There are several metal 3D printing technologies for processing titanium-based alloys, but laser powder bed fusion (LPBF) using powdered titanium is the most common. LPBF is also known as selective laser melting (SLM), direct metal laser sintering (DMLS), direct metal laser melting (DMLM), laser metal fusion (LMF), laser cusing, and others.

The next most used technology would be binder jetting then electron beam melting (EBM). It’s also possible to use a metal resin technology called lithography-based metal manufacturing (LMM) for small and micro-scale parts while on the opposite end of the spectrum, size wise, there’s Cold Fusion and Rapid Plasma Deposition (RPD) for large-scale parts, such as for industrial machinery and defence applications. It is possible to use FDM or extrusion 3D printing with polymer filament infused with titanium powder, but it’s not common.

Titanium filament for extruder-based fused deposition modeling (FDM) is available from a few companies, including Virtual Foundry. This material contains metal powder embedded in PLA and can be printed using FDM printers with extruder temperatures above 205 °C. Once post-processed and sintered, these filaments can produce metal parts that are more than 90% metal, making them suitable for prototypes. If you’re looking for metal filament, watch out for the ones called titanium referring only to their gray color.

3D Printing Technology Guide

Complete Overview of the Types of 3D Printers

“The majority of titanium AM parts are built with powder bed technologies,” according to a report by the consultancy Ampower. “While powder bed fusion is used to produce light-weight components for aviation and racing as well as medical implants, binder jetting is typically used to produce smaller medical instruments from titanium.”

Laser powder bed fusion (LPBF) is a manufacturing technology that uses powdered metal fused by a high-power laser. LPBF produces a part by adding a layer of material to a previous one. Based on the properties of the titanium-based alloy to be processed, the LPBF processing parameters must be optimized and tuned to control porosity, microstructure, and final material properties.

Electron beam powder bed fusion (EB PBF), also called electron beam melting (EBM), is a similar process but uses a higher-power electron beam instead of a laser. The high process temperature of the electron beam results in slower cooling of the single layers and therefore coarser microstructure compared to LPBF, according to Ampower. This characteristic is an advantage for many medical implants.

In both powder bed fusion processes, the metal 3D printers start to work from a metal powdered bed, which is selectively scanned. All the geometrical information is given to the printing system from a CAD model previously defined in a 3D modeling software. The powdered material is mainly characterized by features like particle morphology (irregular or spherical) and particle size distribution. Spherical morphology is desired to allow a good flowability of the powder once the printing process is ongoing. The process from which the powder is created determines its final features. Metal powders can be manufactured by gas atomization, rotary atomization, plasma rotating electrode process, and water atomization. The bottom line is that quality powder will produce quality parts.

Titanium 3D Printers

Not every metal 3D printer can print with titanium, yet the current market of 3D printing systems offers a wide variety of metal 3D printers for processing different titanium-based alloys.

Laser Powder Bed Fusion (LPBF) Printers with Titanium Capabilities

• 3D Systems offers three types of titanium material compatible with several of its PBF 3D printers.
• EOS offers five titanium material options that work on its four metal powder bed fusion 3D printers.
• Colibrium Additive offers titanium and titanium alloys for its M2 Series 5 line of 3D printers.
• Nikon SLM Solutions provides three titanium alloys for its range of 3D printers.
• Velo3D has a titanium solution for its Sapphire family of 3D printers.
• Trumpf’s laser metal fusion 3D printer is designed for titanium part production.
• Renishaw metal 3D printers are popular for producing titanium parts in the medical and dental fields.
• AddUp’s FormUp350 laser metal fusion 3D printer is compatible with titanium.

Metal Binder Jetting Printers with Titanium Capabilities

• Markforged offers one titanium alloy on its PX100 binder jetting 3D printer.
• Desktop Metal offers titanium on its Production System P-50 printer and its X-Series of printers. In 2024, the company launched a “Reactive Safety Kit” for its Production System P-1 3D printer. The kit is required for manufacturing titanium and aluminium.

Electron Beam Melting (EBM) Printers with Titanium Capabilities

• Colibrium Additive offers titanium and titanium alloys for its EBM 3D printers.

Cold Fusion Printers with Titanium Capabilities

• Spee3D announced in 2022 that it now has the capability to 3D print with titanium.

Fused Deposition Modeling (FDM) & Extrusion Printers with Titanium Capabilities

• Desktop Metal offers a proprietary filament filled with titanium alloy for its extrusion Bound Metal Deposition technology.
• Meld Manufacturing is a unique solid-state technology specializing in larger parts.

Pure titanium is not typically used in engineering applications while it is common in the biomedical market for parts, such as knee and hip implants. Titanium-based alloys – controlled mixes of metal constituents that provide specific mechanical properties – are used in a wide range of industries that need to achieve very specific part properties. Metal material suppliers, who have long supplied manufacturers with titanium for casting, are now offering titanium powders formulated specifically for additive manufacturing.

Titaniums for Additive Manufacturing

• Titanium 6Al-4V, grade 5 is the most commonly used in titanium alloy in additive manufacturing and it is ideal for prototypes and functional parts in the aerospace and automotive fields and for military applications. It is also an excellent material for the manufacture of parts with complex geometries and precisions, and production tooling.
• Titanium 6Al-4V, grade 23 is a biocompatible alloy commonly used for medical implants and prostheses.
• Titanium Beta 21S exhibits a higher strength than conventional titanium alloys such as Ti-6Al-4V and has superior oxidation resistance and creep resistance compared to conventional titanium alloys such as Ti-15V-3Cr. Grade 21 Titanium has one of the lowest hydrogen uptake efficiency levels of any titanium alloy. It is an ideal candidate for orthopedic implants and aerospace engine applications. Beta titanium is widely use in orthodontics.
• Cp-Ti (Pure Titanium), grade 1, 2 are extensively used in the medical field for a wide range of applications due to the biocompatibility of titanium with the human body.
• TA15 is a near-alpha titanium-alloy with additives of aluminum and zirconium. The high specific strength of components made of TA15 combined with their high load-bearing capacity and temperature resistance enable them to be used for heavy-duty components in aircraft and engine construction.

Material Primer

Metal Powder for Metal 3D Printing – Buyer’s Guide

Titanium Suppliers

There’s a wide range of titanium and titanium alloys specially formulated for 3D printing in a range of particle sizes and purities from material manufacturers, including:

• Carpenter Technology: TI 6AL-4V ELI
• IperionX: recycled Ti
• 6K Additive: Ti6Al4V
• Sandvik: Osprey TI-6AL-4V Gr.5 and Gr.23
• GKN: CPTi – Gr.1 and Gr.2, Ti64 – Gr. 5 and Gr. 23, Ti6242, Ti5553, Beta 21S
• AP&C (a Colibrium Additive company): CPTi – Gr.1 and Gr.2, Ti-6AI-4V Gr.5 and Gr.23, Ti-6Al-2Sn-4Zr-2Mo, Ti-5Al-5V-5Mo-3Cr
  
• AstroAlloys: TruForm Ti-6Al-4V Gr.5 and Gr.23, Ti-48Al-2Nb-2Cr, Ti-6Al-2Sn-4Zr-2Mo
• Tekna: Ti64 & Ti64 coarse powders
• PyroGenesis Additive: CPTi – Gr.1, Ti-6AI-4V Gr.5 and Gr.23

If purchasing your own metal printer for titanium parts isn’t feasible, there’s a wide range of third-party 3D printing services available. Be sure to inquire which alloy they offer, because pure titanium may need to be specially ordered.

At 3D printing service Craftcloud, you can upload your digital file, select titanium, and receive instant quotes from manufacturing partners. You select the parter you want to work with. Several printer manufacturers, including 3D Systems and EOS, plus material manufacturers, such as Sandvik, offer titanium print-on-demand services.

Accessible Titanium

6 Trusted Providers for Titanium 3D Printing Services

Custom Titanium Implants & Surgical Guides

As 3D printed titanium rapidly gains regulatory approval for custom implants, traditional medical device manufacturers and specialized 3D printing companies, including Zenith Tecnica, 4Web Medical, Camber Spine, Amnovis, and Nexxt Spine, are increasing their titanium manufacturing with 3D printing.

Amnovis, a Belgium-based 3D printed titanium implant manufacturer, recently said it has delivered more than 50,000 titanium implants since 2021.

The ProMade PoC Center for Complex Orthopedic Solutions made news recently as the first point-of-care center for complex cases operated by a medical device company on hospital grounds. LimaCorporate, an Italian company specializing in the design and 3D printing of complex orthopedic solutions, partnered with New York’s Hospital for Special Surgery (HSS) to bring clinical care and biomechanical engineering expertise to one location.

In early 2024, Armadillo Additive, a contract manufacturer based in Granbury, Texas, launched its new advanced metal 3D printing facility targeting precision engineering for the medical device sector. The company will specialise in Ti-6Al-4V Grade 23 titanium products.

The number of US FDA-approved titanium-based 3D printed surgical implants continues to grow as medical manufacturers increasingly adopt additive manufacturing in their production capabilities.

In the medical industry, 3D printed titanium implants are successful across spine, hip, knee, and extremity applications due to the metal’s inherent biocompatibility and good mechanical properties combined with 3D printing’s ability to tailor porous structures — which enable bone integration — and mass customization for better patient outcomes.

3D printed titanium implants are gaining in both regulatory approval and demand. Because most medical implants are manufactured to cover large groups of people with the same condition, they aren’t an ideal fit for everyone. People suffering from rare conditions are often left out. Now, with 3D printing, it is possible to produce implants designed exclusively for individual patients.

The New York-based Hospital for Special Surgery (HSS) reported earlier this year that it is 3D printing custom-made titanium joint replacements for highly complex cases where a standard implant wouldn’t work. HSS was the first hospital in the US to house an 3D printing facility.

In 2023, a surgeon in England performed four wrist surgeries in the same day to correct a deformity of previously broken wrist bones with patient-specific 3D printed titanium plates. “Once this planning process has occurred, the bespoke plate is printed using powdered titanium, then tested, shipped to the UK and sterilized at County hospital ready for surgery,” says Dr. Akshay Malhotra, Consultant Orthopedic Surgeon and Clinical Lead for Hand and Wrist Surgery at University Hospitals of North Midlands.

Presented with a cancer patient whose tumor was destroying his ribcage, doctors at Manipal Hospitals in India turned to 3D printed titanium in 2022. Generally, implants of this magnitude are far too heavy for the human body to bear, but due to titanium’s lightweight and high strength, a patient-specific replacement could be 3D printed that weighed less than 250 grams. Thanks to the success of the 3D printed implant, the patient fully recovered and was able to return to a normal life without dependence on external machines to help him breathe.

In a trail of ankle bone replacement surgery using patient-specific 3D printed titanium talas bones, patients reported positive outcomes. The bone replacement meant patients did not need to have a full ankle joint replacement. Talus bones are very patient specific anatomical features requiring a uniquely designed 3D part based on the patient’s CT scan data.

There have been significant US FDA approvals for 3D printed titanium implants in 2023, mostly covering spinal implants.

• Restor3d receives approval in 2023 for the first all-metal (titanium) 3D printed patient-specific instrument in ankle arthroplasty.
• SurGenTec receives clearance in 2023 for its posterior 3D printed titanium sacroiliac joint fusion system, TiLink-P.
• FloSpine receives FDA approval in 2023 for a 3D printed implant used to support the spine called the Tri-Largo Cervical Interbody Cage System.
• Eminent Spine receives FDA approval in 2023 for its 3D Cervical Interbody Fusion System of 3D printed titanium configurations.
• ChoiceSpine receives FDA approval in 2023 for its Blackhawk Ti 3D Printed Cervical Spacer System in titanium.
• CoreLink receives FDA approval in 2023 for its Siber Ti Sacroiliac Joint Fusion System of porous, nano-surfaced, 3D printed titanium implants.

In the aerospace industry, several titanium-based additively manufactured parts are currently in commercial and military use, with numerous other prototypes making their way toward FAA certification. 3D printed titanium is prized for its low “buy-to-fly” ratio — an aerospace term that refers to the correlation between the weight of the initial material and the printed part’s weight.

Several contract manufacturers specializing in the aerospace, defense, and space markets, such as Primus Aerospace, StarHagen Aerospace, and Zeda, have invested in 3D printers capable of producing titanium components for both prototyping and final parts.

3D printed titanium is almost common in high performance bicycles today where every ounce of weight counts and high-strength is paramount. Used in cranks, break handles, stems, derailleur hangers, and even full frames, titanium is proving as strong as aluminum and as light as carbon fiber, without carbon fibers’ sustainability challenges.

Recently cycle maker Ribble launched its Allroad Ti featuring a 3D printed frame the company says “allows us to handcraft titanium tubes that are significantly more advanced in terms of aerodynamic performance than the standard round tubes found on typical titanium frames.” 3D printing also enabled Ribble to eliminate welds, enable invisible cable routing, and consolidate parts.

New York-based No. 22 Bicycle Company, which has specialized in titanium bikes for years, debuted in August, the Reactor Aero, which integrates several of 3D printed titanium components and will officially launch in 2025. In a press release, Bryce Gracey, a co-founder of No.22 said, “3D printed titanium has phenomenal structural properties. The ability to print internal support structures anywhere in the frame gives us a level of control over the ride quality that has not been possible before.”

Speaking of full frames, bicycle manufacturer Angel Cycle Works 3D prints a full titanium frame in one lightweight piece, which takes critical seconds of race times and enables new design geometry, the company says. Its new hyperbike, called Heaven, is 400g lighter than previous versions. Another full titanium frame is from Pilot launched this year called the Pilot Seiren. This road bike features a frame that’s entirely 3D printed (in three parts) from titanium. The company says 3D printed titanium enables it to custom fit bikes to riders’ preferences and the frames do not need any paint or coating.

Carbon Wasp detailed why it abandoned aluminum and carbon fiber and turned to 3D printed titanium for its newest aftermarket crank arm: “We came up with all sorts of creative ways to clamp the cranks on to the gearbox axle without pinching the carbon fiber but always needed to include some metal inserts … , but had no end of issues with bonding the insets to the carbon.” After some prototyping, Carbon Wasp found that 3D printed lattice-filled titanium cranks were as light as carbon but more robust in an area that is very exposed to impacts.”We still think carbon fiber is the best material for many other uses, including frames, … but we are already working on other titanium parts.”

“The printing process facilitates thinner wall thicknesses, leading to a lighter and stronger frame without stress points,” Pilot’s Tim Blankers told Road.cc cycling website. “The frame weight is just above a kilogram. Pilot can also add material in places where stiffness is desired to optimize power transmission.”

Chinese bike maker Hanglun says it is ramping up it titanium 3D printing in 2024. “We plan to use 3D printing technology to produce titanium bicycle frames and parts with an annual output of more than 50,000 pieces,” the company said. The parts will be applied to a variety of models of bicycles, aiming to provide customers with higher strength, lighter and more durable titanium bicycle products.

There are plenty of 3D printed titanium components on the market for cycling:

• Silca revealed its newest line of 3D printed products earlier this year including a series of titanium derailleur hangers.
• Verve Cycling and Metron Additive Manufacturing launched it’s 3D printed titanium crank called the InfoCrank 3D Ti.
• Moots launched new 3D printed titanium drop-outs and accessories for its new Routt CRD gravel bike.
• Cane Creek launched new titanium 3D printed Electric Wings cranks that are as lightweight as a carbon crankset, but as durable as an aluminium one, the company says.

Designer, a Japanese golf brand, launched a 3D printed titanium golf club earlier this year it says offers golfers increased distance, accuracy, stability, and greater forgiveness. The titanium club head is manufactured using a dual-laser powder bed fusion 3D printer from Farsoon Technologies.

Turning to 3D printed titanium for a completely different reason, semiconductor manufacturer ASML now has its titanium carrier tray preforms (used for wafer production) 3D printed instead of forged, which saves 64% in raw materials and is delivered faster. Norsk Titanium, a metal additive manufacturing company used directed energy deposition (DED) platform, Norsk is printing 80-kilogram (about 176 pounds) near-net-shape preforms — used for semiconductor wafer production — out of Ti64.

Norsk worked with Dutch partner Hittech Group to develop the preform, which, according to Norsk, is used in ASML’s lithography system. ASML, also based in the Netherlands, has been one of the world’s most frequently discussed companies in the context of the chip shortages over the last few years. Specifically, ASML is most well-known for producing the world’s only extreme ultraviolet (EUV) photolithography machines.

Even the US Navy is turning to 3D printed titanium to save time and money and eliminate dependence on a foreign supply chain. Having no domestic capacity to manufacture the large titanium castings required for high-performance centrifugal pumps, the Navy is plagued with long lead times and a supply chain that exploits high-cost and carbon-intensive titanium raw materials. But soon, with new domestic partners IperionX for recycled titanium powders and Carver Pump for additive manufacturing, the Navy will gain the capability to significantly reduce lead times for critical parts, increase equipment availability, and sustainably re-shore a critical US titanium metal supply chain.

3D printing can create very thin-walled, intricate, and complex titanium parts, which is why it’s used for watch cases, such as the Panerai and Holthinrichs timepieces (pictured above).

In 2023, smartphone maker Honor introduced the new folding Magic V2 featuring a 3D printed titanium hinge shift cover that’s lighter than the previous aluminum version and 150% stronger. The company says this this small titanium piece, which can be 3D printed in the tens of thousands, is the key to the product’s durable and smooth folding and unfolding.