.

[11]. Wong J, Glasser F, Imbabi M. Evaluation of thermal conductivity in air permeable concrete for dynamic breathing wall construction. Cement and Concrete Composites. 2007;29(9):647-55.

[12]. Hu J, Meng H, Li G, Ibekwe SI. A review of stimuli-responsive polymers for smart textile applications. Smart Materials and Structures. 2012;21(5):053001.

[13]. Nørstebø CA. Intelligent textiles, soft products. Journal of Future Materials. 2003:1-14.

[14].Robles E, Wiberg M, editors. Texturing the material turn in interaction design. Proceedings of the fourth international conference on Tangible, embedded, and embodied interaction; 2010: ACM.

Statistics
Article View: 413
PDF Download: 703