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→ Capabilities
→ Available Alloys
→ Compare Material Properties
→ Surface Finishes
→ Post-Processing
→ Why Metal 3D Printing?

Direct metal laser sintering (DMLS) is an industrial metal 3D printing process that builds fully functional metal prototypes and production parts in 7 days or less. A range of metals produce final parts that can be used for end-use applications.

Metal 3D printing technology is commonly used for:

  • Prototyping in production-grade materials
  • Complex geometries
  • Functional, end-use parts
  • Reducing metal components in an assembly

We hope you find this guide helpful. If the file did not download, you can find it here.

Metal 3D Printing Guide

Jump start your metal 3D printing with this guide that covers material selection, design, post-processing, and quality inspections. 

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Metal 3D Printing Capabilities

Our basic guidelines for metal 3D printing include important design considerations to help improve part manufacturability, enhance cosmetic appearance, and reduce overall production time.

Metal 3D Printing Tolerances

For well-designed parts, tolerances of +0.003 in. (0.076mm) plus 0.1% of nominal length can typically be achieved. Note that tolerances may change depending on part geometry.

Max Dimensions

Layer Thickness

Minimum Feature Size

Tolerances

*At this time, Inconel 718 and Aluminum are the only materials available on our large format, X Line machine


Metal 3D Printing Material Options

Below is our available metal alloys for 3D printing. Various heat treatments are available depending on material.

Stainless Steel (17-4 PH)

Stainless Steel 17-4 PH is a precipitation hardened stainless steel that is known for its hardness and corrosion resistance. If needing a stainless steel option, select 17-4 PH for its significantly higher tensile strength and yield strength, but recognize that it has far less elongation at break than 316L. Final parts built 17-4 PH receive vacuum solution heat treatment as well as H900 aging.

Primary Benefits

  • Heat treated for full hardness and strength
  • Corrosion resistance


LEARN MORE>

Stainless Steel (316L)

Stainless steel 316L is a workhorse material used for manufacturing acid and corrosion resistant parts. Select 316L when stainless steel flexibility is needed; 316L is a more malleable material compared to 17-4 PH. Final parts built in 316L receive stress relief application.

Primary Benefits

  • Acid and corrosion resistance
  • High ductility

LEARN MORE>

Aluminum (AlSi10Mg)

Aluminum (AlSi10Mg) is comparable to a 3000 series alloy that is used in casting and die casting processes. It has good strength -to-weight ratio, high temperature and corrosion resistance, and good fatigue, creep and rupture strength. AlSi10Mg also exhibits thermal and electrical conductivity properties. Final parts built in AlSi10Mg receive stress relief application.

Primary Benefits

  • High stiffness and strength relative to weight
  • Thermal and electrical conductivity


LEARN MORE>

Inconel 718

Inconel is a high strength, corrosion resistant nickel chromium superalloy ideal for parts that will experience extreme temperatures and mechanical loading. Final parts built in Inconel 718 receive stress relief application. Solution and aging per AMS 5663 is also available to increase tensile strength and hardness.

Primary Benefits

  • Oxidation and corrosion resistance
  • High performance tensile, fatigue, creep, and rupture strength


LEARN MORE>

Cobalt Chrome (Co28Cr6Mo)

Cobalt Chrome (Co28Cr6Mo)​ is a superalloy is known for its high strength-to-weight ratio.

Primary Benefits

  • High performance tensile and creep
  • Corrosion resistance


LEARN MORE>

Titanium (Ti6Al4V)

Titanium (Ti6Al4V) is a workhorse alloy. Versus Ti grade 23 annealed, the mechanical properties of Ti6Al4V are comparable to wrought titanium for tensile strength, elongation, and hardness. Final parts built in Ti6Al4V receive vacuum stress relief application.

Primary Benefits​

  • High stiffness and strength relative to weight
  • High temperature and corrosion resistance


LEARN MORE>

Compare Material Properties

20 μm = high resolution (HR)
30, 40, and 60 μm = normal resolution (NR)

  • US
  • Metric

Materials Resolution Condition Ultimate Tensile Strength
(ksi)		 Yield Stress
(ksi)		 Elongation 
(%)		 Hardness
Stainless Steel
(17-4 PH)		 20 μm Solution & Aged (H900) 199 178 10 42 HRC
30 μm Solution & Aged (H900) 198 179 13 42 HRC
Stainless Steel
(316L)		 20 μm Stress Relieved 82 56 78 90 HRB
30 μm Stress Relieved 85 55 75 88 HRB
Aluminum
(AlSi10Mg) 		 20 μm Stress Relieved 39 26 15 42 HRB
30 μm Stress Relieved 50 33 8 59 HRB
40 μm Stress Relieved 43 27 10 50 HRB
Cobalt Chrome
(Co28Cr6Mo)		 20 μm As Built 182 112 17 39 HRC
30 μm As Built 176 119 14 38 HRC
Inconel 718 20 μm Stress Relieved 143 98 36 33 HRC
30 μm Stress Relieved 144 91 39 30 HRC
30 μm Solution & Aged per AMS 5663 208 175 18 46 HRC
60 μm Stress Relieved 139 83 40 27 HRC
60 μm Solution & Aged per AMS 5663 201 174 19 45 HRC
Titanium
(Ti6Al4V)		 20 μm Stress Relieved 153 138 15 35 HRC
30 μm Stress Relieved 144 124 18 33 HRC

Materials Resolution Condition Ultimate Tensile Strength
(MPa)		 Yield Stress
(MPa)		 Elongation
(%)		 Hardness
Stainless Steel
(17-4 PH)		 20 μm Solution & Aged (H900) 1,372 1,227 10 42 HRC
30 μm Solution & Aged (H900) 1,365 1,234 13 42 HRC
Stainless Steel
(316L)		 20 μm Stress Relieved 565 386 78 90 HRB
30 μm Stress Relieved 586 379 75 88 HRB
Aluminum
(AlSi10Mg) 		 20 μm Stress Relieved 268 180 15 46 HRB
30 μm Stress Relieved 345 228 8 59 HRB
40 μm Stress Relieved 296 186 10 50 HRB
Cobalt Chrome
(Co28Cr6Mo)		 20 μm As Built 1255 772 17 39 HRC
30 μm As Built 1213 820 14 38 HRC
Copper
(CuNi2SiCr)		 20 μm Precipitation Hardened 496 434 23 87 HRB
Inconel 718 20 μm Stress Relieved 986 676 36 33 HRC
30 μm Stress Relieved 993 627 39 30 HRC
30 μm Solution & Aged per AMS 5663 1434 1207 18 46 HRC
60 μm Stress Relieved 958 572 40 27 HRC
60 μm Solution & Aged per AMS 5663 1386 1200 19 45 HRC
Titanium
(Ti6Al4V)		 20 μm Stress Relieved 1055 951 15 35 HRC
30 μm Stress Relieved 993 855 18 33 HRC

These figures are approximate and dependent on a number of factors, including but not limited to, machine and process parameters. The information provided is therefore not binding and not deemed to be certified. When performance is critical, also consider independent lab testing of additive materials or final parts.

Surface Finish Options


Standard Finish

Expect roughness values of 200 to 400 µin Ra (0.005 to 0.010mm Ra), depending on material and resolution. Support structures are removed and layer lines are visible.


Custom Finish

We offer brushed surfaces in a range of grits and polished mirror finishes. Be sure to indicate if the custom surface finish is for functional or aesthetic purposes so we can best consult you on our custom options.

Post-Processing Capabilities for Metal 3D-Printed Parts

Improve strength, dimensional accuracy, and cosmetic appearance of final metal components with DMLS for production.

Surface Finishing

  • 3- and 5-axis milling
  • Turning
  • Polish (Mirror or Brushed)
  • Passivation
  • Wire EDM
  • Tapping and reaming

Heat Treatments

  • Stress relief
  • NADCAP heat treatment
  • Hot isostatic pressing (HIP)
  • Solution annealing
  • Aging

Mechanical Testing

  • Tensile
  • Rockwell Hardness

Powder Analysis & Material

  • Traceability
  • Chemistry
  • Particle size and distribution analysis

Why Use Metal 3D Printing?

See how metal additive manufacturing technology can be used to reduce components within an assembly, fabricate complex geometries, and ultimately save you time and costs.

Click to enlarge

How Does Metal 3D Printing Work?

The DMLS machine begins sintering each layer—first the support structures to the base plate, then the part itself—with a laser aimed onto a bed of metallic powder. After a cross-section layer of powder is micro-welded, the build platform shifts down and a recoater blade moves across the platform to deposit the next layer of powder into an inert build chamber. The process is repeated layer by layer until the build is complete.

When the build finishes, an initial brushing is manually administered to parts to remove a majority of loose powder, followed by the appropriate heat-treat cycle while still fixtured in the support systems to relieve any stresses. Parts are removed from the platform and support structures are removed from the parts, then finished with any needed bead blasting and deburring. Final DMLS parts are near 100 percent dense.

Large Format Metal 3D Printing

We recently added the GE Additive X Line to our fleet of metal 3D printers to build large Inconel 718 and Aluminum (AlSi10Mg) parts. Have a project that might be a good fit? Contact us and we can discuss your requirements.

Learn More >

Metal 3D Printing for Production

Improve strength, dimensional accuracy, and cosmetic appearance for end-use metal components with post-processing options like CNC machining and heat treatments.

Learn More >

Resources

Post-Processing for Metal 3D Printing

Learn how to improve dimensional accuracy, surface roughness, and mechanical properties on metal parts with high-requirement applications.

Read Design Tip

Combining Part Assemblies with Additive Manufacturing to Reduce Cost and Increase Performance

How to find the right opportunities to consolidate multi-part assemblies into single components with industrial 3D printing

Read White Paper

Inconel 718: A Workhorse Material for Additive Manufacturing

Inconel 718 is a go-to material for additive manufacturing of metal parts.

Read Blog

Large Format 3D Printing for Aluminum and Inconel Parts

When you’re printing really large parts in metal, it’s great to have a choice of materials. Aluminum and Inconel 718 both make a lot of sense, but which one is the best for your application?

Read Blog

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Desktop 3D Printers Designed for Professionals

Desktop 3D Printer Series

Professional desktop 3D printers built with the versatility to test design concepts and build strong end use parts. Our platform covers a wide range of applications - varying from flexible and elastic to strong and rigid.

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Onyx One™

Our core desktop printer for functional plastic parts with stunning surface finish.

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Our enhanced desktop printer for stunning prototypes, tools, and production parts.

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Micro carbon fiber filled nylon offers excellent heat resistance, surface finish, and chemical resistance

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Stiff, strong, and extremely light, carbon fiber reinforcement yields parts capable of replacing machined aluminum.

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HSHT Fiberglass delivers the highest impact resistance and heat deflection temperature of our continuous fibers, and can be used for low-temp molds.

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Inexpensive and 11 times stiffer than ABS, this is the perfect entry level continuous fiber for 3D printing functional parts.

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Extremely durable and extremely resistant to catastrophic damage, Kevlar is an excellent choice for harsh environments.

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How metal 3D printers work. Overview of SLM and DMLS technologies. additive manufacturing. 3D metal printing.


Metal 3D printing. Additive technologies.

SLM or DMLS: what's the difference?

Hello everyone, Friends! 3DTool is with you!

BLT metal 3D printer catalog

Selective laser melting ( SLM ) and direct metal laser sintering ( DMLS ) are two additive manufacturing processes that belong to the family of 3D printing using the powder layer method. The two technologies have much in common: they both use a laser to selectively melt (or melt) metal powder particles, bonding them together and creating a pattern layer by layer. In addition, the materials used in both processes are metals in granular form.

The differences between SLM and DMLS come down to the basics of the particle bonding process: SLM uses metal powders with a single melting point and completely melts the particles, while in DMLS the powder consists of materials with variable melting points. nine0014


Specifically:
SLM produces single metal parts while DMLS produces metal alloy parts.
Both SLM and DMLS technologies are used in industry to create final engineering products. In this article, we will use the term "metal 3D printing" to summarize the 2 technologies. We will also describe the main mechanisms of the manufacturing process that are necessary for engineers to understand the advantages and disadvantages of these technologies. nine0002 There are other manufacturing processes for producing dense metal parts, such as electron beam melting (EBM) and ultrasonic additive manufacturing (UAM). Their availability and distribution is rather limited, so they will not be presented in this article.

How 3D printing with SLM or DMLS metal works.

How does metal 3D printing work? The basic manufacturing process for SLM and DMLS is very similar.

1. The printing chamber is first filled with an inert gas (such as argon) to minimize the oxidation of the metal powder. It then heats up to the optimum operating temperature. nine0002 2. A layer of powder is spread over the platform, a powerful laser makes passes along a predetermined path in the program, fusing the metal particles together and creating the next layer.
3. When the sintering process is completed, the platform moves down 1 layer. Next, another thin layer of metal powder is applied. The process is repeated until the entire model is printed.

When the printing process is completed, the metal powder already has strong bonds in the structure. Unlike the SLS process, parts are attached to the platform via support structures. The support in metal 3D printing is created from the same material as the base part. This condition is necessary to reduce deformations that may occur due to high processing temperatures. nine0002 When the 3D printer's chamber cools down to room temperature, excess powder is removed manually, such as with a brush. The parts are then typically heat treated while they are still attached to the platform. This is done to relieve any residual stresses. They can then be further processed. The removal of the part from the platform occurs by means of sawing.

Scheme of operation of a 3D printer for metal.

In SLM and DMLS, almost all process parameters are set by the manufacturer. The layer height used in metal 3D printing varies from 20 to 50 microns and depends on the properties of the metal powder (fluidity, particle size distribution, shape, etc.). nine0002 The basic size of the print area on metal 3D printers is 200 x 150 x 150 mm, but there are also larger sizes of the working area. Printing accuracy is from 50 - 100 microns. As of 2020, metal 3D printers start at $150,000. For example, our company offers 3D metal printers from BLT.
metal 3D printers can be used for small batch production, but the 3D printing capabilities of such systems are more like those of mass production on FDM or SLA machines. nine0002 The metal powder in SLM and DMLS is recyclable: typically less than 5% is consumed. After each impression, the unused powder is collected and sieved, and then topped up with fresh material to the level required for the next production.
Waste in metal printing, are supports (support structures, without which it will not be possible to achieve a successful result). With too much support on the manufactured parts, the cost of the entire production will increase accordingly. nine0002

Adhesion between coats.


3D metal printing on BLT 3D printers

SLM and DMLS metal parts have almost isotropic mechanical and thermal properties. They are hard and have very little internal porosity (less than 0.2% in 3D printed condition and virtually non-existent after processing).
Metal printed parts have higher strength and hardness and are often more flexible than traditionally made parts. However, such metal becomes “tired” faster. nine0014

3D model support structure and part orientation on the work platform.

Support structures are always required when printing with metal, due to the very high processing temperatures. They are usually built using a lattice pattern.

Supports in metal 3D printing perform 3 functions:

• They form the basis for creating the first layer of the part.
• They secure the part to the platform and prevent it from deforming.
• They act as a heat sink, removing heat from the model. nine0014

Parts are often oriented at an angle. However, this will increase the amount of support required, the printing time, and ultimately the overall cost.
Deformation can also be minimized with laser sintering templates. This strategy prevents the accumulation of residual stresses in any particular direction and adds a characteristic surface texture to the part.

Since the cost of metal printing is very high, software simulations are often used to predict how a part will behave during processing. These topology optimization algorithms are otherwise used not only to increase mechanical performance and create lightweight parts, but also to minimize the need for supports and the likelihood of part distortion. nine0014

Hollow sections and lightweight structures.


An example of printing on a BLT 3D printer

Unlike polymer powder melt processes such as SLS, large hollow sections are not typically used in metal printing as the support would be very difficult to remove, if at all possible.
For internal channels larger than Ø 8 mm, it is recommended to use diamond or teardrop cross-sections instead of round ones, as they do not require support. More detailed recommendations on the design of SLM and DMLS can be found in other articles on this topic. nine0014

As an alternative to hollow sections, parts can be made with sheath and cores, which in turn are machined using different laser power and pass speeds, resulting in different material properties. The use of sheath and cores is very useful when making parts with a large solid section, as it greatly reduces printing time and reduces the chance of warping.

The use of a lattice structure is a common strategy in metal 3D printing to reduce part weight. Topology optimization algorithms can also help design organic lightweight shapes. nine0014

Consumables for 3D metal printing.

SLM and DMLS technologies can produce parts from a wide range of metals and metal alloys, including aluminum, stainless steel, titanium, cobalt, chromium and inconel. These materials meet the needs of most industrial applications, from aerospace to medical applications. Precious metals such as gold, platinum, palladium and silver can also be processed, but their use is of a minor nature and is mainly limited to jewelry making. nine0014

The cost of metal powder is very high. For example, a kilogram of 316 stainless steel powder costs approximately $350-$450. For this reason, minimizing part volume and the need for supports is key to maintaining optimal manufacturing cost.
The main advantage of metal 3D printing is its compatibility with high-strength materials such as nickel or cobalt-chromium superalloys, which are very difficult to machine with traditional methods. Significant cost and time savings can be achieved by using metal 3D printing to create a near-clean shape part. Subsequently, such a part can be processed to a very high surface quality. nine0002

Metal post-processing.

Various post methods. treatments are used to improve the mechanical properties, accuracy and appearance of metal printed products.
Mandatory post-processing steps include the removal of loose powder and support structures, while heat treatment (heat annealing) is typically used to relieve residual stresses and improve the mechanical properties of the part.

CNC machining can be used for critical features (such as holes or threads). Sandblasting, plating, polishing, and micro-machining can improve the surface quality and fatigue strength of a metal printed part. nine0014

Advantages and disadvantages of metal 3D printing.

Pros:

1. Metal 3D printing can be used to make complex custom parts, with geometries that traditional manufacturing methods cannot provide.
2. Metal 3D printed parts can be optimized to increase their performance with minimal weight.
3. Metal 3D printed parts have excellent physical properties, metal 3D printers can print a wide range of metals and alloys. Includes difficult-to-machine materials and metal superalloys. nine0014

Cons:

1. Manufacturing costs associated with metal 3D printing are high. The cost of consumables is from $ 500 per 1 kg.
2. The size of the working area in metal 3D printers is limited.

Conclusions.

• Metal 3D printing is most suitable for complex, one-piece parts that are difficult or very expensive to manufacture using traditional methods, such as CNC.
• Reducing the need for building supports, will significantly reduce the cost of printing with metal. nine0002 • 3D printed metal parts have excellent mechanical properties and can be made from a wide range of engineering materials, including superalloys.

And that's all we have! We hope the article was useful to you.

Catalog of 3D printers for metal BLT

You can purchase metal 3d printers, as well as any other 3d printers and CNC machines, by contacting us:

• By email: [email protected]

• By phone: 8(800)775-86-69

• Or on our website: http://3dtool.ru

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Precise 3D metal printing on order in Sprint 3D

Metal 3D printing - additive manufacturing of metal products, which is rightfully one of the most promising and rapidly developing areas in 3D printing as such. The technology itself originates from the conventional sintering of materials used in powder metallurgy. But now it has become more perfect, accurate and fast. And today SPRINT3D offers you metal printing on 3 D printer on really favorable terms. But first, a little information about the production process itself and its capabilities.

Selective Laser Fusion Technology

SLM or Selective Fusion Technology is a type of direct metal printing that achieves a density of 99.5%. The difference is especially noticeable when compared with models obtained by conventional casting. This indicator is achieved due to the introduction of the latest technologies in the hardware part:

  • The use of special rollers for compacting powders and, as a result, the possibility of using powders with a particle size of 5 µm.
  • Bulk density increase to help compact end products.
  • Creates a rarefied atmosphere of inert gases, which ensures maximum purity of the material, no oxidation, and eliminates the risk of introducing third-party chemical compounds into the composition.

But most importantly, the modern 3 D Metal Printer makes it easy to customize the configuration for printing with a specific metal powder. Thus, even with inexpensive material, you can get a first-class result. But only if you use high-quality modern equipment. And here we are ready to surprise you too!

Metal 3D printing B SPRINT 3D

3D printing with own 3D printers

The largest working area is 280x280x350 mm

layer thickness up to 15 microns

3D with various types of metals

Delivery throughout Russia and CIS countries

installation for 3 9020 which we use

Production quality is a key requirement that we set ourselves. Therefore, in our work we use only professional equipment with wide possibilities for metal printing. Let's take a closer look at each of the production units. nine0014

Production unit SLM 280HL

SLM 280HL is a development of the German company SLM Solutions GmbH, which uses the technology of layer-by-layer laser melting of powder metal materials. The installation is equipped with a large working chamber and allows you to create 3D objects with dimensions of 280x280x350 mm. Among the main advantages of printing with this installation are:

  • Small minimum thickness of the applied layer - 20 microns.
  • Filling the working chamber with an inert gas, which allows you to work with various reactive metals.
  • Print speed up to 35 cm/hour.
  • Building layer thickness – 30 and 50 µm.
  • Power - 400 W.

A special highlight is the patented powder feed system, which delivers significantly faster print speeds than most production machines in the same price range. We use the following materials in production:

  • Stainless steel (domestic 07X18H12M2 (Polema), 12X18H10T and imported 316L).
  • Tool steel (imported 1.2709).
  • Heat-resistant alloys 08KhN53BMTYu (similar to Inconel 718, produced by Polem) and EP 741 (produced by VILS).
  • Cobalt Chrome (COCR)

The SLM 280HL 3D printer can be used to create all kinds of metal components, prototypes and end products. If necessary, we can provide small-scale production. nine0014

ProX 100 production unit

ProX 100 is a compact unit for 3 D metal printing, developed by the American company 3D Systems. It uses direct laser sintering technology, which ensures high speed and precision of production. Among the main characteristics it is worth highlighting:

  • The size of the working chamber is 100x100x80 mm.
  • Building layer thickness – 20 and 30 µm. nine0219
  • Power - 50 W.

ProX 100 allows you to create prototypes that can not be developed by standard methods, provides short lead times, guarantees the absence of material porosity and high part density. In addition, we note the standardized quality of all products, regardless of their structure. At the moment, the model is actively used in dentistry when creating high-precision prostheses, but it has found wide application in other industries:

  • Manufacture of engines and their individual parts.
  • Development of medical equipment.
  • Printing jewelry and even contemporary art.

In printing, we use an alloy of cobalt-chromium KX28M6 (manufactured by Polem), originally developed for additive technologies when creating endoprostheses.

Metal 3D printing - current application

Many experts argue that 3D printing as such has not yet fully revealed its potential. For example, Elon Musk plans to use technology in the colonization of Mars to build administrative and residential buildings, equipment and technology right on the spot. And this is quite real, because 3D metal printing technology is already actively used in various industries: