Babysitter cnc-programming

Expert skill for CNC programming and toolpath optimization using CAM software

install

source · Clone the upstream repo

git clone https://github.com/a5c-ai/babysitter

Claude Code · Install into ~/.claude/skills/

T=$(mktemp -d) && git clone --depth=1 https://github.com/a5c-ai/babysitter "$T" && mkdir -p ~/.claude/skills && cp -r "$T/library/specializations/domains/science/mechanical-engineering/skills/cnc-programming" ~/.claude/skills/a5c-ai-babysitter-cnc-programming && rm -rf "$T"

manifest: library/specializations/domains/science/mechanical-engineering/skills/cnc-programming/SKILL.md

CNC Programming Skill

Purpose

The CNC Programming skill provides expert capabilities for CNC programming and toolpath optimization using CAM software, enabling efficient and accurate machining of mechanical components.

Capabilities

Mastercam, NX CAM, Fusion 360 workflow automation
Toolpath strategy selection (roughing, finishing)
Cutting parameter optimization (feeds, speeds)
Tool selection and library management
Work holding and fixture consideration
Toolpath simulation and verification
G-code generation and post-processing
Cycle time estimation and optimization

Usage Guidelines

Machining Strategy

Roughing Operations

Material Removal Strategies

Strategy	Application	Advantages
Adaptive/Dynamic	General roughing	Constant chip load
Pocket	Enclosed areas	Efficient material removal
Facing	Flat surfaces	Surface prep
Plunge rough	Deep pockets	Axial chip evacuation

Stock Allowance

Finishing allowance = 0.25-0.5 mm (typical)
Semi-finish allowance = 0.5-1.0 mm
Rough allowance = Stock - finish - semi-finish

Step-Over Guidelines

Adaptive roughing: 10-25% tool diameter
Pocket roughing: 50-75% tool diameter
Depth of cut: 1-2x tool diameter (end mills)

Finishing Operations

Surface Finish Strategies

Strategy Application Surface Finish
Parallel Flat surfaces Ra 0.8-1.6 um
Contour Walls, profiles Ra 0.8-1.6 um
Scallop 3D surfaces Ra 1.6-3.2 um
Pencil Corners, fillets Clean-up

Step-Over for Finish

Cusp height = r - sqrt(r^2 - (s/2)^2)

For cusp height = 0.01 mm, r = 5 mm:
Step-over s = 0.89 mm

Cutting Parameters

Speed and Feed Calculation

Cutting Speed (SFM): V = pi * D * N / 12 (imperial)
                     V = pi * D * N / 1000 (metric)

Feed Rate: F = f * z * N

Where:
V = cutting speed (SFM or m/min)
D = tool diameter
N = spindle speed (RPM)
f = feed per tooth
z = number of teeth
F = feed rate (IPM or mm/min)

Material-Specific Parameters

Material	Speed (SFM)	Feed/Tooth (in)	Notes
Aluminum	500-1000	0.004-0.008	High spindle, coolant
Steel (mild)	80-120	0.003-0.006	Flood coolant
Steel (hard)	50-80	0.002-0.004	Reduce speed
Stainless	60-100	0.002-0.005	Rigid setup
Titanium	40-60	0.002-0.004	High pressure coolant

Tool Selection

End Mill Selection

Application	Tool Type	Coating
Aluminum roughing	2-3 flute, polished	Uncoated/ZrN
Aluminum finishing	2-3 flute, high helix	Uncoated
Steel roughing	4+ flute, variable helix	AlTiN/TiAlN
Steel finishing	4+ flute	AlTiN
Hardened steel	Ball nose, solid carbide	AlCrN

Tool Life Management

Tool life tracking:
- Material removed (cm3)
- Cutting time (minutes)
- Parts produced

Replace at:
- Wear land > 0.3 mm
- Surface finish degradation
- Dimension out of tolerance

Work Holding

Fixture Considerations

Clamping Force
- Calculate cutting forces
- Apply safety factor (2-3x)
- Distribute clamp forces
- Avoid part distortion
Accessibility
- Clear all tool paths
- Consider tool length
- Allow chip evacuation
- Enable coolant flow

Program Verification

Simulation Checks
- Tool collision detection
- Fixture interference
- Rapid traverse clearance
- Stock remaining verification
First Article
- Reduced feed rate (50%)
- Single block mode
- Verify dimensions
- Adjust offsets as needed

Process Integration

ME-018: CNC Programming and Verification

Input Schema

{
  "part_model": "CAD file reference",
  "material": {
    "name": "string",
    "hardness": "string (e.g., HRC 30)"
  },
  "machine": {
    "type": "3-axis|4-axis|5-axis|lathe",
    "controller": "Fanuc|Siemens|Haas|other",
    "spindle_max": "number (RPM)",
    "rapids": "number (mm/min)"
  },
  "tolerances": {
    "dimensional": "number (mm)",
    "surface_finish": "number (Ra um)"
  },
  "production_volume": "prototype|low|medium|high"
}

Output Schema

{
  "program_info": {
    "program_number": "string",
    "operations": "number",
    "total_tools": "number"
  },
  "cycle_time": {
    "machining": "number (min)",
    "non-cutting": "number (min)",
    "total": "number (min)"
  },
  "tool_list": [
    {
      "tool_number": "number",
      "description": "string",
      "diameter": "number (mm)",
      "length": "number (mm)"
    }
  ],
  "setup_sheet": {
    "work_offset": "string",
    "fixture": "string",
    "stock_size": "array [L, W, H]"
  },
  "nc_file": "file reference"
}

Best Practices

Verify model accuracy before programming
Use consistent tool numbering conventions
Include adequate clearance planes
Optimize tool paths for minimum air cutting
Simulate complete program before machining
Document setup requirements clearly

Integration Points

Connects with CAD Modeling for geometry
Feeds into Process Planning for operations
Supports FAI Inspection for first article
Integrates with DFM Review for manufacturability

Strategy	Application	Surface Finish
Parallel	Flat surfaces	Ra 0.8-1.6 um
Contour	Walls, profiles	Ra 0.8-1.6 um
Scallop	3D surfaces	Ra 1.6-3.2 um
Pencil	Corners, fillets	Clean-up