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Modelling the interlayer bond strength of 3D printed concrete with surface moisture
Abstract Providing additional water to the hydrating cementitious particles is essential to achieve the optimal mechanical performance of the low w/b concrete mixes preferred for 3D printing. This study incorporates superabsorbent polymers (SAP) and additional water in 3D printed concrete (3DPC) to promote the hydration process through delayed internal water release. The study shows that a retentive SAP modifies the rheological development by absorbing the pore fluid for a short period after printing. The absorption-induced stiffening increases the thixotropy and buildability by 49% and 25%, respectively. A retentive SAP increases the flexural strength and interlayer adhesion by 19% and 10%, respectively. This is due to the internal water release that promotes hydration. Evaporation of the interlayer moisture during the pass time has the opposite effect— evaporation reduces the interlayer adhesion. Based on this assumption, an analytical model is proposed. The model accounts for the pass time, bleeding, and the environmental evaporation rate to estimate the surface moisture and predict the lack of interlayer adhesion. In this study, the model accurately (RMSE = 2.5%) predicted an interlayer adhesion reduction from 30% to 50%. The interlayer adhesion results of other studies could also be predicted.
Graphical abstract Display Omitted
Highlights An analytical model for interlayer adhesion of 3DPC is proposed based on the amount of surface moisture on the interlayer. For this mix, the model accurately (RMSE=2.5%) predicts the reduction in interlayer adhesion from 30% to 50%. Internal curing with superabsorbent polymers increases the interlayer adhesion by 10% and flexural strength by 19%. SAPs also improve the initial thixotropy by 49% and buildability by 25% compared to the reference.
Modelling the interlayer bond strength of 3D printed concrete with surface moisture
Abstract Providing additional water to the hydrating cementitious particles is essential to achieve the optimal mechanical performance of the low w/b concrete mixes preferred for 3D printing. This study incorporates superabsorbent polymers (SAP) and additional water in 3D printed concrete (3DPC) to promote the hydration process through delayed internal water release. The study shows that a retentive SAP modifies the rheological development by absorbing the pore fluid for a short period after printing. The absorption-induced stiffening increases the thixotropy and buildability by 49% and 25%, respectively. A retentive SAP increases the flexural strength and interlayer adhesion by 19% and 10%, respectively. This is due to the internal water release that promotes hydration. Evaporation of the interlayer moisture during the pass time has the opposite effect— evaporation reduces the interlayer adhesion. Based on this assumption, an analytical model is proposed. The model accounts for the pass time, bleeding, and the environmental evaporation rate to estimate the surface moisture and predict the lack of interlayer adhesion. In this study, the model accurately (RMSE = 2.5%) predicted an interlayer adhesion reduction from 30% to 50%. The interlayer adhesion results of other studies could also be predicted.
Graphical abstract Display Omitted
Highlights An analytical model for interlayer adhesion of 3DPC is proposed based on the amount of surface moisture on the interlayer. For this mix, the model accurately (RMSE=2.5%) predicts the reduction in interlayer adhesion from 30% to 50%. Internal curing with superabsorbent polymers increases the interlayer adhesion by 10% and flexural strength by 19%. SAPs also improve the initial thixotropy by 49% and buildability by 25% compared to the reference.
Modelling the interlayer bond strength of 3D printed concrete with surface moisture
Moelich, Gerrit Marius (author) / Kruger, Jacques (author) / Combrinck, Riaan (author)
2021-07-28
Article (Journal)
Electronic Resource
English
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