The cloud infrastructure from FP7 IP CloudFlow has been adapted and extended to the needs of CAxMan, and specific workflows implemented.
Analysis-based design has been built on trivariate splines to represent the interior of objects mathematically. Trivariate splines are the foundation the new volumetric CAD-representation (V-rep) now being introduced in ISO 10303. The geometric concepts of V-rep were published as part of STEP part 42 in 2018, and a corresponding STEP Application Reference Module denoted "Extended B-spline geometry" was developed in CAxMan.
V-rep is well suited for the representation of variable/graded materials and anisotropic material, and is fundamentally different from B-rep CA. The trivariate splines are the basis for Isogeometric Analysis (IgA). In CAxMan we realised that block structured splines used in IgA were not sufficient for the interoperability of CAD and IgA. It was decided it to use trimmed trivariate splines. This in principle solves the interoperability issue between B-rep CAD and V-rep CAD/ IgA. However, it poses challenges to the numerical quadrature used in IgA. While quadrature over untrimmed elements is well understood, quadrature over trimmed elements is not. Untrimming, has been developed to address the challenge.
Novel technology for volumetric subdivision for designing voids and cavities has been developed. It has been observed for the mould use case that the voids reduce the thermal strains compared to a similar object without voids. Further, the metric quality control has shown that thermal distortions are smaller for the mould with voids than the without voids. This both reduce the amount of material used and the time needed for subtractive processes. The measured distortions are well aligned with the distortions predicted by thermal simulations developed in CAxMan for the AM-process used.
Using data exchange standards such as STEP and QIF, and cloud workflows for process planning, thermal-stress simulation and metrology-based quality control workflows are mutually interoperable. Interoperability is also established with Missler's TopSolid. Process planning supports thermal stress and distortion simulation, by replacing support structures with spring-like elements acting as boundary conditions. This makes the thermal simulation faster and enables efficient use simulation to predict thermal distortions for different model orientations, temperature ranges, and support structure configurations. Orientation can be optimized according to different criteria, e.g. surface quality, build time and the need for support structures.
Thermal analysis and residual stress simulation target material deposition methods and is complemented by a module for heat treatment. The ambition has been to provide very fast solutions (e.g. minutes, hours), which are suitable for optimisation loops running in the cloud and exploiting HPC resources. The approach is based on a strategy for simplified analysis using inherent strain methods that are suitable for powder-bed AM technologies. The solution has been calibrated through validation benchmarks and integrated into TopSolid.
The quality analysis workflow use 3D scanning to measure the deviation between the nominal CAD-model and the object produced by AM. It provides a deviation map that in CAxMan has been transferred to the CAD-system TopSolid, using the latest version of the QIF-standard.
The main effort in interfacing AM and subtractive manufacturing (SM) has been related to the development of new technology for offset calculations. New technology for simplifying patch networks of surfaces, by replacing them with large functional surfaces better suited for efficient and high-quality NC has also been developed and integrated into Top Solid.
For the injection mould use case, weight saving of 50% are achieved by creating a dedicated “structural mesh”, outside of which material is not necessary. The cycle time when moulding is improved by 10% due to reduction of cooling time by 35%: this turns into a reduction by 10% of the energy used during the injection moulding process. For the Nugear use case, manufacturing costs are reduced by 10%, machining time reduced by 25%, part weight reduced by up to 60% and waste material by up to 95%. AM has also allowed for a perfect balance of the “double face” configuration never achieved before.
CAxMan has identified 4 key exploitable results that involves innovation items from multiple partners. In addition, three joint exploitations involving multiple partners are identified. In addition 23 innovation items are described in the CAxMan Innovation shop with links to more detailed information (
https://caxman.boc-group.eu/innovation-shop(se abrirá en una nueva ventana)). Three videos are published on YouTube.