Your search keyword '"Parametric 3D printing model"' showing total 3 results

1. Elastic buckling and plastic collapse during 3D concrete printing

Author

Suiker, Akke S.J., Wolfs, Rob J.M., Lucas, Sandra M., Salet, Theo A.M., Suiker, Akke S.J., Wolfs, Rob J.M., Lucas, Sandra M., and Salet, Theo A.M.

Abstract

This contribution studies failure by elastic buckling and plastic collapse during 3D concrete printing of wall structures. Four types of experiments were performed, which demonstrate the circumstances under which elastic buckling and plastic collapse occur, the effect of geometrical imperfections on the buckling response, the in- fluence by the curing rate of the concrete material on the buckling stability, and the conditions leading to the successful printing of a complex, practical structure (a picnic table). The experimental results are compared to those computed by the parametric 3D printing model recently developed by Suiker (Int. J. Mech Sci, 137: 145–170, 2018), showing a very good agreement. The design formulas and design graphs deduced from the parametric model serve as a useful tool for accurately designing wall structures against failure during 3D con- crete printing. Furthermore, they may be applied to optimize the process conditions during 3D printing, by providing the maximal printing velocity, the optimal geometrical characteristics, or the minimal amount of material required for adequately printing the structure.

Published

2020

2. Elastic buckling and plastic collapse during 3D concrete printing

Author

Akke S.J. Suiker, Rjm Rob Wolfs, Theo A.M. Salet, Sandra M. Lucas, Applied Mechanics and Design, Concrete Structures, 3D Concrete Printing, and EAISI High Tech Systems

Subjects

Materials science, business.industry, Additive manufacturing, Structural failure, 0211 other engineering and technologies, 3D printing, Parametric 3D printing model, 02 engineering and technology, Building and Construction, Structural engineering, 021001 nanoscience & nanotechnology, Process conditions, Buckling, 021105 building & construction, Parametric model, General Materials Science, 0210 nano-technology, business, 3D printing experiments, Optimization of 3D printing process, Parametric statistics

Abstract

This contribution studies failure by elastic buckling and plastic collapse during 3D concrete printing of wall structures. Four types of experiments were performed, which demonstrate the circumstances under which elastic buckling and plastic collapse occur, the effect of geometrical imperfections on the buckling response, the influence by the curing rate of the concrete material on the buckling stability, and the conditions leading to the successful printing of a complex, practical structure (a picnic table). The experimental results are compared to those computed by the parametric 3D printing model recently developed by Suiker (Int. J. Mech Sci, 137: 145–170, 2018), showing a very good agreement. The design formulas and design graphs deduced from the parametric model serve as a useful tool for accurately designing wall structures against failure during 3D concrete printing. Furthermore, they may be applied to optimize the process conditions during 3D printing, by providing the maximal printing velocity, the optimal geometrical characteristics, or the minimal amount of material required for adequately printing the structure.

Published

2020

3. Elastic buckling and plastic collapse during 3D concrete printing.

Author

Suiker, A.S.J., Wolfs, R.J.M., Lucas, S.M., and Salet, T.A.M.

Subjects

*MECHANICAL buckling, *THREE-dimensional printing, *CONCRETE curing, *STRUCTURAL failures, *WALL design & construction, *PARAMETRIC modeling, *CONCRETE walls

Abstract

This contribution studies failure by elastic buckling and plastic collapse during 3D concrete printing of wall structures. Four types of experiments were performed, which demonstrate the circumstances under which elastic buckling and plastic collapse occur, the effect of geometrical imperfections on the buckling response, the influence by the curing rate of the concrete material on the buckling stability, and the conditions leading to the successful printing of a complex, practical structure (a picnic table). The experimental results are compared to those computed by the parametric 3D printing model recently developed by Suiker (Int. J. Mech Sci, 137: 145–170, 2018), showing a very good agreement. The design formulas and design graphs deduced from the parametric model serve as a useful tool for accurately designing wall structures against failure during 3D concrete printing. Furthermore, they may be applied to optimize the process conditions during 3D printing, by providing the maximal printing velocity, the optimal geometrical characteristics, or the minimal amount of material required for adequately printing the structure. [ABSTRACT FROM AUTHOR]

Published

2020