Cumincad : CUMINCAD References : Search Results

CumInCAD is a Cumulative Index about publications in Computer Aided Architectural Design
supported by the sibling associations ACADIA, CAADRIA, eCAADe, SIGraDi, ASCAAD and CAAD futures

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	Helm, V., J. Willmann, A. Thoma, L. Piskorec, N. Hack, F. Gramazio, and M. Kohler (2015) Iridescence Print: Robotically Printed Lightweight Mesh Structures , 3D Printing and Additive Manufacturing 2 (3): 117–122

	Helm, Volker; Jan Willmann, Andreas Thoma, Luka Piškorec, Norman Hack, Fabio Gramazio, and Matthias Kohler (2015) Iridescence print: Robotically printed lightweight mesh structures. , 3D Printing and Additive Manufacturing 2(3): 117–122

	Beckh, Matthias (2015) Hyperbolic Structures: Shukhov’s Lattice Towers—Forerunners of Modern Lightweight Construction , Chichester, UK: Wiley

	Correa D, Papadopoulou A, Guberan C, et al. (2015) 3D-printed wood: programming hygroscopic material transformations , 3D Print Addit Manuf; 2: 106–116

	Dantas, A. C. S., Scalabrin, D. H., De Farias, R., Barbosa, A. A., Ferraz, A. V. & Wirth, C. (2016) Design of Highly Porous Hydroxyapatite Scaffolds by Conversion of 3D Printed Gypsum Structures – A Comparison Study , Procedia CIRP, 49, 55–60. https://doi.org/10.1016/j.procir.2015.07.030

	Hack, N, Lauer, W, Gramazio, F and Kohler, M (2015) Mesh Mould: Robotically fabricated metal meshes as concrete formwork and reinforcement , Ferro-11: Proceedings of the 11th International Symposium on Ferrocement and 3rd ICTRC International Conference on Textile Reinforced Concrete, pp. 347-359

	Hack, N, Lauer, W, Gramazio, F and Kohler, M (2015) Mesh Mould: robotically fabricated metal meshes as concrete formwork and reinforcement , Ferro-11 and 3rd ICTRC

	Hack, N, Lauer, W, Gramazio, F and Kohler, M (2015) Mesh Mould: robotically fabricated metal meshes as concrete formwork and reinforcement , Ferro, 11, pp. 347-359

	Hamm, C. (2015) Evolution of lightweight structures: analyses and technical applications (Vol 6) , Springer

	Kontovourkis O and Tryfonos G. (2015) Robotic fabrication of tensile mesh structures and real time response—the development and simulation of a custom-made end effector tool , Real time—proceedings of the 33rd eCAADe conference (ed Martens B, Wurzer G, Grasl T, et al.), Vienna, 16–18 September 2015, pp. 389–398.Vienna: Vienna University of Technology

	Kontovourkis O and Tryfonos G. (2015) An additive robotic fabrication methodology for tensile mesh structures development , IASS2015 annual international symposium on future visions (ed Huybers P), Amsterdam, The Netherlands, 17–20 August 2015. Amsterdam, The Netherlands: KIVI

	Menges, A., J. Knippers, V. Schwieger (2014) Landesgartenschau Exhibition Hall: Robotically Fabricated Lightweight Timber Shell , Schwa?bisch Gmu?nd, Germany. Accessed July 1, 2015. http://icd.uni-stuttgart. de/?p=10631

	Partsch, L., Vassiliadis, S., & Papageorgas, P. (2015) 3D Printed Textile Fabrics Structures , 5th International Istanbul Textile Congress 215: Innovative Technologies "Inspire to Innovate" September 11th -12th 215 Istanbul, Turkey. Available at: https://www.researchgate.net/publication/2832889

	Pronk, A., El Ghazi, H., Seffinga, A., & Schuijers, N. H. (2015) Flexible mould by the use of spring steel mesh , Proceedings of the International Association for Shell and Spatial Structures (IASS) Symposium 2015, Amsterdam, Netherlands, pp. 1-9. Available at: https://research.tue.nl/files/11626205/Paper_IASS_glass.pdf

	Hansemann G, Schmid R, Holzinger C, et al (2021) Lightweight Reinforced Concrete Slab: 130 different 3D printed voids. , CPT Worldw - Constr Print Technol 2021; 2021(2): 68

	Adelzadeh, A., Karimian H., Ahlund, K., Robeller, C., (2023) Reciprocal Shell: A Hybrid Timber System for Robotically-fabricated Lightweight Shell Structures , Proceedings of the 41st Conference on Education and Research in Computer Aided Architectural Design in Europe (eCAADe 2023) - Volume 1, Graz, 20-22 September 2023, pp. 651-660

	Bedarf, P., Szabo, A., Zanini, M. & Dillenburger, B. (2021) Machine Sensing for Mineral Foam 3D Printing , International Conference on Intelligent Robots and Systems: Workshop Robotic Fabrication, IROS 2021. https://doi.org/10.3929/ethz-b-000506097BubbleDeck. (2021). The Original Voided Slab. Retrieved May 11 2021, from https://www.bubbledeck.comCobiax. (2021). Voided flat plate slab technologies available worldwide. Retrieved May 11 2021, from https://www.cobiax.com/intl/en/Compas. (2020). Retrieved May 11 2021, from https://compas.dev/index.htmlFernández-Jiménez, A., & Palomo, A. (2005). Composition and microstructure of alkali activated fly ash binder: Effect of the activator. Cement and Concrete Research, 35(10), 1984–1992. https://doi.org/10.1016/j.cemconres.2005.03.003Furet, B., Poullain, P., & Garnier, S. (2019). 3D printing for construction based on a complex wall of polymer-foam and concrete. Additive Manufacturing, 28, 58–64. https://doi.org/10.1016/j.addma.2019.04.002Georgopoulos, C., & Minson, A. (2014). Sustainable concrete solutions. Wiley-Blackwell.Halpern, A. B., Billington, D. P., & Adriaenssens, S. (2013). The Ribbed Floor Slab Systems of Pier Luigi Nervi. Proceedings of the International Association for Shell and Spatial Structures (IASS), 7. http://formfindinglab.princeton.edu/wp-content/uploads/2011/09/Nervi_ribbed_floors.pdfHansemann, G., Schmid, R., Holzinger, C., Tapley, J. P., Peters, S., Trummer, A., & Kupelwieser, H. (2021). Lightweight Reinforced Concrete Slab: 130 different 3D printed voids. CPT Worldwide - Construction Printing Technology, 2021(2), 68.Jipa, A., Calvo Barentin, C., Lydon, G., Rippmann, M., Chousou, G., Lomaglio, M., Schlüter, A., Block, P., & Dillenburger, B. (2019). 3D-Printed Formwork for Integrated Funicular Concrete Slabs. Proceedings of the IASS Annual Symposium 2019, 10. https://www.researchgate.net/publication/335175125_3D-Printed_Formwork_for_Integrated_Funicular_Concrete_SlabsJipa, A., & Dillenburger, B. (2021). 3D Printed Formwork for Concrete: State-of-the-Art, Opportunities, Challenges, and Applications. 3D Printing and Additive Manufacturing, 00, 24. https://doi.org/10.1089/3dp.2021.0024Keating, S. J., Leland, J. C., Cai, L., & Oxman, N. (2017). Toward site-specific and self-sufficient robotic fabrication on architectural scales. Science Robotics, 2(5), 1-15. https://doi.org/10.1126/scirobotics.aam8986Liew, A., López, D. L., Van Mele, T., & Block, P. (2017). Design, fabrication and testing of a prototype, thin-vaulted, unreinforced concrete floor. Engineering Structures, 137, 323–335. https://doi.org/10.1016/j.engstruct.2017.01.075Palomo, A., Grutzeck, M. W., & Blanco, M. T. (1999). Alkali-activated fly ashes: A cement for the future. Cement and Concrete Research, 29(8), 1323–1329. https://doi.org/10.1016/S0008-8846(98)00243-9UN Environment Programme. (2020). Global Status Report for Buildings and Construction. Retrieved May 11 2021, from https://globalabc.org/sites/default/files/inline-files/2020%20Buildings%20GSR_FULL%20REPORT.pdfXu, H., & Van Deventer, J. S. J. (2000). The geopolymerisation of alumino-silicate minerals. International Journal of Mineral Processing, 59(3), 247–266. https://doi.org/10.1016/S0301-7516(99)00074-5Zhao, H., Gu, F., Huang, Q.-X., Garcia, J., Chen, Y., Tu, C., Benes, B., Zhang, H., Cohen-Or, D., & Chen, B. (2016). Connected fermat spirals for layered fabrication. ACM Transactions on Graphics, 35(4), 1–10. https://doi.org/10.1145/2897824.2925958

	(2015) Design strategies for bending-active plate structures out of multiple cross-connected layers , Proceedings of the International Association for Shell and Spatial Structures (IASS). Amsterdam, The Netherlands

	(2015) Simulation of Aggregate Structures in Architecture: Distinct-Element Modeling of Synthetic Non-Convex Granulates , Advances in Architectural Geometry 2014. Berlin/ Heidelberg Springer-Verlag. 1–13

	(2015) From shape to shell: a design tool to materialize freeform shapes using gridshell structures , Design Modelling Symposium, Berlin

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