TY - JOUR
T1 - Additive manufacturing with varying material properties of thermosetting reactive polymers
T2 - A framework and comparison of different modes for implementing material transitions
AU - Pajonk, Adam
AU - Luna-Navarro, Alessandra
AU - Knaack, Ulrich
AU - Blum, Ulrich
PY - 2024
Y1 - 2024
N2 - Additive Manufacturing with Varying Material Properties enables controlled spatial variation of material properties in 3D-printed components, facilitating custom-tailored characteristics, added functionalities and reduced assembly processes. To promote this approach in building façade applications, this paper presents a novel framework for Additive Manufacturing with varying material properties using a thermosetting reactive polymer, specifically polyurethane. By dynamically changing the polyurethane’s chemical composition, the material properties can be precisely controlled. The framework’s individual aspects, including the material, hardware setup and computational system, are described in detail. Additionally, the research explores the implementation of material transitions with this framework, highlighting three different modes (horizontal, vertical and multi plane) and their impact on print time and material consumption. The paper concludes by discussing the potential of this approach for building façade applications, addressing current challenges and outlining future research directions.
AB - Additive Manufacturing with Varying Material Properties enables controlled spatial variation of material properties in 3D-printed components, facilitating custom-tailored characteristics, added functionalities and reduced assembly processes. To promote this approach in building façade applications, this paper presents a novel framework for Additive Manufacturing with varying material properties using a thermosetting reactive polymer, specifically polyurethane. By dynamically changing the polyurethane’s chemical composition, the material properties can be precisely controlled. The framework’s individual aspects, including the material, hardware setup and computational system, are described in detail. Additionally, the research explores the implementation of material transitions with this framework, highlighting three different modes (horizontal, vertical and multi plane) and their impact on print time and material consumption. The paper concludes by discussing the potential of this approach for building façade applications, addressing current challenges and outlining future research directions.
KW - varying property additive manufacturing
KW - thermoset reactive polymers
KW - reactive extrusion additive manufacturing
KW - robotic 3D printing
KW - heterogeneous materials
KW - polyurethane
UR - http://www.scopus.com/inward/record.url?scp=85192988748&partnerID=8YFLogxK
U2 - 10.1080/00038628.2024.2348141
DO - 10.1080/00038628.2024.2348141
M3 - Article
SN - 0003-8628
JO - Architectural Science Review
JF - Architectural Science Review
ER -