Abstract
3D printing or additive manufacturing (AM) is now becoming a common technology in industry. The research activities in this area are constantly increasing, because with the high level of automation and the possibility to produce individual and complex structures, the advantages of additive manufacturing are promising. Most materials used in the construction industry can be used for additive manufacturing, for example steel and concrete. The print head (for example, a welding torch in the AM of steel) is mainly led by industrial robots, whose movements must be transferred from the 3D geometry files to be manufactured. In contrast to all-in-one systems, where hardware, software and printed material are coordinated, most robot-based AM systems are made of components from different manufacturers and branches. The objects to be manufactured are complex and the manufacturing parameters, which significantly influence the geometry and quality of the manufactured part, are manifold. This makes the workflow from the 3D model to the finished object difficult, especially because it is almost impossible to predict the exact manufactured structure geometry or layer height (which would be indispensable for accurate slicing). During the manufacturing process, deviations between the target and actual geometry can occur. In this paper, parametric robot programming (PRP) is presented, which allows flexible motion programming, and a quick and easy reaction to deviations between target and actual geometry during the manufacturing process. Complex geometries are divided into iso-curves whose mathematical functions are determined by means of polynomial regression. The robot can calculate the coordinates to be approached from these functions itself. This allows a simple adjustment of the manufacturing coordinates during the process as soon as target–actual deviations occur. The workflow from the file to the manufactured object is explained. The principle of PRP is transferable and applicable to all robot manufacturers and all conceivable printing processes. In the following article, it will be presented using wire + arc additive manufacturing, in which welding robots or portals can be used to produce steel structures with high deposition rates. Furthermore, the project “AM Bridge 2019” is presented, in which a steel bridge was manufactured in situ over a little creek and the presented PRP was applied.
Highlights
1.1 Additive manufacturing in construction industryAdditive manufacturing found its position as an additional tool to manufacture complex geometries or integrate functionalities in components, which were difficult or impossible1 3 Vol.:(0123456789)Construction Robotics (2020) 4:31–48But 3D printing has not yet landed in the construction industry, which requires long-term reliability, an issue extremely important for buildings with an expected lifespan of 50–100 years, low cost for constructions coupled with a limited development in the craftsmanship, due to low wages and reputation of the industry
Using the newly developed robot programming described hereafter, these additional feedback loops and all associated additional operations can be omitted. This is because in case of parametric robot programming (PRP), the geometry to be manufactured has already been completely described via the parametric robot code
The previously explained workflow was developed for the project “additive manufacturing (AM) Bridge 2019”, where a steel bridge was printed in situ across a creek, see Fig. 17
Summary
Additive manufacturing found its position as an additional tool to manufacture complex geometries or integrate functionalities in components, which were difficult or impossible. 3D printing has not yet landed in the construction industry, which requires long-term reliability, an issue extremely important for buildings with an expected lifespan of 50–100 years, low cost for constructions coupled with a limited development in the craftsmanship, due to low wages and reputation of the industry. In the field of building technology and construction research, the most common material (about 80%) being investigated is concrete (Borg Costanzi 2020). The quite broad developed technologies for polymer materials are used intensive, due to the availability and low costs of the technologies (Knaack et al 2017). Powder-based laser technologies (Strauß 2013; 3DPriyol 2020) for metals are used in the building technology and construction research. Recognized actors in the field are the TU Ilmenau/Fachgruppe Fertigungstechnik/Germany, Cranfield University/UK, who branded the acronym “WAAM” and MX3D (Fig. 1), an art, design, and manufacturing company in Amsterdam/The Netherlands (TU Ilmenau 2020; MX3D 2020)
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