Direct Metal Laser Sintering (DMLS) 3D Printing Services

High-quality metal parts produced precisely and efficiently without the need for expensive tooling

Overview

Direct Metal Laser Sintering 3D Printing

Direct metal laser sintering, or DMLS, is a type of 3D printing technology that uses lasers to melt and fuse metal powders together, layer by layer, to create 3D objects. DMLS is a highly precise and efficient way to create complex metal parts and components. It has a wide range of applications in industries such as aerospace, automotive, and medical devices.

The history of DMLS dates back to the 1990s when it was developed as a way to produce metal parts quickly and cost-effectively. Since then, the technology has evolved and improved, allowing for the creation of increasingly complex and accurate parts. One of the major benefits of DMLS is its ability to produce parts with complex geometries and internal structures that would be difficult or impossible to manufacture using traditional methods. It is also a relatively fast process and requires minimal post-processing, making it a cost-effective option for producing small batches of parts.

Advantages of DMLS 3D Printing

Precision

Strength

Speed

Cost Savings

Expanded Design Freedom

High-Quality Prototypes, Parts, Tooling, and More

Common DMLS 3D Printing Applications

DMLS 3D printing has a diverse range of applications across many industries.

DMLS 3D Printing Materials

TypeNameDescriptionMDS
Aluminum
EOS Aluminum AlSi10MgCombines light weight and good mechanical properties. Different heat treatments can be applied to modify properties, for example, to increase ductility and conductivity. The material has good thermal and electrical conductivity, especially after heat treatment. It can also be used to manufacture gas-tight parts.
Aluminum
EOS Aluminum AlSi10MgCombines light weight and good mechanical properties. Different heat treatments can be applied to modify properties, for example, to increase ductility and conductivity. The material has good thermal and electrical conductivity, especially after heat treatment. It can also be used to manufacture gas-tight parts.
Aluminum
Aluminum F357A lightweight, corrosion-resistant, and highly-dynamic load-bearing material ideal for applications that require a combination of mechanical and thermal load endurance with low weight.
Aluminum
3D Systems LaserForm® AlSi10Mg (A)Combines silicon and magnesium as alloying elements, which results in a significant increase in strength and hardness compared to other aluminum alloys. Due to the very rapid melting and solidification during Direct Metal Printing, LaserForm AlSi10Mg (A) in as-printed condition shows fine microstructure and high strengths. Also known for light weight and high thermal conductivity.
Cobalt
EOS CobaltChrome MP1Parts have good corrosion resistance and high mechanical properties even at elevated temperatures, plus are nickel-free and show a fine, uniform crystal grain structure. This combination is ideal for many applications in the aerospace and medical industries.
Nickel
Stratasys Nickel Alloy K500A nickel-copper alloy with small percentages of titanium and aluminum that can be precipitation hardened. It’s a tested liquid rocket engine (LRE) material, valued by aerospace companies for its oxygen compatibility at high pressures. Components built with Nickel Alloy K500 can be found in sub-scale hardware, heat sink chamber spools, nozzle spools, oil pipelines, and manifolds on rocket engines.
Nickel
Stratasys Nickel Alloy 718A precipitation-hardenable nickel-chromium alloy also containing significant amounts of iron, niobium, and molybdenum along with lesser amounts of aluminum and titanium. Combines corrosion resistance and high strength with outstanding weldability including resistance to post-weld cracking.
Nickel
Stratasys Nickel Alloy 625Is non-magnetic and has excellent fatigue and thermal-fatigue properties combined with excellent corrosion resistance.
Nickel
Nickel Alloy H282A wrought, gamma-prime strengthened superalloy developed for high-temperature structural applications, especially those in aerospace and industrial gas turbine engines. Possesses a unique combination of creep strength, thermal stability, weldability, and fabricability not found in other available commercial alloys.
Stainless Steel
EOS StainlessSteel PH1Conforms to the compositions of DIN 1.4540 and UNS S15500. Characterized by having good corrosion resistance, excellent mechanical properties, and high hardness and strength. Can easily be machined, spark-eroded, welded, micro shot-peened, polished, and coated.
Stainless Steel
EOS StainlessSteel GP1Has good corrosion resistance and mechanical properties, especially ductility.
Stainless Steel
EOS StainlessSteel 316LA high-performance, marine-grade austenitic stainless steel that is molybdenum alloyed for enhanced corrosion resistance in chloride environments. Also known for its high ductility, toughness, and strength.
Stainless Steel
EOS StainlessSteel 17-4PHWidely used in engineering applications, as with other precipitation-hardening steels, due to its corrosion resistance and strength. Parts built from this material can be easily machined, shot-peened, and polished in as-built or heat-treated states.
Stainless Steel
3D Systems LaserForm® 17-4PH (B)Has an outstanding combination of excellent corrosion resistance and high strength combined with good toughness.
Titanium
EOS Titanium Ti64ELIHas a chemical composition and corresponding to ASTM F136 and ASTM F3001. Well-known light alloy characterized by having excellent mechanical properties and corrosion resistance combined with low specific weight and biocompatibility. Can be machined, shot-peened, and polished in as-built and heat-treated states. This material is ideal for many high-performance applications.
Titanium
EOS Titanium Ti64A well-known, light alloy characterized by excellent mechanical properties and corrosion resistance, combined with low specific weight and biocompatibility.
Tool Steel
EOS MaragingSteel MS1Parts show very good mechanical properties and are easily heat-treatable using a simple thermal age-hardening process to obtain excellent hardness and strength.

DMLS 3D Printing General Tolerances and Design Guidelines

Description
Notes
This table depicts the general tolerances for Direct Metal Laser Sintering (DMLS). Stresses during the build and other geometry considerations may cause deviation in tolerances and flatness. Part designs with thicker geometries, flat or broad parts, and parts with uneven wall thicknesses may be prone to significant deviations or warping. Improved tolerances may be possible and must be approved on a case-by-case basis. General tolerances apply before secondary finishing or post-processing unless otherwise specified.
General tolerance
±0.005″ (0.127 mm) for the first inch is typical, plus ±0.002″ (0.0508 mm) for every inch thereafter
Build size
Up to 10″ x 10″ x 10″ (254 x 254 x 254 mm)
Layer height
0.0012″ – 0.0016″ (0.03048 – 0.04064 mm) depending on material
Surface roughness
150 – 400 µin Ra (depending on build orientation and material)
Infill
100%

DMLS 3D Printing Gallery

Ready to Get Your Project Off the Ground?

Speak to a 3D printing expert today! Our team is standing by, ready to help answer questions or get started on a quote for your project.

Vernon Tool® MPM®

Download Our Product Line Catalog

Fill out the form below to download a FREE copy of our Vernon Tool MPM Product Line Catalog.

Vernon Tool® MPM®

Download Our Product Brief

Fill out the form below to download a FREE copy of our Vernon Tool MPM Product Brief.

Vernon Tool® MPM®

Download Our Time Studies

Fill out the form below to download a FREE copy of our Vernon Tool MPM Time Studies.

Play Video

Plant 5

Robotics and R&D

Plant 4

Assembly & Inspection

Plant 3

Assembly & Inspection

Plant 2

Fabrication

Plant 1

Headquarters & CNC Machining