VISI-Series is acknowledged as one of the world's leading PC based design and manufacturing solutions for the mould & die industries. It offers a unique combination of applications, fully integrated wireframe, surface and solid modelling, comprehensive 2D, 3D and 5 axis machining strategies with dedicated high speed routines. Industry specific applications for plastic injection tool design including material flow analysis and progressive die design with step-by-step unfolding provide the toolmaker with unsurpassed levels of productivity.
Vero offer dedicated solutions that eliminate the links between varying software suppliers and the solid-to-surface or CAD>CAM geometry conversions required by traditional systems.
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5 axis machining has traditionally been regarded as advanced technology best suited to the aerospace and automotive industry. 5 axis machining offers many advantages, all of which are now being applied to the mould and die sector. VISI Machining provides the operator with a productive solution for creating highly efficient toolpaths with advanced collision control for the most complex 3D data.
- Extensive CAD interfaces
- 3D to 5 axis toolpath conversion
- Continuous 5 axis roughing / finishing
- 3 + 2 positional machining
- Multiple tool tilting optionsies
- Full gouge protection
- Optimised toolpath movement
- Kinematic simulation
- Customisable postprocessors
- HTML & XLS report output
Extensive range of CAD interfaces. VISI can work directly with Parasolid, IGES, CATIA v4 & v5, Pro-E, UG, STEP, Solid Works, Solid Edge, ACIS, DXF, DWG, STL and VDA files. The extensive range of translators ensures that users can work with data from almost any supplier. For complex 5 axis programming it is often necessary to tweak the geometry so companies working with complex designs will benefit from the simplicity with which their customer's CAD data can be manipulated.
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Deep cavity / core machining. Many complex moulds contain deep cavity areas and small radii which need to be machined with small diameter tools. Generally this would involve the use of tool extensions or longer tools which would increase the risk of deflection and provide a poor surface finish. By approaching this from a different angle, the head can be lowered and the collision detection will automatically tilt the tool and holder away from the work piece. The major advantage of this strategy is the use of shorter tools which will increase tool rigidity, reducing vibration and deflection. As a result, a constant chip load and higher cutting speed can be achieved which will ultimately increase tool life and produce a high quality surface finish. In more shallow areas, larger bull nose cutters can be used with a small lag angle. The major advantage of this approach is a lower number of toolpath passes which also reduces machining time and improves surface finish.