Get your custom parts in production with MakerVerse, your platform for sourcing industrial 3D printed and CNC machined parts.
Industrial parts all from one source
Instant quotations and reliable lead times
L-PBF, SLS, MJF, FDM, SLA, DLP, and more
3D printing steel, other metals and plastics
Choose your 3D Printing and CNC Materials
Our 3D printing and CNC machining material portfolio contains different metals and polymers, ensuring maximum flexibility for every on-demand manufacturing use case.
Metal 3D Printing
Metal 3D printing is ideal for creating complex and dimensionally stable metal parts. It is equally suitable for producing functional prototypes as well as engineered parts.
Polymer or plastic 3D printing are used in a multitude of products and sectors due to their low cost, ease of manufacture, versatility and water resistance. It is equally suitable for printed parts that require good mechanical properties or must be produced very efficiently, i.e. jigs & fixtures on replacement parts.
Polymer 3D Printing
CNC - Metal and Polymer
CNC (Computer Numerical Control) machining is a manufacturing process that uses computer-controlled equipment to cut, shape, and form materials. It is commonly used to create precision parts and components for a variety of industries, including aerospace, automotive, medical, and industrial. Here at MakerVerse we offer CNC machined parts for your projects, either for prototyping or for serial production.
"Working with MakerVerse and leveraging their extensive eco-system to support on demand parts requirements has allowed us to be more responsive and agile.
They have successfully delivered on what we have asked of them to date, and this allows us to focus our expertise on where it is most needed."
Quan Lac Vice President of Additive Manufacturing at Siemens Energy
Working with MakerVerse and leveraging their extensive eco-system to support on demand parts requirements has allowed us to be more responsive and agile. They have successfully delivered on what we have asked of them to date, and this allows us to focus our expertise on where it is most needed.
Quan Lac Vice President of Additive Manufacturing at Siemens Energy
Germany
Hear it From our Customers: real stories, real success
MakerVerse really took the time to understand our project and help us. Working together was a great experience, as they were always so open and transparent about all the parts we ordered.
Camilla Chitvanni Co-Head of Engineering at Swissloop Tunneling
With many additive manufacturing technologies, a 150+ material portfolio, and a full range of finishes, you gain maximum flexibility for every specific use case. You can learn more about the main characteristics of our materials in our available data sheets below.
At MakerVerse, we offer different 3D printing technologies for printing metal and polymer parts at industrial quality from rapid prototyping to production. Lead times are from just 06 business days.
L-PBF is used for printing metal parts. This 3D printing technology is equally suitable for producing functional prototypes as well as engineered parts. Due to its high precision, this technology can realize complex, dimensionally- stable parts.
L-PBF - Laser Powder Bed Fusion
SLS is used for producing polymer parts for a range of use cases. Whether used for functional prototypes or end-use applications, this 3D printing technology is very accurate and not susceptible to tooling wear.
SLS - Selective Laser Sintering
MJF, a 3D printing technology for polymer parts, is especially suitable for prototypes that require good mechanical properties (e.g. prototypes for injection molding parts). It is also capable of producing high-quality end-use parts.
MJF - Multi Jet Fusion
FDM -Fused Deposition Modeling
FDM produces parts out of thermoplastics. This 3D printing technology is useful for functional prototyping, especially for visual and geometric assessments. Specific use cases are jigs and fixtures and parts for art, architecture, and model-making.
SLA - Stereolithography
SLA is a 3D printing technology that unlocks intricate design possibilities with precision and versatility. It's one of the most popular resin-based 3D printing technologies, combining low costs with advantageous mechanical attributes.
DLP - Digital Light Processing
DLP is a cutting-edge additive manufacturing technique that utilizes photopolymers and UV light to produce highly detailed and smooth-finished parts. The projector selectively cures the resin layer by layer, building the object from the bottom up.
PolyJet
PolyJet printing, or material jetting, is a 3D printing technology that jets and instantly UV-cures thin layers of liquid photopolymer, producing parts with remarkable detail and an impeccably smooth surface finish.
WAAM -Wire Arc Additive Manufacturing
WAAM is a 3D printing technology is gaining traction in manufacturing, and for good reason. The process is fast, accurate, and capable of precisely producing large objects. This technology creates everything from enormous crane hooks to entire bridges in Amsterdam.
Makerverse provides a diverse range of CNC Machining technologies, encompassing CNC Milling, CNC Drilling, and CNC Turning. Harness precision and efficiency with our state-of-the-art services!
CNC milling is a highly accurate machining process that uses multi-point cutting tools to create parts. This manufacturing process is compatible with almost any material and offers high standards regarding surface finish. It's also an efficient technology, offering short lead times and serial production capabilities.
CNC Milling Services
CNC turning is a machining process that creates exact parts with cylindrical shapes, like shafts and sleeves. A pre-programmed computer program controlling the cutting tool enables high accuracy levels, making CNC turning capable of everything from simple to intricate parts. This technology is compatible with almost any material – including polymers and metals.
CNC Turning Services
CNC drilling produces holes in preparation for threading or for end-use. It offers unparalleled precision and repeatability, ensuring consistent hole placements across high-volume production runs.
Rapid casting combines traditional casting methods with 3D-printed molds. This technology is ideal for low-cost, one-off parts. MakerVerse will design the mold for you - you only need to provide the design file for the part and we take care of the rest.
Sheet Metal Fabrication
Sheet metal fabrication cuts, bends, and shapes metal into various forms using specialized tools. This process is ideal for producing precise parts in large quantities. We offer full range of cutting methods: Laser, Waterjet, Plasma and more.
Vacuum Casting
Vacuum casting uses a master pattern to create a silicon mold, which is then filled with liquid plastic, making this technology perfect for producing small batches of intricate, high-quality plastic components. It’s a cost-effective technology for prototypes, production, and specialized parts.
Injection molding uses a mold to inject molten material into a shaped cavity to create a solid object. This technology is capable of producing high-quality and high-precision parts. It offers consistent quality, design flexibility, and cost-effectiveness.
Working with MakerVerse and leveraging their extensive eco-system to support on demand parts requirements has allowed us to be more responsive and agile. They have successfully delivered on what we have asked of them to date, and this allows us to focus our expertise on where it is most needed.
Quan Lac Vice President of Additive Manufacturing at Siemens Energy
MakerVerse really took the time to understand our project and help us. Working together was a great experience, as they were always so open and transparent about all the parts we ordered.
Camilla Chitvanni Co-Head of Engineering at Swissloop Tunneling
MakerVerse is a great partner for us on our journey towards revolutionizing automotive technology. Their focus on both innovation and precision is a perfect fit.
Stefan Ender Co-founder and Managing Director at DeepDrive
Working closely with MakerVerse on this project was so helpful. The personal touch and technical expertise made all the difference, and I look forward to working together again.
Francesco Longhetti Head of WARR Rocketry
Hear it From our Customers: real stories, real success
LPBF
SLS
MJF
FDM
CNC Metal
CNC Polymer
Aluminum AlSi10Mg
Copper Alloy CuNi2SiCr
Copper Alloy CuCrZr
Copper CuCP
Hastelloy X
Inconel 625
Inconel® 718
Scalmalloy AlMgSc
Stainless Steel 17-4PH (1.4542)
Stainless Steel 316L (1.4404)
Titanium Ti6AI4V
Tooling Steel MS1 (1.2709)
Aluminum AlSi10Mg
Main characteristics: A good balance of strength, hardness, and dynamic properties values characterizes this aluminum alloy. Furthermore, AlSi10Mg has good thermal and electrical conductivity. It can also be used for printed parts that have to function in wet environments due to its corrosion resistance.
Use cases: AlSi10Mg is often used in housing applications. This aluminum alloy can also be used for functional prototypes due to the possibility of realizing complex parts. Other usage areas are in heat exchangers because of its good thermal conductivity or in lightweight geometries like brackets.
Copper Alloy CuNi2SiCr
Main characteristics: Copper (Cu) is one of the most flexible materials for engineering. It has excellent electrical and thermal conductivity – its thermal conductivity is up to ten times higher than that of many steels. Its good electrical conductivity makes copper well-suited for electrical engineering. Copper is also very resistant to corrosion.
The CuNi2SiCr alloy is a thermally hardenable copper-based alloy that combines thermal and electrical conductivity well. It offers good rigidity of the printed part. This alloy also has good corrosion resistance and can generally be used in harsher conditions where pure copper is not suited, thanks to the addition of nickel and silicon.
Use cases: The combination of properties makes CuNi2SiCr ideal for electrical engineering parts, tooling, and parts used by welding technologies.
Copper Alloy CuCrZr
Main characteristics: This copper alloy has an advantageous combination of electrical and thermal conductivity. It also features good mechanical properties, making it a popular material across industries.
Use cases: CuCrZr is widely used, for example, for molds and cooling inserts for metal casting, electrodes, welding technology, and current-carrying parts for electro-technology such as induction coils.
Copper CuCP
Main characteristics: Copper (Cu) is one of the most flexible materials for engineering. It has excellent electrical and thermal conductivity – its thermal conductivity is up to ten times higher than that of many steels. Its good electrical conductivity makes copper well-suited and a popular material in electrical engineering. Copper is also very resistant to corrosion. CuCp is a high-purity copper, generally allowing a copper content over 99.95%. Therefore, it is suitable mainly where high electrical or heat conductivity is required.
Use cases: Given the characteristics, pure copper (CuCP) is mainly used in applications that include electrical motors, inductors, or other designs required for electrical applications, where high conductivity (both thermal and electrical) is the main criterion for material choice.
Prototypes for functional parts are also done using copper. Due to its corrosion resistance, copper is often used in the marine industry. Another specific use case is the use of copper in heat exchangers.
Hastelloy X
Main characteristics: Hastelloy X is a nickel-based alloy containing chromium, iron, and molybdenum. This combination allows for oxidation resistance while allowing high-temperature strength and fabrication simultaneously. It can be easily fabricated and formed due to good flexibility.
Use cases: Given its characteristics, this material is mainly used in turbine engines for parts located in the combustion zone, like combustor cans, frame holders, and tailpipes. It can also be used for pipes or valves in industrial furnace applications, chemical processing, and petrochemical industries. Its high usability for pressure vessels and heat exchangers is often used in nuclear and chemical reactors.
Inconel 625
Main characteristics: Inconel 625 (IN625) is a nickel-based non-ferrous alloy with good performance in high-temperature environments and exceptional resistance against oxidation. This is mainly because IN625 has less iron and a higher chromium concentration than other alloys. Further, IN625 can withstand high temperatures, much like other nickel superalloys.
Use cases: Given its strong corrosion resistance, Inconel 625 is ideal for environments involving harsh chemicals or seawater. This also makes it suitable for chemical processing and waste/pollution management applications. IN625 is commonly used for jet engine parts, high- or low-pressure valves, turbine shroud rings, flare stacks, or heat exchangers.
Inconel® 718
Main characteristics: Inconel 718 (IN718) is a nickel-based superalloy with good performance in high-temperature environments. This is mainly because IN718 has good mechanical properties up to 700 °C. Furthermore, the metal has excellent oxidation and corrosion resistance, making it an ideal fit in demanding environments. Another advantage is the high strength of the material.
Use cases: IN718 is ideal for challenging use cases, such as those involving the aerospace or energy industry. It is often used in gas turbine parts, which withstand high forces and temperatures. This also makes the material ideal for exhaust components. Another everyday use is in the chemical industry, especially oil, for pipes or valves.
Scalmalloy AlMgSc
Main characteristics: Scalmalloy is an aluminum-magnesium alloy that contains a comparatively high amount of scandium. This specific blend of elements gives Scalmalloy an improved strength over traditional casting alloys. Scalmalloy has a high tensile strength and low material density, comparable to titanium-based alloys at room temperatures. Additionally, it shows excellent corrosion resistance and allows for electric conductivity. Scalmalloy is an approved material under FIA regulations.
Use cases: Aluminum-based alloys like Scalmalloy are ideal for lightweight engineering. It’s frequently used in structural components for light construction industries like aircraft or high-performance cars, where every kilogram of weight matters. Other typical use cases are applications in robotics, semiconductor machinery, and high-quality prototypes.
Stainless Steel 17-4PH (1.4542)
Main characteristics: The stainless-steel material 17-4 PH is characterized by high yield strength and good corrosion resistance. It is a multipurpose steel that can be heat-treated to a hardness of 34 HRC with a tensile strength of 95% compared to the forged material. The steel can be welded using tungsten inert gas (TIG) welding or electric arc welding processes.
Use cases: 17-4 PH is capable of high-strength, robust metal parts often used for industrial applications.
Stainless Steel 316L (1.4404)
Main characteristics: 316L is a stainless steel that stands out due to its excellent corrosion resistance, making it an excellent fit for printed parts used in moist environments. Due to its good machinability, parts out of 316L can easily be reworked or enhanced with further features. Furthermore, 316L has a high elasticity.
Use cases: 316L is used in various aerospace, automotive, food, and energy applications. It is also used for components like pipes and valves in the chemical industry. Another typical use case is wristwatch cases and bracelets.
Titanium Ti6AI4V
Main characteristics: Titanium is used extensively due to its high strength, low weight ratio, and high corrosion and oxidation resistance. All these properties make titanium and its alloys attractive materials for various use cases and industries.
Use cases: Due to titanium’s biocompatibility, it is used for medical and dental applications. Its high strength and comparatively low weight make it appealing for high-performance parts like gearboxes and connecting rods in racing cars and bionic brackets in the aviation industry.
Tooling Steel MS1 (1.2709)
Main characteristics: This tooling steel, or MS1, is characterized by high tensile strength and toughness. It can be used in higher temperatures since its mechanical properties remain stable up to approximately 400°C. Another advantage of 1.2709 is that its mechanical properties can be optimized through heat treatment and martensitic hardening.
Use cases: 1.2709 has various use cases. For example, it is often used for tooling inserts for injection molding, extrusion tool inserts, or functional prototypes. Furthermore, this tooling steel can be used for tooling and fixtures. Due to its high strength, it is regularly used in motorsports and aviation.
PA 11
PA 12
PA 12 Glass-filled (GF)
PA 12 Al-filled
PA 12 Flame Retardant (FR)
PA 11
Main characteristics: PA 11 is a bio-based polymer and provides excellent mechanical properties. Its high ductility and impact strength make it attractive for functional parts in various industries such as automotive. PA 11 parts can also be dyed and are biocompatible, which is why it is used increasingly in the orthotics sector for small series and individualized parts.
Use cases: Typical applications for PA 11 include interior parts for automotive, prosthetics and orthotics, and functional prototypes.
PA 12
Main characteristics: PA 12 is a polyamide (PA) and and a standard Selective Laser Sintering (SLS) material. This material combines high strength with long-term stability. Further advantages of PA 12 lie in its chemical resistance and biocompatibility. Therefore, the medical industry often uses this material for various applications.
Use cases: PA 12 is usually used for fully functional prototypes and end-use parts. One specific application area is in the orthopedic sector due to PA 12’s biocompatibility.
PA 12 Glass-filled (GF)
Main characteristics: PA 12 GF is a polyamide filled with glass beads. This filling makes the material ideal for long-term usability. This plastic can withstand high thermal loads and combines high density and tensile strength.
Use cases: PA 12 GF is often used for fully functional prototypes. Furthermore, it is often used for end-use parts, e.g., in the automotive industry, where it can be placed near high-temperature environments.
PA 12 Al-filled
Main characteristics: PA 12 Al-filled is a polyamide filled with aluminum (Al)—the aluminum sealing results in a metallic-looking appearance. One of the significant advantages of PA 12 Al-filled is its excellent dimensional stability at high temperatures combined with the light weight of plastic. In addition, surfaces can be finished by grinding, polishing, or coating, resulting in even more possibilities to individualize each part regarding the specific use case.
Use cases: Popular applications for PA 12 Al-filled include fully functional prototypes and jigs and fixtures. Another everyday use case is components that must operate under high temperatures and significant stress.
PA 12 Flame Retardant (FR)
Main characteristics: PA 12 FR is a polyamide with a special chemical flame retardant. This makes the material particularly suitable for industries requiring such flame retardancy from a safety or regulatory perspective. Additionally, it offers a high tensile strength.
Use cases: PA 12 FR is approved for specific aerospace applications, making it popular for interior components in aircraft. It is also used in passive parts for electronic components.
PA 11
PA 12
TPU
PA 11
Main characteristics: An elongation at break up to 40 % (depending on build direction) combined with a high impact resistance makes PA 11 in MJF a desirable option for mechanically stressed parts. The material is made from a renewable raw material and is biocompatible, which means it is approved for skin contact, for example.
Use cases: They mechanically stressed parts where high flexibility is needed. Typical use cases are functional prototypes or lower limb prosthetics.
Lead time: 7 days.
PA 12
Main characteristics: PA12 can be well processed in the Multi Jet Fusion process with attractive costs and high reusability of already used powder. Components also have beautiful mechanical properties and provide chemical resistance, e.g., against oils and greases, which makes them suitable for functional parts.
Use cases: Typical use cases are functional prototyping or printing of prosthetics and orthotics.
Lead time: 7 days.
TPU
Main characteristics: TPU allows flexible elastomeric parts to be produced with the advantages of the MJF process. This material-process combination is ideal whenever high elasticity or shock absorption with high design freedom is required.
Use cases: TPU is often used for robotic clamps or elastic covers and folding bellows. Another specific use case is for energy-absorbing parts that prevent accidents, like a helmet.
Lead time: 9 days.
ABS-ESD7
ABS-M30
ABS-M30i
ASA
PC
PC-ABS
ULTEM® 1010
ULTEM® 9085
ABS-ESD7
Main characteristics: ABS-ESD7 is a blend of ABS with carbon. This results in a robust, durable material with electrostatic discharge properties (ESD). The ESD feature mitigates product damage by preventing the buildup of static electricity. This serves as ABS-ESD7’s main differentiator from other FDM materials.
Use cases: With its ESD properties, ABS-ESD7 is often used for components in the electronics industry, such as electronic fixtures, housings, or customized packaging. It’s also an excellent choice in environments with an increased risk of explosions from sparks. That’s why this is the preferred choice for parts involving fuel tanks and the packaging of dangerous goods.
Lead time: 6 days.
ABS-M30
Main characteristics: ABS M30 is a modified acrylonitrile butadiene styrene (ABS) material combining strength and durability with low weight and a high load capacity. The material provides a good compromise between mechanical properties, cost, and accuracy. It also has better mechanical properties than conventional ABS.
Use cases: ABS M30 is often used for loaded functional prototypes, production gears, jigs and fixtures, and manufacturing tools. It’s ideal for form and fit testing. Thanks to its versatility and affordable price, it’s widely used across industries.
Lead time: 6 days.
ABS-M30i
Main characteristics: ABS M30i has properties similar to ABS M30: high strength and durability combined with low weight and a high load capacity. However, according to ISO 10993 and USP Class VI, this material is biocompatible and can be sterilized.
Use cases: This material is helpful for parts requiring biocompatibility, high strength, and the possibility of sterilization. For example, some applications include surgical aids, medical devices, and manufacturing tools for the food industry. It’s an attractive option for parts that come into contact with skin.
Lead time: 6 days.
ASA
Main characteristics: ASA filament is the ideal general-purpose thermoplastic and is suitable for various applications. It has a chemical structure comparable to ABS but offers improved mechanical properties, surface finish, and UV resistance. ASA is available in 10 different colors.
Use cases: With its variety of color options and high aesthetics, ASA is the most popular FDM material for polymer prototypes of industrial-grade quality. Thanks to its high UV resistance, it can be ideally used for outside applications. It is also often used in aesthetic consumer goods prototypes and the automotive industry.
Lead time: 6 days.
PC
Main characteristics: Polycarbonate (PC) combines good mechanical properties such as impact resistance, strength, rigidity, and hardness with high temperature, dimensional stability, and heat resistance.
Use cases: PC is typically used for jigs and fixtures, cases, and visual models.
Lead time: 6 days.
PC-ABS
Main characteristics: PC-ABS is an ideal choice when the temperature resistance of polycarbonates (PC) and the flexural strength of ABS are required. This unique blend of both materials stands out with its high-impact strength, especially at low temperatures.
Use cases: PC-ABS is applicable for solid tools and functional prototypes. It is frequently used in the automotive and electronics industry.
Lead time: 6 days.
ULTEM® 1010
Main characteristics: ULTEM 1010 is a high-performance thermoplastic polyetherimide (PEI). It offers the highest heat resistance, tensile strength, and chemical resistance. It also possesses the lowest coefficient of thermal expansion among all FDM materials. It’s ideal for challenging and highly specialized applications.
Use cases: ULTEM 1010 is frequently used across industries for high-strength jigs and lightweight composite tooling. Certified grade ULTEM can also be used for food contact production tools and customized medical applications.
Lead time: 8 days.
ULTEM® 9085
Main characteristics: ULTEM is one of the so-called high-performance thermoplastics. Its outstanding strength makes it an alternative to metallic materials. Together with the property of flame retardancy, the material is prevalent in the aviation and rail industries.
Use cases: ULTEM materials are used for flame-retardant parts required in planes or trains. Due to its low toxicity, PEI-based polymers can also be used for medical and food components.
Lead time: 8 days.
Aluminum
Brass
Steel
Superalloys
Titanium
Tooling steel
Aluminum
Main characteristics: A good balance of strength, hardness, and dynamic properties values characterizes aluminum and its related alloys. It’s a lightweight, malleable metal that is easy to machine and has good corrosion resistance.
Use cases: Aluminum is commonly used in the aerospace, automotive, and electronics industries for parts such as housings, brackets, and heat sinks.
Brass
Main characteristics: Brass is a corrosion-resistant alloy made from copper and zinc. The main benefits are that its easily machinable and has good thermal and electrical conductivity.
Use cases: Brass is often used for decorative applications and in plumbing, hardware, and electrical components.
Steel
Main characteristics: Steel is characterized by high yield strength and strong corrosion resistance. It’s a multi-purpose metal offering both good weldability and machinability.
Use cases: Steel is widely used for everything from vales to fittings to medical instruments. Many industries, from aerospace to food processing, use stainless steel.
Superalloys
Main characteristics: Superalloys are high-performance alloys offering excellent heat resistance, strength, and corrosion resistance.
Use cases: Superalloys are commonly used in the aerospace and energy industries for heavy-duty parts such as turbine blades, exhaust systems, and heat exchangers.
Titanium
Main characteristics: Titanium is used extensively due to its high strength and low weight ratio. It also offers high corrosion and oxidation resistance.
Use cases: Due to titanium’s biocompatibility, it is used for medical and dental applications. Its high strength and comparatively low weight make it appealing for high-performance parts like gearboxes and connecting rods in racing cars and bionic brackets in the aviation industry.
Tooling steel
Main characteristics: Tooling steel is characterized by a high tensile strength and a high toughness. It can be used in higher temperatures since its mechanical properties remain stable at high temperatures. Heat treatment can further optimize mechanical properties.
Use cases: This metal is often used for tooling inserts for injection molding, extrusion tool inserts, or for functional prototypes. Furthermore, this tooling steel can be used for tooling and fixtures.
PA
PTFE
POM
PA
Main characteristics: PA (Polyamide), also known as nylon, is a strong, lightweight polymer. It offers good wear resistance and low friction.
Use cases: This polymer is often used for gears, bearings, and structural components in various industries, from automotive to consumer goods.
PTFE
Main characteristics: PTFE (Polytetrafluoroethylene), also known as Teflon, is a highly heat-resistant and low-friction polymer. This material also offers excellent chemical resistance.
Use cases: PTFE is commonly used in applications that require non-stick properties, such as bearings, seals, and electrical components.
POM
Main characteristics: POM (Polyoxymethylene), also known as Acetal, is a strong and stiff polymer. It offers good dimensional stability combined with low friction.
Use cases: Various industries often use POM for gears, bearings, and electrical components.
Working with Makerverse on a mock-up project was a fantastic experience. Their ‘all from one source’ approach made the process smooth and efficient. The team’s open dialogue and positive attitude made collaboration effortless. I highly recommend Makerverse and look forward to working together on future projects.
Steffen Jahrmarcht Engineer at Siemens Energy
MakerVerse really took the time to understand our project and help us. Working together was a great experience, as they were always so open and transparent about all the parts we ordered.
Camilla Chitvanni Co-Head of Engineering at Swissloop Tunneling
MakerVerse is a great partner for us on our journey towards revolutionizing automotive technology. Their focus on both innovation and precision is a perfect fit.
Stefan Ender Co-founder and Managing Director at DeepDrive
Just upload the STL file to MakerVerse and place an order. It could not be more simple. Dimensional tolerances were surprisingly good, exceeding expectations. The ease of use of your web page, combined with instant quoting and helpful feedback, made the process seamless.
Nils Pistora Mechanical Engineer at MAX IV
Hear it From our Customers: real stories, real success
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