Cooling
Cooling settings directly influence print quality, structural integrity, and material behavior. Proper configuration ensures optimal solidification of layers, minimizes defects in overhangs/bridges, and balances speed with part durability. Active cooling fans are critical for materials like PLA but require careful calibration to avoid warping or delamination in temperature-sensitive filaments.
Cooling Requirements by Material
PLA and Cooling-Dependent Materials
Active Cooling: Essential for clean overhangs, bridges, and surface quality.
Fan Speed: Typically 100% for most PLA prints to prevent layer curling and sagging.
Exceptions: Large, thick PLA parts may tolerate lower fan speeds (70–80%) to reduce warping.
High-Warping Materials (ABS, ASA, PC)
Cooling Strategy: Minimal or no active cooling for medium/large parts to maintain layer adhesion.
Exceptions: Enable cooling (20–50%) for small features (e.g., pins, thin walls) to prevent deformation.
Enclosure Use: Maintains ambient temperature, reducing reliance on active cooling.
Flexible Filaments (TPU, TPE)
Cooling Approach: Limited cooling (0–30%) to prevent nozzle jams and ensure layer bonding.
Slicer-Specific Cooling Parameters
Fan Activation and Layer Control
Initial Layers: Disable cooling for the first 0.5–0.7mm to enhance bed adhesion.
Variable Fan Speeds:
Bridges/Overhangs: 100% fan speed for rapid solidification.
Dense Infill Areas: Reduce fan speed (50–70%) to minimize warping.
Minimal Layer Time
Function: Pauses between layers to allow cooling if print time falls below a threshold.
Typical Range: 5–15 seconds (lower for PLA; higher for ABS in enclosures).
Lift Head: Raises the nozzle during pauses, reducing heat transfer but increasing stringing.
Layer Height and Cooling Efficiency
Thin Layers (0.1–0.2mm): Improve overhang quality by reducing unsupported material.
Thick Layers (≥0.3mm): Require longer cooling times or lower print speeds.
Advanced Cooling Techniques
Auxiliary Cooling Systems
Purpose: High-speed printers (e.g., Bambu Lab X1, Voron Trident) use secondary fans to enhance airflow for rapid cooling.
Implementation:
Dual-Sided Fans: Ensure even cooling for complex geometries.
Nozzle-Specific Ducts: Direct airflow precisely to overhangs or bridges.
Dynamic Cooling Adjustments
Overhangs/Bridges: Automatically increase fan speed in slicers (e.g., PrusaSlicer, Cura) for targeted cooling.
Material-Specific Profiles: Save custom cooling settings for filaments with unique requirements (e.g., PETG at 50–80% fan speed).
Geometry-Driven Cooling
Small Features: Prioritize cooling for towers, spikes, or fine details to prevent melting.
Large Flat Surfaces: Use monotonic ordering to align layer lines and improve surface consistency.
Cooling and Overhang Optimization
Critical Parameters for Overhangs
Fan Speed: Maximize airflow (100%) to solidify material before sagging.
Print Speed: Reduce to 5–20mm/s for steep overhangs (≥45°).
Temperature: Lower nozzle temperature by 5–10°C to reduce filament viscosity.
Layer Height: Use ≤0.2mm layers to minimize overhang angles.
Slicer-Specific Strategies
Cura: Enable "Bridge Settings" for adaptive cooling and speed adjustments.
PrusaSlicer: Adjust "Overhangs Speed" and "Bridge Fan Speed" in filament settings.
Troubleshooting Cooling Issues
Warping/Delamination
Causes: Excessive cooling on ABS/ASA; uneven airflow.
Solutions:
Disable cooling for initial layers.
Use enclosures and minimize chamber drafts.
Poor Overhang Quality
Causes: Insufficient cooling, high print speed, or incorrect nozzle temperature.
Solutions:
Increase fan speed and reduce print temperature.
Reorient the model to face overhangs toward cooling fans.
Nozzle Temperature Fluctuations
Causes: Cooling fans blowing directly on the heater block.
Solutions:
Install a silicone sock on the heater block.
Adjust fan duct orientation to target extruded material, not the nozzle.
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