If you're looking for high quality tool steel 3D Printing, we have you covered. Utilizing our powder bed fusion and directed energy deposition technologies, we are capable of delivering tool steel parts in a way that others cannot. Beyond our technology breadth, we also offer a range of tool steels. From maraging steel to vecalloy to Haynes, we have a variety of tool steels to meet your application. With standard lead times of 2 weeks but rush deliveries possible in a few days, we are capable of meeting any customer's needs.
Don't have the time to learn about every process and material we offer...just need some great 3D printed tool steel parts?
Submit an RFQ via our secure platform and let our experts do the thinking for you, presenting the right solutions for the application. Or email us with a description of your project and we'll be in touch.
Our 3D Printing service is the most comprehensive in the industry, offering each of the major 3D Printing processes and as broad a range of materials as you can find in the market.
When it comes to metal 3D Printing, our capabilities are unmatched. From small parts to large, tight tolerances or near net shape for speed and savings, and industrial to industrial and medical grade materials, we are uniquely capable of supporting virtually any metal 3D Printing project.
Submit an RFQ via our secure platform and let our experts identify and present the right solutions for the application. Or email us with a description of your project and we'll be in touch to discuss.
3D Printing, or Additive Manufacturing as it less popularly but perhaps more accurately known, is the process of building up objects layer-by-layer, adding material as you go. Its emergence as a tool not only for prototyping, but also functional applications (e.g., replacement parts, tooling) and production parts (that commonly wouldn't be achievable any other way) provided the inspiration for 3Diligent. Below are overviews of our different metal additive technologies. Please click into any of these process options for more information, including additional perspective on our resin, plastic, gypsum technologies. Or simply submit an RFQ and our team will identify and present the most economical solution that meets the requirements of your particular application.
Please visit our Resources Section for more information about the history of 3D Printing, how additive manufacturing can fit into your business strategies for prototyping, replacement parts, tooling, and production parts that call for additive manufacturing's unique abilities.
Selectively melting powdered material with a focused energy source - a laser or electron beam. This is the most accurate of metal printing technologies before post-processing, allowing tolerances potentially tighter than .005". Powder Bed Fusion technology also offers tremendous geometric flexibility, including the ability to fabricate "no assembly required" parts with "captured" sub-assemblies that are held in place by unmelted powder until it is removed in post-processing. It is generally best for parts under a 10" in the X, Y, or Z dimension, although sizes up to 14" in a given dimension are possible for select materials.
The process of spraying an adhesive binder onto powdered material to build up a part, sintering the part in a furnace, and infiltrating that "green" part with a lower melting temperature metal. Binder Jetting with Metal Infiltration is most commonly done with a stainless steel matrix infiltrated with bronze (see picture above). Very cost effective but not as high accuracy (tolerances on the order of 1%-3%), Binder Jetting with Metal Infiltration is a great option for complex, traditionally cast geometries (e.g., jewelry).
Jetting powdered metal into a melt pool created by a focused energy source. Directed Energy Deposition is a very fast process relative to other technologies, with a rapid deposition and melting rate. The tradeoff is lower as-built tolerances; design files should typically be provided assuming a 200 micron overbuild to be removed in post-processing. Because it does not operate as a powder bed, Directed Energy Deposition (DED) is ideal for part repair applications and adding features to existing parts. Additionally, its faster deposition rate makes it a viable option for ground-up building of larger parts, up to 7 feet in a single dimension.
Sheet Lamination involves laying down sheets of metal foil on top of one another, using vibration and tremendous weight to create a bond between the layers, then cutting away excess material. This metal 3D Printing process does not require heat, making it uniquely suited for embedded sensors. Additionally, because foil sheets can be readily traded in and out during the fabrication process, dissimilar laminates can be used, making it an intriguing fabrication option for heat exchanger parts.
Metal Extrusion involves a heated nozzle processing metal beads housed in a polymer jacket. The nozzle melts the polymer jacket just enough to lay the material down on the build platform, layer by layer. The "green" parts are then placed in a furnace where the polymer material burns off, leaving a ~95%-97% dense sintered metal part.
This process is slated to be introduced to commercial markets and offered by 3Diligent in early 2018.
Similar to Binder Jetting with Metal Infusion, this process involves spraying an adhesive binder onto powdered metal beads, layer-by-layer, to build up a part. Once the "green" part is built, the part is placed into a furnace where the adhesive is burned off, leaving a dense part. This process is best for smaller parts, as shrinkage of the green part in post-processing creates challenges with larger geometries.
This Metal Printing process will be offered by 3Diligent in early 2018.