Power vs Speed¶
Understanding the relationship between laser power, movement speed, and material interaction is crucial for achieving high-quality cuts and engravings.
The Fundamental Relationship¶
Energy delivered to material = Power x Time
When the laser moves more slowly, it delivers more energy per unit area. When it moves faster, less energy is delivered.
Key principle:
More power + slow speed = High energy (deep cuts, dark burns)
Less power + fast speed = Low energy (light marks, shallow cuts)
Balance is key: Different materials and operations require different combinations.
Understanding Power¶
What is Power?¶
Laser power is the intensity of the laser beam, typically measured in watts (W).
Power control:
- Rayforge uses the S parameter (0-1000) to control power
- S0 = 0% power (off)
- S500 = 50% power
- S1000 = 100% power (maximum your laser can produce)
Example:
Absolute Power vs Percentage¶
Your laser has a maximum power rating:
- 5W diode laser
- 40W CO2 laser
- 80W CO2 laser
When you set 50% power:
- 5W laser delivers: 2.5W
- 40W laser delivers: 20W
- 80W laser delivers: 40W
Implication: Settings that work on one laser won't directly transfer to a different wattage laser. You must adjust for your specific laser power.
Understanding Speed¶
What is Speed?¶
Feed rate (or cutting speed) is how fast the laser head moves across the material, measured in mm/min or inches/min.
Speed ranges:
- Very slow: 50-300 mm/min (deep cuts, thick materials)
- Moderate: 500-1500 mm/min (general cutting, engraving)
- Fast: 2000-5000 mm/min (light engraving, travel moves)
Example:
Speed Affects Energy Density¶
Slower movement = More time at each point = More energy delivered
Example:
- Laser power: 40W
- Speed 1: 100 mm/min
- Speed 2: 1000 mm/min
At 100 mm/min, the laser spends 10x longer at each point compared to 1000 mm/min, delivering 10x more energy.
The Power-Speed Matrix¶
Different combinations of power and speed produce different results:
| Power | Speed | Result | Use Case |
|---|---|---|---|
| High | Slow | Very deep cuts, charring | Cutting thick materials |
| High | Fast | Moderate cuts/engraving | Fast cutting, efficient production |
| Low | Slow | Deep engraving, controlled burns | Detailed engraving, dark marks |
| Low | Fast | Light engraving, surface marks | High-speed raster engraving |
Visualization:
Power
^
| Charring/ | Through-cut
| Too deep | (ideal)
| |
|------------- +-------------
| Good | Too fast/
| engraving | Not cutting
| |
+-----------------------------> Speed
Material-Specific Considerations¶
Wood¶
Cutting:
- Medium to high power
- Moderate speed
- Multiple passes for thick wood
Example (3mm plywood, 40W CO2):
- Power: 70-80%
- Speed: 200-400 mm/min
- Passes: 1-2
Engraving:
- Low to medium power
- High speed for raster
- Lower speed for deeper marks
Example (wood engraving, 40W CO2):
- Power: 20-30%
- Speed: 2000-3000 mm/min
Acrylic¶
Cutting:
- High power
- Very slow speed
- Produces clean, flame-polished edges
Example (3mm cast acrylic, 40W CO2):
- Power: 80-100%
- Speed: 100-200 mm/min
- Passes: 1 (through-cut)
Engraving:
- Low power
- Fast speed
- Produces frosted appearance
Example (acrylic engraving, 40W CO2):
- Power: 15-25%
- Speed: 2500-4000 mm/min
Cardboard / Paper¶
Cutting:
- Very low power
- Fast speed
- High fire risk - monitor constantly
Example (cardboard, 40W CO2):
- Power: 10-20%
- Speed: 1000-2000 mm/min
Engraving:
- Extremely low power
- Very fast speed
Example (paper engraving, 40W CO2):
- Power: 5-10%
- Speed: 3000-5000 mm/min
Leather¶
Cutting:
- Medium power
- Moderate speed
Example (leather, 40W CO2):
- Power: 40-60%
- Speed: 300-600 mm/min
Engraving:
- Low power
- Fast to moderate speed
- Creates dark, detailed marks
Example (leather engraving, 40W CO2):
- Power: 15-25%
- Speed: 2000-3000 mm/min
Multi-Pass Strategies¶
When to Use Multiple Passes¶
Reasons:
- Material too thick for single pass
- Preventing excessive charring
- Achieving cleaner cuts
- Reducing heat buildup
How it works: Instead of one deep cut, make several shallower cuts:
- Pass 1: Cuts 30% through
- Pass 2: Cuts 60% through
- Pass 3: Cuts 90% through
- Pass 4: Cuts fully through
Benefits of Multi-Pass¶
Cleaner cuts:
- Less charring on edges
- Less heat stress on material
- Better edge quality
Thicker materials:
- Cut materials beyond single-pass capability
- Safer than maxing out power
Heat management:
- Allows material to cool between passes
- Reduces warping and melting
Multi-Pass Settings¶
General approach:
- Determine total energy needed to cut through
- Divide into multiple passes (2-5 passes typical)
- Adjust speed or power to deliver energy gradually
Example (6mm plywood, 40W CO2):
Single pass (may fail or char heavily):
- Power: 100%
- Speed: 100 mm/min
- Passes: 1
- Result: Excessive charring, incomplete cut
Multi-pass (better):
- Power: 80%
- Speed: 200 mm/min
- Passes: 3
- Result: Clean cut, minimal charring
Configuring Multi-Pass in Rayforge¶
In operation settings:
- Select Contour operation
- Set Passes to desired number (e.g., 3)
- Adjust power/speed as needed
- Rayforge will automatically repeat the cut path
G-code result:
; Pass 1
G0 X10 Y10
M4 S800
G1 X50 Y10 F200
; ...path...
M5
; Pass 2 (same path repeated)
G0 X10 Y10
M4 S800
G1 X50 Y10 F200
; ...path...
M5
; Pass 3
; ...
Reading Burn Marks and Adjusting¶
Visual Feedback¶
Material tells you if settings are correct:
Too much power or too slow:
- Heavy charring (black edges)
- Excessive smoke
- Melted/deformed edges
- Material warping
Too little power or too fast:
- Incomplete cuts
- Light surface marks only
- No visible change
Just right:
- Clean cuts all the way through
- Minimal charring
- Smooth edges
- Consistent depth
Adjusting Based on Results¶
If cut doesn't go through:
- Increase power by 10-20%
- OR decrease speed by 20-30%
- OR add another pass
If too much charring:
- Decrease power by 10-20%
- OR increase speed by 20-30%
- OR switch to multi-pass with lower power
If engraving too light:
- Increase power by 10-15%
- OR decrease speed by 15-25%
If engraving too dark/burned:
- Decrease power by 10-15%
- OR increase speed by 15-25%
Diode Lasers vs CO2 Lasers¶
Diode Lasers (Typically 5-20W)¶
Characteristics:
- Lower power output
- 445nm wavelength (blue light)
- Absorbed differently by materials
Power/speed considerations:
- Slower speeds needed (lower power)
- Multiple passes often required
- Struggles with thick materials
- Excellent for wood engraving
Example (wood engraving, 5W diode):
- Power: 60-80%
- Speed: 500-1500 mm/min
CO2 Lasers (Typically 40-150W)¶
Characteristics:
- Higher power output
- 10,600nm wavelength (infrared)
- Efficiently absorbed by organic materials
Power/speed considerations:
- Faster speeds possible
- Clean through-cuts on thicker materials
- Better for cutting acrylic, wood
Example (wood cutting, 40W CO2):
- Power: 70-90%
- Speed: 200-500 mm/min
Material Testing Workflow¶
Using the Material Test Grid¶
Rayforge's Material Test Grid automates power/speed testing:
- Create grid: Features > Operations > Material Test Grid
- Set ranges:
- Power: 20% to 80% (or appropriate range)
- Speed: 500 to 2000 mm/min (or appropriate range)
- Run grid on scrap material
- Inspect results:
- Find the cell with best cut quality
- Note the power/speed values
- Use those settings in your actual job
Example grid result:
500mm/min 1000mm/min 1500mm/min 2000mm/min
20% Too light Too light Too light Too light
40% Good Too light Too light Too light
60% Too dark Good Light Too light
80% Charred Too dark Good Light
Conclusion: Use 60% power at 1500 mm/min for this material.
See Material Test Grid for details.
Advanced Topics¶
Kerf Compensation¶
Kerf is the width of material removed by the laser beam.
Power/speed affect kerf:
- Higher power = Wider kerf
- Slower speed = Wider kerf (more material burned away)
Adjust kerf compensation if parts come out wrong size:
- Parts too small: Reduce kerf compensation
- Parts too large: Increase kerf compensation
See Kerf for details.
Raster Speed Variation¶
For raster engraving, Rayforge varies speed to create different gray tones:
How it works:
- Light areas: Fast speed, low power
- Dark areas: Slow speed, higher power (or just higher power at constant speed)
Bidirectional raster:
- Laser engraves left-to-right, then right-to-left
- Must maintain consistent power at varying speeds
- M4 (laser mode) ensures constant power
Air Assist and Cooling¶
Air assist affects results:
- Reduces charring
- Cools material
- Blows away smoke/debris
Settings interaction:
- With air assist: May need slightly higher power
- Without air assist: More charring, may need lower power/faster speed
Common Mistakes¶
Mistake 1: Maxing Out Power¶
Problem: Using 100% power for everything.
Why it's bad:
- Excessive charring
- Accelerated wear on laser tube
- Less control and precision
Solution: Use appropriate power (usually 60-80% for cuts).
Mistake 2: Ignoring Material Variation¶
Problem: Using same settings for all "wood" without testing.
Why it's bad:
- Different wood species vary significantly
- Plywood vs solid wood behaves differently
- Moisture content affects results
Solution: Test each new material type with a Material Test Grid.
Mistake 3: Not Adjusting for Thickness¶
Problem: Using same settings for 3mm and 6mm material.
Why it's bad:
- 6mm needs much more energy (lower speed or more passes)
- 3mm settings won't cut through 6mm
Solution: Adjust speed (slower) or passes (more) for thicker materials.
Mistake 4: Focusing on Power Only¶
Problem: Only adjusting power, never speed.
Why it's bad:
- Speed is equally important
- Sometimes speed adjustment is more effective
Solution: Adjust both power AND speed to find optimal settings.
Quick Reference¶
Starting Points (40W CO2 Laser)¶
| Material | Thickness | Power | Speed | Passes |
|---|---|---|---|---|
| Plywood | 3mm | 70% | 300 mm/min | 1-2 |
| Plywood | 6mm | 80% | 200 mm/min | 2-3 |
| Acrylic | 3mm | 90% | 150 mm/min | 1 |
| Acrylic | 6mm | 100% | 80 mm/min | 1-2 |
| Cardboard | 2mm | 15% | 1500 mm/min | 1 |
| Leather | 2mm | 50% | 400 mm/min | 1 |
Note: These are starting points only. Always test on your specific machine and material.
Starting Points (5W Diode Laser)¶
| Material | Thickness | Power | Speed | Passes |
|---|---|---|---|---|
| Wood engrave | - | 70% | 800 mm/min | 1 |
| Wood cut | 3mm | 90% | 100 mm/min | 3-5 |
| Cardboard | 2mm | 50% | 500 mm/min | 2 |
| Leather engrave | - | 60% | 600 mm/min | 1 |
Note: Diode lasers struggle with thick materials. Multi-pass is often required.
Best Practices¶
- Always test new materials with Material Test Grid
- Start conservative (lower power, moderate speed) and increase gradually
- Use multi-pass for thick materials rather than maxing out power
- Adjust one parameter at a time (power OR speed, not both)
- Document successful settings for future reference
- Account for material variation (different batches may need adjustment)
- Monitor first few cuts of any job to catch issues early
Related Pages¶
- Material Test Grid - Automated power/speed testing
- Understanding Operations - Operation types and settings
- Kerf - Compensation techniques
- Laser Safety - Safe power/speed practices