All About Titanium

Classes and Grades

There are three classes of titanium&#;alpha-alloys, beta-alloys, and alpha-beta alloys&#;and various titanium-alloy grades that fall under these classes. Although there are around fifty different titanium alloy grades, ASTM International recognizes only 31 titanium metal and alloys in total, only four of which are actually pure. Each alloy type has different properties that make it more suitable for particular applications. 

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The list below describes the titanium classes and the grades that fall under them, along with their composition, features, and applications.

Alpha (α) Titanium

This class covers pure titanium and titanium alloys that are stabilized with elements like aluminum. They are super strong and ductile (although less so than other classes), formable, lightweight, corrosion resistant, and have high-temperature stability. Of the alpha class, Xometry offers Grade 2 titanium parts via CNC machining or sheet cutting.

Grade 1 pure titanium

• Composition: 99% titanium, 0.2% iron, 0.18% oxygen, and trace amounts of other elements such as nitrogen, carbon, and hydrogen
• Features: The softest, most ductile, and most formable of all the grades
• Applications: Plating, piping, tubing, automotive, power generation, aerospace

Grade 2 pure titanium

• Composition: 99% titanium, 0.3% iron, 0.25% oxygen, and trace amounts of other elements
• Features: Slightly stronger than Grade 1, more affordable than other grades as it&#;s more widely used and so produced in larger volumes
• Applications: Welding, anodizing, lining material, power generation, petroleum

Grade 3 pure titanium

• Composition: 99.2&#;99.7% titanium, with a maximum of 0.30% iron, 0.35% oxygen, 0.08% carbon, 0.05% nitrogen, and 0.015% hydrogen
• Features: Least commonly used pure titanium grade, stronger than Grades 1 and 2 but less ductile and formable
• Applications: Anodizing, cryogenic vessels, condenser tubing, pressure vessels, heat exchangers, piping systems, marine, chemical processing (pipes, flanges, tubing, tanks, pumps, heat exchangers)

Grade 4 pure titanium

• Composition: 98.9&#;99.5% titanium, with up to 0.50% iron, 0.40% oxygen, 0.08% carbon, 0.05% nitrogen, and 0.015% hydrogen
• Features: Strongest of all Alpha titanium alloys (comparable to stainless and low-carbon steel)
• Applications: Marine components (i.e., airframe structures and heat exchangers), industrial equipment (tanks, reactors, valves, pipes, connecting rods, pumps), surgical implants, aerospace, chemical processing, oil & gas

Beta (β) Titanium

The beta class includes titanium alloys that are stabilized with elements like vanadium or molybdenum. These, too, are corrosion-resistant, workable, and have a high strength-to-weight ratio. They also have better ductility and formability than alphas. 

Grade 7

• Composition: 99% titanium, 0.12-0.25% palladium, 0.3% iron, 0.25% oxygen, and other elements
• Features: Highest corrosion resistance of all titanium alloys, can withstand harsh environments, nearly identical to Grade 2
• Applications: Welding, forming, desalination, chemical manufacturing

Grade 11

• Composition: 99.75% titanium, and 0.25% palladium
• Features: Corrosion resistance (particularly in acidic environments), similar to Grades 1 and 2, crevice corrosion resistance, highly ductile, impact toughness
• Applications: Welding, chemical processing and storage, ducts, pumps, and heat exchangers

Grade 12 (Ti-0.3Mo-0.8Ni)

• Composition: 99% titanium, 0.6-0.9% nickel, 0.2-0.4% molybdenum, up to 0.3% iron, up to 0.25% oxygen, and other elements
• Features: Strong, corrosion resistant (particularly in reducing acids), durable, thermally stable
• Applications: Welding, forming, marine components (ships, offshore drilling platforms), chemical manufacturing, and heat exchangers

Alpha-Beta (α-β) Titanium

These alloys combine features of both alpha and beta types. They&#;re strong, ductile, corrosion resistant, and can withstand high temperatures. Of these, Xometry regularly provides quotes on CNC or sheet cut parts made of Grade 5 titanium.

Grade 5 (Ti-6Al-4V)

• Composition: 88-90% titanium, 5.5-6.75% aluminum, 3.5-4.5% vanadium, and trace amounts of other elements (iron, oxygen, carbon, and hydrogen)
• Features: The most commonly used titanium alloy (accounts for half of all the titanium used in the world), high strength, good ductility, heat resistant, can be heat treated, formabile, corrosion resistant
• Applications: Engines and structural components in aerospace (landing gear, firewalls, hydraulic systems, etc.), automotive parts (engine parts, crankshafts, valve seats, connecting rods, exhausts, suspension, frames, springs), medical (i.e., joint implants), sporting goods, consumer products, 3D printing

Grade 6 (Ti-5Al-2.5Sn)

• Composition: 92% titanium, 5% aluminum, 2.5% tin, and 0.5% iron
• Features: Strength, ductility, creep resistance, temperature stability, suitable for higher service temperatures of 900°F
• Applications: Casings/rings in turbine engines, structural members/frames in aerospace, and chemical processing parts

Grade 23 (Ti-6Al-4V ELI)

• Composition: 88-90% titanium, 5.5-6.5% aluminum, 3.5-4.5% vanadium, 0.25% iron, 0.13% oxygen, and other elements
• Features: Similar to Grade 5 but more pure, ductile, and tough, has high tensile and yield strength, high weldability
• Applications: Aerospace, dental (tooth implants), medical (implants, bone and joint replacements, surgical staples, ligature clips

Grade of Titanium Used for 3D Printing

Grade 5 (Ti 6Al-4V) titanium is the one used for 3D printing. Grade 5 is best for 3D printing because of its high strength, excellent formability, and thermal stability. Powder bed fusion 3D printing methods like selective laser melting, electron beam melting, and direct metal laser sintering are used to 3D print titanium. These processes consist of selectively melting titanium powder that has been precisely laid onto a print bed. A powerful laser or electron beam melts the titanium powder and fuses it with the preceding layers of printed material to build completed parts.

Limitations

Despite raving about all of titanium&#;s perks, it&#;s worth having a look at a few things this metal is not so good at. For starters, it can be reactive at high temperatures of over 700°F&#;something that makes the fabrication rather tedious and highly controlled. Production of titanium has to be in a carefully controlled and oxygen-free environment. 

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While its low thermal conductivity does have its benefits, it can lead to the heat generated during manufacturing to build up in the tool rather than the material&#;not great news for the tool&#;s lifespan and quality. In addition, at temperatures above 570°F, titanium has low creep resistance (the slow deformation of a material when constantly under heavy loads). Finally, refining raw rocks and minerals to get pure titanium is not a cheap, easy, or quick endeavor.

Titanium Applications

Titanium is used in everything from condensers in power plants and desalination plants to consumer goods like golf clubs and bicycle frames. Our aerospace and automotive customers heavily rely on titanium, as it often finds itself useful in their projects. 

In aerospace, it accounts for nearly 50% of an aircraft&#;s total weight and it's so valuable in the industry that it&#;s even sometimes referred to as &#;aerospace metal.&#; For automakers, titanium&#;s characteristics can create parts with better aerodynamics and performance. Its low density and high strength also make it a more cost-effective manufacturing process since less material is needed.

We&#;ve already covered the titanium grades most commonly used in different industries above (such as industrial, chemical processing, and marine), but here are a few more ways titanium is widely being used around the world today. 

• Jewelry: Used to make piercings, watches, necklaces, rings, and other jewelry items. Sometimes mixed with gold to make 24-karat gold alloys which are harder and more durable than pure gold alternatives. Its biocompatibility also makes titanium a popular go-to for people allergic to other metals, like nickel.
• Medical: Used in surgical and dental tools, implants, joint replacements, and osseointegration for better patient outcomes and implants/prosthetics that can last up to 30 years.
• Architectural: While steel is still the preferred metal for building frames, titanium is often used for glass frames, facades, roofs, interior wall surfaces, and ceilings thanks to its corrosion resistance and high strength-to-weight ratio.
• Composites: Titanium-based composites are recently developed materials used to make titanium fiber-reinforced or powder-reinforced composites. These have higher stiffness, wear resistance, and strength than conventional alloys. Although fairly new, titanium composites are starting to make their way to the aerospace and automotive industries.
• 3D Printing: Grade 5 titanium is used in 3D printing with powder bed fusion 3D printing methods, like direct metal laser sintering (a service we offer here at Xometry), selective laser melting, and electron beam melting. To build strong 3D printed parts, titanium powder is laid onto the printer&#;s bed and then the machine&#;s laser/electron beam fuses the particles together in cross sections of the parts design, layer by layer.

Why Laser Etching? The power of laser etching has been grossly underestimated in the manufacturing industry. A lot of manufacturers get stuck in traditional etching&#;

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