3D‐Printing with steel of a bolted connection

Erven, Maren; Lange, Jörg; Feucht, Thilo

doi:10.1002/cepa.1367

Cited by 8 publications

(2 citation statements)

References 22 publications

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“…Currently, the AM processes of structural components in steel, despite being expensive and novel, represent a powerful line of research that operates at the limits of structural design innovation: the properties of the materials, the manufacturing techniques, the transport and installation and execution on site [3]. The main difficulties presented by this manufacturing technique are the dimensional limitations of the AM machines, the precision parameters and the need to consider mold release restrictions, tolerances, minimum thicknesses and angles [4].…”

Section: Introductionmentioning

confidence: 99%

Proposal and experimental verification of additive manufactured beam‐column connection designed by topological optimization

Gil,

Goñi,

Fábregas

et al. 2023

ce papers

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The aim of this research is to provide an alternative for the conventional design of beam‐to‐column connections in building structures. The new design is performed by means of Structural Topological Optimization and executed by means of additive manufacturing with steel.Regarding the methodology, the joint that would be manufactured by conventional methods (i.e. welded and bolted plates) is modelled by means of finite elements in the first place. Its behavior is obtained, as well as the boundary conditions and the loads to be applied to the part that is going to be optimized. Subsequently, a solid part is defined and optimized by means of the optimization module TOSCA. Then, the complete joint is simulated with the optimized connection, and the behavior and the weight of the material used are compared with those of the conventional joint. Some modifications are made to improve some aspects of the design.Afterwards, the optimized joint is printed with steel S316L, the connection is assembled with the columns and beams, and it is tested. The experimental results are analyzed to be able to make the necessary adjustments both in the connection and in the design methodology.

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Section: Introductionmentioning

confidence: 99%

Proposal and experimental verification of additive manufactured beam‐column connection designed by topological optimization

Gil,

Goñi,

Fábregas

et al. 2023

ce papers

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“…While some approaches tackle the task of producing full buildings like houses (Koshnevis and Hwang 2006) or bridges (Van der Velden 2019), others focus on highly specialized components like façade-connectors (Mohsen 2020), lost formwork (Burger et al 2020) , fire-protection cladding (Pain 2022) or even hybrid applications (Carvalho, Cruz and Figueiredo 2022). Nowadays, the scope of AM R&D covers most of the materials common in construction such as metal (Erven 2021), concrete (Anton 2020), glass (Seel 2018) and ceramics (de Witte 2022) upon which this article takes a deeper look.…”

Section: Introductionmentioning

confidence: 99%

Support-strategies for Robocasting Ceramic Building Components

Wolf,

Carvalho,

Figueiredo

et al. 2023

Proceedings of the 41st International Conference on Education and Research in Computer Aided Architectural Design in Europe (eC

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The introduction of ceramic additive manufacturing technologies in the building industry offers unprecedented opportunities to architects and engineers towards a new brickarchitecture. Robocasting appears as a suitable technology to produce the medium-to large-scale components needed for building applications. This process involves deploying individual strands of clay layerwise to form an object. Unlike powder-bed or sheetlamination-processes, robocasting does not come with a process-inherent supportmaterial. Using support-material increases the range of producible geometries and therefore is a crucial necessity to exploit the technology. In this paper, first the limits of the unsupported process were identified. Also, a representative architectural component, which included overhangs, bridged areas and arcs was designed generatively. In the first stage, its geometry was derived from the material-related limitations of the used clay. Next, different strategies to exceed the process-related limitations have been developed and tested. The results are discussed and an overview of these counteractions and their applicability is provided. Ultimately, the representative architectural component was fabricated once again, with a geometry exceeding the geometric limitations by applying the support-strategies that were developed beforehand.

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