Abstract
A challenge for the deployment of IGA in industry is existing solutions (CAD, FEA) and the legacy and bulk of preexisting digital information. Rather than focusing on application areas dominated by FEA, IGA should focus on novel applications areas where fewer established solutions exist and the legacy of exiting digital information is minor. One such area is additive manufacturing (AM). In AM the trivariate spline representations are superior to traditional finite elements with respect to representation of variable and anisotropic material.
However, even for AM, a prerequisite for deployment of IGA on a broad scale is near seamless interoperability between boundary structure (b-rep) CAD and IGA. The integration of sculptured surfaces (B-splines and NURBS) into volumetric CAD models (b-rep) was a central research topic in the 1980s, then standardized as part of ISO 10303 (STEP) in the 1990s. The development of b-rep CAD focused on the needs of CAM (Computer Aided Manufacturing) where small gaps between surfaces were not regarded as an issue. STEP was introduced to provide interoperability between CAD-systems. Direct translators between CAD-systems have still a wide use as they can exchange information not supported by STEP. However, for product life cycle management (PLM) and long-term archiving and storing (LOTAR) the use of standards is important for ensuring that data is accessible also in the future. There is no guarantee that vendor proprietary formats will have future support.
STEP has been the natural standard to augment with IGA capabilities. The EC Factories of the Future Project TERRIFIC (2011-2014) focused on tri-variate spline models and IGA. TERRIFIC proposed several extensions to STEP to support IGA with respect to Locally Refined Splines (T-splines, LR B-splines), as well as tri-variate spline models. Some of these extensions have been published as part of STEP in 2018. In the EC Factories of the Future Project CAxMan [1] (2015-2018) the STEP work of TERRIFIC has been continued. Further augmentations of STEP related to IGA are underway supported by other members of the STEP community. The focus of the CAxMan project has been computer assisted technologies for AM with a special attention to analysis-based design, trimmed trivariate CAD-models and IGA. This exposes IGA to an application domain where many challenges are still unsolved.
The CAxMan-project has received funding from the European Union's Horizon 2020 research and innovation programme under grant agreement No 680448.
REFERENCES
[1] https://www.caxman.eu
However, even for AM, a prerequisite for deployment of IGA on a broad scale is near seamless interoperability between boundary structure (b-rep) CAD and IGA. The integration of sculptured surfaces (B-splines and NURBS) into volumetric CAD models (b-rep) was a central research topic in the 1980s, then standardized as part of ISO 10303 (STEP) in the 1990s. The development of b-rep CAD focused on the needs of CAM (Computer Aided Manufacturing) where small gaps between surfaces were not regarded as an issue. STEP was introduced to provide interoperability between CAD-systems. Direct translators between CAD-systems have still a wide use as they can exchange information not supported by STEP. However, for product life cycle management (PLM) and long-term archiving and storing (LOTAR) the use of standards is important for ensuring that data is accessible also in the future. There is no guarantee that vendor proprietary formats will have future support.
STEP has been the natural standard to augment with IGA capabilities. The EC Factories of the Future Project TERRIFIC (2011-2014) focused on tri-variate spline models and IGA. TERRIFIC proposed several extensions to STEP to support IGA with respect to Locally Refined Splines (T-splines, LR B-splines), as well as tri-variate spline models. Some of these extensions have been published as part of STEP in 2018. In the EC Factories of the Future Project CAxMan [1] (2015-2018) the STEP work of TERRIFIC has been continued. Further augmentations of STEP related to IGA are underway supported by other members of the STEP community. The focus of the CAxMan project has been computer assisted technologies for AM with a special attention to analysis-based design, trimmed trivariate CAD-models and IGA. This exposes IGA to an application domain where many challenges are still unsolved.
The CAxMan-project has received funding from the European Union's Horizon 2020 research and innovation programme under grant agreement No 680448.
REFERENCES
[1] https://www.caxman.eu