Details

Autor(en) / Beteiligte

• Nerella, Venkatesh Naidu
• Hempel, Simone
• Mechtcherine, Viktor

Titel

Effects of layer-interface properties on mechanical performance of concrete elements produced by extrusion-based 3D-printing

Ist Teil von

• Construction & building materials, 2019-04, Vol.205, p.586-601

Ort / Verlag

Elsevier Ltd

Erscheinungsjahr

2019

Link zum Volltext

Quelle

Alma/SFX Local Collection

Beschreibungen/Notizen

• •Mechanical tests and SEM investigations on layer-interfacial bonds were performed.•Composition, followed by printing interval, influenced bond strength pronouncedly.•Flexural and compressive strengths varied depending on the interface microstructure.•Microstructure inspections revealed air cavities and other defects at interfaces.•Mixture with SCMs yielded superior bond strengths and self-healing ability. Interfaces between layers in 3D-printed elements produced by extrusion-based material deposition were investigated on both macro- and micro-scales. On the macro-scale, compression and flexural tests were performed on two 3D-printable cement-based compositions (3PCs), namely Mixtures C1 (with Portland cement as sole binder) and C2 (containing pozzolanic additives) at testing ages of 1 day and 28 days. The influences of binder composition and time interval between layers on layer-interface strength were critically analyzed. The investigated time intervals were 2 min, 10 min and 1 day. The investigations revealed that Mixture C2 exhibited lower degrees of anisotropy and heterogeneity as well as superior mechanical performance in comparison to Mixture 1. In particular, Mixture C2 showed a less pronounced (below 25%) decrease in interface bond strength as observed in flexural tests for all time intervals under investigation. In contrast, the decrease in flexural strength measured for C1 specimens amounted to over 90% due to the higher porosity at the interfaces of the printed concrete layers. Microscopic observations supported the findings of the macroscopic investigations. SEM images also delivered additional information on morphology of interfacial defects as well as “self-healing”.