Delcam upgrades integrated CAM for SolidWorks
PIC CAP: Delcam for SolidWorks offers Delcam’s proven machining algorithms fully integrated into the SolidWorks environment.
Delcam has launched the 2016 release of its Delcam for SolidWorks integrated CAM software for SolidWorks. This includes a range of enhancements, in particular more options for the Vortex high-efficiency area-clearance strategy, faster creation of multiple set-ups, more efficient turning and user-interface improvements to make programming even easier and faster.
Full details on the new release, including video demonstrations of the main enhancements, are on the Delcam for SolidWorks Learning Zone – www.delcam.tv/dfs2016/lz
Delcam for SolidWorks offers Delcam’s proven machining algorithms, which are already used by more than 50,000 customers, fully integrated into the SolidWorks environment. The program looks and behaves like SolidWorks, and offers full associativity so that any changes in the CAD model are reflected automatically in the toolpaths.
However, this associativity is more intelligent than that offered in many other integrated CAM systems. Delcam for SolidWorks doesn’t simply modify the existing toolpaths but also reviews the choice of cutting tools and machining strategies, and changes them if necessary.
The 2016 release includes a number of enhancements to the Vortex area-clearance strategy. Vortex gives the fastest safe metal removal from solid carbide tooling, in particular designs that give deeper cuts by using the full flute length as the cutting surface. It produces toolpaths with a controlled engagement angle and so maintains the optimum cutting conditions for the complete roughing cycle, giving faster machining and longer tool life.
The ability has now been added to adjust and fine tune the non-cutting moves of 2.5D and 3D Vortex toolpaths, with options to retract the tool and/or to increase the feedrate. These options can be set individually, or can be combined to achieve an optimum toolpath, with a reduced cycle time.
Other roughing improvements include the ability to take into account any remaining stock on the model during holder collision checking, ensuring that Z-level roughing toolpaths are completely free of tool-holder collisions.
Milling of inside or outside groove features has been upgraded with a number of improvements. These include support for different types of roughing links, wind-fan approach and retract moves for finishing, better gouge checking for plunges and retracts, and tool radius and partline cutter compensation support.
Five-axis swarf machining has been made more flexible with a new option to control the upper and lower Z limits of a simultaneous five-axis swarf toolpath. This is useful if there are limitations on the tool length that can be used or if the stepdown needs to be varied for different segments of the toolpath.
In turning, the engage angle can now be set for the lead-in approach move. By controlling the approach move in this way, smoother chip formation and lower cutting forces can be achieved.
Interface improvements include the ability to create additional setups quickly during FeatureRECOGNITION, via a new button in the Feature Wizard. This reduces the overall programming time significantly.