Metal filament 3d printers

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Metallic 3D Printing Filament

Which metallic filament is right for me?

Real Metal Filament - real stainless steel filament printed on your desktop 3D printer. This metal 3D printing filament can be debinded and sintered, leaving your 3D printed part solid 316L or 17-4 PH stainless steel metal. If you are looking for an affordable way to create one-off, custom metal parts, small-batch manufactured parts, or just want to finally print with real metal on your desktop printer, this is your best option.

Metal Composite Filament - plastic filament infused with metal powders. These materials are still mostly PLA plastic and will have typical PLA filament characteristics. The metal powder (bronze, copper, or magnetic iron) provides aesthetic characteristics as opposed to their real metal properties. For example, printed parts in metal composite filament can rust/patina and even be sanded and polished to shine. So, if you are just searching for a metallic look, using a metal composite material is your best option.

Metallic 3D Printing Filament Collections

All Metallic 3D Printing Filament 3D Printer Filament

Metallic 3D Printing Filament

Metal 3D Printing Filament

Print with real metal on your desktop 3D printer.

The Virtual Foundry

If you can print plastic, you can print pure metal parts.

Metal Composite Filament

Plastic materials like PLA that are infused with metal powders

Guides & Articles

How to Succeed with 3D Printing Metal on a Desktop 3D Printer

The time is here to explore easy and affordable metal 3D printing. 3D printing with real metal on a desktop 3D printer is now possible using Ultrafuse Metal 3D printing filament from BASF Forward AM.

BASF Forward AM: A Look at One of Additive Manufacturing's Top Chemical Producers

BASF Forward AM is the production branch of BASF that creates a wide range of additive manufacturing materials for businesses and personal 3D printing.

3D Printer Filament Comparison Guide

There are many different kinds of 3D printer filament, and each one has it's own strengths for different projects. Knowing these differences is key to a successful 3D printing experience and so we have created a Filament Comparison Guide with everything you need to know about every type of filament available.

Stainless Steel Metal 3D Printing on Benchtop 3D Printers

A MatterHackers presentation on advanced materials and their rising presence in 3D printing and BASF Ultrafuse 316L, a composite filament that yields pure metal components

Casting Metal Parts From 3D Prints

Follow Sylatech as they transform legacy casting processes with 3D printing.

How to Succeed When 3D Printing With Metal PLA

Learn the best tips and tricks for 3D printing with metal-infused PLA 3D printing filament.

How To: Post Process Metal Filled Filaments

While 3D printing in true metal is still cost prohibitive to most people, 3D printing composite materials to achieve the look and feel of metal is easy, and all it takes is time.

Tech Breakdown: A Detailed Account of ColorFabb SteelFill Filament

An in-depth review of SteelFill 3D filament, the next great metallic PLA from ColorFabb that delights users with its metal characteristics and relatively easy printing.

FFF Metal 3D Printing for the Lab, Classroom or Studio

FFF Metal 3D Printing Course

Create custom metal parts with ease with TVF’s FFF Metal 3D Printing Course!
This course is in-person (via zoom), hands-on instruction on making the perfect metal parts from your current FFF 3D printer and common kiln. Materials Included!

Your Choice of Equipment

Flexibility and Control

Fully In-House Metal 3D Printing

Use your favorite FDM / FFF 3D printer
Use your favorite kiln or furnace
Or
Get the same equipment we use

Influence every step of the process
No cloud-based software
Military Form 889 Compliant

Make full metal parts in-house
No need to send your parts away

PRINT > DEBIND > SINTER Common FDM 3D PrinterCommon Kiln/FurnaceThe only fully hands-on metal 3D printing system

Go Deeper with the Basics

The basics of getting started and working with Metal FilamentWatch as Integza uses Stainless Steel filament to 3D print an aerospike Rocket Nozzle.

See how Filamet™ Compares to other FFF Metal Technologies

What materials are on your wish list?

If you could 3D print any metal (or glass or ceramic), what material would it be?
You can do it, and you can do it now.

Learn about Custom Filamet™ Projects

The Advantages of Printing with Filamet™ 3D Printing Filaments

✔ Low barrier to entry
✔ Familiar processes

✔ Minimal energy consumption
✔ Mature technology (FFF)

✔ Low hardware costs
✔ Hardware flexibility – capability to customize printer

✔ Safer solution – no chemicals in printing, no chemicals in debinding

Reach out!
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Head Straight to the Shop

We make every material 3D printable. Contact our sales team to learn more. Some limitations may apply.

Just so you know that you’re in good company…
Here are just a few of the organizations using our technology.

We have dozens of relationships within many of the members of the National Lab system. We work on military applications with friendly nations all over the world, but these are our favorite.Just a few of the schools we work with. A through D alphabetically, many more to add.

Steel 3D Printing - A Quick Guide / Sudo Null IT News

Any metal 3D printing technology can print with steel. This is the most popular material. But which steel grades and which technology is best for your application? Will printed steel parts really be as strong and durable as traditionally made parts?

Let's see how a 3D printed steel part is revolutionizing manufacturing and opening doors to new applications in aerospace, medical equipment, automotive, tool making, heavy industry, architecture and more. In addition, more affordable desktop printers are expanding the scope and scope of real steel 3D printed parts.

Strength of steel printed parts.

Cast steel part (left), 3D printed version (center). On the right, a fully 3D printed hinge requires no assembly. (Source: Desktop Metal)

The most common question when it comes to a 3D printed metal model is "Will it be as strong as a forged or cast part?" ?". The short answer is yes... and no.

3D printed steel parts can be just as strong, and sometimes even stronger, than those made in the traditional way. It depends on many factors such as: end use, type of steel, choice of 3D printing method, post-processing and shape of the part. Also, the comparison depends on which of the strength characteristics you focus on: tensile strength, static load strength, fatigue strength, etc.

Parts printed from steel are used in the aerospace industry, for the military, and also, for example, for the manufacture of a footbridge, shown below. Therefore, the strength of printed products is beyond doubt, but let's take a closer look.

Queen Maxima of the Netherlands officially opens a 3D printed metal bridge. Photo by Adriaande Groot (Source: MX3D)

A 3D printed or laser powder sintered (LPBF) steel part has a finer grain structure than cast metal products. This provides better tensile strength characteristics, but in other respects the cast parts are currently still stronger. Most often, LPBF 3D printing is used to replace cast components, but in some cases, 3D printed components can replace forged parts.

One study showed that, under certain conditions, stainless steel parts made using LPBF 3D printers were three times stronger than parts made from the same steel using the traditional method.

In experiments comparing 3D printed steel parts to traditionally made steel parts, researchers create identical parts using two methods and compare their performance. However, head-to-head comparison of details is only part of the big picture.

The main advantage of printing with steel is not only its strength, but also the unique ability to create internal channels and lattice fillings in parts, which is impossible using traditional manufacturing methods. Metal 3D printing makes it possible to produce parts faster than traditional production, since this method does not require the use of special equipment and tools, it allows you to create assemblies as a whole, eliminating the need for subsequent assembly and welding. Designing a printed part usually means that less metal is needed to make it, and therefore less weight, for the same strength.

MX3D Wire Arc Additive Manufacturing (WAAM) printed steel architectural support (Source: MX3D)

Steel 3D printing is also more stable and cost effective as it reduces waste. When using subtractive manufacturing methods, such as CNC machining, you make a part by cutting it out of a large one, with a lot of waste. With additive manufacturing, you only use the material you need to make the finished product.

Steel 3D printing is not intended to replace traditional methods in all areas, but it may be a better choice for a wide range of applications. Particularly when the required parts are unique and designed for specific applications, such as rocket engines, racing cars or the oil and gas industry. 3D printing is the fastest and most flexible technology for mass production and prototype production. For military and industrial applications, steel 3D printing is a faster and more efficient way to create individual parts for vehicles and machines. Stainless steel 3D printing is rapidly finding applications in medicine to create unique surgical instruments and implants.

If you know what characteristics your final product should have (tensile strength, compressive strength, hardness, density, etc.), then all these parameters can be incorporated into the product at the production stage.

Types of steel for 3D printing

Metal powder is the most used metal material for 3D printing (Source: GKN Additive)

There are thousands of different grades of steels and alloys with different mechanical properties, used in traditional manufacturing but in 3D printing there are only a few dozen of them, and some of them are unique, created specifically for this technology. Among the steel options, the following can be distinguished:

Stainless steel (316L, 304L , 17-4PH, 15-5PH, 420, 254, Ph2, GP1, 630, 410).
Tool steel (D2, M2, h23, h21, MS1, 1.2709).
Low alloy steel (4140).
Structural alloyed (20MnCr5).

Recently, unique alloys have been developed specifically for 3D printing, designed to solve the problems that occur with classical production methods.

For example, 3D printer manufacturer Desktop Metal released a patented stainless steel in 2022 that the company says combines the tensile strength, ductility, and corrosion resistance of 13-8 PH stainless steel, combined with the hardness low alloy steel like 4140. The company says customers can go to market with this material and skip the galvanizing step to protect products from corrosion.

ExOne offers two special blends of steel and bronze that the company says allows 3D printed steel parts to achieve increased corrosion resistance while being easy to machine and polish.

While most of the metal powders used in 3D printing are similar to those used for other manufacturing methods, their numbers are on the rise as more companies adopt the technology. Some metal powder manufacturers, such as GKN, also make custom powders for specific 3D printing applications.

How to print with steel

The strength, properties and applications of 3D printed steel products largely depend on which 3D printing technology you use. Some methods produce stronger parts, other methods provide better hardness or abrasion resistance, and some technologies are simply very fast.

Below are the main metal 3D printing methods, their properties and some of the most common application examples.

Fused Deposition Printing (FDM)

BCN3D's Epsilon printer extrudes metal filament from stainless steel (Source: BCN3D) as more printer manufacturers certify metallic filaments for use on their printers, such as Ultimaker, BCN3D, Makerbot, Raise3D. Raise3D has recently released a complete metal printing suite - Metalfuse (3D printer, debinding oven and sintering oven).

This method is still much more popular for printing plastics, but with new plastic filaments filled with stainless steel powder, strong metal parts can be produced.

FDM media was once limited to thermoplastics. Companies like BASF Forward AM and The Virtual Foundry now offer metal filaments that can be used on almost any FDM printer as long as it has a hardened steel nozzle for abrasive media.

These materials are approximately 80% metal and 20% plastic. After printing, the post-processing process removes the plastic, resulting in 100% metal parts.

Due to the removal of the bonding plastic, FDM metal parts shrink during post-processing. The amount of shrinkage is constant and can be taken into account in CAD systems, which allows to obtain relatively accurate finished parts.

Forward AM's 316L Stainless Steel Ultrafuse filament produces finished parts with material properties that the company claims are comparable to injection molded metal parts.

(Source: BCN3D)

While 3D printing with metallic materials may not be suitable for demanding applications such as aerospace, the economics of producing simple metal components without critical loads on an affordable FDM printer can outweigh the impossibility of applying them in some areas.

Metal prototype parts and finished parts that will not be subjected to extreme stress are ideal uses for this technology.

Bound Metal Deposition (BMD)

Desktop Metal's Studio System 3D printer used bonded metal bars that were extruded layer by layer to form a metal part (Source: Desktop Metal)

Similar to FDM, Metal mesh deposition method (BMD) or bonded powder extrusion (BPE) is a 3D printing process based on extrusion. This method uses bonded metal rods or bonded powdered metal filaments, which consist of a much higher percentage of metal powder than the filaments used in FDM. As with FDM, post-treatment to remove the binder and heat treatment in a final sintering oven are required.

There are only a few 3D printers using this method such as Desktop Metal, Markforged and more recently 3DGence, but more companies are entering this market, so stay tuned. These printers are valued as a convenient solution for office 3D metal printing, they are more expensive than most FDM printers, but cheaper than the powder-based metal 3D printing technologies described below.

These printers use their own proprietary filament. Desktop Metal and Markforged offer four types of steel.

Ideal niches for this technology are metal prototype parts, where it is necessary to test the functionality of a part before mass production using traditional methods. Popular applications are molds, punching dies, nozzles, impellers, fasteners and heat exchangers.

For example, Shukla Medical uses Markforged's Metal X printer to print steel prototypes of its orthopedic implant removal tools.

Laser powder sintering.

Laser powder sintering technology uses one or more lasers to melt powdered metal into a desired shape layer by layer (Source: GE Additive) metal printing. This technology is used by 80% of all metal 3D printers on the market.

This method uses powerful lasers to selectively sinter metal powder layer by layer.

LPBF 3D printers are available in a wide range of sizes, prices and laser powers. These and other characteristics affect the properties of the finished part, print speed and other parameters of the finished products.

Steel and steel alloys are the most popular material for LPBF equipment and, unlike FDM and BMD, metal powders are commercially available as they are most commonly used in traditional production methods.

LPBF is a technology that maximizes the quality of a 3D printed part. Applications include aerospace components such as monolithic thrust chambers, rocket engine components and heat exchangers, molds, tools and other applications, as well as high wear parts and surgical instruments.

Binder Jetting

Binder 3D printing technology uses metal powder and a binder to form metal parts (Sorrce: ExOne) binder, and not with a laser. During post-processing, the binder is removed.

Binder application stands out for its high printing speed compared to other 3D printing methods or traditional manufacturing, and metal parts made with this technology have material properties equivalent to those made by metal injection molding.

The number of manufacturers producing metal-bonded inkjet 3D printers is much smaller than that of LPBF machines. Leading manufacturers include ExOne, Desktop Metal, Digital Metal, GE Additive and HP.

Binder blasting is ideal for medium to high volume production of metal tools and spare parts.

In fact, HP claims that its Metal Jet 3D printer was designed specifically for mass production of 316L stainless steel products. HP has partnered with Parmatech to produce metal parts for the medical industry. Pennsylvania-based ExOne uses this technology to manufacture hard metal cutting tools and tool steels.

Electron Beam Melting (EBM)

(Source: GE Additive)

Electron Beam Melting (EBM) is another powder cladding technology. It works in a similar way to selective laser melting (SLM), but instead of using a laser as the energy source, it uses a much more powerful beam of charged particles.

The recoater moves the powder onto the printing plate and an electron beam selectively melts each layer of powder. After each layer is printed, the plate is lowered and another one is applied on top of the previous layer.

EBM can be much faster than SLM, but SLM produces smoother and more accurate pieces. The electron beam is wider than the laser beam, so EBM cannot produce the same precise parts as SLM. Another difference is that the manufacturing process takes place in a vacuum chamber, which reduces the amount of impurities in the material that can lead to defects. That is why EBM is often chosen for printing components for the aerospace, automotive, defense, petrochemical and medical implant industries.

Titanium is the most popular metal for most EBM applications, however steel can be used.

Cold Spray

(Source: Impact Innovations)

Cold spray 3D printing is done by injecting metal powders through a jet nozzle into a supersonic stream of pressurized gases such as air, nitrogen or helium. The process is called "cold" because the metal particles do not melt, but hit the metal substrate and adhere to its surface during the so-called plastic deformation.

Cold spray printed products are not prone to porosity, thermal cracking and other defects associated with melt-based technologies. This method has several advantages over other production methods. The technology is used in the military and aerospace industries around the world. For example, the US Army uses cold spray to repair the mounts of a worn Bradley 25mm steel turret gun.

In the automotive industry, cold spray steel is used for crash repairs because the high strength steel substrates in cars can be susceptible to thermal repair methods such as welding.

Direct Energy Deposition (DED) and Wire Arc Additive Manufacturing (WAAM)

WAAM Steel Parts from MX3D (Source: MX3D)

Direct Energy Deposition (DED) uses welding powder or wire that enters through a nozzle and is fed into the power source to melt the metal. A melt region is created and applied to the substrate. DED is a new process, reminiscent of an old building technology known as "cladding", in which a coating is applied to a substrate, often for thermal insulation or weather resistance. DED is useful for fabricating large objects as a whole, as well as complex geometries that require extensive machining. DED can get such parts much closer to finished than traditional CNC machining.

Because DED uses a coating process, it can be used to add complex geometries to existing steel parts, thus combining complexity with cost reduction. For example, the French company AddUp advertises a rocket nozzle that uses a preformed large 304 stainless steel hopper cone printed with an isogrid structure, usually made from a larger piece by traditional methods.

A technology related to DED is wire-arc additive manufacturing (WAAM). Instead of powder, WAAM uses a metal wire that is melted by an electric arc. The process is controlled by robotic arms. WAAM is also capable of producing large-sized metal parts, as demonstrated by the Dutch company MX3D and its nine thousand-pound 41-foot stainless steel bridge in Amsterdam, as well as an oil and gas equipment repair part, proving that parts can be made in the field.

Micro 3D printing

Micro parts printed from steel (Source: 3D MicroPrint)

Micro scale additive manufacturing, or micro 3D printing, can produce products with a resolution of a few microns (or less). There are three micro 3D printing methods to produce metal parts.

LMM (lithography-based metal fabrication) is a light-based technology that creates tiny parts from raw materials, including stainless steel, for applications such as surgical instruments and micro-mechanical parts.

Electrochemical deposition is the latest micrometal 3D printing process developed by the Swiss company Exaddon. In this process, the printing nozzle applies liquid with metal ions, creating details at the atomic level.

A third micrometal 3D printing method is microselective laser sintering, in which a layer of metal nanoparticle ink is applied to a substrate, then dried to produce a uniform layer of nanoparticles.

German researchers have successfully tested micro SLS printing of hollow microneedles using 316L stainless steel.

Metal parts from 3D Systems, Desktop Metal, MX3D and Materalise.

Are there any benefits to 3D printing metallic filament other than aesthetics?

I recently tore a piece off a radio controlled car that I have. Since I can't find a direct replacement at the moment, I modeled it and it seems to be easy to 3D print.

My biggest concern is how heat resistant the replacement will be - it's a combined structural/exhaust heat deflector.

I used to know about 30-40% steel-filled PLA, but looking at the reviews/reviews, everyone claims that steel/metal-filled PLA doesn't have any structural advantages.

Is there any advantage to this other than style? Heat resistance, conductivity, stiffness, toughness?

▲ 1

As far as I know, the only mechanical advantage of metal-containing filament is that it is the basis for printing metal parts on a filament printer.

This works similar to metal injection molding: the part is printed using filament containing the highest possible percentage of the chosen metal (usually stainless steel, bronze or copper), with an appropriate shrinkage factor applied to the dimensions; the plastic is then baked in a vacuum oven, followed by raising the temperature to the sintering temperature of the incorporated metal to fuse the metal particles into a solid part.

This allows parts to be produced with the same levels of accuracy as investment casting, but with shapes that would not be possible (eg hollow spaces that do not connect to the surface of the part) and materials (stainless steel). steel) that are difficult to cast, let alone investment casting.

Notably, in this case, the metallic inclusion does not affect the mechanical properties of part as printed on , but rather is the final part; the plastic only serves as a carrier, allowing metal to be delivered using a conventional 3D printer.

Jun 6 22 , @ Zeiss Ikon

▲ 1

The only advantage is the look (arguably the copper-filled filament I tried looks like copper colored plastic) and weight. It weighs more, so if your model needs weight, this is one way to achieve it, although there are other ways.

Personally, I think it's worse than normal thread because it's not really as strong.