ASA

Also known as Acrylonitrile Styrene Acrylate

Acrylonitrile Styrene Acrylate (ASA) has emerged as a superior alternative to ABS in 3D printing, combining durability with exceptional resistance to weathering. Known for its ability to withstand UV exposure, heat, and harsh environments, ASA is the go-to filament for functional parts that thrive outdoors. From automotive components to garden fixtures, ASA bridges the gap between industrial-grade performance and practical printability.

Polymaker's ASA makes for great outdoor applications

What Is ASA?

ASA is a thermoplastic polymer engineered to excel in outdoor and high-stress environments. Its composition—acrylonitrile for chemical resistance, styrene for rigidity, and acrylate for UV stability—makes it a robust alternative to ABS. Unlike ABS, ASA retains its color and mechanical properties even after prolonged sun exposure, thanks to its UV-resistant acrylic ester elastomer.

Printing with ASA: Precision and Preparation

ASA demands careful calibration to balance adhesion, warping, and layer bonding. Here’s how to optimize your prints:

Key Settings

• Nozzle Temperature: 240–280°C (start at 250°C and adjust based on filament brand).

• Bed Temperature: 90–110°C (heated bed essential for adhesion).

• Print Speed: 35–70 mm/s (slower speeds improve layer bonding).

• Ambient Temperature: Maintain a draft-free environment or use an enclosed printer (70°C chamber ideal).

Adhesion and Warping

• Build Plate: Use PEI sheets, BuildTak, or adhesion items such as Magigoo Original for reliable first-layer grip.

• Enclosure: Critical for minimizing warping and cracking, especially in large prints.

• Cooling: Reduce or disable part cooling fans to prevent rapid cooling and warping.

Challenges

• Fumes: ASA emits VOCs during printing; ensure proper ventilation or air filtration.

• Moisture Sensitivity: Store filament in a dry, sealed container to prevent moisture absorption.

• Stringing: Fine-tune retraction (1–2 mm at 20–30 mm/s) to minimize oozing.

Advantages of ASA

1. UV Resistance: Retains color and strength under prolonged sun exposure, ideal for outdoor signs, automotive trim, and patio fixtures.

2. Thermal Stability: Heat deflection temperature of 86–96°C (1.8 MPa) outperforms PLA and rivals ABS.

3. Mechanical Strength: Tensile strength of 47.1 MPa and impact resistance of 180 J/m (notched) ensure durability in high-stress applications.

4. Chemical Resistance: Withstands oils, acids, and alkalis, suitable for industrial or automotive parts.

5. Post-Processing: Smoothable with acetone vapor for a polished finish, though should be taken with extreme caution due to the flammability of acetone.

Limitations of ASA

1. Print Complexity: Requires an enclosed printer, heated bed, and precise temperature control.

2. Fume Management: Strong odor during printing necessitates ventilation.

3. Not Food-Safe: Unsuitable for kitchenware or medical applications.

4. Material Sensitivity: Prone to warping if printed in humid or drafty environments.

ASA vs. ABS: A Practical Comparison

Property	ASA	ABS
UV Resistance	Excellent	Poor
Heat Resistance	86–96°C (HDT)	100–110°C (HDT)
Impact Strength	180 J/m (Notched)	200 J/m (Notched)
Print Difficulty	Moderate	Challenging
Outdoor Use	Ideal	Not Recommended

Applications of ASA

• Automotive: Exterior trim, mirror housings, and under-hood components.

• Outdoor Fixtures: Garden tools, patio furniture, and UV-resistant signage.

• Industrial: Jigs, enclosures, and chemical-resistant parts.

• Consumer Goods: Durable phone cases, outdoor toys, and sporting equipment.