Multi-axial 3D printing of biopolymer-based concrete composites in construction

Research output: Contribution to journalJournal articleResearchpeer-review

Standard

Multi-axial 3D printing of biopolymer-based concrete composites in construction. / Christ, Julian; Leusink, Sander; Koss, Holger.

In: Materials and Design, Vol. 235, 112410, 2023.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Christ, J, Leusink, S & Koss, H 2023, 'Multi-axial 3D printing of biopolymer-based concrete composites in construction', Materials and Design, vol. 235, 112410. https://doi.org/10.1016/j.matdes.2023.112410

APA

Christ, J., Leusink, S., & Koss, H. (2023). Multi-axial 3D printing of biopolymer-based concrete composites in construction. Materials and Design, 235, [112410]. https://doi.org/10.1016/j.matdes.2023.112410

Vancouver

Christ J, Leusink S, Koss H. Multi-axial 3D printing of biopolymer-based concrete composites in construction. Materials and Design. 2023;235. 112410. https://doi.org/10.1016/j.matdes.2023.112410

Author

Christ, Julian ; Leusink, Sander ; Koss, Holger. / Multi-axial 3D printing of biopolymer-based concrete composites in construction. In: Materials and Design. 2023 ; Vol. 235.

Bibtex

@article{79ad3fbdbbea49fcad75aa13478a4a8a,
title = "Multi-axial 3D printing of biopolymer-based concrete composites in construction",
abstract = "This paper explores the free-form potential of 3D concrete printing, enabled by a novel concrete-like composite made from 80 %-w/v mammal gelatin solution in water with 35 %-w/w gelatin solution to mineral aggregate ratio. This complete replacement of cementitious binders in 3D printing mortar aims on improving the sustainability and advancing the setting control through the material{\textquoteright}s thermoplasticity. The material was extruded with a novel and heated ram extruder, traversed with a KUKA robot arm, and cooled by a box fan under normal ambient temperature and humidity conditions. Printing trials with cylinders of 20 cm diameter and various overhang inclinations were carried out – both vertically and multi-directionally sliced. The overhang was increased until the fresh material could no longer support itself. The multi-directionally sliced objects showed the largest overhang capabilities. The thermoplastic printing mortar was able to print a maximum overhang of 80◦. This demonstrated freedom of shape and applicability of the bio-based mortar to a 3D printing process could pave the way for highly optimized building components with a minimum use of material. This can increase the sustainability aspects of concrete structures.",
author = "Julian Christ and Sander Leusink and Holger Koss",
year = "2023",
doi = "10.1016/j.matdes.2023.112410",
language = "English",
volume = "235",
journal = "Materials and Design",
issn = "0264-1275",
publisher = "Elsevier",

}

RIS

TY - JOUR

T1 - Multi-axial 3D printing of biopolymer-based concrete composites in construction

AU - Christ, Julian

AU - Leusink, Sander

AU - Koss, Holger

PY - 2023

Y1 - 2023

N2 - This paper explores the free-form potential of 3D concrete printing, enabled by a novel concrete-like composite made from 80 %-w/v mammal gelatin solution in water with 35 %-w/w gelatin solution to mineral aggregate ratio. This complete replacement of cementitious binders in 3D printing mortar aims on improving the sustainability and advancing the setting control through the material’s thermoplasticity. The material was extruded with a novel and heated ram extruder, traversed with a KUKA robot arm, and cooled by a box fan under normal ambient temperature and humidity conditions. Printing trials with cylinders of 20 cm diameter and various overhang inclinations were carried out – both vertically and multi-directionally sliced. The overhang was increased until the fresh material could no longer support itself. The multi-directionally sliced objects showed the largest overhang capabilities. The thermoplastic printing mortar was able to print a maximum overhang of 80◦. This demonstrated freedom of shape and applicability of the bio-based mortar to a 3D printing process could pave the way for highly optimized building components with a minimum use of material. This can increase the sustainability aspects of concrete structures.

AB - This paper explores the free-form potential of 3D concrete printing, enabled by a novel concrete-like composite made from 80 %-w/v mammal gelatin solution in water with 35 %-w/w gelatin solution to mineral aggregate ratio. This complete replacement of cementitious binders in 3D printing mortar aims on improving the sustainability and advancing the setting control through the material’s thermoplasticity. The material was extruded with a novel and heated ram extruder, traversed with a KUKA robot arm, and cooled by a box fan under normal ambient temperature and humidity conditions. Printing trials with cylinders of 20 cm diameter and various overhang inclinations were carried out – both vertically and multi-directionally sliced. The overhang was increased until the fresh material could no longer support itself. The multi-directionally sliced objects showed the largest overhang capabilities. The thermoplastic printing mortar was able to print a maximum overhang of 80◦. This demonstrated freedom of shape and applicability of the bio-based mortar to a 3D printing process could pave the way for highly optimized building components with a minimum use of material. This can increase the sustainability aspects of concrete structures.

U2 - 10.1016/j.matdes.2023.112410

DO - 10.1016/j.matdes.2023.112410

M3 - Journal article

VL - 235

JO - Materials and Design

JF - Materials and Design

SN - 0264-1275

M1 - 112410

ER -

ID: 379714325