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- 16 NovHenriette Bier acts as member of the scientific committee of Oxford Journal Interacting with Computers
- 16 NovA. Liu Cheng and H. Bier publish paper on Adaptive Building-Skin Components as Context-Aware Nodes in an Extended Cyber-Physical Network for IEEE World Forum on Internet of Things 2016
- 04 NovTiantian Du and Nimish Biloria hosted the workshop "Transitional Space Design and the Concept of Architectural Thermodynamics"
- 04 NovHenriette Bier appointed as member of the scientific committee of IJAC journal
- 18 OctDr. Nimish Biloria appointed as Scientific Committee member for the CAAD Futures 2017 Conference: Future Trajectories of Computation in Design
- 23 SepHenriette Bier appointed as member of the scientific committee of CAAD Futures 2017: Future Trajectories of Computation in Design
- 23 SepHenriette Bier certified reviewer of Elsevier's Journal of Materials and Design
- 23 SepProf. Kas Oosterhuis speaker at MakeHappen! Inspiration Day 2016
- 16 SepHyperbody graduate students Ralph Cloot and Arwin Hidding in collaboration with Sina Mostafavi and supervised by Kas Oosterhuis design a building for Neurotopia
- 15 SepDr. Nimish Biloria has been appointed as Associate Partner for the LASG (Living Architecture Systems Group), University of Waterloo, Canada
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Author- By: N. Biloria
- Date
- 04.01.2016
- Keywords
- Material engineering, Robotics, Micro-climate, Physiological support, Real-time interaction, Health and Energy, Multi-performative interiors, Scalability, Sustainable material usage
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Fibrous Smart Material Topologies initiated by Dr. Nimish Biloria has received funding from 3TU.Bouw and will be implemented in collaboration with TU Eindhoven, U Twente and EURECAT
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Fibrous Smart Material Topologies initiated by Dr. Nimish Biloria has received funding from 3TU.Bouw and will be implemented in collaboration with TU Eindhoven, U Twente and EURECAT
The project is a truly inter-disciplinary initiative for the 'designed engineering' of heterogeneous fibres with variable material behaviors to create real-time responsive interior environments (furniture systems). These smart furniture systems will embody properties of real-time adaptive temperature control, real-time structural adaptability and real-time physiological support of the human body. These properties shall be fully self-regulated (devoid of external power sources) via engineering multi-layered fibre compositions, which, can sense the forces exerted by the human body and accordingly alter their physical properties. The scale of operation is chosen deliberately, considering the time-span of one year within which we will produce of a fully operational 1:1 physical prototype and scientific material-research guidelines. A research through design approach with 3 iterations: working on the yarn (U Twente + EURECAT), textile (TUE) and product (TUD) levels shall be adopted in this research. Each iteration will consist of the development of a prototype, the creation of future usage scenarios + business possibilities and a workshop to envision future requirements. In this project, prototypes and material output will be co-designed with material scientists, architects, textile and industrial designers and will be used to assess 1) design challenges, 2) business opportunities, and 3) technical feasibility of scalable multi-performative interior systems for applications such as healthcare and future office environments.
https://www.3tu.nl/bouw/en/