Platforms


Atomic Diffusion Manufacturing

Atomic Diffusion Manufacturing (ADM) uses metal powder bound by plastic, to print “green” parts in much the same way that FDM platforms do. The parts are then fused across all 3 axis in a sintering oven. The sintering process brings them close to, but not up to the alloys melting point, while vaporizing the plastic medium contained in the part. Shrinkage in the part does occur but is consistent and adjusted for automatically in the build process. The finished parts are fully dense and have virtually the same isotropic strength characteristics as the original alloy.
This technology is ideal for a wide range of professional and industrial applications, including automotive, aerospace and defense applications, machine shop, supply chain manufacturing, etc. A unique feature of this metal printing process is the ability to create “honeycombed” or hollow enclosed structures which provide very high strength to weight ratios in the finished parts. It allows for the production of complex shapes with no need for tooling, and it permits the production of dramatically different designs which could not be produced from conventional processes like machining, stamping or die casting ie. enclosed honeycomb. This process does not require special environmental, electrical or safety considerations making it highly accessible to most commercial shops.

Materials
- Stainless Steel, Tooling Steel, Titanium, Aluminum, Inconel
Post Processing
- Parts can be annealed, machined, polished, coated or chemically finished after printing.
Printers
- MetalX

Continuous Fiber Fabrication

Continuous Fiber Fabrication (CFF) is a solid thermoplastic based fabrication method which utilizes nylon and nylon composite filaments for build material, that may also be simultaneously incorporated with various continuous fibers during the the fabrication process.
In this process, the continuous fibers are extruded separately from a second print head directly into the nylon substrate, across any layer(s) on the X,Y axis. As rebar is used to strengthen cement, so to are the continuous fibers used to bolster the thermoplastic substrate. The continuous fibers are pre-engineered and generally un-altered in the printing process. Fibers may be added at specific layers to achieve greater part strength, abrasion resistance, rigidity, and heat deflection wherever needed. This platform is ideal for machine shops, fabricators, service bureaus, and any manufacturers looking for strong, functional, lightweight parts. With these added benefits the CFF process is able to build parts with greater functionality and durability and is an ideal choice for many functional prototyping, molding, tooling, production and supply chain applications.

Materials
- Nylon and Nylon composite filaments are the primary build and support material. Depending on which qualities are desirable (strength, rigidity, abrasion resistance and heat deflection), Carbon Fiber, Kevlar, and Fiberglass can be added to the build in continuous strands.
Post Processing
- Parts can be glued, machined, sanded, chemically treated, painted and coated
Printers
- Onyx Pro, Mark 2, Mark X

​Color Jet Printing

Color Jet Printing (CJP) is a powder printing process which uses colored or clear resin binders to fuse a talcum-like powder into shape, as it is deposited in consecutive layers onto a print bed, until the bed is filled.
This platform is best suited to applications where visualisation and full color representation are the priority. Examples include display and concept models, figurines, replicas, artifacts, and reproductions. Once the parts are printed and post treated, they have a porcelain or ceramic quality and although they will stand up to some handling, they are not intended for functional use. Whether printed with color, or left natural white, parts can be additionally clear coated to add a smooth surface finish.

Materials
- Gypsum powder is the primary build and support material used in this process. Plastic resin and cyanoacrylates (superglue) are used to saturate, combine, and reinforce the model geometry.
Post Processing
- Parts can be sanded, coated and/or painted after printing. Machining of parts is not recommended
Printers
- Projet 660 Plus

Direct Metal Printing

Direct Metal Printing (DMP) uses a powerful laser to spot sinter metal powder into shape, as the powder is deposited in consecutive layers onto a print bed, until the bed is filled.
This process is well suited for producing fully dense and functional metal parts with impressive accuracy and resolution. The technology is ideal for medical, aerospace and defense applications where weight to strength ratios are critical. It allows for the production of small and extremely complex shapes with no need for tooling, and it will allow for dramatically different part design than those available using conventional processes like machining, stamping or die casting. It bypasses multiple stages of the traditional production process for cast or forged metal parts, thereby saving both time and money in development of functional end use metal parts. Similar to SLS this process can produce multiple parts simultaneously and offers economies of scale for short run, high value production.

Materials
- Stainless Steel, Titanium, Aluminum, and Inconel in powdered forms are the primary build and support materials used in this process.
Post Processing
- Parts can be annealed, machined, polished, coated or chemically finished after printing.
Printers
- sPro DMP 320

​Fused Deposition Modeling

Fused Deposition Modelling (FDM) is a solid thermoplastic based rapid prototyping method that extrudes melted filament, layer by layer, to build a solid or lattice-filled model. Internal structures can contain closed hollow cells which reduces material use and provide parts with high strength to weight ratios.
Customers in automotive, medical device, engineering, architecture and other industries rely on FDM capabilities for rapid delivery of dimensionally accurate, functional prototypes, as well as small-quantity production parts. The thermoplastic parts are able to resist high temperatures, mechanical stresses and chemical degradation. FDM technology is perfect for producing durable jigs, tooling or fixtures used in manufacturing processes. FFF (Fused Filament Fabrication) is also often used to denote this platform.

Materials
- Engineering-grade thermoplastics such as ABS, Nylon and polycarbonates are the primary build and support materials used in this process.
Post Processing
- Parts can be glued, machined, sanded, chemically treated, painted and coated
Printers
- Onyx One, Taz 6, Mini, Ultimaker 3, Ultimaker 3 Extended

Multi Jet Printing

Multi Jet Printing (MJP) is a liquid plastic process that uses jetted droplets of UV reactive plastic deposited in layers, and solidified with light, in order to create intricate and complex geometries with a high degree of accuracy, and fine feature detail.
This process is ideal for rapid prototyping and provides a quick turnaround time. Printed parts have good compressive strength, smooth surfaces and exceptional feature detail, as well as mechanical properties suitable for study models, form & fit testing, watertight and pressure applications, as well as limited functional use.

Materials
- UV reactive acrylics, rubber-like elastomeric polymers, and wax are the primary build and support materials used in this process.
Post Processing
- Parts can be painted, metal coated, glued and machined after printing.
Printers
- Projet 2500, Projet 3600, Projet 5500

Stereolithography

Stereolithography (SLA) is a liquid plastic process that uses laser light to solidify UV reactive resins on a build plate, as it descends into a vat of liquid resin. Each layer is etched by laser and solidified just below the surface of the liquid, which prevents oxidization and produces exceptional surface quality rivaling that of injection molding.
This process offers the best all-round form/fit prototyping capability for the verification of design elements before committing to your chosen production route. Its high accuracy and good surface finish makes it the preferred choice for design and concept models, engineering verification and master patterns for silicone rubber molds. It produces dimensionally accurate models with good feature detail and is best suited for parts with geometries having relatively low material volumes such as shells, enclosures, meshes and latices etc.

Materials
- UV reactive Acrylic resin is the primary build and support material used in this process.

Post Processing
- Parts can be painted, metal coated, glued and machined after printing

Printers
- Form 2, Projet 7000


Selective Laser Sintering

Selective Laser Sintering (SLS) uses a laser to sinter powdered thermoplastic into shape as the powder is deposited in consecutive layers onto a print bed until the entire bed is filled.
SLS is the rapid prototyping technology of choice for a range of functional prototype applications, including those with snap fits, living hinges and other mechanical joints. The ability of SLS to build multiple pieces at a time provides some economies of scale for short run, high value production and makes the process a good choice for manufacturing end use products with complex geometries that require isotropic strength, stiffness, and/or heat resistance.

Materials
- Nylon powder is the primary build and support material used in this process. Additional materials such as carbon, aluminum and fiberglass can be added to this process in order to achieve greater part strength, rigidity, and heat deflection.
Post Processing
- Parts can be dyed, painted, and machined after printing.
Printers
- ProX 500