This is often the most sought-after topic because it relates directly to reducing scrap and costs. Automatic vs. Manual Nesting Strategies : A deep dive into the Lantek Expert Cut
Right-click the contour, select Edit Technology , reduce the lead-in length, or change its angle.
For thick sheets, program the laser to cut the leftover scrap framework into smaller pieces, making it significantly easier and safer for shop floor operators to unload. lantek expert tutorial
Click File > Import to bring in external files (DXF/DWG).
Access the via the main configuration menu to manage machine-specific parameters like gas pressures, feed rates, and lead-in lengths. Section 2: Importing and Preparing CAD Geometry This is often the most sought-after topic because
For small parts that might tip over on the machine slats and collide with the cutting head, apply micro-joints. These are tiny gaps in the cutting path (usually 0.5mm to 1.5mm wide) that keep the part securely attached to the skeleton skeleton sheet until the operator shakes them loose manually. 6. Step 5: Simulation and G-Code Generation
: For small parts that might tip over and fall through the machine grid, add small micro-joints. This keeps the part attached to the skeleton until the entire sheet is done. For thick sheets, program the laser to cut
After finalizing the layout, you must define how the CNC machine will physically cut the material. Lead-ins and Lead-outs
Click to let Lantek calculate the shortest travel path, minimizing non-cutting rapid movements. 7. Step 6: Simulation and G-Code Generation
Beyond arranging parts, Lantek Expert controls the physics of the cut through its "Technology Tables." These are customizable databases that store parameters for different materials and thicknesses. For instance, cutting 10mm steel with a laser requires different speed, power, and gas pressure settings than cutting 2mm aluminum. Lantek Expert allows operators to assign these parameters automatically, reducing the margin for human error. Furthermore, the software optimizes the tool path—the actual route the cutting head travels. Strategies such as "common cutting," where two parts share a single cut line, and optimized piercing sequences reduce cycle times and extend the lifespan of the cutting consumables.