Publications
Implementation of a surrogate model for a novel path-based finite element simulation for additive manufacturing processes in construction
2022 | Ekanayaka, V.; Hürkamp, A. : Implementation of a surrogate model for a novel path-based finite element simulation for additive manufacturing processes in construction. In: PAMM. (2022.)
Project(s)
Integrated Additive Manufacturing Processes for Reinforced Shotcrete 3D Printing (SC3DP) Elements with Precise Surface Quality
Design of Structural Steel Components According to Manufacturing Possibilities of the Robot-Guided DED-Arc Process
2022 | C. Müller, J. Müller, H. Kloft, and J. Hensel : Design of Structural Steel Components According to Manufacturing Possibilities of the Robot-Guided DED-Arc Process. In: Buildings, vol. 12, no. 12, p. 2154. (Dec. 2022.) doi: 10.3390/buildings12122154
Project(s)
Wire and Arc Additive Manufacturing (WAAM) of Complex Individualized Steel Components
The effects of building position on surface and fatigue of DED-arc steel components.
2022 | Hensel, J., Müller, J., Scharf-Wildenhain, R. et al. : The effects of building position on surface and fatigue of DED-arc steel components. In: Weld World. (2022) https://doi.org/10.1007/s40194-022-01431-0
Project(s)
Wire and Arc Additive Manufacturing (WAAM) of Complex Individualized Steel Components
WAAM of structural components—building strategies for varying wall thicknesses
2023 | Müller, J., Hensel, J.: WAAM of structural components—building strategies for varying wall thicknesses. In: Weld World. (2023) https://doi.org/10.1007/s40194-023-01481-y
Project(s)
Wire and Arc Additive Manufacturing (WAAM) of Complex Individualized Steel Components
A Novel Methodology for the Thermographic Cooling Rate Measurement during Powder Bed Fusion of Metals Using a Laser Beam.
2023 | Wenzler, D.L., Bergmeier, K., Baehr, S., Diller, J., Zaeh, M.F.: A Novel Methodology for the Thermographic Cooling Rate Measurement during Powder Bed Fusion of Metals Using a Laser Beam. In: Integrating Materials and Manufacturing Innovation. (2023) https://doi.org/10.1007/s40192-023-00291-w
Project(s)
Laser Powder-Bed Fusion (LPBF) of Steel Elements for Construction – Basics of Design and Mechanical Resilience.
Process Control for Additive Manufacturing of Concrete Components
2022 | Lachmayer L., Dörrie R., Kloft H., Raatz A.: Process Control for Additive Manufacturing of Concrete Components. In: RILEM Bookseries Vol. 37, pp. 351-356, (3rd RILEM International Conference on Concrete and Digital Fabrication (DC 2022), England), (6 pages), https://doi.org/10.1007/978-3-031-06116-5_52
Project(s)
Process Control and Adaptive Path Planning for Additive Manufacturing Processes Based on Industrial Robots with an Extended Degree of Freedom
Integration of Additive Manufacturing in the Construction Process
Vorüberlegungen bei der Anwendung robotischer Systeme – eine baubetriebliche Untersuchung für den Beton-3D-Druck
2022 | Placzek, G.; Schwerdtner, P.: Vorüberlegungen bei der Anwendung robotischer Systeme – eine baubetriebliche Untersuchung für den Beton-3D-Druck. In: Bauingenieur 97 (2022), Heft 12, S. 423-433. doi.org/10.37544/0005-6650-2022-12-59
Pragmatic Design Decision Support for Additive Construction Using Formal Knowledge and Its Prospects for Synergy with a Feedback Mechanism
2022 | Li, C.; Zahedi, A.; Petzold, F.: Pragmatic Design Decision Support for Additive Construction Using Formal Knowledge and Its Prospects for Synergy with a Feedback Mechanism. In: Buildings, vol. 12, no. 12, p. 2072, Nov. 2022, doi: 10.3390/buildings121220
Project(s)
Integrating Digital Design and Additive Manufacturing through BIM-Based Decision Support and Digital Twin Methods
The Effect of Water, Nanoparticulate Silica and Dry Water on the Flow Properties of Cohesionless Sand
2022 | Hamilton, L. D.; Zetzener, H.; Kwade, A.: The Effect of Water, Nanoparticulate Silica and Dry Water on the Flow Properties of Cohesionless Sand. In: Processes 2022, 10, 2438. https://doi.org/10.3390/pr10112438
Project(s)
Particle-Bed 3D Printing by Selective Cement Paste Intrusion (SPI) – Particle Surface Functionalisation, Particle Synthesis and Integration of WAAM Reinforcement
Modelling the influence of material and process parameters on shotcrete 3D printing strands – cross-section adjustment for automatic robotic manufacturing
2022 | Lachmayer, L.; Böhler, D.; Freund, N.; Mai, I.; Lowke, D.; Raatz, A.: Modelling the influence of material and process parameters on shotcrete 3D printing strands – cross-section adjustment for automatic robotic manufacturing. Automation in Construction, Volume 145, https://doi.org/10.1016/j.autcon.2022.104626
Project(s)
Process Control and Adaptive Path Planning for Additive Manufacturing Processes Based on Industrial Robots with an Extended Degree of Freedom
Combining Wire and Arc Additive Manufacturing and Selective Paste Intrusion for Additively Manufactured Structural Concrete
2022 | Straßer, A.; Weger, D.; Matthäus, Carla; Kränkel, T.; Gehlen, C.: Combining Wire and Arc Additive Manufacturing and Selective Paste Intrusion for Additively Manufactured Structural Concrete. In: Visions and Strategies for Reinforcing Additively Manufactured Concrete Structures 61-72 (2022)
Project(s)
Particle-Bed 3D Printing by Selective Cement Paste Intrusion (SPI) – Particle Surface Functionalisation, Particle Synthesis and Integration of WAAM Reinforcement
Selective Paste Intrusion: Stability of Cement Paste Mixtures Towards Changing Ambient Temperature
2022 | Straßer, A.; Matthäus, Carla; Weger, D.; Kränkel, T.; Gehlen, C.: Selective Paste Intrusion: Stability of Cement Paste Mixtures Towards Changing Ambient Temperature. In: Third RILEM International Conference 296–301 (2022)
Project(s)
Particle-Bed 3D Printing by Selective Cement Paste Intrusion (SPI) – Particle Surface Functionalisation, Particle Synthesis and Integration of WAAM Reinforcement
Research data management and a system design to semi-automatically complete integrated data management plans
2022 | SHAH, S. A. H.; Petzold, F.: Research data management and a system design to semi-automatically complete integrated data management plans. In: ASCAAD. (2022)
Project(s)
The service project Information Infrastructure serves and supports all information and data infrastructure aspects of the TRR 277 in close cooperation with the Leibniz-Supercomputing Centre (LRZ) and the University Library at the Technical University of Munich and the University Library Braunschweig.
Research data management of large scale projects and a reference model of data life cycle for dynamic DMPs
2022 | SHAH, S. A. H.: Research data management of large scale projects and a reference model of data life cycle for dynamic DMPs. In: Forum Bauinformatik. 157-165 (2022)
Author(s)
Project(s)
The service project Information Infrastructure serves and supports all information and data infrastructure aspects of the TRR 277 in close cooperation with the Leibniz-Supercomputing Centre (LRZ) and the University Library at the Technical University of Munich and the University Library Braunschweig.
Core Winding: Force-Flow Oriented Fibre Reinforcement in Additive Manufacturing with Concrete.
2022 | Gantner, S., Rennen, P., Rothe, T., Hühne, C., & Hack, N.: Core Winding: Force-Flow Oriented Fibre Reinforcement in Additive Manufacturing with Concrete. In: RILEM International Conference on Concrete and Digital Fabrication (pp. 391-396), (2022) Springer, Cham
Project(s)
Integration of Individualized Prefabricated Fibre Reinforcement in Additive Manufacturing with Concrete
Bewehrungskonzepte beim 3D-Druck von Konstruktionsbeton
2022 | Lowke, D.; Gehlen, C.; Kloft, H.; Freund, N.; Matthäus, C.: Bewehrungskonzepte beim 3D-Druck von Konstruktionsbeton. In: BfT International, 02.2021, S. 92.
Project(s)
Integrated Additive Manufacturing Processes for Reinforced Shotcrete 3D Printing (SC3DP) Elements with Precise Surface Quality
Interlayer Reinforcement in Shotcrete-3D-Printing: The Effect of Accelerator Dosage on the Resulting Bond Behavior of Integrated Reinforcement Bars
2022 | Freund, N., & Lowke, D.: Interlayer Reinforcement in Shotcrete-3D-Printing: Interlayer Reinforcement in Shotcrete-3D-Printing: The Effect of Accelerator Dosage on the Resulting Bond Behavior of Integrated Reinforcement Bars. In: Open Conference Proceedings, 1, 83–95, 2022
https://doi.org/10.52825/ocp.v1i.72
Project(s)
Integrated Additive Manufacturing Processes for Reinforced Shotcrete 3D Printing (SC3DP) Elements with Precise Surface Quality
A Closed-Loop Workflow for Quality Inspection and Integrated Post-processing of 3D-Printed Concrete Elements
2022 | Hack, N.; Jantzen, C.; Brohmann, L.; Gerke, M.; Mawas, K.; Maboudi, M.: A Closed-Loop Workflow for Quality Inspection and Integrated Post-processing of 3D-Printed Concrete Elements. In: RILEM Bookseries, 364-369 (2022)
https://doi.org/10.1007/978-3-031-06116-5_54
Additive Fertigung von Stahlbewehrungen
2022 | Riegger, F.; Zäh, M. F.: Additive Fertigung von Stahlbewehrungen. In: Zeitschrift für wirtschaftlichen Fabrikbetrieb 117 (7-8), S. 448–451. (2022)
DOI: 10.1515/zwf-2022-1091
Project(s)
Particle-Bed 3D Printing by Selective Cement Paste Intrusion (SPI) – Particle Surface Functionalisation, Particle Synthesis and Integration of WAAM Reinforcement
Mobile Additive Manufacturing: A Case Study of Clay Formwork for Bespoke in Situ Concrete Construction
2022 | Dielemans, G.; Lachmayer, L.; Recker, T.; Atanasova, L.; Hechtl, M.; Matthäus, C.; Raatz, A.; Dörfler, K.: Mobile Additive Manufacturing: A Case Study of Clay Formwork for Bespoke in Situ Concrete Construction. In: Buswell, R., Blanco, A., Cavalaro, S., Kinnell, P. (eds) Third RILEM International Conference on Concrete and Digital Fabrication. DC 2022. RILEM Bookseries, vol 37. Springer, Cham.
https://doi.org/10.1007/978-3-031-06116-5_3
Additive Manufacturing using mobile robots: Opportunities and challenges for building construction
2022 | Dörfler, K.; Dielemans, G.; Lachmayer, L.; Recker, T.; Raatz, A.; Lowke, D.; Gerke, M.: Additive Manufacturing using mobile robots: Opportunities and challenges for building construction. In: Cem. Concr. Res., vol. 158, Aug. 2022, doi: 10.1016/J.CEMCONRES.2022.106772.
Formal knowledge as a basis for BIM-based design decision support in additive manufacturing
2022 | Li, C.; Petzold , F.: Formal knowledge as a basis for BIM-based design decision support in additive manufacturing. In 33. Forum Bauinformatik 2022
Project(s)
Integrating Digital Design and Additive Manufacturing through BIM-Based Decision Support and Digital Twin Methods
Towards informed design decision support of additive manufacturing in construction: The use of integrated knowledge in BIM-based architectural design
2022 | Li, C.; Petzold, F.: Towards informed design decision support of additive manufacturing in construction: The use of integrated knowledge in BIM-based architectural design. In Arab Society for Computer Aided Architectural Design (ASCAAD) (2022)
Project(s)
Integrating Digital Design and Additive Manufacturing through BIM-Based Decision Support and Digital Twin Methods
A Lean-based Production Approach for Shotcrete 3D Printed Concrete Components
2021 | Placzek, G., Brohmann, L., Mawas, K., Schwerdtner, P., Hack, N., Maboudi M., Gerke, M.: D.: A Lean-based Production Approach for Shotcrete 3D Printed Concrete Components. In: 2021 Proceedings of the 38th ISARC, Dubai, UAE, Pages 811-818
doi.org/10.22260/ISARC2021/0110
PBF-LB/M/316L vs. hot-rolled 316L – comparison of cyclic plastic material behavior
2022 | lautet Diller, J.; Siebert, D.; Radlbeck, C.; Mensinger, M: PBF-LB/M/316L vs. hot-rolled 316L – comparison of cyclic plastic material behavior. In: Procedia Structual Integrity 2022
Project(s)
Laser Powder-Bed Fusion (LPBF) of Steel Elements for Construction – Basics of Design and Mechanical Resilience.
Einfluss der Abkühlrate auf das Korngefüge von Bauteilen aus austenitischem Edelstahl, hergestellt durch pulverbettbasiertes Laserstrahlschmelzen
2020 | Diller, J.; Radlbeck, C.; Mensinger, M: Einfluss der Abkühlrate auf das Korngefüge von Bauteilen aus austenitischem Edelstahl, hergestellt durch pulverbettbasiertes Laserstrahlschmelzen (LPBF) In: DASt-Kolloqium 2020
Project(s)
Laser Powder-Bed Fusion (LPBF) of Steel Elements for Construction – Basics of Design and Mechanical Resilience.
Individual Layer Fabrication (ILF) – Additive Fertigung durch selektives Binden von Holzspänen zu Einzelschichten
2021 | Aßhoff, C.; Bunzel, F.; Buschmann, B.; Henke, K.; Talke, D.; Saile, B.: Individual Layer Fabrication (ILF) – Additive Fertigung durch selektives Binden von Holzspänen zu Einzelschichten. In: Holztechnologie 2021, 62, 5
Additive Fertigung von Bauteilen aus Holz
2022 | Aßhoff, C.; Bunzel, F.; Buschmann, B.; Henke, K.; Talke, D.; Saile, B.: Additive Fertigung von Bauteilen aus Holz. In: Holz-Zentralblatt 2022, 33, 557
Einfluss von Geometrie- und Fertigungsrestriktionen auf die mechanische Festigkeit von WAAM-Bauteilen
2022 | Jahns, H., Unglaub, J., Thiele, K.: Einfluss von Geometrie- und Fertigungsrestriktionen auf die mechanische Festigkeit von WAAM-Bauteilen. In: DGM-Informationsgesellschaft (Hg.): 3. Fachtagung Werkstoffe und Additive Fertigung 11. – 13. Mai 2022
Project(s)
Wire and Arc Additive Manufacturing (WAAM) of Complex Individualized Steel Components
Ableitung von Integrationsansätzen des “Beton-3D-Drucks” in den Bauprozess anhand von Merkmalen der additiven Fertigung
2020 | Placzek, G.; Schwerdtner, P.: Ableitung von Integrationsansätzen des “Beton-3D-Drucks” in den Bauprozess anhand von Merkmalen der additiven Fertigung. In: Bauwirtschaft. Berlin : Werner Verlag ((2020)), Heft 4, , S. 208 – 222.
https://www.researchgate.net/publication/349054139_Ableitung_von_Integrationsansatzen_des_Beton-3D_Drucks_in_den_Bauprozess_anhand_von_Merkmalen_der_additiven_Fertigung
Veränderungen in der Bauproduktionsstrategie durch die Integration der additiven Fertigung
2022 | Placzek, G. : Veränderungen in der Bauproduktionsstrategie durch die Integration der additiven Fertigung. In: Tagungsband zum 31. BBB-Assistent:innentreffen, Innsbruck 2022. Hrsg.: Universität Innsbruck, Arbeitsbereich für Baumanagement, Baubetrieb und Tunnelbau (iBT), Studia Verlag 2022, S. 238-253.
DOI: 10.25651/1.2022.0004
Author(s)
Thermal Optimization of Additively Manufactured Lightweight Concrete Wall Elements with Internal Cellular Structure through Simulations and Measurements
2022 | Briels, D.; Kollmannsberger, S.; Leithner, F.; Matthäus, C.; Nouman, A.S.; Oztoprak, O.; Rank, E.: Thermal Optimization of Additively Manufactured Lightweight Concrete Wall Elements with Internal Cellular Structure through Simulations and Measurements. In: Buildings 2022, 12, 1023,
https://doi.org/10.3390/buildings12071023
Project(s)
Integration of Passive and Active Functions in Additively Manufactured Construction Elements
An accurate strategy for computing reaction forces and fluxes on trimmed locally refined meshes
2022 | D’Angella, D., Kollmannsberger, S., Reali, A., Rank, E., Hughes, T. J. R.: An accurate strategy for computing reaction forces and fluxes on trimmed locally refined meshes. In: Journal of Mechanics, vol. 38, pp. 60–76, Apr. 2022
http://doi: 10.1093/jom/ufac006
Approach to optimize the interlayer waiting time in additive manufacturing with concrete utilizing FEM modeling
2022 | Ekanayaka, V.; Lachmayer, L.; Raatz, A; Hürkamp, A.: Approach to optimize the interlayer waiting time in additive manufacturing with concrete utilizing FEM modeling. In: Procedia CIRP Design, 2022
https://doi.org/10.1016/j.procir.2022.05.295
Project(s)
Process Control and Adaptive Path Planning for Additive Manufacturing Processes Based on Industrial Robots with an Extended Degree of Freedom
Influence of Material and Process Parameters on Hardened State Properties of Shotcrete 3D-Printed Elements
2022 | Böhler, D., Mai, I., Freund, N., Lachmayer, L., Raatz, A., Lowke, D.: Influence of Material and Process Parameters on Hardened State Properties of Shotcrete 3D-Printed Elements. In: Buswell, R., Blanco, A., Cavalaro, S., Kinnell, P. (eds) Third RILEM International Conference on Concrete and Digital Fabrication. DC 2022. RILEM Bookseries, vol 37. Springer, Cham.
https://doi.org/10.1007/978-3-031-06116-5_38
Project(s)
Particle-Bed 3D Printing by Selective Cement Activation (SCA) – Particle Surface Functionalisation, Particle-Bed Compaction and Reinforcement Implementation
Effect of Curing in Selective Cement Activation
2022 | Herding, F., Mai, I., Lowke, D.: Effect of Curing in Selective Cement Activation. In: Buswell, R., Blanco, A., Cavalaro, S., Kinnell, P. (eds) Third RILEM International Conference on Concrete and Digital Fabrication. DC 2022. RILEM Bookseries, vol 37. Springer, Cham.
https://doi.org/10.1007/978-3-031-06116-5_42
Project(s)
Particle-Bed 3D Printing by Selective Cement Activation (SCA) – Particle Surface Functionalisation, Particle-Bed Compaction and Reinforcement Implementation
Fluid intrusion in powder beds for selective cement activation – an experimental and analytical study
2022 | Mai, I.; Lowke, D.; Perrot, A.: Fluid intrusion in powder beds for selective cement activation – an experimental and analytical study. In: Cement and Concrete Research, CCR 156 (106771), 2022
https://doi.org/10.1016/j.cemconres.2022.106771
Project(s)
Particle-Bed 3D Printing by Selective Cement Activation (SCA) – Particle Surface Functionalisation, Particle-Bed Compaction and Reinforcement Implementation
Material-process interactions in particle bed 3D printing and the underlying physics
2022 | Lowke, D.; Mai, I.; Keita, E.; Perrot, A.; Weger, D.; Gehlen, C.; Herding, F.; Zuo, Wenqiang; Roussel, N.: Material-process interactions in particle bed 3D printing and the underlying physics. In: Cement and Concrete Research, CCR 156 (106748), 2022
https://doi.org/10.1016/j.cemconres.2022.106748
Project(s)
Particle-Bed 3D Printing by Selective Cement Activation (SCA) – Particle Surface Functionalisation, Particle-Bed Compaction and Reinforcement Implementation
Evaluating the Effect of Methyl Cellulose on Hardened State Properties in Selective Cement Activation
2022 | Mai, I., Herding, F., Lowke, D.: Evaluating the Effect of Methyl Cellulose on Hardened State Properties in Selective Cement Activation. In: Buswell, R., Blanco, A., Cavalaro, S., Kinnell, P. (eds) Third RILEM International Conference on Concrete and Digital Fabrication. DC 2022. RILEM Bookseries, vol 37. Springer, Cham.
https://doi.org/10.1007/978-3-031-06116-5_43
Project(s)
Particle-Bed 3D Printing by Selective Cement Activation (SCA) – Particle Surface Functionalisation, Particle-Bed Compaction and Reinforcement Implementation
Jointing Principles in AMC—Part 1: Design and Preparation of Dry Joints
2022 | Lanwer, J.-P.; Weigel, H.; Baghdadi, A.; Empelmann, M.; Kloft, H.: Jointing Principles in AMC—Part 1: Design and Preparation of Dry Joints. In: Applied Sciences, 2022, 12, 4138
https://doi.org/10.3390/app12094138
Project(s)
Integration of Individualized Prefabricated Fibre Reinforcement in Additive Manufacturing with Concrete
Automatic geometric inspection in digital fabrication
2022 | Mawas K., Maboudi M., Gerke M.: Automatic geometric inspection in digital fabrication. In: ISPRS Congress (2022 edition), 6–11 June 2022, Nice, France
https://doi.org/10.5194/isprs-archives-XLIII-B1-2022-459-2022
Autonomous sensing and localization of a mobile robot for multi-step additive manufacturing in construction
2022 | Lachmayer, Recker, T.; Dielemans, G.; Dörfler, K.; Raatz, A.: Autonomous sensing and localization of a mobile robot for multi-step additive manufacturing in construction. In: 24th International society for photogrammetry and remote sensing, 2022
https://doi.org/10.5194/isprs-archives-XLIII-B1-2022-453-2022
Project(s)
Process Control and Adaptive Path Planning for Additive Manufacturing Processes Based on Industrial Robots with an Extended Degree of Freedom
Contour Tracking Control for Mobile Robots applicable to Large-scale Assembly and Additive Manufacturing in Construction
2022 | Lachmayer, L.; Recker, T.; Raatz, A.: Contour Tracking Control for Mobile Robots applicable to Large-scale Assembly and Additive Manufacturing in Construction. In: 9th CIRP Conference on Assembly Technology and Systems, 2022
https://doi.org/10.1016/j.procir.2022.02.163
Project(s)
Process Control and Adaptive Path Planning for Additive Manufacturing Processes Based on Industrial Robots with an Extended Degree of Freedom
Methodology to Determine Melt Pool Anomalies in Powder Bed Fusion of Metals Using a Laser Beam by Means of Process Monitoring and Sensor Data Fusion.
2022 | Harbig, J.; Wenzler, D.L.; Baehr, S.; Kick, M.K.; Merschroth, H.; Wimmer, A.; Weigold, M.; Zaeh, M.F.: Methodology to Determine Melt Pool Anomalies in Powder Bed Fusion of Metals Using a Laser Beam by Means of Process Monitoring and Sensor Data Fusion. In: Materials, 2022, 15, 1265. https://doi.org/10.3390/ma15031265
Project(s)
Laser Powder-Bed Fusion (LPBF) of Steel Elements for Construction – Basics of Design and Mechanical Resilience.
Cyclic plastic material behavior of 316L manufactured by laser powder bed fusion (PBF-LB/M).
2022 | Diller, J.; Rier, L.; Siebert, D.; Radlbeck, C.; Krafft, F.; Mensinger, M.: Cyclic plastic material behavior of 316L manufactured by laser powder bed fusion (PBF-LB/M). , In: Materials Characterization, Volume 191, 2022, 112153, ISSN 1044-5803, https://doi.org/10.1016/j.matchar.2022.112153.
Project(s)
Laser Powder-Bed Fusion (LPBF) of Steel Elements for Construction – Basics of Design and Mechanical Resilience.
Surface quality parameters for structural components manufactured by DED-arc processes
2022 | Hensel, J.; Przyklenk, A.; Müller, J.; Köhler, M.; Dilger, K.: Surface quality parameters for structural components manufactured by DED-arc processes. In: Materials and Design 215, 2022.
DOI: 10.1016/j.matdes.2022.110438
Project(s)
Wire and Arc Additive Manufacturing (WAAM) of Complex Individualized Steel Components
Fluid intrusion in powder beds for selective cement activation – An experimental and analytical study
2022 |Lowke, D.; Mai, I.; Perrot, A.: Fluid intrusion in powder beds for selective cement activation – An experimental and analytical study, In: Cement and Concrete Research, Volume 156, June 2022, 106748, DOI: http//:doi.org/10.1016/j.cemconres.2022.106771
Project(s)
Particle-Bed 3D Printing by Selective Cement Activation (SCA) – Particle Surface Functionalisation, Particle-Bed Compaction and Reinforcement Implementation
Material-process interactions in particle bed 3D printing and the underlying physics
2022 |Lowke, D.; Mai, I.; Keita, E.; Perrot, A.; Weger, D,; Gehlen, C.; Herding, F.; Zuo, W.; Roussel, N.: Material-process interactions in particle bed 3D printing and the underlying physics, In: Cement and Concrete Research, Volume 156, June 2022, 106748, DOI: http//:doi.org/10.1016/j.cemconres.2022.106748
Project(s)
Particle-Bed 3D Printing by Selective Cement Activation (SCA) – Particle Surface Functionalisation, Particle-Bed Compaction and Reinforcement Implementation
Surface quality parameters for structural components manufactured by DED-arc processes
2022 | Hensel, J.; Przyklenk, A.; Müller, J.; Köhler, M.; Dilger, K.: Surface quality parameters for structural components manufactured by DED-arc processes, In: Materials and Design 215 (2022), DOI: 10.1016/j.matdes.2022.110438
Project(s)
Wire and Arc Additive Manufacturing (WAAM) of Complex Individualized Steel Components
Digital Fabrication with Cement-Based Materials: Process Classification and Case Studies
2022 | Buswell, R. A.; Bos, F. P.; Leal da Silva, W. R.; Hack, N.; Kloft, H.; Lowke, D.; Freund, N.; Fromm, A.; Dini, E.; Wangler, T.; Lloret-Fritschi, E.; Schipper, R.; Mechtcherine, V.; Perrot, A.; Vasilic, K.; Roussel, N.: Digital Fabrication with Cement-Based Materials: Process Classification and Case Studies. In: Roussel, N. and Lowke, D. (2022). Digital Fabrication with Cement-Based Materials (Reports 36). RILEM State-of-the-Art. DOI: https://doi.org/10.1007/978-3-030-90535-4_2
Project(s)
Integrated Additive Manufacturing Processes for Reinforced Shotcrete 3D Printing (SC3DP) Elements with Precise Surface Quality
Integration of Individualized Prefabricated Fibre Reinforcement in Additive Manufacturing with Concrete
Structural Design and Testing of Digitally Manufactured Concrete Structures
2022 | Asprone, D.; Menna, C.; Bos, F.; Mata-Falcón, J.; Ferrara, L.; Auricchio, F.; Cadoni, E.; Cunha, V. M. C. F.; Esposito, L.; Fromm, A.; Grünewald, S.; Kloft, H.; Mechtcherine, V.; Naidu Nerella, V.; Schipper, R.: Structural Design and Testing of Digitally Manufactured Concrete Structures. In: Roussel, N. and Lowke, D. (2022). Digital Fabrication with Cement-Based Materials (Reports 36). RILEM State-of-the-Art. DOI: https://doi.org/10.1007/978-3-030-90535-4_6
Author(s)
Project(s)
Integrated Additive Manufacturing Processes for Reinforced Shotcrete 3D Printing (SC3DP) Elements with Precise Surface Quality
Fabrication Information Modeling: Closing the gap between Building Information Modeling and Digital Fabrication
2021 |Slepicka, M.; Vilgertshofer, S.; Borrmann, A.: Fabrication Information Modeling: Closing the gap between Building Information Modeling and Digital Fabrication, In: Proceedings of the 38th ISARC, Dubai, UAE, 2021, P. 9-16, DOI: https://doi.org/10.22260/ISARC2021/0004
Project(s)
Integrating Digital Design and Additive Manufacturing through BIM-Based Decision Support and Digital Twin Methods
Interlayer Reinforcement Combined with Fiber Reinforcement for Extruded Lightweight Mortar Elements
2020 | Matthäus, C.; Kofler, N.; Kränkel, T.; Weger, D.; Gehlen, C.: Interlayer Reinforcement Combined with Fiber Reinforcement for Extruded Lightweight Mortar Elements. In: Materials 2020, 13, 4778, 2020. – DOI: https://doi.org/10.3390/ma13214778.
Project(s)
Extrusion of Near-Nozzle Mixed Concrete –Individually Graded in Density and in Rate of 3D Fibre Reinforcement
Finite Cell Method for functionally graded materials based on V-models and homogenized microstructures
2020 | Wassermann, B.; Korshunova, N.; Kollmannsberger, S.; Rank, E.; Elber, G.: Finite Cell Method for functionally graded materials based on V-models and homogenized microstructures. In: Advanced Modeling and Simulation in Engineering Sciences (7), pp. 49, 2020. – DOI: 10.1186/s40323-020-00182-1.
Current Surveying Methods for the Integration of Additive Manufacturing in the Construction Process
2020 | Maboudi, M.; Gerke, M.; Hack, N.; Brohmann, L.; Schwerdtner, P.; Placzek, G.: Current Surveying Methods for the Integration of Additive Manufacturing in the Construction Process. In: The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Volume XLIII-B4-2020, 2020 XXIV ISPRS Congress, 2020. – DOI: https://doi.org/10.5194/isprs-archives-XLIII-B4-2020-763-2020.
Inspection Methods for 3D Concrete Printing
2020 | Buswell, R.; Kinnell, P.; Xu, J.; Hack, N.; Kloft, H.; Maboudi, M.; Gerke, M.; Massin, P.; Grasser, G.; Wolfs, R.; Bos, F.: Inspection Methods for 3D Concrete Printing. In: RILEM Bookseries 28, pp. 790-803, 2020. – DOI: https://doi.org/10.1007/978-3-030-49916-7_78.
Influence of process parameters on the interlayer bond strength of concrete elements additive manufactured by Shotcrete 3D Printing (SC3DP)
2020 | Kloft, H.; Krauss, H.-W.; Hack, N.; Herrmann, E.; Neudecker, S.; Varady, P.; Lowke, D.: Influence of process parameters on the interlayer bond strength of concrete elements additive manufactured by Shotcrete 3D Printing (SC3DP). In: Cement and Concrete Research 134, 2020. – DOI: https://doi.org/10.1016/j.cemconres.2020.106078.
Project(s)
Integrated Additive Manufacturing Processes for Reinforced Shotcrete 3D Printing (SC3DP) Elements with Precise Surface Quality
Integration of Individualized Prefabricated Fibre Reinforcement in Additive Manufacturing with Concrete
Bewehrungsstrategien für den Beton-3D-Druck
2020 | Kloft, H.; Empelmann, M.; Hack, N.; Herrmann, E. Lowke, D.: Bewehrungsstrategien für den Beton-3D-Druck. In: Beton- und Stahlbetonbau 115, 2020. – DOI: https://onlinelibrary.wiley.com/doi/epdf/10.1002/best.202000032.
Project(s)
Integrated Additive Manufacturing Processes for Reinforced Shotcrete 3D Printing (SC3DP) Elements with Precise Surface Quality
Integration of Individualized Prefabricated Fibre Reinforcement in Additive Manufacturing with Concrete
Jointing Principles for Combination of Concrete Elements Produced by Different Additive Manufacturing Processes
Studying the Bond Properties of Vertical Integrated Short Reinforcement in the Shotcrete 3D Printing Process
2020 | Freund, N.; Dressler, I.; Lowke, D.: Studying the Bond Properties of Vertical Integrated Short Reinforcement in the Shotcrete 3D Printing Process. In: RILEM Bookseries 28, pp. 612–621, 2020. – DOI: https://doi.org/10.1007/978-3-030-49916-7_62.
Project(s)
Integrated Additive Manufacturing Processes for Reinforced Shotcrete 3D Printing (SC3DP) Elements with Precise Surface Quality
Control of Strand Properties Produced with Shotcrete 3D Printing by Accelerator Dosage amd Process Parameters
2020 | Dressler, I.; Freund, N.; Lowke, D.: Control of Strand Properties Produced with Shotcrete 3D Printing by Accelerator Dosage amd Process Parameters. In: RILEM Bookseries 28, pp. 42–52, 2020. – DOI: https://doi.org/10.1007/978-3-030-49916-7_5.
Project(s)
Integrated Additive Manufacturing Processes for Reinforced Shotcrete 3D Printing (SC3DP) Elements with Precise Surface Quality
Reinforced Particle-Bed Printing by Combination of the Selective Paste Intrusion Method with Wire and Arc Additive Manufacturing – A First Feasibility Study
2020 | Weger, D.; Baier, D.; Straßer, A.; Prottung, S.; Kränkel, T.; Bachmann, A.; Gehlen, C.; Zäh, M.: Reinforced Particle-Bed Printing by Combination of the Selective Paste Intrusion Method with Wire and Arc Additive Manufacturing – A First Feasibility Study. In: RILEM Bookseries 28, pp. 978–987, 2020. – DOI: https://doi.org/10.1007/978-3-030-49916-7_95.
Project(s)
Particle-Bed 3D Printing by Selective Cement Paste Intrusion (SPI) – Particle Surface Functionalisation, Particle Synthesis and Integration of WAAM Reinforcement
Particle bed 3D printing by selective cement activation – Applications, material and process technology
2020 | Lowke, D.; Talke, D.; Dreßler, I.; Weger, D.; Gehlen, C.; Ostertag, C.; Rael, R.: Particle bed 3D printing by selective cement activation – Applications, material and process technology. In: Cement and Concrete Research 134,2020. – DOI: https://doi.org/10.1016/j.cemconres.2020.106077.
Project(s)
Particle-Bed 3D Printing by Selective Cement Activation (SCA) – Particle Surface Functionalisation, Particle-Bed Compaction and Reinforcement Implementation
Experimental and numerical assessment of new precast concrete connections under bending loads
2020 | Baghdadi, A.; Heristchian, M.; Ledderose, L.; Kloft, H.: Experimental and numerical assessment of new precast concrete connections under bending loads. In: Engineering Structures 212, ELSEVIER, 2020. – DOI: https://doi.org/10.1016/j.engstruct.2020.110456.
Project(s)
Integrated Additive Manufacturing Processes for Reinforced Shotcrete 3D Printing (SC3DP) Elements with Precise Surface Quality
Under-resolved and large eddy simulations of a decaying Taylor-Green vortex with the cumulant lattice Boltzmann method
2021 | Geier, M.; Lenz, S.; Schönherr, M.; Krafczyk, M.: Under-resolved and large eddy simulations of a decaying Taylor-Green vortex with the cumulant lattice Boltzmann method. In: Theoretical and Computational Fluid. Dynamics 35, 169-208, 2021.
Author(s)
Project(s)
Modelling and Simulation of Shotcrete 3D Printing (SC3DP) Based on a Massively Parallel Multi-Phase, Multi-Component Coupled LBM-DEM Approach
Additive Fertigung im Bauwesen: 3D-Betondruck als eine Schlüsseltechnologie für die Digitalisierung der Bauwirtschaft
2020 | Hack, N.; Kloft, H.; Lowke, D.: Additive Fertigung im Bauwesen: 3D-Betondruck als eine Schlüsseltechnologie für die Digitalisierung der Bauwirtschaft. In: Ingenieurbaukunst 2020 – Made in Germany, Jahrbuch der Bundesingenieurkammer, S. 178-183, 2020.
Project(s)
Integrated Additive Manufacturing Processes for Reinforced Shotcrete 3D Printing (SC3DP) Elements with Precise Surface Quality
Integration of Individualized Prefabricated Fibre Reinforcement in Additive Manufacturing with Concrete
A process classification framework for defining and describing Digital Fabrication with Concrete
2020 | Buswell, R.A.; Leal da Silva; W.R.; Bos, F.P.; Schipper, H.R.; Lowke, D.; Hack, N.; Kloft, H.; Mechtcherine, V.; Wangler, T.; Roussel, N.: A process classification framework for defining and describing Digital Fabrication with Concrete. In: Cement and Concrete Research 134, 2020. – DOI: https://doi.org/10.1016/j.cemconres.2020.106068.
Author(s)
Project(s)
Integrated Additive Manufacturing Processes for Reinforced Shotcrete 3D Printing (SC3DP) Elements with Precise Surface Quality
Integration of Individualized Prefabricated Fibre Reinforcement in Additive Manufacturing with Concrete
The Effect of Accelerator Dosage on Fresh Concrete Properties and on Interlayer Strength in Shotcrete 3D Printing
2020 | Dreßler, I.; Freund, N.; Lowke, D.: The Effect of Accelerator Dosage on Fresh Concrete Properties and on Interlayer Strength in Shotcrete 3D Printing. In: Materials 2020, 13, 374, 2020. – DOI: https://doi.org/10.3390/ma13020374.
Project(s)
Integrated Additive Manufacturing Processes for Reinforced Shotcrete 3D Printing (SC3DP) Elements with Precise Surface Quality
Vom WAAM-Bauteil zum WAAM-Bauwerk
2020 | Thiele, K.; Unglaub, J.; Begemann, F.: Additive Fertigung: Vom WAAM-Bauteil zum WAAM-Bauwerk. In: Berichte aus dem Konstruktiven Ingenieurbau, Universität der Bundeswehr München, 20/3, S. 19-24, 2020.
Project(s)
Wire and Arc Additive Manufacturing (WAAM) of Complex Individualized Steel Components
Additive Manufacturing of Wood Composite Panels for Individual Layer Fabrication (ILF)
2021 | Buschmann, B.; Henke, K.; Talke, D.; Saile, B.; Asshoff, C.; Bunzel, F.: Additive Manufacturing of Wood Composite Panels for Individual Layer Fabrication (ILF). In: Polymers – Special Issue “3D Printing in Wood Science”, 13, 3423, 2021. DOI: https://doi.org/10.3390/polym13193423.
Large Particle 3D Concrete Printing – A Green and Viable Solution
2021 | Mai, I.; Brohmann, L.; Freund, N.; Gantner, S.; Kloft, H.; Lowke, D.; Hack, N.: Large Particle 3D Concrete Printing – A Green and Viable Solution. In: Materials, 14, 6125, 2021. DOI: https://doi.org/10.3390/ma14206125.
Project(s)
Integrated Additive Manufacturing Processes for Reinforced Shotcrete 3D Printing (SC3DP) Elements with Precise Surface Quality
Integration of Individualized Prefabricated Fibre Reinforcement in Additive Manufacturing with Concrete
Towards realizing the information backbone of robotized construction – Computational methods and cyber-physical architectures for collaborative robotic fleets
2021 | Borrmann, A.; Bruckmann, T.; Dörfler, K.; Hartmann, T.; Smarsly, K.: Towards realizing the information backbone of robotized construction – Computational methods and cyber-physical architectures for collaborative robotic fleets. In: Proc. of the CIB W78 Conference, 2021.
Project(s)
Integrating Digital Design and Additive Manufacturing through BIM-Based Decision Support and Digital Twin Methods
BIM für die Additive Fertigung im Bauwesen
2021 | Slepicka, M.: BIM für die Additive Fertigung im Bauwesen. In: Borrmann A., König M., Koch C., Beetz J. (Hrsg.) Building Information Modeling – Technologische Grundlagen und industrielle Praxis. VDI-Buch. Springer Vieweg, Wiesbaden. 2021. DOI: https://doi.org/10.1007/978-3-658-33361-4_28.
Author(s)
Project(s)
Integrating Digital Design and Additive Manufacturing through BIM-Based Decision Support and Digital Twin Methods
A Lean-based Production Approach for Shotcrete 3D Printed Concrete Components
2021 | Placzek, G.; Brohmann, L.; Mawas, K.; Schwerdtner, P.; Hack, N.; Maboudi M.; Gerke, M.: D.: A Lean-based Production Approach for Shotcrete 3D Printed Concrete Components. In: 2021 Proceedings of the 38th ISARC, Dubai, UAE, Pages 811-818, 2021. DOI: doi.org/10.22260/ISARC2021/0110.
Mechanical properties of wire and arc additively manufactured high-strength steel structures
2021 | Müller, J.; Hensel, J.; Dilger, K.: Mechanical properties of wire and arc additively manufactured high-strength steel structures. In: Welding in the World, DOI: 10.1007/s40194-021-01204-1.
Project(s)
Wire and Arc Additive Manufacturing (WAAM) of Complex Individualized Steel Components
Integrating reinforcement in digital fabrication with concrete: A review and classification framework
2021 | Mechtcherine, V.; Buswell, R.; Kloft, H.; Bos, F. P.; Hack, N.; Wolfs, R.; Sanjayan, J.; Nematollahi, B.; Ivaniuk, E.; Neef, T.: Integrating reinforcement in digital fabrication with concrete: A review and classification framework. In: Cement and Concrete Composites, 119, 2021. – DOI: https://doi.org/10.1016/j.cemconcomp.2021.103964.
Project(s)
Integrated Additive Manufacturing Processes for Reinforced Shotcrete 3D Printing (SC3DP) Elements with Precise Surface Quality
Integration of Individualized Prefabricated Fibre Reinforcement in Additive Manufacturing with Concrete
Automated shotcrete 3D printing – Printing interruption for extended component complexity
2021 | Lachmayer, L.; Dörrie, R.; Kloft,H.; Raatz, A.: Automated shotcrete 3D printing – Printing interruption for extended component complexity. In: ISARC, 2021.
Project(s)
Integrated Additive Manufacturing Processes for Reinforced Shotcrete 3D Printing (SC3DP) Elements with Precise Surface Quality
Process Control and Adaptive Path Planning for Additive Manufacturing Processes Based on Industrial Robots with an Extended Degree of Freedom
Additive Manufacturing of Thermally Enhanced Lightweight Concrete Wall Elements with Closed Cellular Structures
2021 | Dielemans, G., Briels, D., Jaugstetter, F., Henke, K., Dörfler, K.: Additive Manufacturing of Thermally Enhanced Lightweight Concrete Wall Elements with Closed Cellular Structures. In: Journal of Facade Design & Engineering, 9(1), 59–72. – DOI: https://doi.org/10.7480/jfde.2021.1.5418.
Mobile Additive Manufacturing: a robotic system for cooperative on-site construction
2021 | Dielemans, G., Dörfler, K.: Mobile Additive Manufacturing: a robotic system for cooperative on-site construction. In: IROS 2021 Workshop Robotic Fabrication: Sensing in Additive Construction, 2021.
Approach to an optimized printing path for additive manufacturing in construction utilizing FEM modeling
2021 | Lachmayer, L.; Ekanayaka, V.; Hürkamp, A.; Raatz, A.: Approach to an optimized printing path for additive manufacturing in construction utilizing FEM modeling. In: Procedia CIRP CMS, 2021.
Project(s)
Process Control and Adaptive Path Planning for Additive Manufacturing Processes Based on Industrial Robots with an Extended Degree of Freedom
New calculation approach for selecting and orienting the reinforcing material for robotic concrete manufacturing
2021 | Baghdadi, A.; Doerrie, R.; Kloft, H.: New calculation approach for selecting and orienting the reinforcing material for robotic concrete manufacturing. In: Proceedings of the IASS Annual Symposium 2020/21 and the 7th International Conference on Spatial Structures Inspiring the Next Generation. 23 – 27 August, Guilford, UK, 2021.
Project(s)
Integrated Additive Manufacturing Processes for Reinforced Shotcrete 3D Printing (SC3DP) Elements with Precise Surface Quality
Parametric design of in-plane concrete dry joints by FE method and Fuzzy logic toward utilising additive manufacturing technique
2021 | Baghdadi, A.; Meshkini, A.; Kloft, H.: Parametric design of in-plane concrete dry joints by FE method and Fuzzy logic toward utilising additive manufacturing technique. In: Proceedings of the IASS Annual Symposium 2020/21 and the 7th International Conference on Spatial Structures Inspiring the Next Generation. 23 – 27 August, Guilford, UK, 2021.
Project(s)
Jointing Principles for Combination of Concrete Elements Produced by Different Additive Manufacturing Processes
Inspiration of Interlocking Wooden Puzzles for Precast Concrete Construction Conceptual Design of Structures
2021 | Baghdadi, A.; Meshkini, A.; Kloft, H.: Inspiration of Interlocking Wooden Puzzles for Precast Concrete Construction Conceptual Design of Structures. In: International fib Symposium, September 16-18, Switzerland, 2021.
Project(s)
Jointing Principles for Combination of Concrete Elements Produced by Different Additive Manufacturing Processes
Virtual Prototyping mit DEM zur Entwicklung eines Near-Nozzle-Mixing Verfahrens für den additiven 3D Betondruck für den Roboter Einsatz
2021 | Tan, Y.; Dahlenburg, M.; Kessler, S.; Fottner, J.: Virtual Prototyping mit DEM zur Entwicklung eines Near-Nozzle-Mixing Verfahrens für den additiven 3D Betondruck für den Roboter Einsatz. In: 25. Fachtagung Schüttgutfördertechnik. OVGU Magdeburg, 2021.
Project(s)
Extrusion of Near-Nozzle Mixed Concrete –Individually Graded in Density and in Rate of 3D Fibre Reinforcement
Node-Based Shape Optimization and Mechanical Test Validation of Complex Metal Components and Support Structures, Manufactured by Laser Powder Bed Fusion
2021 | Ghantasala, A.; Diller, J.; Geiser, A.; Wenzler, D.; Siebert, D.; Radlbeck, C.; Wüchner, R.; Mensinger, M.; Bletzinger, K.U.: Node-Based Shape Optimization and Mechanical Test Validation of Complex Metal Components and Support Structures, Manufactured by Laser Powder Bed Fusion. In: Advances in Manufacturing, Production Management and Process Control. AHFE 2021; Lecture Notes in Networks and Systems, vol 274. Springer, Cham. – DOI: https://doi.org/10.1007/978-3-030-80462-6_2.
Project(s)
Laser Powder-Bed Fusion (LPBF) of Steel Elements for Construction – Basics of Design and Mechanical Resilience.
3D Structural Puzzle – Numerical Multi Scale Shape and Topology Optimisation Methods to Additively Manufacture Optimal Structures from Optimised Pieces
Use of Wood in Additive Manufacturing in Construction
2021 | Henke, K.; Talke, D.; Buschmann, B.: Use of Wood in Additive Manufacturing in Construction. In: Proceedings of the 17th Rapid.Tech 3D Conference, Erfurt, Germany, 22 -23 June 2021, M. Kynast, Ed., München: Hanser, Carl, 2021, pp. 177–187.
Computation of Implicit Representation of Volumetric Shells with Predefined Thickness
2021 | Geier, M.; Alihussein, H.: Computation of Implicit Representation of Volumetric Shells with Predefined Thickness. In: Algorithms 14.4, 125, 2021.
Author(s)
Project(s)
Modelling and Simulation of Shotcrete 3D Printing (SC3DP) Based on a Massively Parallel Multi-Phase, Multi-Component Coupled LBM-DEM Approach
A Direct Effective Viscosity Approach for Modeling and Simulating Bingham Fluids with the Cumulant Lattice Boltzmann Method
2021 | Geier, M.; Kutscher, K.; Krafczyk, M.: A Direct Effective Viscosity Approach for Modeling and Simulating Bingham Fluids with the Cumulant Lattice Boltzmann Method. In: Open Journal of Fluid Dynamics 11.01, 34, 2021. – DOI: https://www.scirp.org/html/3-2320649_107771.htm.
Project(s)
Modelling and Simulation of Shotcrete 3D Printing (SC3DP) Based on a Massively Parallel Multi-Phase, Multi-Component Coupled LBM-DEM Approach
Injection 3D concrete printing in a carrier liquid – Underlying physics and applications to lightweight space frame structures
2021 | Lowke, D.: Injection 3D concrete printing in a carrier liquid – Underlying physics and applications to lightweight space frame structures. In: Cement and Concrete Composites, 2021. – DOI: https://doi.org/10.1016/j.cemconcomp.2021.104169.
Project(s)
Integrated Additive Manufacturing Processes for Reinforced Shotcrete 3D Printing (SC3DP) Elements with Precise Surface Quality
Integration of Individualized Prefabricated Fibre Reinforcement in Additive Manufacturing with Concrete
Bewehrungskonzepte beim 3D-Druck von Konstruktionsbeton
2021 | Lowke, D.; Gehlen, C.; Kloft, H.; Freund, N.; Matthäus, C.: Bewehrungskonzepte beim 3D-Druck von Konstruktionsbeton. In: BfT International, 02.2021, S. 92, 2021.
Project(s)
Particle-Bed 3D Printing by Selective Cement Paste Intrusion (SPI) – Particle Surface Functionalisation, Particle Synthesis and Integration of WAAM Reinforcement
Integrated Additive Manufacturing Processes for Reinforced Shotcrete 3D Printing (SC3DP) Elements with Precise Surface Quality
Numerical evaluation of high cycle fatigue life for additively manufactured stainless steel 316L lattice structures
2021 | Alaimo, G.; Carraturo, M.; Korshunova, N.; Kollmannsberger, S.: Numerical evaluation of high cycle fatigue life for additively manufactured stainless steel 316L lattice structures. In: Material Design and Processing Communication 3 (4), pp. e249, Wiley, 2021. – DOI: 10.1002/mdp2.249.
Hierarchical multigrid approaches for the finite cell method on uniform and multi-level hp-refined grids
2021 | Jomo, J.; Oztoprak, O.; de Prenter, F.; Zander, N.; Kollmannsberger, S.; Rank, E.: Hierarchical multigrid approaches for the finite cell method on uniform and multi-level hp-refined grids. In: Computer Methods in Applied Mechanics and Engineering 386, pp. 114075, 2021. – DOI: 10.1016/j.cma.2021.114075.
Dauerhaftigkeit – Potenzial additiver Fertigung und Performance im Vergleich zu konventioneller Fertigung
2021 | Gehlen, C.; Lowke, D.; Weger, D.; Dreßler, I.: Dauerhaftigkeit – Potenzial additiver Fertigung und Performance im Vergleich zu konventioneller Fertigung. In: BfT International, 02.2021, S. 94, 2021.
Project(s)
Particle-Bed 3D Printing by Selective Cement Paste Intrusion (SPI) – Particle Surface Functionalisation, Particle Synthesis and Integration of WAAM Reinforcement
Integrated Additive Manufacturing Processes for Reinforced Shotcrete 3D Printing (SC3DP) Elements with Precise Surface Quality
Multiscale analysis of high damping composites using the finite cell and the mortar method
2021 | Paolini, A.; Korshunova, N.; Kollmannsberger, S.; Rank, E.: Multiscale analysis of high damping composites using the finite cell and the mortar method. In: International Journal of Structural Stability and Dynamics, 2021. – DOI: 10.1142/S0219455421501492.
Uncertainty quantification of microstructure variability and mechanical behavior of additively manufactured lattice structures
2021 | Korshunova, N.; Papaioannou, I.; Kollmannsberger S.; Straub, D.; Rank, E.: Uncertainty quantification of microstructure variability and mechanical behavior of additively manufactured lattice structures. In: Computer Methods in Applied Mechanics and Engineering 385 (1), pp. 114049, 2021. – DOI: https://doi.org/10.1016/j.cma.2021.114049.
Development of a Robot-Based Multi-Directional Dynamic Fiber Winding Process for Additive Manufacturing Using Shotcrete 3D Printing
2021 | Hack, N.; Bahar, M.; Hühne, C.; Lopez, W.; Gantner, S.; Khader, N.; Rothe, T.: Development of a Robot-Based Multi-Directional Dynamic Fiber Winding Process for Additive Manufacturing Using Shotcrete 3D Printing. In: Fibers 2021, 9, 39, 2021. – DOI: https://doi.org/10.3390/fib9060039.
Project(s)
Integration of Individualized Prefabricated Fibre Reinforcement in Additive Manufacturing with Concrete
Penetration of Cement Pastes into Particle-Beds: A Comparison of Penetration Models
2021 | Weger, D.; Pierre, A.; Perrot, A.; Kränkel, T.; Lowke, D.; Gehlen, C.: Penetration of Cement Pastes into Particle-Beds: A Comparison of Penetration Models. In: Materials 2021, 14, 389. – DOI: https://doi.org/10.3390/ma14020389.
Project(s)
Particle-Bed 3D Printing by Selective Cement Paste Intrusion (SPI) – Particle Surface Functionalisation, Particle Synthesis and Integration of WAAM Reinforcement
Additive Fertigung im Bauwesen
2021 | Kloft, H., Gehlen, C., Dörfler, K., Hack, N., Henke, K., Lowke, D., Mainka, J. and Raatz, A. (2021), TRR 277: Additive Fertigung im Bauwesen. In: Bautechnik, 98: 222-231. – DOI: https://doi.org/10.1002/bate.202000113.
Schweißtechnische Verarbeitung von hochfestem Stahl als Aufbauwerkstoff beim Wire and Arc Additive Manufacturing
2021 |Müller, J., Hensel, J., Dilger, K.: Schweißtechnische Verarbeitung von hochfestem Stahl als Aufbauwerkstoff beim Wire and Arc Additive Manufacturing. In: Fortschrittsberichte der Materialforschung und Werkstofftechnik / Bulletin of Materials Research and Engineering, Band 10, Clausthaler Zentrum für Materialtechnik (Hrsg.), Shaker Verlag Düren 2021 (ISBN: 978-3-8440-8021-6)
Project(s)
Wire and Arc Additive Manufacturing (WAAM) of Complex Individualized Steel Components
Bending behavior of octet-truss lattice structures: modelling options, numerical characterization and experimental validation
2021 | Korshunova, N.; Alaimo, G.; Hosseini, S. B.; Carraturo, M.; Reali, A.; Niiranen, J.; Auricchio, F.; Rank, E.; Kollmannsberger, S.: Bending behavior of octet-truss lattice structures: modelling options, numerical characterization and experimental validation. In: Materials & Design, 2021.
A CT-based numerical characterization of tensile behavior of additively manufactured octet-truss structures and its experimental validation
2021 | Korshunova, N.; Alaimo, G.; Hosseini, S.; Carraturo, M.; Reali, A.; Niiranen, J.; Auricchio, F.; Rank, E.; Kollmannsberger, S.: A CT-based numerical characterization of tensile behavior of additively manufactured octet-truss structures and its experimental validation. In: Additive Manufacturing, p. 101949, 2021. – DOI: https://doi.org/10.1016/j.addma.2021.101949.
Integrating Digital Design and Additive Manufacturing Through BIM-Based Digital Support – A decision support system using Semantic Web and Multi-Criteria Decision Making
2021 | Li, C.; Petzold, F.: Integrating Digital Design and Additive Manufacturing Through BIM-Based Digital Support – A decision support system using Semantic Web and Multi-Criteria Decision Making. In: Proceedings of the 26th International Conference of the Association for Computer-Aided Architectural Design Research in Asia (CAADRIA) 2021, Volume 1, 263-270.
Project(s)
Integrating Digital Design and Additive Manufacturing through BIM-Based Decision Support and Digital Twin Methods
Practical solutions in additive manufacturing – Innovative jointing principles
2021 | Empelmann, M.; Kloft, H.: Practical solutions in additive manufacturing – Innovative jointing principles. In: BFT International 87, Issue 2, p. 93.
Project(s)
Jointing Principles for Combination of Concrete Elements Produced by Different Additive Manufacturing Processes
Particle-Bed Binding by Selective Paste Intrusion—Strength and Durability of Printed Fine-Grain Concrete Members
2021 | Weger, D.; Gehlen, C.: Particle-Bed Binding by Selective Paste Intrusion—Strength and Durability of Printed Fine-Grain Concrete Members. In: Materials 2021, 14, 586. – DOI: doi.org/10.3390/ma14030586.
Author(s)
Project(s)
Particle-Bed 3D Printing by Selective Cement Paste Intrusion (SPI) – Particle Surface Functionalisation, Particle Synthesis and Integration of WAAM Reinforcement
Individual layer fabrication (ILF): a novel approach to additive manufacturing by the use of wood
2021 | Henke, K.; Talke, D.; Bunzel, F.; et al.: Individual layer fabrication (ILF): a novel approach to additive manufacturing by the use of wood. Eur. J. Wood Prod. – DOI: doi.org/10.1007/s00107-020-01646-2.
The lattice Boltzmann method for nearly incompressible flows
2021 | Lallemand, P.; Luo, L.; Krafczyk, M.; Yong, W.: The lattice Boltzmann method for nearly incompressible flows. In: Journal of Computational Physics 431. – DOI: doi.org/10.1016/j.jpc.2020.109713.
Author(s)
Project(s)
Modelling and Simulation of Shotcrete 3D Printing (SC3DP) Based on a Massively Parallel Multi-Phase, Multi-Component Coupled LBM-DEM Approach
Herausforderungen für einen traditionellen Werkstoff auf dem Weg in die Zukunft – Digitaler Beton.
2020 | Lowke, D.: Herausforderungen für einen traditionellen Werkstoff auf dem Weg in die Zukunft – Digitaler Beton. In: BFT International, 02-2020, Vol. 86, S. 75, 2020.
Author(s)
Project(s)
Integrated Additive Manufacturing Processes for Reinforced Shotcrete 3D Printing (SC3DP) Elements with Precise Surface Quality
Injection 3D Concrete Printing (I3DCP): Basic Principles and Case Studies.
2020 | Hack, N.; Dressler, I.; Brohmann, L.; Gantner, S.; Lowke, D.; Kloft, H.: Injection 3D Concrete Printing (I3DCP): Basic Principles and Case Studies. In: Materials 2020, 13, 1093, 2020. – DOI: https://doi.org/10.3390/ma13051093.
Project(s)
Integrated Additive Manufacturing Processes for Reinforced Shotcrete 3D Printing (SC3DP) Elements with Precise Surface Quality
Integration of Additive Manufacturing in the Construction Process
