Materiali intelligenti per edifici NZEB. Opzioni tecnologiche adattive per il progetto sostenibile

Autori

  • Rosa Romano Università degli Studi di Firenze

DOI:

https://doi.org/10.19229/2464-9309/7132020

Parole chiave:

materiali nano-strutturati, comfort indoor, involucro adattivo, nZEB, efficienza energetica

Abstract

L’articolo presenta alcuni dei risultati della ricerca europea COST Action TU 1403 Adaptive Envelope, finalizzata a mappare a livello internazionale l’innovazione tecnologica legata alla progettazione e realizzazione di sistemi di facciata adattivi, analizzando i subsistemi che dalla micro alla macro-scala permettono di raggiungere e superare i target energetico-ambientali previsti dalle normative nazionali e internazionali vigenti. Partendo dall’analisi dello stato dell’arte, la trattazione si focalizzerà in particolare sul tema dei materiali intelligenti utilizzabili per la realizzazione di sistemi di chiusura verticale a schermo avanzato, capaci di migliorare il comfort indoor e l’efficienza energetica di edifici nuovi ed esistenti. Attraverso l’analisi delle caratteristiche materiche, tecnologiche e funzionali, saranno definiti i parametri qualitativi e prestazionali che ne caratterizzano l’utilizzo e il funzionamento a scala reale.

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Biografia autore

Rosa Romano, Università degli Studi di Firenze

Architetto e PhD, è Ricercatore presso il Dipartimento di Architettura. Svolge attività di ricerca prevalentemente nell’ambito delle tematiche inerenti la Sostenibilità Ambientale e il Risparmio Energetico degli edifici, approfondendo il tema della progettazione e valutazione energetica di componenti di facciata innovativi per il clima Mediterraneo.
E-mail: rosa.romano@unifi.it

Riferimenti bibliografici

Addington, D. M. and Schodek, D. L. (2005), Smart Materials and New Technologies – For the architecture and design professions, Architectural Press, Oxford. [Online] Available at: bintian.files.wordpress.com/2013/01/smart-materials-new-technologies-for-the-architecture-design-professions.pdf [Accessed 11 April 2020].

Aelenei, D., Aelenei, L., Loonen, R., Perino, M. and Serra, V. (2019), “Adaptive facades”, in Asdrubali, F. and Desideri, U. (eds), Handbook of Energy Efficiency in Buildings – A Life Cycle Approach offers a comprehensive and in-depth coverage of the subject with a further focus on the Life Cycle, Butterworth-Heinemann, Oxford, pp. 384-411. [Online] Available at: doi.org/10.1016/B978-0-12-812817-6.00039-5 [Accessed 11 April 2020].

Aelenei, L., Aelenei, D., Romano, R., Mazzucchelli, E. S., Brzezicki, M. and Rico-Martinez, J. M. (2018), Case Studies – Adaptive Facade Network, TU Delft Open for the COST Action 1403 Adaptive Facade Network, Delft. [Online] Available at: tu1403.eu/wp-content/uploads/Vol-3-1_for-web-Open-Access-9789463661102.pdf [Accessed 11 April 2020].

Aelenei, L., Pereira, R., Ferreira, A., Gonçalves, H. and Joyce, A. (2014), “Building Integrated Photovoltaic System with Integral Thermal Storage: A Case Study”, in Energy Procedia | Renewable Energy Research Conference – RERC 2014, pp. 172-178. [Online] Available at: doi.org/10.1016/j.egypro.2014.10.425 [Accessed 11 April 2020].

Alston, M. E. (2015), “Natures Building as Trees: Biologically Inspired Glass as an Energy System”, in Optics and Photonics Journal, vol. 4, n. 5, pp. 136-150. [Online] Available at: dx.doi.org/10.4236/opj.2015.54013 [Accessed 11 April 2020].

Correa, D. and Menges, A. (2017), “Fused filament fabrication for multi-kinematic-state climate-responsive aperture”, in Menges, A., Sheil, B., Glynn, R. and Skavara, M. (eds), Fabricate 2017, UCL Press, pp. 190-195. [Online] Available at: dx.doi.org/10.2307/j.ctt1n7qkg7.30 [Accessed 11 April 2020].

Del Grosso, A. E. and Basso, P. (2010), “Adaptive building skin structures”, in Smart Materials and Structures, vol. 19, n. 12, pp. 1-12. [Online] Available at: doi.org/10.1088/0964-1726/19/12/124011 [Accessed 11 April 2020].

Gallo, P. and Romano, R. (2018), “The SELFIE façade system. From Smart Buildings to Smart grid”, in Techne | European Pathway for the Smart Cities to come on behalf of EERA Joint Programme on Smart Cities, special series, vol. 1, pp. 166-172. [Online] Available at: doi.org/10.13128/Techne-22702 [Accessed 11 April 2020].

Hawkes, E., An, B., Benbernou, N. M., Tanaka, H., Kim, S., Demaine, E. D., Rus, D. and Wood, J. R. (2010), “Programmable matter by folding”, in PNAS – Proceedings of the National Academy of Science of the United States of America, vol. 107, n. 28, pp. 12441-12445. [Online] Available at: doi.org/10.1073/pnas.0914069107 [Accessed 11 April 2020].

Herzog, T., Krippner, R. and Lang, W. (2017), Facade Construction Manual, 2nd edition, Detail Business Information GmbH, Munich.

Juaristi, M., Gómez-Acebo, T. and Monge-Barrio, A. (2018), “Qualitative analysis of promising materials and technologies for the design and evaluation of Climate Adaptive Opaque Façades”, in Building and Environment, vol. 144, pp. 482-501. [Online] Available at: dx.doi.org/10.1016/j.buildenv.2018.08.028 [Accessed 11 April 2020].

Kretzer, M. and Rossi, D. (2012), “ShapeShift”, in Leonardo, vol. 45, n. 5, pp. 480-481.

Luible, A. and Overend, M. (2018), “COST Action TU1403 – Adaptive Facades Network”, in Luible, A. and Gosztonyi, S. (eds), Facade 2018 - Adaptive! | Proceedings of the COST Action TU1403 – Adaptive Facades Network Final Conference, Lucerne University of Applied Sciences and Arts Lucerne, Lucerne Switzerland, 26-27 November 2018, TU Delf Open, pp. 19-23. [Online] Available at: tu1403.eu/wp-content/uploads/COST_endconference2018_webversion.pdf [Accessed 11 April 2020].

Mazzucchelli, E. S., Alston, M., Brzezicki, M. and Doniacovo, L. (2018), “Study of a BIPV Adaptive System: Combining Timber and Photovoltaic Technologies”, in Journal of Facade Design and Engineering, vol. 6, n. 3, pp. 149-162. [Online] Available at: doi.org/10.7480/jfde.2018.3.2602 [Accessed 11 April 2020].

Memon, S. A. (2014), “Phase change materials integrated in building walls: A state of the art review”, in Renewable and Sustainable Energy Reviews, vol. 31, pp. 870-906. [Online] Available at: dx.doi.org/10.1016/j.rser.2013.12.042 [Accessed 11 April 2020].

Pesenti, M., Masera, G. and Fiorito, F. (2018), “Exploration of Adaptive Origami Shading Concepts through Integrated Dynamic Simulations”, in Journal of Architectural Engineering, vol. 24, issue 4, pp. 1-14.

Reichert, S., Menges, A. and Correa, D. (2014), “Meteorosensitive architecture: Biomimetic building skins based on materially embedded and hygroscopically enabled responsiveness”, in Computer-Aided Design, vol. 60, pp. 50-69. [Online] Available at: doi.org/10.1016/j.cad.2014.02.010 [Accessed 11 April 2020].

Romano, R. (2010), Smart Skin Envelope – Integrazione architettonica di tecnologie dinamiche e innovative per il risparmio energetico, Firenze University Press, Firenze. [Online] Available at: www.fupress.com/archivio/pdf/5056.pdf [Accessed 11 April 2020].

Velikov, K. and Thün, G. (2013), “Responsive Building Envelopes: Characteristics and evolving paradigms”, in Trubiano, F. (ed.), Design and Construction of High-Performance Homes – Building Envelopes, Renewable Energies and Integrated Practice, Routledge, pp. 75-92. [Online] Available at: rvtr.com/files/HPH.pdf [Accessed 11 April 2020].

Wood, D. M., Correa, D., Krieg, O. D. and Menges, A. (2016), “Material Computation – 4D Timber Construction: Towards Building-Scale Hygroscopic Actuated, Self-Constructing Timber Surfaces”, in International Journal of Architectural Computing, vol. 14, issue 1, pp. 49-62. [Online] Available at: doi.org/10.1177/1478077115625522 [Accessed 11 April 2020].

Yoneda, Y. (2007), Interactive Living Glass regulates air quality. [Online] Available at: inhabitat.com/carbon-dioxide-sensing-living-glass/ [Accessed 11 April 2020].

P. Cabrita, I. Diniz and L. Aelenei, ‘Solar XXI – BIPV/T Systems’, Lisbon, 2006 (credit: L. Alenei). AGATHÓN 7 | 2020

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Pubblicato

21-06-2020

Come citare

Romano, R. (2020) «Materiali intelligenti per edifici NZEB. Opzioni tecnologiche adattive per il progetto sostenibile», AGATHÓN | International Journal of Architecture Art and Design, 7(online), pagg. 124–131. doi: 10.19229/2464-9309/7132020.

Fascicolo

Sezione

Architettura | Saggi & Punti di vista