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Hexagon Manufacturing Intelligence News
Hexagon unveils new capabilities in 3D printing
Hexagon takes the guesswork out of 3D printing precision metal components with Advanced Compensation technology.
hexagon.com
Hexagon’s Manufacturing Intelligence division has unveiled new capabilities in 3D printing with a new technology that eliminates costly trial-and-error in precision metal part production. The innovative Advanced Compensation approach uses advanced geometry compensation to ensure large or complex metal parts distort into their intended shape during the printing process. By combining process simulation and 3D scan compensation, the most challenging parts with tight quality tolerances can be printed successfully with just one prototype build.
Despite its transformative potential, additive manufacturing has faced several barriers that have slowed the pace of adoption in safety-critical and precision-engineered applications such as machine building, aerospace and medical prosthetics that require high surface quality, repeatability and dimensional accuracy. The complex physical processes of laser powder bed fusion (LPBF) printing often lead to inconsistencies, deviations and defects that are unacceptable quality for complex parts with tight, critical tolerances.
Hexagon’s Simufact Additive software is trusted by leading manufacturers to predict distortions and shrinkage with accurate simulations, helping eliminate print trials completely for most accuracies of parts with global compensation methods. For parts with more complex features, the company’s VGSTUDIO MAX software has become indispensable for additive manufacturing because its powerful metrology and 3D scan analysis capabilities make it easy to compensate the printable mesh based on the measured deviations from an optical or CT scan and address localised distortions.
Hexagon’s most demanding customers have adopted a new approach called Advanced Compensation to achieve consistently high quality – even with thin walls that are prone to buckling, or challenging materials such as titanium or Inconel. This hybrid process combines process simulation with metrology-based compensation, fast-tracked high-quality prints, achieving surface profiles that are 98-100% within tolerance.
3D printer OEM Additive Industries was able to print a stainless-steel jet engine exhaust mixer with 0.2mm precision with just one prototype build. Alex Redwood, Head of Applications & Additive Studios at Additive Industries explains: “Thanks to Advanced Compensation, we successfully printed a large 316L steel component with an impressive surface tolerance of +/-0.2 mm – despite natural distortion of over 3 mm in previous builds. Achieving this precision required only one previous trial build, reducing time, material waste and allowed us to reduce the supports structure to the bare minimum. This level of control and efficiency opens up new possibilities for large-scale additive manufacturing applications.”
This workflow is now built into Hexagon’s Simufact Additive software. This integrated experience makes it accessible to any engineer using Simufact Additive, so they can pre-deform a part for global distortions using simulation then compensate that same print-ready mesh using a 3D scan. No metrology experience is required because the metrology-based compensation utilises powerful VGSTUDIO MAX technology that can accept imperfect or incomplete 3D scan data to create a clean mesh that morphed from the nominal CAD, removing a practical barrier to this important compensation method.
Mathieu Perennou, Director of Additive Strategy at Hexagon commented: “If you’re making a large complex geometry, simulation will save you time and money – even for a one-off part. But when simulation alone isn’t enough, we’ve made it much easier to take an optical 3D scan then compensate those remaining problem features so you can print ‘second time right’.
“This data-driven approach takes the guesswork out of printing small batch parts, and it can be scaled up to refine a process for larger volumes using digital twin approaches that consider not just the geometry, but also the machine parameters or material behaviour where part performance is critical.”
www.hexagon.com