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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	Zivkovic, S., C. Battaglia (2018) Rough Pass Extrusion Tooling, CNC Post Processing of 3D-Printed Sub-additive Concrete Lattice Structures , ACADIA 2018 Recalibration: On Imprecision and Infidelity: Proceedings of the 38th Annual Conference of ACADIA, ed. by P. Anzaline, M. del Signore and A.J. W, 302-311. Mexico City: ACADIA.

	Zivkovic, Sasa, and Christopher Battaglia. (2018) Rough Pass Extrusion Tooling. CNC Post-Processing of 3D-Printed Sub-Additive Concrete Lattice Structures , ACADIA 18: Recalibration; On Imprecisionand Infidelity; Proceedings of the 38th Annual Conference of the Association for Computer Aided Design Architecture, 302-311. Mexico City, Mexico 18-20 October, 2018. CUMINCAD. http://papers. cumincad.org/cgi-bin/works/paper/acadia18_302

	Bhooshan, S., Bhooshan, V., Dell'Endice, A., Chu, J., Singer, P., Megens, J., Van Mele, T., & Block, P. (2022) The Striatus bridge: Computational design and robotic fabrication of an unreinforced, 3D-concrete-printed, masonry arch bridge , Architecture, Structures and Construction. https://doi.org/10.1007/s44150-022-00051-y

	Bhooshan, S., Bhooshan, V., Dell'Endice, A., Chu, J., Singer, P., Megens, J., Van Mele, T., Block, P., (2022) The Striatus bridge: Computational design and robotic fabrication of an unreinforced, 3D-concrete-printed, masonry arch bridge , Archit. Struct. Constr. 521-543. https://doi.org/10.1007/s44150-022-00051-y

	Bhooshan, S., Dell'Endice, A., Du, C., Bouten, S., Van Mele, T. and Block, P. (2021) Striatus-3D concrete printed masonry bridge , Venice, Italy, 2021 [Online]. Available at: https://block.arch.ethz.ch/brg/project/striatus-3d-concrete-printed-masonry-bridge-venice-italy-2021 (Accessed 31 March 2022)

	Weiguo Xu, Yuan Gao, and Chenwei Sun (2020) 3D-Printed Concrete Structural Components in the Baoshan Pedestrian Bridge Project , Fabricate 2020: Making Resilient Architecture, 140–47

	Weiguo Xu, Yuan Gao, Chenwei Sun, Zhi Wang, Jane Burry, Jenny Sabin, Bob Sheil, and Marilena Skavara (2020) Fabrication and Application of 3D-Printed Concrete Structural Components in the Baoshan Pedestrian Bridge Project , Fabricate 2020, 140–47, Making Resilient Architecture

	Xu, W (2020) FABRICATION AND APPLICATION OF 3D-PRINTED CONCRETE STRUCTURAL COMPONENTS IN THE BAOSHAN PEDESTRIAN BRIDGE PROJECT , Fabricate 2020: Making Resilient Architecture

	Xu, Weiguo (2020) Fabrication and Application of 3D-Printed Concrete Structural Components in the Baoshan Pedestrain Bridge Project , Fabricate 2020: Making Resilient Architecture, pp. 140-147

	Bard, J, Cupkova, D, Washburn, N and Zeglin, G (2019) Thermally Informed Robotic Topologies:Pro fi le-3D-Printing for the RoboticConstruction of Concrete Panels, ThermallyTuned Through High ResolutionSurface Geometry , Willmann, J, Block, P, Hutter, M, Byrne, K and Schork, T (eds), Robotic Fabrication in Architecture, Art and Design 2018, Springer Nature Switzerland AG, Basel, pp. 113-125

	Battaglia CA, Miller MF and Zivkovic S (2018) Sub-additive 3D printing of optimized double curved concrete lattice structures , Robotic Fabrication in Architecture, Art and Design. Cham: Springer, 2018, pp 242–255.

	Battaglia CA, Miller MF, and Zivkovic S. (2019) Sub-additive 3D printing of optimized double curved concrete lat-tice structures , Robotic fabrication in architecture, art and design 2018, Cham: Springer

	Battaglia, C., M. Miller, S. Zivkovic (2019) Sub-Additive 3D Printing of Optimized Double Curved Concrete Lattice Structures , Robotic Fabrication In Architecture, Art, And Design 2018, Vol. 1, ed. J. Willmann, P. Block, M. Hutter, K. Byrne, T. Schork, 245-255. Heidelberg: Springer

	Battaglia, C.A., Miller, M.F. and Zivkovic, S. (2018) Sub-Additive 3D Printing of Optimized Double Curved Concrete Lattice Structures , Rob\|Arch 2018

	Battaglia, C.A. (2018) Sub-additive 3D Printing of Optimized Double Curved Concrete Lattice Structures , Robotic Fabrication Architecture, Art, and Design, 242–255. New York: Springer

	Battaglia, Christopher A., Martin Fields Miller, and Sasa Zivkovic (2019) Sub-Additive 3D Printing of Optimized Double Curved Concrete Lattice Structures , Robotic Fabrication in Architecture, Art and Design 2018. Cham: Springer

	Bernhard, M., Hansmeyer, M. and Dillenburger, B. (2018) Volumetric modelling for 3D printed architecture , Advances in Architectural Geometry 2018, Gothenburg, Sweden, pp. 392-415

	Bernhard, M., M. Hansmeyer, B. Dillenburger. (2018) Volumetric modelling for 3D printed architecture , Advances Architectural Geometry 2018. City: Göteborg. Publisher: KlePublishing GmbH

	Beyhan, F., & Arslan Selcuk, S. (2018) 3D Printing in Architecture: One Step Closer to a Sustainable Built Environment , Lecture Notes in Civil Engineering, 253–268. https://doi.org/10.1007/978-3-319-63709-9_20Ching-Shun, T. (2006). Smart Structures: Designs with Rapid Prototyping. Progress in Design & Decision Support Systems in Architecture and Urban Planning, 415–429. Retrieved from http://papers.cumincad.org/data/works/att/ddss2006-pb-415.content.pdfDefacto (2016) The Rise Pavilion [Project] Guinness World Record: Largest 3D Printed Structure 2016 Retrieved from https://3dprint.com/147981/defacto-rise-pavilion-guinness/

	Biranchi Panda, Yi Wei Daniel Tay, Suvash Paul, and M J Tan (2018) Current Challenges and Future Potential of 3D Concrete Printing , Materialwissenschaft Und Werkstofftechnik 49 (May): 666–73

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