Impresión 3D en arcilla de columnas biorreceptivas texturizadas: Hacia una tecnología de construcción democrática, sostenible y emergente
Abstract
Clay 3D printing has been gaining increasing interest as a sustainable and environmentally friendly building material with favourable climatic and economic qualities
References
Ddeal.com (2023). 3D Printing a House: Time Duration. Medium. https://medium.com/@3Ddeal/3d-printing-a-house-time-duration-9d7f8374c414.
Abdalla, H., Fattah, K.P., Abdallah, M. & Tamimi, A.K. (2021). Environmental Footprint and Economics of a Full-Scale 3D-Printed House. Sustainability, 13(21), p. 11978. https://doi.org/10.3390/su132111978.
Abdallah, Y.K. (s.f.). Gaudi Morphogenesis. https://www.academia.edu/31718614/Gaudi_Morphogenesis_pdf.
Abdallah, Y.K. & Estévez, A.T. (2021). 3D-Printed Biodigital Clay Bricks. Biomimetics, 6(4), p. 59. https://doi.org/10.3390/biomimetics6040059.
Abdallah, Y.K. & Estévez, A.T. (2023). 3D-Printed Bioreceptive Tiles of Reaction–Diffusion (Gierer–Meinhardt Model) for Multi-Scale Algal Strains’ Passive Immobilization. Buildings, 13(8), p. 1972. https://doi.org/10.3390/buildings13081972.
Abdallah, Y.K. & Estévez, A.T. (2023). Biomaterials Research-Driven Design Visualized by AI Text-Prompt-Generated Images. Designs, 7(2), p. 48. https://doi.org/10.3390/designs7020048.
Abdallah, Y.K. & Estévez, A.T. (2023). Biowelding 3D-Printed Biodigital Brick of SeashellBased Biocomposite by Pleurotus ostreatus Mycelium. Biomimetics, 8(6), p. 504. https://doi.org/10.3390/biomimetics8060504. additive.dk. (s.f.). Adrian Rygh Brun - International 1st. prize: 3D printed concrete/Mycelium. https://additive.dk/integrated-3d-printed-wall.
Advances in Wound Care. (2021). Epithelialization in Wound Healing: A Comprehensive Review | Advances in Wound Care. https://doi.org/10.1089%2Fwound.2013.0473.
Agustí-Juan, I. & Habert, G. (2017). Environmental design guidelines for digital fabrication. Journal of Cleaner Production, 142, pp. 2780-2791. albertoestévez.es. (s.f.). Alberto T. Estévez architect. http://albertoestevez.es/.
Allouzi, R., Al-Azhari, W. & Allouzi, R. (2020). Conventional Construction and 3D Printing: A Comparison Study on Material Cost in Jordan. Journal of Engineering, 2020, pp. 1-14. https://doi.org/10.1155/2020/1424682.
Aniwaa. (s.f.). Clay 3D printer: selection and guide to ceramic clay 3D printing. Recuperado de https://www.aniwaa.com/buyers-guide/3d-printers/clay-3d-printer-selection-and-guide/.
Aniwaa. (s.f.). Guide to Robotic Arm 3D Printing. https://www.aniwaa.com/guide/3dprinters/robotic-arm-3d-printing-guide/.
Anónimo. (2023). This 3D-printed house could resist a 9.0 magnitude earthquake. https://www.euronews.com/next/2023/10/25/this-company-has-3d-printed-a-house-that-canwithstand-a-90-magnitude-earthquake.
Anton, A. & Abdelmahgou, A. (2018). Ceramic Components - Computational Design for Bespoke Robotic 3D Printing on Curved Support. eCAADe Proceedings. https://doi.org/10.52842/conf.ecaade.2018.2.071.
Anton, A., Reiter, L., Wangler, T., Frangez, V., Flatt, R.J., & Dillenburger, B. (2021). A 3D concrete printing prefabrication platform for bespoke columns. Automation in Construction, 122, p. 103467.
ArchDaily. (2019). ETH Zurich Develops 3D-Printed Concrete Columns. https://www.archdaily.com/921635/eth-zurich-develops-3d-printed-concrete-columns.
ArchDaily. (2020). 5 Alternative Materials for Building Emergency Shelters. https://www.archdaily.com/939873/5-alternative-materials-for-building-emergency-shelters?ad_campaign=special-tag.
ArchDaily. (2020). Alternative Healthcare Facilities: Architects Mobilize their Creativity in Fight against COVID-19. https://www.archdaily.com/937840/alternative-healthcare-facilitiesarchitects-mobilize-their-creativity-in-fight-against-covid-19?ad_campaign=special-tag.
ArchDaily. (2020). Community Centers for Displaced Populations. https://www.archdaily.com/939820/community-centers-for-displaced-populations?ad_campaign=special-tag.
ArchDaily. (2020). Public Spaces with Scaffolding: an Alternative in Emergency Situations. https://www.archdaily.com/940513/public-spaces-with-scaffolding-an-alternative-inemergency-situations?ad_campaign=special-tag.
ArchDaily. (2020). The Use of Prefabrication in 6 Emergency Projects Around the World. https://www.archdaily.com/939754/the-use-of-prefabrication-in-6-emergency-projectsaround-the-world?ad_campaign=special-tag.
ArchDaily. (2021). Refugee Camps: From Temporary Settlements to Permanent Dwellings. https://www.archdaily.com/940384/refugee-camps-from-temporary-settlements-topermanent-dwellings?ad_campaign=special-tag.
Architecture, Design and Conservation - Danish Portal for Artistic and Scientific Research. (2022). Textile Columns: Drawing and weaving with 3D printed clay: BE-AM 2022 Symposium and Exhibition. https://adk.elsevierpure.com/en/publications/textile-columnsdrawing-and-weaving-with-3d-printed-clay. architectureindevelopment.org. (s.f.). A--D -- Mousgoum dwellings. https://architectureindevelopment.org/project/68.
AZoM.com. (2022). 3D Printing Clay Bricks for Construction. https://www.azom.com/news.aspx?newsID=57853.
Bazli, M., Ashrafi, H., Rajabipour, A. & Kutay, C. (2023). 3D printing for remote housing: Benefits and challenges. Automation in Construction, 148, p. 104772. https://doi.org/10.1016/j.autcon.2023.104772.
Bergaya, F. & Lagaly, G. (2006). General introduction: clays, clay minerals, and clay science. Developments in Clay Science, 1, pp. 1-18.
Biomimicry 3.8. (s.f.). Biomimicry Resource Handbook. https://biomimicry.net/the-buzz/resources/biomimicry-resource-handbook/.
Boafo, F., Kim, J.-H. & Kim, J.-T. (2016). Performance of Modular Prefabricated Architecture: Case Study-Based Review and Future Pathways. Sustainability, 8(6), p. 558. https://doi.org/10.3390/su8060558.
Bories, C., Vedrenne, E., Paulhe-Massol, A., Vilarem, G. & Sablayrolles, C. (2016). Development of porous fired clay bricks with bio-based additives: Study of the environmental impacts by Life Cycle Assessment (LCA). Construction and Building Materials, 125, pp. 1142-1151. https://doi.org/10.1016/j.conbuildmat.2016.08.042.
Building Bytes 3D Printed Bricks by Brian Peters at Dutch Design Week. https://www.dezeen.com/2012/10/31/building-bytes-3d-printed-bricks-brian-peters/.
Camacho, D.D., Clayton, P., O’Brien, W.J., Seepersad, C., Juenger, M., Ferron, R. & Salamone, S. (2018). Applications of additive manufacturing in the construction industry–A forward-looking review. Automation in Construction, 89, pp. 110-119.
Carpenter, S. (2019). 3D Printing in Construction – How Long Does it Take to Print a House? https://all3dp.com/2/3d-printing-in-construction-how-long-does-it-take-to-print-ahouse/.
Chang, B. (s.f.). The use of 3D printing in homebuilding is set to drastically expand in 2023. https://www.businessinsider.com/2023-new-year-of-3d-printed-homes-us-photos2022-12#but-proponents-of-the-construction-tech-like-zack-mannheimer-ceo-of-3dprinting-construction-startup-alquist-believe-printing-may-alleviate-some-of-the-sorespots-in-the-traditional-home-building-process-12.
Civil-protection-humanitarian-aid.ec.europa.eu. (s.f.). Jordan. https://civil-protectionhumanitarian-aid.ec.europa.eu/where/middle-east-and-northern-africa/jordan_en.
Delgado, J.M.D., Oyedele, L., Ajayi, A., Akanbi, L., Akinade, O., Bilal, M. and Owolabi, H. (2019). Robotics and automated systems in construction: Understanding industry-specific challenges for adoption. Journal of Building Engineering, 26, p. 100868.
Dezeen. (2012). Building Bytes 3D printed bricks by Brian Peters at Dutch Design Week. https://www.dezeen.com/2012/10/31/building-bytes-3d-printed-bricks-brian-peters/.
Dezeen. (2021). First tenants move into 3D-printed home in Eindhoven. https://www.dezeen.com/2021/05/06/3d-printed-home-project-milestone-eindhoven/.
Dezeen. (2021). Seven 3D-printed houses that have been built around the world https://www.dezeen.com/2021/05/14/seven-3d-printed-houses-around-world/.
Dixit, M.K. (2019). 3-D Printing in Building Construction: A Literature Review of Opportunities and Challenges of Reducing Life Cycle Energy and Carbon of Buildings. IOP Conference Series: Earth and Environmental Science, 290, p. 012012. https://doi.org/10.1088/1755-1315/290/1/012012.
Dong, L., Wang, Y., Li, H.X., Jiang, B. & Al-Hussein, M. (2018). Carbon reduction measures based LCA of prefabricated temporary housing with renewable energy systems. Sustainability, 10(3), p. 718.
Edwards, B. (2010). Rough guide to sustainability. Riba Publishing.
Estévez, A.T. & Abdallah, Y.K. (2022). The New Standard is Biodigital: Durable and Elastic 3D-Printed Biodigital Clay Bricks. Biomimetics, 7(4), p. 159. https://doi.org/10.3390/biomimetics7040159.
Estévez, A.T. & Abdallah, Y.K. (2023). Biodigital design and symbolism in the Sagrada Familia Biodigital Bridge. World Review of Science, Technology and Sustainable Development, 19(4), pp. 365-382. https://doi.org/10.1504/wrstsd.2023.133889.euronews.
Estévez, A.T. (2023). “Biodigital Architecture and Genetics”, en Alberto T. Estévez (ed.), 5th International Conference for Biodigital Architecture & Genetics, iBAG-UIC Barcelona, Barcelona, p. 15.
Feng, P., Meng, X., Chen, J.-F. & Ye, L. (2015). Mechanical properties of structures 3D printed with cementitious powders. Construction and Building Materials, 93, pp. 486-497. https://doi.org/10.1016/j.conbuildmat.2015.05.132.
Ferretti, E., Moretti, M., Chiusoli, A., Naldoni, L., De Fabritiis, F. & Visonà, M. (2022). Mechanical Properties of a 3D-Printed Wall Segment Made with an Earthen Mixture. Materials, 15(2), p. 438. https://doi.org/10.3390/ma15020438.
Foley, N.K. (1999, Septiembre). Environmental Characteristics of Clays and Clay Mineral Deposits. https://doi.org/10.3133/70220359
Garfield, L. (s.f.). In under six months, a robot can produce this home for as little as $300,000. https://www.businessinsider.com/home-3d-printer-robot-construction-branch-technology-2018-4 [Acceso 22 Nov. 2023].
Gomaa, M., Jabi, W., Veliz Reyes, A. & Soebarto, V. (2021). 3D printing system for earth-based construction: Case study of cob. Automation in Construction, 124, p. 103577. https://doi.org/10.1016/j.autcon.2021.103577.
Greguric, L. (s.f.) How Much Does a 3D Printed House Cost in 2021? https://all3dp.com/2/3dprinted-house-cost/.
Gunawardena, T. & Mendis, P. (2022). Prefabricated Building Systems—Design and Construction. Encyclopedia, 2(1), pp. 70-95. https://doi.org/10.3390/encyclopedia2010006.
Gürsoy, B. (s.f.) From Control to Uncertainty in 3D Printing with Clay. http://papers.cumincad.org/data/works/att/ecaade2018_104.pdf.
Hahn, J. (2022). Blast Studio 3D prints column from mycelium to make ‘architecture that could feed people’. https://www.dezeen.com/2022/01/18/blast-studio-tree-column-myceliumdesign/.
Hayes, S., Toner, J., Desha, C. & Gibbs, M. (2020). Enabling biomimetic place-based design at scale. Biomimetics, 5(2), p. 21.
Herder, G. (2022). First 3D Printed House Made From Local Raw Earth. https://www.eclectictrends.com/first-3d-printed-house-made-from-local-raw-earth/.
Hossain, M.A., Zhumabekova, A., Paul, S.C. & Kim, J.R. (2020). A review of 3D printing in construction and its impact on the labor market. Sustainability, 12(20), p. 8492. https://www.fastcompany.com/3062703/this-bricklaying-robot-can-build-low-cost-housesin-two-days.
Jiang, H., Qin, S., Fu, J., Zhang, J. & Ding, G. (2021). How to model and implement connections between physical and virtual models for digital twin application. Journal of Manufacturing Systems, 58, pp. 36-51. https://doi.org/10.1016/j.jmsy.2020.05.012.
Joh, C., Lee, J., Bui, T.Q., Park, J. & Yang, I.-H. (2020). Buildability and Mechanical Properties of 3D Printed Concrete. Materials, 13(21), p. 4919. https://doi.org/10.3390/ma13214919.
Keighley, D.G. (2013). Sedimentology and sedimentary basins: from turbulence to tectonics by Mike Leeder. Chichester: Wiley-Blackwell.
Khalili Tari, M., Reza Faraji, A., Aslani, A. & Zahedi, R. (2023). Energy simulation and life cycle assessment of a 3D printable building. Cleaner Materials, p. 100168. https://doi.org/10.1016/j.clema.2023.100168.
Kornmann, M. (2005). Clay Building Materials: Manufacturing and Properties. New South Wales Technical and Further Education Commission: New South Wales.
Lozano-Miralles, J.A., Hermoso-Orzáez, M.J., Martínez-García, C. & Rojas-Sola, J.I. (2018). Comparative study on the environmental impact of traditional clay bricks mixed with organic waste using life cycle analysis. Sustainability, 10(8), p. 2917.
Lubelli, B., et al. (2021). Influence of brick and mortar properties on bioreceptivity of masonry – Results from experimental research. Construction and Building Materials, 266, p.121036. https://doi.org/10.1016/j.conbuildmat.2020.121036.
Marjan Colletti. (s.f.). Coralloid Cocoons. https://www.marjancolletti.com/coralloid-cocoons.
McFadden, C. (2021). 7 of the most beautiful 3D-printed houses and cabins. https://interestingengineering.com/lists/7-of-the-most-beautiful-3d-printed-houses-and-cabins.
Miles, M. (2006). Utopias of mud? Hassan Fathy and alternative modernisms. Space and Culture, 9(2), pp. 115-139.
Mohseni, A., Vieira, F.R., Pecchia, J.A. & Gürsoy, B. (2023). Three-Dimensional Printing of Living Mycelium-Based Composites: Material Compositions, Workflows, and Ways to Mitigate Contamination. Biomimetics, 8(2), p. 257. https://doi.org/10.3390/biomimetics8020257.
Molitch-Hou, M. (2014). PolyBricks: 3D Printed Clay for 3D Printed Buildings. https://3dprintingindustry.com/news/polybricks-3d-printed-clay-3d-printed-buildings-28627/.
Moreno-Maroto, J.M. & Alonso-Azcárate, J. (2018). What is clay? A new definition of “clay” based on plasticity and its impact on the most widespread soil classification systems. Applied Clay Science, 161, pp. 57-63.
Mostafavi, S., Bier, H., Bodea, S. & Anton, A. (2015). Informed Design to Robotic Production Systems, Developing Robotic 3D Printing System for Informed Material Deposition, eCAADe 2015 Proceedings, Viena, pp. 287-296.
Munir, Q. & Kärki, T. (2021). Cost Analysis of Various Factors for Geopolymer 3D Printing of Construction Products in Factories and on Construction Sites. Recycling, 6(3), p. 60. https://doi.org/10.3390/recycling6030060.
Mustafa, K.F., Prieto, A. & Ottele, M. (2021). The role of geometry on a self-sustaining bioreceptive concrete panel for facade application. Sustainability, 13(13), p. 7453. Paolo Verme, Chiara Gigliarano, Wieser, C., Hedlund, K., Petzoldt, M. & Santacroce, M. (2015). The Welfare of Syrian Refugees. World Bank Publications.
Perrot, A., Rangeard, D. & Courteille, E. (2018). 3D printing of earth-based materials: Processing aspects. Construction and Building Materials, 172, pp. 670-676. https://doi.org/10.1016/j.conbuildmat.2018.04.017.
Rayna, T. & Striukova, L. (2016). From rapid prototyping to home fabrication: How 3D printing is changing business model innovation. Technological Forecasting and Social Change, 102, pp. 214-224.
Re, D., Biccari, C.D. & Corallo, A. (2022). A Cost Model for Additive Manufacturing in Construction.IOP Conference Series: Earth and Environmental Science, 1101(9), p. 092014. https://doi.org/10.1088/1755-1315/1101/9/092014.
Reynolds, J. (2022). How Long Does It Take to 3D Print a House? https://www.nikkoindustries.com/blogs/news/how-long-does-it-take-to-3d-print-a-house.
Rovenskii, V.Y. (2000). Geometry of Curves and Surfaces with MAPLE. Google Books. Springer Science & Business Media. https://books.google.es/books?id=K31Nzi_xhoQC&pg=PA277&dq=conoid+maple&lr=&ei=B9hvSs_qKYzSkASR8c3XDg&redir_esc=y#v=onepage&q=conoid%20maple&f=.
Royal Danish Academy (2019). 3D printing ceramics: A modular column system. https://royaldanishacademy.com/project/3d-printing-ceramics-modular-column-system.
Salandin, A., Quintana-Gallardo, A., Gómez-Lozano, V. & Guillén-Guillamón, I. (2022). The First 3D-Printed Building in Spain: A Study on Its Acoustic, Thermal and Environmental Performance. Sustainability, 14(20), p. 13204, https://doi.org/10.3390/su142013204.
Schuldt, S.J., Jagoda, J.A., Hoisington, A.J. & Delorit, J.D. (2021). A systematic review and analysis of the viability of 3D-printed construction in remote environments. Automation in Construction, 125, p. 103642. https://doi.org/10.1016/j.autcon.2021.103642.
Segovia, M. & Garcia-Alfaro, J. (2022). Design, Modeling and Implementation of Digital Twins. Sensors, 22(14), p. 5396, https://doi.org/10.3390/s22145396.
Shahzad, W.M., Rajakannu, G. & Kordestani Ghalenoei, N. (2022). Potential of Modular Offsite Construction for Emergency Situations: A New Zealand Study. Buildings, 12(11), p. 1970. https://doi.org/10.3390/buildings12111970.sheltercluster.org. (s.f.).
Shen, S., Lee, N.A., Lockett, W.J., Acuil, A.D., Gazdus, H.B., Spitzer, B.N. & Buehler, M.J. (2023). Robust Myco-Composites as a Platform for Versatile Hybrid-Living Structural Materials. arXiv (Cornell University). https://doi.org/10.48550/arxiv.2305.12151.
Smolova, M. & Smolova, D. (2021). Emergency architecture. Modular construction of healthcare facilities as a response to pandemic outbreak. E3S Web of Conferences, 274, p. 01013. https://doi.org/10.1051/e3sconf/202127401013.
Sullivan, Louis H. (1896, Marzo). The tall office building artistically considered, Lippincott’s Magazine, Filadelfia, pp. 403-409.
SYRIA: Shelter Sector (2016) Year-End Report | Shelter Cluster. https://sheltercluster.org/syria-hub/documents/syria-shelter-sector-2016-year-end-report. The World’s Largest 3D-Printed Neighborhood Is Here (s.f.). https://www.bloomberg.com/features/2023-3d-printed-houses-austin-texas/#:~:text=A%20layer%20of%20Lavacrete%20will.This Twisting Tower is Made Out of 2000 3D-Printed Terracotta Bricks. Available online: https://inhabitat.com/this-twisting-tower-is-made-out-of-2000-3dprinted-terracotta-bricks/.
Turan, M. (2009). Reconstructing the balloon frame: a study in the history of architectonics.
Tyrer-Jones, A. (2023). Researchers develop new fungi-based 3D printing material. https://3dprintingindustry.com/news/researchers-develop-new-fungi-based-3d-printing-material-225036/.
UCL (2022). Computational Seeding of Bio-Receptive Materials. https://www.ucl.ac.uk/ bartlett/architecture/research/computation-and-craft-technologies/computationalseeding-bio-receptive-materials. Universitat Internacional de Catalunya (s.f.). Master’s Degree in Biodigital Architecture. https://www.uic.es/en/estudis-uic/architecture/masters-degree-biodigital-architecture.
Universiteit Gent. (s.f.). Mechanical properties and durability of 3D printed cementitious materials. https://www.ugent.be/ea/structural-engineering/en/research/projects/allprojects/ mechanical-properties-and-durability-of-3d-printed-cementitious-materials. Van Den Bergh, J., Nieuw, C., Slob, W., Escalante Suarez, M. and Velema, P. (s.f.). Modular 3D printing construction: towards affordable, adjustable and climate- resilient housing. https://sdgs.un.org/sites/default/files/2022-05/2.4.4-14-van%20den%20Bergh%20-Modular%203D%20printing%20construction.pdf.
Wang, D., Zhang, Y., Zhu, Y., Wu, C., Zhou, Y. & Han, Q. (2021). Mechanical performance of sustainable modular prefabricated composite shear panels under cyclic loading. Journal of Constructional Steel Research, 179, p. 106423. https://doi.org/10.1016/j.jcsr.2020.106423.
Weisstein, E.W. (s.f.). Hyperbolic Paraboloid. http://mathworld.wolfram.com/HyperbolicParaboloid.html.
Wikipedia. (2023). Syrian refugee camps. https://en.wikipedia.org/wiki/Syrian_refugee_camps#/media/File:Kurdish_Refuge_Camp_in_Suruc_Turkey.jpg.
Wu, P., Wang, J. & Wang, X. (2016). A critical review of the use of 3-D printing in the construction industry. Automation in Construction, 68, pp. 21-31. www.granddesignsmagazine.com. (s.f.). Construction duration estimation. https://www.granddesignsmagazine.com/self-build/construction/construction-duration-estimation/.
Xiao, J., Lv, Z., Duan, Z. & Hou, S. (2022). Study on preparation and mechanical properties of 3D printed concrete with different aggregate combinations. Journal of Building Engineering, [online] 51, p. 104282. doi:https://doi.org/10.1016/j.jobe.2022.104282.
Yu, Q., Zhu, B., Li, X., Meng, L., Cai, J., Zhang, Y. & Pan, J. (2023). Investigation of the rheological and mechanical properties of 3D printed eco-friendly concrete with steel slag. Journal of Building Engineering, 72, p. 106621. https://doi.org/10.1016/j.jobe.2023.106621.
Zaha-hadid.com. (2023). Thallus for White in the City – Zaha Hadid Architects. https://www.zaha-hadid.com/2017/04/05/thallus-for-white-in-the-city/.
Zakrzewski, W., Dobrzynski, M., Szymonowicz, M. & Rybak, Z. (2019). Stem cells: Past, Present, and Future. Stem Cell Research & Therapy, 10(1). https://doi.org/10.1186/s13287-019-1165-5.
Zhang, J., Wang, J., Dong, S., Yu, X. & Han, B., (2019). A review of the current progress and application of 3D printed concrete. Composites Part A: Applied Science and Manufacturing, 125, p. 105533.
Zhang, N., Wu, Y., Yang, R. & Xie, G. (2023). Digital Simulation and Analysis of AssemblyDeviation Prediction Based on Measurement Data. Applied Sciences, 13(22), pp. 12193- 12193. https://doi.org/10.3390/app132212193.
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