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A promotion is running on the new Nylon PA12 White at 1€, limiting its availability to meet the high market demand:
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Your file requires a customized quote for this set-up. Proceed with your request and you will receive a price from our experts for the realization of your project.
Move over the different options to get more information about them in this info box.
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We produce external or internal threads including metric M and MF threads from M2 to M16 and GAS threads from 1/4, 1/8, 1/2 and 3/4.
More info >You want to apply the configuration chosen for the other files as well:
Thicknesses below 1 mm have been identified in the files configured in the Quote. By accepting this option, the customer, i.e. the designer of the file, is responsible for compliance with this feature. We cannot guarantee the integrity of these areas even if the file has passed validation.
If you do not want to assume these responsibilities, please go back to the set-up and replace the file with one meeting the 3D Printing Guidelines.
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Move over the different options to get more information about them in this info box.
Alternatively, visit our tutorial pages.
There are more than 30 processing materials in Weerg and they are offered in a constantly updated list to offer the latest available technologies.
Compare the data sheets of each material to discover their properties, the sectors in which they are used and to understand which of the many is right for you.
The technologies with which the chosen material is processed are listed under the heading Processings.
Weerg's know-how and machine park enable optimal processing with each technology.
3D Printing, or Additive Manufacturing, is a set of production processes and technologies that are currently revolutionizing the industry.
The wide choice of technologies and materials makes it excellent for both rapid prototyping and for cutting costs and time-to-market of new products created in medium to large runs.
Milling, turning and other types of CNC processing are carried out in Weerg by a HERMLE machine park, fully automated and with 5-axis continuous machining stations.
Multi Jet Fusion (MJF) technology from HP produces finished parts with excellent mechanical properties, good detail and high repeatability. The best alternative to injection molding for medium production runs.
Fused Deposition Modeling (FDM) printing technology allows thermoplastic polymers with unique mechanical, thermal and chemical properties to be processed. By using specific support materials, the full potential of this technology can be maximized.
Masked Stereolithography (MSLA) is a variant of SLA that allows resin parts to be produced even faster at a lower cost. It is used to process high-performance resins for industrial use.
Finishes allow you to change the appearance and look of the parts produced with our online manufacturing services.
The wide choice of solutions allows you to customize and create unique items produced either by 3D printing or CNC machining from solid material.
Printing modes are settings that affect some mechanical properties such as load at break and elongation at break.
Tolerances, surface quality and minimum thickness of parts do not change based on this choice.
A Weerg technician ensures that the following variables are checked in your file:
Possible difficulties will be communicated by e-mail by our experts.
An automatic analysis is being carried out on the file to detect any critical issues. The result will indicate if the file is suitable to be placed into production.
The automatic analysis of the file has detected thicknesses of less than 1 mm that are subject to breakage or imperfections during printing.
Check the critical areas of the file via the 3D preview here in Weerg. Using CAD drawing software then edit the file and upload it back to Weerg to repeat the automatic analysis.
If you accept that such thicknesses may cause imperfections in production, you can ignore this message.
The automatic analysis carried out on the file has not detected any thicknesses below 1 mm. It means that the file is suitable to be put into production.
Option valid for MJF printing only.
In order to achieve better tolerances and surfaces, our technicians will orient your parts according to their judgement, to prepare them for printing, understanding their functionality and aesthetics.
If you do not want this to happen and wish to keep the original orientation with which you have saved the part, enable this option.
When there are specific requests and/or tight tolerances for CNC machining orders, it is possible to attach the related tables in .pdf or .dwg format.
It is not possible to attach photos and images of the part to be produced
Mechanical processings are suitable for applications where the required tolerances are very tight.
The versatility of our equipment allows you to choose between 3 tolerance levels: ±0.05mm, ±0.07mm, ±0.10mm.
For more information visit the Support Center
Enter the suitable machining operations for your part.
The system will suggest to you the available machining operations according to the diameter measurement of the modelled pre-hole.
Please refer to our Thread Table and the available H7/h7 Table.The density represents the level of optimisation of your build: it has a limited impact on the final cost and is given to you by the program you used to nest your 3D Build.
A .step or .stp file is required for automatic quotation for this material.
The file cannot be produced with this material due to the format: for CNC machining of aluminium, steel and other metals, the accepted formats are .step and .stp.
If you have uploaded an .stl file, the format will not allow correct analysis for this technology.
The file is smaller than the minimum dimensions achievable with this material ().
Uploaded file dimensions: .
Minimum supported dimensions: .
If the export scale and measurement unit are correct, please consider choosing another material.
Please contact Support if you require technical assistance.
The file is larger than the maximum dimensions that can be achieved with this material ().
Uploaded file dimensions: .
Maximum dimensions supported: .
If the export scale and measurement unit are correct, please consider splitting into several parts or choosing another material.
Contact Support if you need technical assistance.
Its versatility and low production cost have made it one of the most used materials in the manufacturing industry.
The white color allows it to be used in all possible colors, to be able to adapt it to one's own production line and used in one's reference market.
Characterized by high ductility and flexibility, it is an optimal choice where strength and performance are fundamental.
It is a composite material made by reinforcing the Nylon base with Carbon Fibre. The result is a stable material, with high mechanical properties, a high lightness and excellent resistance to the absorption of moisture, oils, greases and hydrocarbons.
It is a composite material made by reinforcing the Nylon base with Carbon Fibre. The result is a stable material, with high mechanical properties, impressive lightness, excellent resistance to oils, greases, hydrocarbons and high temperatures .
Suitable to withstand demanding conditions, it is recommended in all applications where thermal stability and structural rigidity are required.
Clear Resin is made after processing with a Translucent finish or frost effect, which guarantees a pleasant and homogeneous aesthetic performance. MSLA printing also allows you to achieve a high degree of detail, with layers of 50µm.
MSLA printing technology is used for this material, which involves the use of removable supports in post-production. If you wish, we can perform this operation for you: just choose the Professional finish when setting up your quote. Alternatively, choose the Basic finish and we will provide you with the components with the media witnesses, which you can remove yourself with a light cleaning job.
This high temperature resin offers high dimensional stability, a smooth surface finish and high mechanical strength for moulding applications.
With a heat deflection temperature of 238°C, this resin is designed to withstand high process temperatures and is the perfect choice for many applications where high temperature resistance is critical.
From prototyping and production to moulding, this resin will help you create professional-quality designs.
Tough resin (or resistant) boasts excellent resilience, its mechanical properties include elasticity and the ability to flex without compromising the structure of the part. The finish is smooth, homogeneous and with a high degree of detail with layers of 50 µm.
MSLA printing technology is used for this material, which involves the use of removable supports in post-production. If you wish, we can perform this operation for you: just choose the Professional finish when setting up your quote. Alternatively, choose the Basic finish and we will provide you with the components with the media witnesses, which you can remove yourself with a light cleaning job.
It is the perfect balance of quality, resolution, and price, making it the ideal choice for those looking for a reliable and cost-effective general purpose resin.
Polypropylene (PP) has always been used in the manufacturing industry for the mix of mechanical properties with good elasticity and low density combined with excellent chemical resistance. It guarantees excellent resistance to moisture and chemical agents and electrical insulation.
Excellent mechanical properties and chemical resistance that also remains subject to high temperatures.
PEEK CF is a carbon fibre reinforced composite material that makes it high performance compared to PEEK.
This specific ABS (acrylonitrile-butadiene-styrene) has been made to be compatible for all uses in food contact contexts. Like other ABSs, it has a good mix of mechanical properties, including ductility and temperature resistance.
This specific ABS (acrylonitrile-butadiene-styrene) has been made to be compatible for all uses in medical and health settings. Like other ABSs, it has a good mix of mechanical properties, including ductility and temperature resistance.
An improved chemical formula for an improved Acrylonitrile Butadiene Styrene ABS resin to get better mechanical properties compared to the standard resin
304 steel is an excellent material to be machined both for chip removal and for moulding even for high depths and is also suitable to be joined by welding. The good mechanical properties are combined with excellent chemical resistance and a wide range of working temperatures: it can be used both at low temperatures in cryogenic environments and at high temperatures.
316L steel combines excellent mechanical properties and good workability with one of the best chemical resistances in the steel family. It has a lengthy resistance to most chemicals, salts and acids, as well as in challenging environments such as the marine environment. The chemical resistance also makes it compatible to be used in medical applications both instrumental and engineering.
C45 steel has an average carbon content and is one of the most widely used remediation steels. It lends itself to surface hardening to obtain a homogeneously hard surface. It is the most popular among construction steels thanks to its properties and competitive cost.
The 18NiCrMo5 steel alloy offers excellent mechanical properties that can be refined and altered according to the requirements of each application. The components can be hardened or undergo a cementing treatment to harden the surface and increase resistance to wear and contact, which are crucial elements for mechanical components.
The 39NiCrMo3 alloy has excellent mechanical properties, including excellent toughness and mechanical strength. The surface of the objects produced with this material, however, can be hardened both through a tempering and nitriding process, which create a uniform and hard layer that gives excellent resistance to wear.
Lightness, ease of welding and high chemical resistance are the key characteristics of this alloy. It is used whenever it is necessary to join several parts together to create the final component and/or where optimal corrosion resistance is required even for long periods, such as in marine environments.
Thanks to the zinc alloy, this aluminium is distinguished by its high mechanical properties that are similar to those of some steels. Its impact resistance and ductility are excellent, as well as its thermal stability with varying temperatures. Its resistance to fatigue and cyclic loads, which is fundamental in the aeronautical sector, is also of equal interest.
This aluminium alloy is easy to work with both for chip removal and with other traditional technologies including welding. It has excellent chemical resistance and interesting mechanical properties that make it suitable for the most varied applications. As part of the 6000 series, it also lends itself to heat treatments to modify its properties to adapt them to the final use intended for the component
Brass is a non-ferrous metal with good mechanical properties, workability, combined with excellent chemical resistance. Also great for applications where low friction or good electrical conductivity are required.
Copper C101 is a variant without alloying elements and given that it is metal in pure form, it enhances the electrical and thermal conductivity properties. It has a high ductility and resistance to impacts that make it performing in a range of niche applications.
The CuSn12 bronze alloy is suitable for use in all mechanical applications where excellent resistance to friction and wear is required. Some examples are the bearings on motion axes and shafts. The excellent corrosion resistance of this alloy is also of relevance, which makes it excellent for use in challenging environments such as the marine sector
Nylon 6 +MOS2 is a polyamide or Nylons polymer that offers good workability. It has interesting mechanical properties with high resistance and resilience combined with excellent wear resistance and self-lubrication performance. It has a high resistance to fats, oils and atmospheric agents but cannot be used in contact with concentrated acids.
POM-C, also called Delrin, is a material with excellent tribological properties and wear resistance. With excellent mechanical properties, it combines excellent dimensional stability and chemical resistance that make it suitable for applications in contact with food. It is easy to work by chip removal, both for milling and lathing.
Use CNC-machined PVC parts to achieve the full potential of your projects. They will be durable, cost-effective and more corrosion-resistant parts than other materials.
The components with Soft Touch Black Finish are painted with a combination of products for which the surface is soft to the touch and opaque. To achieve this effect, this paint adds a uniform thickness of material of about 100 microns on your parts.
The painting can be applied to components produced in HP MJF and is created by spraying an industrial two-component product in two or more coats. The coating is partially uniform and increases in thickness by about 100 microns. However, the porosity of the material may be visible, especially on the non-aesthetic side, as it is a characteristic feature of the printing technology.
The painting can be applied to components produced in HP MJF and is created by spraying an industrial two-component product in two or more coats. The coating is partially uniform and increases in thickness by about 100 microns. However, the porosity of the material may be visible, especially on the non-aesthetic side, as it is a characteristic feature of the printing technology.
The painting can be applied to components produced in HP MJF and is created by spraying an industrial two-component product in two or more coats. The coating is partially uniform and increases in thickness by about 100 microns. However, the porosity of the material may be visible, especially on the non-aesthetic side, as it is a characteristic feature of the printing technology.
The painting can be applied to components produced in HP MJF and is created by spraying an industrial two-component product in two or more coats. The coating is partially uniform and increases in thickness by about 100 microns. However, the porosity of the material may be visible, especially on the non-aesthetic side, as it is a characteristic feature of the printing technology.
The painting can be applied to components produced in HP MJF and is created by spraying an industrial two-component product in two or more coats. The coating is partially uniform and increases in thickness by about 100 microns. However, the porosity of the material may be visible, especially on the non-aesthetic side, as it is a characteristic feature of the printing technology.
The painting can be applied to components produced in HP MJF and is created by spraying an industrial two-component product in two or more coats. The coating is partially uniform and increases in thickness by about 100 microns. However, the porosity of the material may be visible, especially on the non-aesthetic side, as it is a characteristic feature of the printing technology.
The painting can be applied to components produced in HP MJF and is created by spraying an industrial two-component product in two or more coats. The coating is partially uniform and increases in thickness by about 100 microns. However, the porosity of the material may be visible, especially on the non-aesthetic side, as it is a characteristic feature of the printing technology.
The painting can be applied to components produced in HP MJF and is created by spraying an industrial two-component product in two or more coats. The coating is partially uniform and increases in thickness by about 100 microns. However, the porosity of the material may be visible, especially on the non-aesthetic side, as it is a characteristic feature of the printing technology.
The painting can be applied to components produced in HP MJF and is created by spraying an industrial two-component product in two or more coats. The coating is partially uniform and increases in thickness by about 100 microns. However, the porosity of the material may be visible, especially on the non-aesthetic side, as it is a characteristic feature of the printing technology.
The components produced in PEEK have a crystalline structure in the amorphous state once removed from the printer's construction plan. They can undergo an annealing heat treatment in a thermostatic stove in which, through a controlled cycle, the material is given time to crystallize and create an organized semi-crystalline structure. This treatment markedly improves the mechanical properties and thermal resistance of the material.
The Top Black™ finish retains the iconic surface stone effect of MJF technology with the advantage of making it homogeneous over the entire area, eliminating any unwanted traces or residues.
The new dyes used for this special finish provide longer-lasting protection, even from UV rays, preventing the colour from fading over time.
The Top Black™ line of finishes represents the best aesthetic and technical solution for products manufactured by Additive Manufacturing.
After months of development, the first of these finishes was born: Top Black™ for Nylon produced with MJF technology.
Metal materials produced by machining can be sandblasted to even out the surface, remove tool marks and improve the fatigue performance of components. With this finish, sharp edges may be slightly bevelled as a result of surface sanding.
Anodizing is applicable to aluminium alloys and plays both the role of changing the colour of the object, but above all of protecting it, creating a protective barrier against chemical attacks and oxidation. It has a thickness of 10 microns in the interior and 20 microns for the exterior.
Anodizing is applicable to aluminium alloys and plays both the role of changing the colour of the object, but above all of protecting it, creating a protective barrier against chemical attacks and oxidation. It has a thickness of 10 microns in the interior and 20 microns for the exterior.
Anodizing is applicable to aluminium alloys and plays both the role of changing the colour of the object, but above all of protecting it, creating a protective barrier against chemical attacks and oxidation. It has a thickness of 10 microns in the interior and 20 microns for the exterior.
Gloss Blue Anodizing is applicable to aluminium alloys and plays both the role of changing the colour of the object, but above all of protecting it, creating a protective barrier against chemical attacks and oxidation. It has a thickness of 10 microns in the interior and 20 microns for the exterior.
Anodizing is an electrolytic passivation process used to increase the thickness of the natural oxide layer on the surface of metal components.
The process is called anodizing because the part to be treated constitutes the anodic electrode of an electrolytic cell. Anodizing increases corrosion and wear resistance and provides better adhesion to primers and glues than bare metal. Anodic films can also be used to achieve different aesthetic effects, either with thick, porous coatings that can absorb dyes, or with thin, transparent coatings that add interference effects of reflected light waves.
Gloss Red Anodizing is applicable to aluminium alloys and plays both the role of changing the colour of the object, but above all of protecting it, creating a protective barrier against chemical attacks and oxidation. It has a thickness of 10 microns in the interior and 20 microns for the exterior.
Anodizing is an electrolytic passivation process used to increase the thickness of the natural oxide layer on the surface of metal components.
The process is called anodizing because the part to be treated constitutes the anodic electrode of an electrolytic cell. Anodizing increases corrosion and wear resistance and provides better adhesion to primers and glues than bare metal. Anodic films can also be used to achieve different aesthetic effects, either with thick, porous coatings that can absorb dyes, or with thin, transparent coatings that add interference effects of reflected light waves.
Gloss Green Anodizing is applicable to aluminium alloys and plays both the role of changing the colour of the object, but above all of protecting it, creating a protective barrier against chemical attacks and oxidation. It has a thickness of 10 microns in the interior and 20 microns for the exterior.
Anodizing is an electrolytic passivation process used to increase the thickness of the natural oxide layer on the surface of metal components.
The process is called anodizing because the part to be treated constitutes the anodic electrode of an electrolytic cell. Anodizing increases corrosion and wear resistance and provides better adhesion to primers and glues than bare metal. Anodic films can also be used to achieve different aesthetic effects, either with thick, porous coatings that can absorb dyes, or with thin, transparent coatings that add interference effects of reflected light waves.
Matte Blue Anodizing is applicable to aluminium alloys and plays both the role of changing the colour of the object, but above all of protecting it, creating a protective barrier against chemical attacks and oxidation. It has a thickness of 10 microns in the interior and 20 microns for the exterior.
Anodizing is an electrolytic passivation process used to increase the thickness of the natural oxide layer on the surface of metal components.
The process is called anodizing because the part to be treated constitutes the anodic electrode of an electrolytic cell. Anodizing increases corrosion and wear resistance and provides better adhesion to primers and glues than bare metal. Anodic films can also be used to achieve different aesthetic effects, either with thick, porous coatings that can absorb dyes, or with thin, transparent coatings that add interference effects of reflected light waves.
Matte Red Anodizing is applicable to aluminium alloys and plays both the role of changing the colour of the object, but above all of protecting it, creating a protective barrier against chemical attacks and oxidation. It has a thickness of 10 microns in the interior and 20 microns for the exterior.
Anodizing is an electrolytic passivation process used to increase the thickness of the natural oxide layer on the surface of metal components.
The process is called anodizing because the part to be treated constitutes the anodic electrode of an electrolytic cell. Anodizing increases corrosion and wear resistance and provides better adhesion to primers and glues than bare metal. Anodic films can also be used to achieve different aesthetic effects, either with thick, porous coatings that can absorb dyes, or with thin, transparent coatings that add interference effects of reflected light waves.
Matte Green Anodizing is applicable to aluminium alloys and plays both the role of changing the colour of the object, but above all of protecting it, creating a protective barrier against chemical attacks and oxidation. It has a thickness of 10 microns in the interior and 20 microns for the exterior.
Anodizing is an electrolytic passivation process used to increase the thickness of the natural oxide layer on the surface of metal components.
The process is called anodizing because the part to be treated constitutes the anodic electrode of an electrolytic cell. Anodizing increases corrosion and wear resistance and provides better adhesion to primers and glues than bare metal. Anodic films can also be used to achieve different aesthetic effects, either with thick, porous coatings that can absorb dyes, or with thin, transparent coatings that add interference effects of reflected light waves.
