Freeze-Thaw Performance of 3D Printed Concrete: Influence of Interfaces

“…5(a)) showed the highest residual strain value as compared to the other two types of specimens (Fig. 5(b) and (c)), which is in accordance with the findings of Wang et al 42 This could be due to the fact that FT damage is primarily localized along the weak interfaces, as stated in the literature, 30,34,41 which are perpendicular to the length change measurements for this type of specimen (Fig. 5(a)).…”

“…14,19,[22][23][24][25][26] The durability of three-dimensional (3-D)-printed concrete structures is only recently being examined. [27][28][29][30][31][32][33][34][35] The layer-wise process of additive manufacturing with cement-based materials may lead to microstructural heterogeneities such as weak interfaces. 14,25,36 Further research is necessary to understand whether 3-D-printed cement-based elements can be assumed to behave as a homogenous material with an isotropic material response.…”

“…The presence of cold joints, macropores, and interfaces in the printed cementitious elements may influence their FT response. 30,31,36 In addition, the quality of the entrained air (that is, shape, size, and spacing), commonly used in conventional concrete to increase its FT resistance 37,38 may be altered due to the shearing process, the processing parameters such as extrusion pressure, and the interaction of air-entraining admixtures with other admixtures typically used in the mixture design of printed materials, such as high-range water-reducing admixtures (HRWRAs) and accelerators. 35,39,40 Few studies have investigated the FT response of printed cementitious specimens.…”

“…35,39,40 Few studies have investigated the FT response of printed cementitious specimens. 27,30,34,35,41,42 Das et al 35 used protected paste volume analysis to predict similar performance for the cast and printed specimens under freezing conditions. Das et al 30 measured the FT resistance of printed and cast specimens using ASTM C666 Procedure B and concluded that printed specimens have lower resistance to FT cycles as compared to cast specimens due to high capillary porosity at the interface between the printed filaments.…”

“…27,30,34,35,41,42 Das et al 35 used protected paste volume analysis to predict similar performance for the cast and printed specimens under freezing conditions. Das et al 30 measured the FT resistance of printed and cast specimens using ASTM C666 Procedure B and concluded that printed specimens have lower resistance to FT cycles as compared to cast specimens due to high capillary porosity at the interface between the printed filaments. 30 Zhang et al 34 measured higher FT damage in printed specimens as compared to cast samples using the dynamic elastic modulus; they concluded that the FT-induced damage occurred along weak printed interfaces, and the aggregates were more difficult to dislodge from the surface of printed specimens than cast samples due to the extrusion pressure leading to a densely packed surface in printed materials.…”

Examining Effect of Printing Directionality on the Freezing-and-Thawing Response of Three-Dimensional-Printed Cement Paste

“…5(a)) showed the highest residual strain value as compared to the other two types of specimens (Fig. 5(b) and (c)), which is in accordance with the findings of Wang et al 42 This could be due to the fact that FT damage is primarily localized along the weak interfaces, as stated in the literature, 30,34,41 which are perpendicular to the length change measurements for this type of specimen (Fig. 5(a)).…”

“…14,19,[22][23][24][25][26] The durability of three-dimensional (3-D)-printed concrete structures is only recently being examined. [27][28][29][30][31][32][33][34][35] The layer-wise process of additive manufacturing with cement-based materials may lead to microstructural heterogeneities such as weak interfaces. 14,25,36 Further research is necessary to understand whether 3-D-printed cement-based elements can be assumed to behave as a homogenous material with an isotropic material response.…”

“…The presence of cold joints, macropores, and interfaces in the printed cementitious elements may influence their FT response. 30,31,36 In addition, the quality of the entrained air (that is, shape, size, and spacing), commonly used in conventional concrete to increase its FT resistance 37,38 may be altered due to the shearing process, the processing parameters such as extrusion pressure, and the interaction of air-entraining admixtures with other admixtures typically used in the mixture design of printed materials, such as high-range water-reducing admixtures (HRWRAs) and accelerators. 35,39,40 Few studies have investigated the FT response of printed cementitious specimens.…”

“…35,39,40 Few studies have investigated the FT response of printed cementitious specimens. 27,30,34,35,41,42 Das et al 35 used protected paste volume analysis to predict similar performance for the cast and printed specimens under freezing conditions. Das et al 30 measured the FT resistance of printed and cast specimens using ASTM C666 Procedure B and concluded that printed specimens have lower resistance to FT cycles as compared to cast specimens due to high capillary porosity at the interface between the printed filaments.…”

“…27,30,34,35,41,42 Das et al 35 used protected paste volume analysis to predict similar performance for the cast and printed specimens under freezing conditions. Das et al 30 measured the FT resistance of printed and cast specimens using ASTM C666 Procedure B and concluded that printed specimens have lower resistance to FT cycles as compared to cast specimens due to high capillary porosity at the interface between the printed filaments. 30 Zhang et al 34 measured higher FT damage in printed specimens as compared to cast samples using the dynamic elastic modulus; they concluded that the FT-induced damage occurred along weak printed interfaces, and the aggregates were more difficult to dislodge from the surface of printed specimens than cast samples due to the extrusion pressure leading to a densely packed surface in printed materials.…”

Examining Effect of Printing Directionality on the Freezing-and-Thawing Response of Three-Dimensional-Printed Cement Paste

Two Year Exposure of 3D Printed Cementitious Columns in a High Alpine Environment

Mechanical performance of sinusoidally architected concrete enabled by robotic additive manufacturing