This guide explains the "Minimal Layer Time" setting in PrusaSlicer and its critical role in achieving optimal interlayer adhesion and mechanical strength, particularly when printing with high-temperature engineering materials on the Vision Miner 22IDEX. Properly configuring this setting helps ensure each new layer fuses effectively with the previous one, leading to parts with near-isotropic strength.
The primary goal of adjusting Minimal Layer Time is to maximize the temperature of the previously printed layer just before the next layer is extruded onto it. For polymers, especially high-temperature ones, strong interlayer adhesion relies on sufficient thermal energy to allow polymer chains across the layer interface to diffuse and entangle. If a layer cools too much before the next is applied, adhesion is compromised, resulting in weaker parts, particularly along the Z-axis (build direction).
This guide details how to locate and adjust the Minimal Layer Time and related cooling settings in PrusaSlicer. The benefit is achieving parts with significantly improved Z-strength, potentially exceeding 80% of the XY-strength, mimicking the near-isotropic properties of injection-molded parts. Prerequisites include basic familiarity with PrusaSlicer and understanding the thermal properties of the filament being used.
- Be aware of the high operating temperatures (nozzle, bed, chamber) when working with high-performance materials.
Warning: High temperatures required for engineering materials can cause severe burns. Avoid touching the hotend, build plate, or printed part during and immediately after printing.
¶ 1. Understanding Layer Time and Its Impact
When printing, each layer requires a certain amount of time to complete. This "layer time" dictates how long the previously deposited layer sits exposed to the chamber environment before the next layer is added.
- Material Science Perspective: For optimal layer bonding, the surface of the previous layer should ideally be at or near its glass transition temperature (Tg) or even slightly above when the new molten material is deposited. This promotes polymer chain mobility and inter-diffusion across the layer boundary, creating a strong weld.
- Too Long Layer Time: If a layer takes too long (e.g., printing multiple disparate parts simultaneously across a large build plate), the previous layer cools down significantly. This reduces chain mobility, hinders diffusion, and results in poor interlayer adhesion, leading to anisotropic weakness (parts are much weaker in Z than XY).
- Too Short Layer Time: Conversely, if layers are printed too quickly without sufficient cooling (especially on small cross-sectional areas), heat can accumulate excessively. The part may not solidify adequately, leading to deformation, sagging, or even melting under the heat of subsequent layers.
Therefore, the goal is to find a balance: keep layer times short enough to maintain high surface temperature for bonding, but long enough to allow the layer to solidify sufficiently to support the next. Printing parts sequentially (one at a time) inherently minimizes layer time compared to printing all parts layer-by-layer concurrently.
These critical settings are found within the filament-specific configuration:
- Open PrusaSlicer.
- Navigate to the Filament Settings tab.
- Select the filament profile you wish to configure from the dropdown menu.
- In the left-hand panel, click on Cooling.
- Identify the key parameters under the "Cooling Thresholds" section:
- Slow down if layer print time is below: This is the core "Minimal Layer Time" setting (in seconds). If a layer is calculated to print faster than this value, the printer will reduce its speed.
- Min print speed: This sets the lowest speed the printer will slow down to when enforcing the minimal layer time.
- Enable fan if layer print time is below: Controls automatic part cooling fan activation for very fast layers (less relevant for high-temp materials where the fan is often detrimental to strength).
The ideal Minimal Layer Time value is highly material-dependent:
- Set the Target: In the "Slow down if layer print time is below" field, enter your target minimum time in seconds.
- Starting Point: The standard Vision Miner slicing profiles contain appropriate Minimal Layer Time values for various materials. These values serve as excellent reference points. Feel free to use them as a starting point and adjust accordingly based on your specific geometry and print observations.
- Set the Speed Floor: Define the "Min print speed" (e.g.,
15 mm/s). This prevents the printer from slowing down too much. Excessively slow speeds can sometimes be counterproductive, potentially causing surface defects or melting due to prolonged contact and heat conduction from the hot nozzle to the part.
- Consider Sequential Printing: For maximum strength, especially with high-temp materials, use PrusaSlicer's "Print Settings" -> "Output options" -> "Complete individual objects" feature. This prints each object fully before moving to the next, inherently keeping layer times short and consistent for each part.
Tip: When printing sequentially, ensure adequate clearance between objects on the build plate to prevent collisions with the print head assembly. PrusaSlicer helps visualize this clearance.
Part cooling fans drastically increase the cooling rate of the deposited layer. While beneficial for materials like PLA to freeze overhangs and bridges quickly, excessive cooling is detrimental to layer adhesion for most high-temperature materials.
- General Guideline: For materials like Nylon, PC, PEEK, PEKK, and Ultem printed in a heated chamber, disable the part cooling fan for most of the print to maximize layer fusion. Set fan speeds to
0% in the main cooling settings.
- Overhangs and Bridging: Cooling may be necessary only for challenging geometries like steep overhangs or long bridges to prevent sagging or collapse.
- Navigate to Filament Settings -> Cooling.
- Enable Enable dynamic fan speeds.
- Configure the fan speed curve based on overhang angle or enable Bridging fan speed. Start with low values (e.g.,
10-30%) only for severe overhangs/bridges.
- Vision Miner profiles provide optimized starting points for dynamic cooling, but geometry-specific adjustments are often needed.
Important: Using the fan unnecessarily with high-temp materials will significantly reduce Z-axis strength by cooling the previous layer too quickly before the next one bonds. Only use it where structurally required for overhangs/bridges.
- Q: My small parts look melted or deformed. What's wrong?
- A: Your Minimal Layer Time might be set too low for the material, or your Min Print Speed is too high, preventing adequate slowdown. Heat is accumulating faster than it can dissipate. Increase the Slow down if layer print time is below value, or decrease the Min print speed. Ensure the chamber temperature isn't excessively high for the specific feature size being printed.
- Q: Why is printing sequentially recommended for strength?
- A: It drastically reduces the time between depositing subsequent layers on the same part, keeping the previous layer hotter and promoting better fusion compared to hopping between multiple parts layer-by-layer.
- Q: When using high-temp materials, should the fan ever be on?
- A: Generally no, except for specific features like steep overhangs (> 45-60 degrees depending on material) or bridges where localized, rapid cooling is needed to prevent drooping or collapse. Use dynamic fan settings sparingly for these cases only.
Mastering the Minimal Layer Time setting is essential for unlocking the full mechanical potential of parts printed on the Vision Miner 22IDEX, particularly with advanced materials. By carefully balancing layer time, print speed, and cooling, you can achieve superior interlayer adhesion and near-isotropic strength. Always perform test prints with relevant geometries after adjusting these settings.
Contact Vision Miner Support for further assistance.