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Additive manufacturing of a bridge in situ

Additive manufacturing of a bridge in situ ReferencesGebhardt, A.; Kessler, J.; Thurn, L. (2018) 3D Printing: Understanding Additive Manufacturing, Munich: Carl Hanser.Frazier, W. E. (2014) Metal Additive Manufacturing: A Review. Journal of Materials Engineering and Performance 23, pp. 1917–1928.Ali, Y. S. K.; Günther, K.; Henckell, P.; Bergmann, J. P. (2016) Additive fertigung von 3D‐Verbundstrukturen mittels MSG‐Schweißens. DVS‐Bericht 327, pp. 75–80.Bergmann, J.; Henckell, P.; Ali, Y.; Reimann, J.; Hildebrand, J. (2018) Grundlegende wissenschaftliche Konzepterstellung zu bestehenden Herausforderungen und Perspektiven für die additive Fertigung mit Lichtbogen. DVS‐Bericht. Düsseldorf: DVS‐Media.Williams, S.; Martina, F.; Addison, A.; Ding, J.; Pardal, G.; Colegrove, P. (2015) Wire+Arc Additive Manufacturing. Materials Science and Technology 32, No. 7, pp. 641–647.Posch, G.; Chladil, K.; Chladil, H. (2017) Material properties of CMT―metal additive manufactured duplex stainless steel blade‐like geometries. Welding in the World 61, pp. 873–882.Laghi, V.; Palermo, M.; Gasparini, G.; Girelli, V.; Trombetti, T. (2019) Geometrical Characterization of Wire‐and‐Arc Additive Manufactured Steel Elements. Advanced Materials Letters 10, pp. 695–699.Bandari, Y.; Williams, S.; Ding, J.; Martina, F. (2015) Additive manufacture of large structures: robotic or CNC systems? Bedford, UK: Welding Engineering and Laser Processing Centre (WELPC), Cranfield University.Feucht, T.; Lange, J.; Erven, M. (2019) 3‐D‐Printing with Steel: Additive Manufacturing of Connection Elements and Beam Reinforcements. ce/papers 3, Nordic Steel 2019 (Copenhagen), pp. 343–348. https://doi.org/10.1002/cepa.1064Feldmann, M.; Kühne, R.; Citarelli, S.; Reisgen, U.; Sharma, R.; Oster, L. (2019) 3D‐Drucken im Stahlbau mit dem automatisierten Wire Arc Additive Manufacturing. Stahlbau 88, pp. 203–213. https://doi.org/10.1002/stab.201800029Mechtcherine, V.; Grafe, J.; Nerella, V. N.; Spaniol, E.; Hertel, M.; Füssel, U. (2018) 3D‐printed steel reinforcement for digital concrete construction – Manufacture, mechanical properties and bond behaviour. Construction and Building Materials 179, pp. 125–137.Erven, M.; Feucht, T.; Lange, J.; Eiber, M.; Hildebrand, J.; Bergmann, J. P. (2019) Numerische und experimentelle Untersuchungen von Knoten im konstruktiven Stahlbau. DVS Congress 2019. Düsseldorf: DVS Media.MX3D (2021) MX3D Bridge. https://mx3d.com/industries/infrastructure/mx3d‐bridge/ [accessed on: 22 Feb 2022]Gardner, L.; Kyvelou, P.; Herbert, G.; Buchanan, C. (2020) Testing and initial verification of the world's first metal 3D printed bridge. Journal of Constructional Steel Research 172,. 106233.Ding, D.; Pan, Z.; Cuiuri, D.; Li, H. (2015) Process planning for robotic wire and arc additive manufacturing. Wollongong: University of Wollongong.Ribeiro, F. (1998) 3D printing with metals. Computing & Control Engineering Journal 9, pp. 31–38.Feucht, T.; Lange, J.; Erven, M.; Costanzi, C. B.; Knaack, U.; Waldschmitt, B. (2020) Additive manufacturing by means of parametric robot programming. Construction Robotics 4, No. 1, pp. 31–48.Kazanas, P.; Deherkar, P.; Almeida, P.; Lockett, H.; Williams, S. (2012) Fabrication of geometrical features using wire and arc additive manufacture. Proceedings of the Institution of the Mechanical Engineers, Part B: Journal of Engineering Manufacture 226, pp. 1042–1051.Waldschmitt, B. (2019) Additive Manufacturing of a Bridge [Master's thesis]. TU Darmstadt.Almeida, P. (2012) Process control and development in wire and arc additive manufacturing. Dissertation, Cranfield University School of Applied Sciences.Fronius, Bruckner, J.; Egerland, S.; Himmelbauer, K.; Millinger, A.; Schörghuber, M.; Söllinger, D.; Waldhör, A. (2013) Schweißpraxis aktuell: CMT‐Technologie: Cold Metal Transfer – ein neuer Metall‐Schutzgas‐Schweißprozess. Kissing: WEKA MEDIA GmbH & Co. KG.Zhang, Y. M.; Li, P.; Chen, Y.; Male, A. T. (2002) Automated system for welding‐based rapid prototyping. Mechatronics 12, pp. 37–53.Feucht, T.; Lange, J.; Waldschmitt, B.; Schudlich, A.‐K.; Klein, M.; Oechsner, M. (2020) Welding Process for the Additive Manufacturing of cantilevered Components with the WAAM in: da Silva, L. F. M.; Martins, P. A. F.; El‐Zein, M. S. (eds.) Advanced Joining Processes. 125, Ponta Delgada, Singapore: Springer, pp. 67–78.Spinnanker GmbH (2020) Spinnanker Betonlose Fundamenttechnik. http://www.spinnanker.com/de/?produkt&technik [accessed on: 15 Nov 2021] http://www.deepdyve.com/assets/images/DeepDyve-Logo-lg.png Steel Construction: Design and Research Wiley

Additive manufacturing of a bridge in situ

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Wiley
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© 2022 Ernst & Sohn GmbH
ISSN
1867-0520
eISSN
1867-0539
DOI
10.1002/stco.202100045
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Abstract

ReferencesGebhardt, A.; Kessler, J.; Thurn, L. (2018) 3D Printing: Understanding Additive Manufacturing, Munich: Carl Hanser.Frazier, W. E. (2014) Metal Additive Manufacturing: A Review. Journal of Materials Engineering and Performance 23, pp. 1917–1928.Ali, Y. S. K.; Günther, K.; Henckell, P.; Bergmann, J. P. (2016) Additive fertigung von 3D‐Verbundstrukturen mittels MSG‐Schweißens. DVS‐Bericht 327, pp. 75–80.Bergmann, J.; Henckell, P.; Ali, Y.; Reimann, J.; Hildebrand, J. (2018) Grundlegende wissenschaftliche Konzepterstellung zu bestehenden Herausforderungen und Perspektiven für die additive Fertigung mit Lichtbogen. DVS‐Bericht. Düsseldorf: DVS‐Media.Williams, S.; Martina, F.; Addison, A.; Ding, J.; Pardal, G.; Colegrove, P. (2015) Wire+Arc Additive Manufacturing. Materials Science and Technology 32, No. 7, pp. 641–647.Posch, G.; Chladil, K.; Chladil, H. (2017) Material properties of CMT―metal additive manufactured duplex stainless steel blade‐like geometries. Welding in the World 61, pp. 873–882.Laghi, V.; Palermo, M.; Gasparini, G.; Girelli, V.; Trombetti, T. (2019) Geometrical Characterization of Wire‐and‐Arc Additive Manufactured Steel Elements. Advanced Materials Letters 10, pp. 695–699.Bandari, Y.; Williams, S.; Ding, J.; Martina, F. (2015) Additive manufacture of large structures: robotic or CNC systems? Bedford, UK: Welding Engineering and Laser Processing Centre (WELPC), Cranfield University.Feucht, T.; Lange, J.; Erven, M. (2019) 3‐D‐Printing with Steel: Additive Manufacturing of Connection Elements and Beam Reinforcements. ce/papers 3, Nordic Steel 2019 (Copenhagen), pp. 343–348. https://doi.org/10.1002/cepa.1064Feldmann, M.; Kühne, R.; Citarelli, S.; Reisgen, U.; Sharma, R.; Oster, L. (2019) 3D‐Drucken im Stahlbau mit dem automatisierten Wire Arc Additive Manufacturing. Stahlbau 88, pp. 203–213. https://doi.org/10.1002/stab.201800029Mechtcherine, V.; Grafe, J.; Nerella, V. N.; Spaniol, E.; Hertel, M.; Füssel, U. (2018) 3D‐printed steel reinforcement for digital concrete construction – Manufacture, mechanical properties and bond behaviour. Construction and Building Materials 179, pp. 125–137.Erven, M.; Feucht, T.; Lange, J.; Eiber, M.; Hildebrand, J.; Bergmann, J. P. (2019) Numerische und experimentelle Untersuchungen von Knoten im konstruktiven Stahlbau. DVS Congress 2019. Düsseldorf: DVS Media.MX3D (2021) MX3D Bridge. https://mx3d.com/industries/infrastructure/mx3d‐bridge/ [accessed on: 22 Feb 2022]Gardner, L.; Kyvelou, P.; Herbert, G.; Buchanan, C. (2020) Testing and initial verification of the world's first metal 3D printed bridge. Journal of Constructional Steel Research 172,. 106233.Ding, D.; Pan, Z.; Cuiuri, D.; Li, H. (2015) Process planning for robotic wire and arc additive manufacturing. Wollongong: University of Wollongong.Ribeiro, F. (1998) 3D printing with metals. Computing & Control Engineering Journal 9, pp. 31–38.Feucht, T.; Lange, J.; Erven, M.; Costanzi, C. B.; Knaack, U.; Waldschmitt, B. (2020) Additive manufacturing by means of parametric robot programming. Construction Robotics 4, No. 1, pp. 31–48.Kazanas, P.; Deherkar, P.; Almeida, P.; Lockett, H.; Williams, S. (2012) Fabrication of geometrical features using wire and arc additive manufacture. Proceedings of the Institution of the Mechanical Engineers, Part B: Journal of Engineering Manufacture 226, pp. 1042–1051.Waldschmitt, B. (2019) Additive Manufacturing of a Bridge [Master's thesis]. TU Darmstadt.Almeida, P. (2012) Process control and development in wire and arc additive manufacturing. Dissertation, Cranfield University School of Applied Sciences.Fronius, Bruckner, J.; Egerland, S.; Himmelbauer, K.; Millinger, A.; Schörghuber, M.; Söllinger, D.; Waldhör, A. (2013) Schweißpraxis aktuell: CMT‐Technologie: Cold Metal Transfer – ein neuer Metall‐Schutzgas‐Schweißprozess. Kissing: WEKA MEDIA GmbH & Co. KG.Zhang, Y. M.; Li, P.; Chen, Y.; Male, A. T. (2002) Automated system for welding‐based rapid prototyping. Mechatronics 12, pp. 37–53.Feucht, T.; Lange, J.; Waldschmitt, B.; Schudlich, A.‐K.; Klein, M.; Oechsner, M. (2020) Welding Process for the Additive Manufacturing of cantilevered Components with the WAAM in: da Silva, L. F. M.; Martins, P. A. F.; El‐Zein, M. S. (eds.) Advanced Joining Processes. 125, Ponta Delgada, Singapore: Springer, pp. 67–78.Spinnanker GmbH (2020) Spinnanker Betonlose Fundamenttechnik. http://www.spinnanker.com/de/?produkt&technik [accessed on: 15 Nov 2021]

Journal

Steel Construction: Design and ResearchWiley

Published: May 1, 2022

Keywords: additive manufacturing; innovative structures; steel bridge; in situ manufacturing; wire and arc additive manufacturing; parametric robot programming; Welding and cutting; Special structures; Schweißen und Schneiden; Sonderkonstruktionen

References