How to Speed Up 3D Printing: 80% Faster Prints | 2025

You’ve designed the perfect model, loaded your filament, hit “print,” and then… you wait. And wait. Some 3D prints can take 12, 24, or even 48 hours to complete, turning your exciting project into a test of patience.

But here’s the good news: you can dramatically reduce your 3D printing time without turning your masterpiece into a blob of melted plastic. By optimizing hardware, tweaking slicer settings, and making smart design choices, you can achieve print speeds that are 50-80% faster than default settings.

This comprehensive guide reveals every proven method to speed up your 3D printing process. From simple setting adjustments that take seconds to advanced techniques used by professionals, you’ll discover the fastest way to print 3D models while maintaining the quality you need.

Let’s transform your 3D printer from a slowpoke into a speed demon.

Why Does 3D Printing Take So Long?

Understanding why 3D printing is inherently slow helps you identify which speed optimization techniques will work best for your specific needs. The fundamental nature of additive manufacturing creates several unavoidable time constraints.

The Layer-by-Layer Process Explained

3D printing builds objects one microscopic layer at a time, with each layer needing to properly adhere before the next begins. A typical 10cm tall object printed at 0.2mm layer height requires 500 individual layers, each demanding precise movement and material deposition.

The print head must travel across the entire layer, depositing material in a specific pattern. After each layer, the printer needs a fraction of a second to move to the next height, and the previous layer must be solid enough to support the new material.

This process can’t be rushed infinitely because physics sets hard limits. Melted plastic needs time to flow through the nozzle, and deposited material requires cooling time to maintain its shape.

Key Factors Affecting 3D Printing Speed

Several variables determine your actual 3D printing speed settings and overall print time:

Mechanical Limitations: Your printer’s stepper motors, belts, and frame can only move so fast before vibrations and inaccuracies appear. Budget printers typically max out around 60mm/s, while premium machines can handle 150mm/s or more.

Material Properties: Different filaments have unique melting points and flow characteristics. PLA prints fastest at 60-80mm/s, while flexible TPU materials may require speeds as low as 20-30mm/s for reliable results.

Model Complexity: A simple cube prints much faster than an intricate miniature with fine details. Complex geometries require more travel moves, retractions, and potentially slower speeds to maintain accuracy.

Understanding Speed vs Quality Trade-offs

Every speed increase involves compromises. Understanding these trade-offs helps you make informed decisions about how to increase 3d printing speed for your specific project.

Higher speeds can introduce several quality issues:

• Ringing/Ghosting: Vibrations from rapid movements create wavy patterns on surfaces
• Poor Layer Adhesion: Less time for layers to bond properly
• Stringing: Fast movements can pull molten filament between parts
• Dimensional Inaccuracy: Overshooting on corners and curves

The key is finding your printer’s sweet spot where speed and quality meet your project’s requirements.

Hardware Upgrades for Faster 3D Printing

The right hardware modifications can dramatically improve your 3D print speed settings without the quality penalties of pushing stock equipment too hard. These upgrades address the physical limitations that bottleneck your printing speed.

Choosing the Right Nozzle Size for Speed

Your nozzle is the ultimate bottleneck in the 3D printing process. Upgrading from the standard 0.4mm nozzle is the fastest way to reduce print times significantly.

Nozzle Size Comparison Table:

Nozzle Size	Layer Height Range	Speed Increase	Best Use Case
0.25mm	0.05-0.2mm	0.5x (slower)	Ultra-fine details
0.4mm	0.1-0.32mm	1x (baseline)	General purpose
0.6mm	0.15-0.48mm	1.5-2x faster	Large prints, prototypes
0.8mm	0.2-0.64mm	2-3x faster	Fast drafts, vases
1.0mm	0.25-0.8mm	3-4x faster	Maximum speed

Larger nozzles extrude more material per second, allowing higher layer heights and wider line widths. A 0.8mm nozzle can reduce a 10-hour print to just 3-4 hours with minimal detail loss on larger objects.

High-Flow Hotends: When and How to Upgrade

Standard hotends become a limiting factor when pushing high speeds or using larger nozzles. High-flow hotends like the E3D Volcano or Slice Engineering Mosquito can melt filament 2-3x faster than stock options.

These hotends feature longer melt zones and improved heat transfer, allowing volumetric flow rates of 25-40mm³/s compared to standard hotends’ 10-15mm³/s. This upgrade is essential when combining large nozzles with best 3d printer print speed settings above 100mm/s.

Installation typically involves replacing your entire hotend assembly and updating firmware settings. The investment ($100-200) pays off quickly through dramatically reduced print times for large projects.

Motion Systems: CoreXY vs Delta vs Cartesian

Your printer’s motion system fundamentally limits how fast it can move while maintaining accuracy. Understanding these differences helps when selecting a speed-focused printer.

Cartesian (Prusa i3 style): The moving bed limits acceleration, typically maxing out around 60-80mm/s for quality prints. The bed’s mass creates momentum that fights direction changes.

CoreXY: Stationary bed and lightweight moving parts allow speeds of 150-300mm/s. The belt configuration provides excellent precision at high speeds, making it ideal for 3d printing speed settings optimization.

Delta: Extremely fast for tall objects (200-400mm/s possible) but requires careful calibration. The unique kinematics excel at curved movements but can struggle with sharp corners.

Quick Hardware Upgrade Comparison Table

Upgrade Type	Cost	Difficulty	Speed Improvement	Quality Impact
Larger Nozzle	$10-20	Easy	2-4x	Minimal on large parts
High-Flow Hotend	$100-200	Moderate	1.5-2x	None
All-Metal Heatbreak	$20-30	Easy	1.2x	None
Linear Rails	$50-100	Hard	1.3x	Improved
32-bit Board	$50-150	Moderate	1.5x	Improved

Essential 3D Printing Speed Settings

Software optimization often delivers the biggest speed improvements without spending a penny on hardware. Understanding these critical slicer settings transforms your print times while maintaining acceptable quality levels.

Optimizing Print Speed (mm/s) Settings

The print speed setting directly controls how fast your nozzle moves while extruding filament. Most slicers default to conservative 50-60mm/s speeds, but modern printers can handle much more.

Start by increasing your general print speed to 80mm/s and test the results. Many printers maintain excellent quality at this recommended speed for 3d printing, offering a 33% time reduction immediately.

Different features require different speeds for optimal results:

• Infill: 100-150mm/s (hidden inside, quality matters less)
• Inner Walls: 80-100mm/s (structural but not visible)
• Outer Walls: 40-60mm/s (visible surface quality critical)
• First Layer: 20-30mm/s (adhesion is paramount)
• Top/Bottom: 40-50mm/s (visible surfaces need quality)

Layer Height: The Biggest Speed Factor

Layer height impacts print time more than any other single setting. Doubling your layer height cuts print time nearly in half, making this the most powerful speed optimization available.

Layer Height Quick Reference:

• 0.1mm: Ultra-fine detail, miniatures (slowest)
• 0.2mm: Standard quality, good detail/speed balance
• 0.3mm: Fast printing, slight layer lines visible
• 0.4mm: Maximum speed, visible layers (with 0.4mm+ nozzle)

Remember the 80% rule: your maximum layer height should not exceed 80% of your nozzle diameter. A 0.4mm nozzle caps out at 0.32mm layers for reliable extrusion.

Acceleration and Jerk Settings Explained

Acceleration and jerk control how quickly your printer changes speed and direction. Optimizing these best settings for 3d printing unlocks significantly faster prints without the quality issues of simply increasing travel speed.

Acceleration determines how quickly the printer reaches target speed:

• Stock settings: 500-1000 mm/s²
• Optimized: 1500-3000 mm/s²
• Maximum (quality loss): 4000-5000 mm/s²

Jerk controls instantaneous speed changes at corners:

• Conservative: 5-8 mm/s
• Balanced: 10-15 mm/s
• Aggressive: 20-30 mm/s

Start with moderate increases and test print quality. Modern firmware like Marlin 2.0 includes advanced features like S-Curve acceleration for smoother motion at high speeds.

Temperature Settings for Faster Printing

Higher printing temperatures reduce filament viscosity, allowing faster extrusion without under-extrusion problems. This often-overlooked adjustment enables higher speed settings to work properly.

Temperature Adjustments for Speed:

• PLA: Increase 5-10°C above normal (210-220°C for speed)
• PETG: Add 10-15°C (245-260°C)
• ABS: Add 10-20°C (250-270°C)

Monitor for stringing or oozing, which indicates excessive temperature. Each 5°C increase typically allows 10-20% faster printing speeds before under-extrusion occurs.

Infill Strategies to Reduce Print Time

Infill optimization offers massive time savings since it comprises the bulk of most prints’ volume. Smart infill choices can cut hours off print times while maintaining sufficient part strength.

Best Infill Patterns for Speed

Not all infill patterns are created equal when optimizing for speed. The pattern geometry directly impacts how much the print head must slow down for direction changes.

Fastest Infill Patterns:

1. Lines/Rectilinear: Straight back-and-forth motion, minimal direction changes
2. Grid: Simple crosshatch, fast but slightly stronger than lines
3. Triangles: Good strength-to-speed ratio
4. Lightning (Cura 4.2+): Revolutionary adaptive pattern, 50-70% faster

Slowest Patterns (avoid for speed):

• Honeycomb/Hex: Constant direction changes
• Gyroid: Beautiful but extremely slow
• Cubic: Many retractions and travels

Optimal Infill Density by Print Type

Choosing the right infill percentage dramatically impacts 3d print speed settings without compromising functionality. Most prints need far less infill than beginners assume.

Infill Density Guidelines:

• Display models: 5-15% (purely cosmetic items)
• Prototypes: 15-25% (testing fit and form)
• Functional parts: 25-40% (everyday use items)
• High-stress parts: 40-60% (mechanical components)
• Solid alternative: 3-4 perimeter walls instead of 100% infill

Dropping from 50% to 20% infill can reduce print time by 30-40% with minimal strength loss for most applications.

Lightning Infill: The Game-Changer

Lightning infill deserves special attention as a revolutionary approach to support material. Available in Cura 4.12 and newer, it generates branching structures only where needed for top surface support.

This intelligent pattern reduces print time by 50-70% compared to traditional infill while using 30-50% less material. It analyzes your model and creates tree-like supports reaching up to support overhangs and top surfaces.

Lightning infill works best for:

• Large decorative prints
• Prototypes for testing fit
• Models with large internal volumes
• Prints where internal structure visibility doesn’t matter

Support Structure Optimization

Support material significantly increases print time and material usage. Optimizing support settings and design choices eliminates hours of unnecessary printing while maintaining print success rates.

Reducing Support Requirements

The best support is no support at all. Several techniques minimize or eliminate support needs entirely, providing the fastest way to print 3d models successfully.

Design Strategies to Avoid Supports:

• Orient models to minimize overhangs
• Use 45-degree chamfers instead of 90-degree overhangs
• Design with bridging in mind (printers can bridge 20-50mm gaps)
• Split complex models into support-free sections

Adjusting your overhang threshold from the default 45° to 55-60° can eliminate 30-40% of support material. Most printers handle 55° overhangs reliably with proper cooling.

Tree Supports vs Traditional Supports

Tree supports revolutionize support generation by creating organic, branch-like structures that use 40-60% less material than traditional supports. They’re easier to remove and leave minimal scarring on your prints.

Tree Support Advantages:

• 40-60% faster printing than normal supports
• Uses 50-70% less material
• Easier removal with less surface damage
• Better for complex geometries with multiple overhang areas

Configure tree supports with 50-60° branch angles and 2-3mm branch diameter for optimal strength and speed balance. The time savings compound with taller models where traditional supports would create massive pillars.

Overhang Angle Adjustments

Fine-tuning overhang angles based on your printer’s capabilities dramatically reduces support requirements. Most modern printers with adequate cooling can handle steeper overhangs than default settings assume.

Test your printer’s limits with an overhang test print, then adjust slicer settings accordingly:

• Stock cooling: 45-50° maximum overhang
• Upgraded cooling: 55-65° possible
• With support interface layers: 70-75° achievable

Each 5° increase in overhang tolerance can eliminate 15-20% of support material on complex models, directly translating to faster print times.

Advanced Techniques to Speed Up 3D Printing

These professional-level optimizations push your printer to its absolute limits while maintaining quality. Implementing these techniques requires more expertise but delivers dramatic speed improvements.

Input Shaping and Vibration Control

Input shaping compensates for printer vibrations at high speeds, eliminating the ringing artifacts that typically limit how to increase 3d printing speed. This firmware feature allows 40-60% speed increases without quality loss.

Modern firmware like Klipper and Marlin 2.0 support input shaping. The process involves:

1. Measuring your printer’s resonance frequencies
2. Configuring compensation algorithms
3. Testing with increasingly aggressive acceleration values

Properly configured input shaping enables acceleration values of 5000-10000 mm/s² compared to typical 1000-3000 mm/s² limits, dramatically reducing print times on complex geometries.

Variable Layer Height Strategy

Variable layer height (adaptive layers) automatically adjusts layer thickness based on model geometry. Flat areas print with thick layers for speed, while detailed sections use thin layers for quality.

This technique can reduce print time by 20-40% compared to uniform layer heights. The slicer analyzes your model and optimizes each layer independently:

• Flat surfaces: Maximum layer height (0.3-0.4mm)
• Gentle curves: Medium layers (0.2mm)
• Fine details: Minimum layers (0.1-0.15mm)

Most modern slicers support variable layer height. PrusaSlicer offers particularly intuitive controls for this feature.

Multi-Part Printing Optimization

Printing multiple parts simultaneously often proves faster than sequential printing, especially for smaller objects. The efficiency comes from reduced travel moves and optimized heat management.

Multi-Part Best Practices:

• Arrange parts 5-10mm apart for easy separation
• Group similar heights together
• Use sequential printing for tall, narrow parts
• Consider print bed capacity vs. travel efficiency

Printing four identical parts together typically takes only 2.5-3x the time of a single part, effectively giving you 25-33% faster production rates.

Graphics Card Settings for Faster Slicing

An often-overlooked bottleneck occurs before printing even starts: slicing speed. Complex models can take 10-30 minutes to slice on integrated graphics.

Force your slicer to use dedicated graphics:

1. Open GPU settings (NVIDIA Control Panel/AMD Settings)
2. Add slicer executable to program list
3. Set to “High Performance” GPU
4. Restart slicer software

This simple change can accelerate slicing by 5-10x, especially valuable when iterating on 3d printing speed settings for optimal results.

Design Tips for Faster 3D Prints

Smart design choices during modeling can reduce print times more effectively than any slicer setting. These techniques require thinking about manufacturing during the design phase.

Optimal Model Orientation

Orientation dramatically impacts both print time and quality. The Z-axis is always slowest, so minimizing model height provides the best 3d printer print speed improvements.

Orientation Guidelines:

• Minimize Z-height whenever possible
• Orient largest flat surface toward build plate
• Consider splitting tall models horizontally
• Balance support needs with layer count

A 200mm tall vase printed upright might take 8 hours. The same vase printed in two 100mm halves takes only 3-4 hours total, including assembly time.

Breaking Down Complex Models

Decomposing complex models into simpler sub-assemblies often reduces total print time while improving quality. This approach eliminates supports and enables optimal orientation for each component.

Effective Model Splitting:

1. Identify natural break points in the design
2. Add alignment features (pins, slots, or keys)
3. Consider glue surface area and visibility
4. Design for easy post-processing access

Professional designers routinely use this technique for large prints, reducing 24-hour prints to multiple 4-6 hour sessions with better overall results.

Teardrop Holes and Support-Free Design

Teardrop-shaped holes eliminate support requirements for horizontal openings while maintaining dimensional accuracy. This simple design modification saves hours on mechanical parts with multiple holes.

The teardrop profile supports itself during printing:

• Bottom: Circular for accurate sizing
• Top: 45° peaked roof that prints without support
• Result: Perfect holes without support material or post-processing

Similar design principles apply to other features:

• Use 45° chamfers instead of fillets
• Design bridges under 40mm spans
• Add sacrificial bridges for large overhangs

Wall Thickness Optimization

Optimizing wall thickness for your nozzle size prevents unnecessary perimeter passes while maintaining strength. Walls should be multiples of your nozzle width for efficiency.

Wall Optimization Formula:

• 0.4mm nozzle: Use 0.8mm, 1.2mm, or 1.6mm walls
• 0.6mm nozzle: Use 1.2mm, 1.8mm, or 2.4mm walls
• Avoid: Walls like 1.0mm that require partial-width passes

This optimization can reduce perimeter printing time by 20-30% while actually improving part strength through better layer adhesion.

Material Selection for Speed

Material choice significantly impacts achievable print speeds. Some filaments naturally print faster while maintaining quality, while others require careful parameter tuning for speed optimization.

Fastest Printing Filaments

Not all filaments are created equal when pursuing the fastest way to print 3d objects. Material properties like viscosity, cooling behavior, and layer adhesion directly affect maximum reliable speeds.

Speed-Optimized Filament Rankings:

1. PLA: 60-120mm/s – Low melting point, excellent cooling
2. PETG: 40-80mm/s – Good balance of speed and strength
3. ABS: 40-70mm/s – Requires enclosure for best results
4. ASA: 40-70mm/s – Similar to ABS with UV resistance
5. TPU: 15-30mm/s – Flexible materials print slowly
6. Nylon: 30-50mm/s – Requires precise temperature control

High-flow variants of standard filaments enable 20-30% faster printing. Look for materials specifically marketed for high-speed printing with optimized flow characteristics.

Speed Resins for Resin Printers

Resin printing technology offers different speed optimization opportunities. Modern speed resins can reduce layer cure times from 8-10 seconds to just 1-2 seconds per layer.

Speed resin advantages include:

• 4-8x faster printing than standard resins
• 25cm models printable in 5-6 hours
• Maintained detail quality at high speeds
• Compatible with most modern resin printers

Leading speed resin manufacturers like Siraya Tech and Phrozen have developed formulations that cure rapidly without sacrificing mechanical properties.

Material-Specific Speed Settings Table

Material	Nozzle Temp	Bed Temp	Print Speed	Retraction Speed	Max Flow Rate
PLA	200-220°C	60°C	60-120mm/s	40-60mm/s	15mm³/s
PETG	230-250°C	80°C	40-80mm/s	30-40mm/s	12mm³/s
ABS	240-260°C	100°C	40-70mm/s	40-50mm/s	11mm³/s
TPU 95A	220-240°C	60°C	15-30mm/s	Disabled	5mm³/s
Nylon	250-270°C	80°C	30-50mm/s	40-60mm/s	10mm³/s

These settings provide starting points for speed optimization. Always perform temperature towers and speed tests when pushing materials to their limits.

Common Mistakes That Slow Down 3D Printing

Avoiding these common pitfalls prevents unnecessary slowdowns and failed prints when implementing 3d print speed settings. Even experienced users fall into these traps when chasing faster print times.

Over-Supporting Your Models

Excessive support generation is the most common speed killer in 3D printing. Default support settings err on the side of caution, generating far more support than necessary.

Common over-support mistakes:

• Using supports for 45-50° overhangs (most printers handle these)
• Generating supports for small features under 5mm
• Not utilizing support blockers in the slicer
• Ignoring bridging capabilities for gaps under 30mm

Review every support structure before printing. Each eliminated support saves both printing and post-processing time.

Ignoring Printer Maintenance

Poor maintenance creates inconsistent extrusion and quality issues that force slower printing speeds. Regular maintenance enables sustained high-speed printing without problems.

Critical maintenance for speed:

• Clean nozzle monthly (or after 100 hours printing)
• Lubricate linear rails/rods every 50 hours
• Check belt tension weekly
• Verify extruder gear cleanliness
• Calibrate E-steps after any hotend changes

A well-maintained printer reliably handles 30-50% higher speeds than a neglected machine experiencing gradual degradation.

Using Wrong Settings for Your Material

Applying PLA settings to PETG or ABS guarantees poor results and forces speed reductions. Each material requires 3d print retraction speed and temperature optimization for reliable high-speed printing.

Material-specific errors to avoid:

• Using PLA temperatures for PETG (causes under-extrusion)
• Excessive retraction with flexible filaments
• Ignoring cooling requirements for each material
• Not adjusting flow rates for material density differences

Create separate slicer profiles for each material type with optimized parameters. The setup time pays dividends through consistent high-speed results.

Not Calibrating After Changes

Any hardware modification requires recalibration to maintain print quality at higher speeds. Skipping calibration after upgrades wastes the performance potential of new components.

Essential calibrations after upgrades:

• E-steps after nozzle/hotend changes
• PID tuning for new heater cartridges
• Linear advance/pressure advance for new hotends
• Acceleration limits for frame modifications
• Z-offset after any bed/nozzle work

Proper calibration unlocks the full potential of hardware upgrades while preventing the quality issues that force speed reductions.

Quick Reference Guide: Speed Settings by Printer Type

This comprehensive reference table provides recommended speed for 3d printing based on your specific printer type and desired quality level. Use these as starting points for optimization.

Printer Type	Draft Quality	Standard Quality	High Quality	Max Possible
Ender 3 Style	80-100mm/s	50-70mm/s	30-50mm/s	150mm/s
Prusa MK3S+	100-150mm/s	60-80mm/s	30-50mm/s	200mm/s
CoreXY	150-250mm/s	80-120mm/s	40-60mm/s	400mm/s
Delta	200-300mm/s	100-150mm/s	50-80mm/s	500mm/s
Resin (FDM)	N/A	2s/layer	4s/layer	1s/layer

Additional Speed Factors:

• Add 20-30% for infill speeds
• Reduce 50% for first layer
• Increase 10-20% with high-flow hotend
• Decrease 20-30% for flexible materials

Remember: these speeds assume proper printer calibration and maintenance. Start conservatively and increase gradually while monitoring quality.

Frequently Asked Questions

What is the Recommended Speed for 3D Printing?

The recommended speed for 3d printing varies by printer type and material. For standard PLA printing on common printers like the Ender 3, 50-60mm/s provides an excellent balance of speed and quality.

Modern printers with quality components can handle 80-100mm/s for most prints without issues. Premium machines with rigid frames and advanced motion systems achieve 150-200mm/s routinely. Always start with manufacturer recommendations and increase gradually.

Can I Double My 3D Print Speed Settings?

Doubling print speed is possible but requires a systematic approach. Simply changing 50mm/s to 100mm/s in your slicer will likely cause under-extrusion and poor quality.

To successfully double speeds:

1. Increase hotend temperature by 10-15°C
2. Verify your hotend can melt filament fast enough
3. Adjust acceleration and jerk settings appropriately
4. Test with calibration prints before committing
5. Fine-tune retraction settings for the new speed

What’s the Best 3D Printer Print Speed for Beginners?

Beginners should start with conservative speeds of 40-50mm/s for PLA printing. This provides good quality while being forgiving of minor calibration issues.

As experience grows, gradually increase speeds:

• Month 1: 40-50mm/s (learn basics)
• Month 2-3: 50-70mm/s (understand quality factors)
• Month 3+: 70-100mm/s (optimize for speed)

Focus on understanding how speed affects quality before pushing limits. This foundation enables successful high-speed printing later.

How Fast Can the Fastest 3D Printers Print?

The fastest FDM 3D printers achieve remarkable speeds through advanced engineering. Commercial speed-focused printers reach:

• Motion speeds: 500-1000mm/s
• Printing speeds: 300-500mm/s
• Acceleration: 10,000-50,000mm/s²

Consumer printers with modifications can achieve 200-400mm/s reliably. Delta printers hold many speed records due to their lightweight moving mass and efficient kinematics.

Does Increasing 3D Print Retraction Speed Help?

Optimal 3d print retraction speed improves stringing without significantly impacting overall print time. Most materials perform best with retraction speeds of 30-60mm/s.

Excessive retraction speed can cause:

• Filament grinding in the extruder
• Inconsistent extrusion after retraction
• Increased wear on extruder components
• Heat creep in all-metal hotends

Balance retraction speed with distance for best results. Typically, 40-50mm/s with 0.5-2mm distance handles most scenarios effectively.

Conclusion

Dramatically reducing your 3D printing time doesn’t require accepting poor quality or buying expensive equipment. By systematically optimizing hardware, software settings, and design approaches, you can achieve 50-80% faster prints while maintaining the quality your projects demand.

Start with the easiest wins: increase layer height to 0.3mm, optimize your infill settings, and reduce unnecessary supports. These simple changes often cut print times in half without any investment. Then progressively implement advanced techniques like larger nozzles, variable layer heights, and design optimization.

Remember that the best settings for 3d printing depend on your specific needs. A decorative vase benefits from different optimizations than a mechanical part. Test systematically, document what works, and build a library of optimized profiles for different use cases.

Ready to transform your 3D printing speed? Pick one technique from this guide and test it on your next print. Track the time savings and quality differences. Once comfortable, layer in additional optimizations until you find your printer’s sweet spot between speed and quality. Your future self will thank you every time a print finishes hours earlier than expected.

The fastest way to print 3d isn’t about pushing your printer to its breaking point—it’s about intelligent optimization that works with your equipment’s strengths while minimizing its limitations. Now stop reading and start printing faster!