Slide 001: Cutting Operations β Materials & Tool Selection¶
Slide Visual¶
Slide Overview¶
This slide covers the practical aspects of CNC cutting operations, focusing on material-specific considerations and tool selection for optimal results. Students will learn to match the right tool to each material and cutting operation.
Instruction Notes¶
Material Categories for CNC Routing¶
Wood & Wood Products - Softwoods (pine, cedar, poplar): Easy to cut, lower cutting forces, tend to produce fuzzy edges. Use sharp tools and adequate feed rates to prevent burning. - Hardwoods (oak, maple, walnut): Higher cutting forces, better edge quality. Require slower feed rates and moderate spindle speeds. Figured grain (curly maple, burls) requires downcut or compression bits. - Plywood: Cross-laminated layers resist tearout in one direction but are prone in the other. Compression bits provide clean edges on both faces. Watch for glue lines dulling tools faster. - MDF: Highly abrasive (resin binder wears tool edges quickly). Produces fine dust β excellent dust collection is essential. Very consistent and flat β ideal for jigs and templates.
Plastics - Cast acrylic: Machines well with sharp single-flute tools. Chip clearance is critical β chips that don't evacuate will re-melt and weld to the tool. Use moderate RPM (12,000-16,000). - Extruded acrylic: Lower melting point than cast β more prone to gumming. Reduce RPM further and use aggressive chip load. - HDPE/Delrin: Flexible chips, high chip load OK. Single-flute O-flute preferred. Very forgiving material for beginners.
Metals (on CNC Routers) - Aluminum 6061-T6: Machinable on CNC routers with appropriate parameters. Single-flute, polished O-flute bits required. Cutting fluid mandatory. Maximum stepdown: 0.04"β0.06" per pass. Feed rate: 30-60 IPM at 10,000-16,000 RPM. - Brass: Similar to aluminum but more forgiving. Use 0-flute or single-flute bits. - Steel: NOT suitable for CNC routers β requires CNC mill rigidity and low spindle speeds.
Tool Selection Matrix¶
| Operation + Material | Recommended Tool |
|---|---|
| Profile cut, plywood | ΒΌ" compression spiral |
| Pocket, hardwood | ΒΌ" 2-flute upcut spiral |
| Through-cut, acrylic | ΒΌ" single-flute O-flute |
| V-carve, any wood | 60Β° or 90Β° V-bit |
| 3D contour, finishing | ΒΌ" ball-nose end mill |
| Slotting, aluminum | β " single-flute O-flute |
| Engraving | 30Β° or 15Β° engraving bit |
| Spoilboard surfacing | 1"β2" flattening/fly cutter |
Recognizing Good vs. Bad Cuts¶
Train your eyes and ears: - Good cut: Consistent chip formation, clean edges, no burning, steady cutting sound - Rubbing: Fine dust instead of chips, burning smell, high-pitched noise - Overloaded: Rough edges, chatter marks, tool deflection visible, motor straining
Key Talking Points¶
- Material selection drives tool selection β never use the wrong tool for the material
- Plastics require special attention to chip evacuation and heat management
- Aluminum CAN be cut on a CNC router but requires significant parameter reduction
- Learning to read chip formation is the most important diagnostic skill
- MDF is the most abrasive common material β expect faster tool wear
Learning Objectives (Concept Check)¶
- [ ] Select the appropriate cutting tool for 5 different material/operation combinations
- [ ] Describe material-specific challenges for wood, plastic, and aluminum
- [ ] Identify good vs. bad cutting conditions by visual and auditory cues
Last Updated: 2026-03-19