TY - GEN
T1 - 3D-Concrete Printing-Graded Concrete Extrusion
AU - Dahlenburg, Maximilian
AU - Hechtl, Christian Maximilian
AU - Matthaus, Carla
AU - Fottner, Johannes
N1 - Publisher Copyright:
© 2022 IEEE.
PY - 2022
Y1 - 2022
N2 - Nowadays, additive manufacturing is one of the leading research focuses in the construction sector. Among many established processes such as shotcrete, selective paste intrusion, and selective cement activation, extrusion processes represent the vast majority of methods used for large-scale printed building elements. Current extrusion processes use premixed concrete pumped through a hose, optionally accelerated at the nozzle, and then deposited. A new system approach, named Gradation-Ready Extrusion System (GRES), has been developed to exploit the benefits of additive manufacturing even better. It improves conventional extrusion by technically enabling the production of graded, multi-material building components, i.e., material properties can be varied within a single component. Thus, GRES enables sections to be made with different load-bearing capabilities or thermal conductivities. This in-situ gradation possibility significantly increases the potential use cases in concrete extrusion. GRES enables the continuous production of fresh concrete by metering and mixing raw materials directly before deposition (near-nozzle). Hence, avoiding long hose distances and the associated conflicting demands on material design; workability vs. buildability. The system design is based on material research, discrete element method simulations, and experimental prototype optimization. It comprises three sections-mixing, conveying, and compressing-each independently controllable by a programmable logic controller. Input values, for example, mix design and process parameters, are entered at the developed graphical user interface. Unlike existing extruding systems, with GRES, the concrete base mixture and its properties can be adjusted during the printing of complex geometries, resulting in multi-material graded concrete components optimized for load-bearing and insulation.
AB - Nowadays, additive manufacturing is one of the leading research focuses in the construction sector. Among many established processes such as shotcrete, selective paste intrusion, and selective cement activation, extrusion processes represent the vast majority of methods used for large-scale printed building elements. Current extrusion processes use premixed concrete pumped through a hose, optionally accelerated at the nozzle, and then deposited. A new system approach, named Gradation-Ready Extrusion System (GRES), has been developed to exploit the benefits of additive manufacturing even better. It improves conventional extrusion by technically enabling the production of graded, multi-material building components, i.e., material properties can be varied within a single component. Thus, GRES enables sections to be made with different load-bearing capabilities or thermal conductivities. This in-situ gradation possibility significantly increases the potential use cases in concrete extrusion. GRES enables the continuous production of fresh concrete by metering and mixing raw materials directly before deposition (near-nozzle). Hence, avoiding long hose distances and the associated conflicting demands on material design; workability vs. buildability. The system design is based on material research, discrete element method simulations, and experimental prototype optimization. It comprises three sections-mixing, conveying, and compressing-each independently controllable by a programmable logic controller. Input values, for example, mix design and process parameters, are entered at the developed graphical user interface. Unlike existing extruding systems, with GRES, the concrete base mixture and its properties can be adjusted during the printing of complex geometries, resulting in multi-material graded concrete components optimized for load-bearing and insulation.
KW - 3DCP
KW - Additive manufacturing in construction
KW - Concrete gradation
KW - Extrusion
KW - Lightweight concrete
KW - Near-nozzle-mixing
UR - http://www.scopus.com/inward/record.url?scp=85146305202&partnerID=8YFLogxK
U2 - 10.1109/ICCAKM54721.2022.9990494
DO - 10.1109/ICCAKM54721.2022.9990494
M3 - Conference contribution
AN - SCOPUS:85146305202
T3 - Proceedings - 2022 3rd International Conference on Computation, Automation and Knowledge Management, ICCAKM 2022
BT - Proceedings - 2022 3rd International Conference on Computation, Automation and Knowledge Management, ICCAKM 2022
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 3rd International Conference on Computation, Automation and Knowledge Management, ICCAKM 2022
Y2 - 15 November 2022 through 17 November 2022
ER -