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Compliance, Stress-Based and Multi-Physics Topology-Optimization for 3D Printed Concrete Structures (2018-09)

10.1007/978-3-319-99519-9_30

 Vantyghem Gieljan,  Boel Veerle,  de Corte Wouter,  Steeman Marijke
Contribution - Proceedings of the 1st RILEM International Conference on Concrete and Digital Fabrication, pp. 323-332

Abstract

Recent advancements in Additive Manufacturing (AM) technologies have pushed the limits of manufacturability and have encouraged the design of products with increased complexity. Topology Optimization (TO) algorithms, on the other hand, have provided engineers with a tool for intelligently exploiting this design freedom by efficiently optimizing the shape of engineering structures. In this paper, three important developments of TO that might influence the manufacturing process and design of 3D-printed concrete structures are discussed. The first example shows how general structural TO problems, such as the well-known minimum compliance problem, can help to determine the optimal printing path and can discover the ideal location of the steel reinforcements. Secondly, it is considered how stress-based TO can enhance the shape of fiber-reinforced concrete components where the lack of steel reinforcements introduces a non-negligible strength asymmetry. In a third and last example, traditional structural TO techniques are extended to allow for multiphysics optimization. The thermal transmittance through a construction component is minimized, while the overall material usage is restricted. Results show the generation of very efficient (multi-material) structures that are aesthetically pleasing at the same time. The presented techniques aid in the search for more efficient structural design and might help overcome some of the technological challenges related to large-scale concrete 3D-printing.

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BibTeX 
@inproceedings{vant_boel_cort_stee.2019.CSBaMPTOf3PCS,
  author            = "Gieljan Vantyghem and Veerle Boel and Wouter de Corte and Marijke Steeman",
  title             = "Compliance, Stress-Based and Multi-Physics Topology-Optimization for 3D Printed Concrete Structures",
  doi               = "10.1007/978-3-319-99519-9_30",
  year              = "2019",
  volume            = "19",
  pages             = "323--332",
  booktitle         = "Proceedings of the 1st RILEM International Conference on Concrete and Digital Fabrication: Digital Concrete 2018",
  editor            = "Timothy Paul Wangler and Robert Johann Flatt",
}
Formatted Citation

G. Vantyghem, V. Boel, W. de Corte and M. Steeman, “Compliance, Stress-Based and Multi-Physics Topology-Optimization for 3D Printed Concrete Structures”, in Proceedings of the 1st RILEM International Conference on Concrete and Digital Fabrication: Digital Concrete 2018, 2019, vol. 19, pp. 323–332. doi: 10.1007/978-3-319-99519-9_30.

Vantyghem, Gieljan, Veerle Boel, Wouter de Corte, and Marijke Steeman. “Compliance, Stress-Based and Multi-Physics Topology-Optimization for 3D Printed Concrete Structures”. In Proceedings of the 1st RILEM International Conference on Concrete and Digital Fabrication: Digital Concrete 2018, edited by Timothy Paul Wangler and Robert Johann Flatt, 19:323–32, 2019. https://doi.org/10.1007/978-3-319-99519-9_30.