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Ultrasint® PA11
3D printing material
Ultrasint® PA11 is a bio-based 3D printing material. Discover the benefits and applications of this sustainable material.
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Do you know that you can send back your Nylon PA11 for recycling?
Ultrasint® PA11 Material Guide
What is Ultrasint® PA11?
Ultrasint® PA11 is a bio-derived powder with exceptionally high toughness. This material has the particularity of offering high ductility and impact strength for all applications. Do you need durable parts able to withstand high mechanical loads and stress? Ultrasint® PA11 is an option to consider.
Ultrasint® PA11 is based on 100% renewable biomass sources. The Castor seed is extracted from the castor plant to make oil. The oil is then converted into the monomer (11-aminoundecanoic acid), which is finally polymerized into Polyamide 11.
This PA11 material is a sustainable alternative to PA12, offering interesting properties for your components requiring skin contact. Parts 3D printed with this PA11 material are white.
Ultrasint® PA11 is printed using Selective Laser Sintering. Please keep in mind that you will have to respect specific design guidelines to avoid any problem during the additive manufacturing process. Be sure to check the material design guidelines while creating your 3D file and before you send it for 3D printing.
What are the possible applications for this material?
Medical
Approved for skin contact
As this material is resistant and approved for skin contact, making it possible to create made-to-measure medical devices such as orthopedic parts.
- Impact resistance
Charpy impact unnotched: 198 kJ/m2
Ultrasint® PA11 has a good impact resistance making it particularly adapted to the automotive sector for example, to manufacture car interior components.
- Food contact
Compliant with food safety standards, using Ultrasint® PA11 ensures a safe and durable use in food-related applications.
Pricing
The printing price of your design is calculated automatically the moment it is uploaded. As you modify your object (changing material, finishing, size, using batch control or hollowing feature, etc.) you will note that the price changes automatically. The pricing is based on a series of factors, including total volume, object size, and bounding box – to name a few.
The estimated shipping time is also calculated automatically as the object is uploaded and each time you make a modification on it. Delivery time should be added to processing time.
For more information, check our pricing page.
How does Selective Laser Sintering work?
Sculpteo uses a layer by layer process called Selective Laser Sintering (SLS) to manufacture Ultrasint® PA11 parts.
The Selective Laser Sintering technology uses a highly specific laser that sinters thin layers of powder together one layer at a time. After each round of lasering, the printing bed is lowered and another layer of powder is evenly swept across the top for another round of sintering. This 3D printing process continues until the part is fully printed according to the 3D file.
Maximum size raw (white/unpolished): | 176 × 226 × 309 mm |
Maximum size polished: | 176 × 226 × 309 mm |
Maximum dyed regular: | 180 x 220 x 220 mm |
Maximum size dyed in black: | 180 x 220 x 300 mm |
Maximum size dyed polished: | 180 x 220 x 220 mm |
The maximum size of your models are limited by the physical size of our 3D printers – nothing can be printed larger than the printer bed. |
Due to the printing process, your objects will have upskin and downskin. Upskin is a little concave, whereas downskin will show slight convex. Upskin will appear on the top of your object, downskin at the bottom. This is important to consider when you set the orientation of your 3D model. If the upskin and downskin will affect your design, set the orientation beforehand and we will honor it, if you are not sure, our technicians will choose the best one. |
Standard layer thickness | 100µm |
Accuracy | X-Y : +/- 0,3 % (min : 0,4mm) Z : +/- 0,6 % (min : 0,6mm) |
Minimum wall thickness | 0.8mm |
Stemmed elements with support | 0.8mm |
Stemmed elements without support | 1.5mm |
Minimum height and width details | Embossed : 0.5 mm
|
Ratio Depth / width | 1/1 |
Enclosed parts ? | Yes |
Interlocking parts ? | Yes |
Our material has the ability to print the most complex designs of our materials . An example of a complex design is a volume enclosed within another volume, like a chain or a ball joint connection. Our printers have the ability to print a fully interlocked chain, with no support structures to remove. |
Minimum spacing between fixed walls | 0.5 mm |
Minimum clearance between parts | 0.5 mm |
For a successful 3D print a minimum clearance between objects is required to allow excess material to be sand blown out. If this space is not left within the design, the object will be a solid. This is particularly important for articulated objects – as the space left between the walls will define the object’s ability to move.
Clearance should be at least 0.5 mm, however that is the minimum for small objects. Larger objects require more space between their parts. This is due to the HP printing process. Our printer beds are heated during the process, and larger objects are heated for longer periods. A small space between large objects runs the risk of melting together as it remains under heat for a long period of time. In some other cases, holes should be added to allow us to drain for the excess powder material within the clearance.
Hollowing ? | Yes: 5mm |
Our online hollowing optimization tool has the ability to greatly reduce the price and the weight of a print by reducing the amount of material used. Using the tool requires adding two holes to your model, which will serve as the drain for the excess powder material within the object. The minimum size of these holes is determined by our website. Otherwise, it is possible to hollow your object manually in your 3D modeling software. |
Value (Dry) | Value (Cond) | Method | |
Tensile Strength | 52 MPa (X) / 54 MPa (Z) | 45 MPa (X) / 46 MPa (Z) | ISO 527-2 (23°C) |
Tensile Modulus | 1750 MPa (X) / 1800 MPa (Z) | 1100 MPa (X) / 1250MPa (Z) | ISO 527-2 (23°C) |
Elongation at Break | 28% (X) / 24% (Z) | 45% (X) / 31% (Z) | ISO 527-2 (23°C) |
Tensile Strength | 31 MPa (X) / 29 MPa (Z) | 28 MPa (X) / 26 MPa (Z) | ISO 527-2 (80°C) |
Tensile Modulus | 370 MPa (X) / 420 MPa (Z) | 300 MPa (X) / 360 MPa (Z) | ISO 527-2 (80°C) |
Elongation at Break | >150% (X) / 51% (Z) | >150% (X) / 54% (Z) | ISO 527-2 (80°C) |
Charpy Impact unnotched | 184 kJ/m² (X) / 85 kJ/m² (Z) | 198 kJ/m² (X) / 85 kJ/m² (Z) | ISO 179-1 |
HDT B (0.45 MPa, dry) | 176°C | 176°C | ISO 75-2 |
* The test conducted by Sculpteo has shown different values for the elongation at break and tensile strength. Please contact us for further details
They use Ultrasint® PA11:
3D printing to create unique eco-responsible orthopedic devices
Ready to 3D print with Ultrasint® PA11
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