Titanium aluminide

Titanium aluminide, Ti Al, commonly gamma titanium, is an intermetallic chemical compound. It is lightweight and resistant to oxidation ^[1] and heat, but has low ductility. The density of γ-TiAl is about 4.0 g/cm³. It finds use in several applications including aircraft, jet engines, sporting equipment and automobiles.^{[citation needed]} The development of TiAl based alloys began circa 1970. The alloys have been used in these applications only since about 2000.

Titanium aluminide has three major intermetallic compounds: gamma TiAl, alpha 2-Ti₃Al and TiAl₃. Among the three, gamma TiAl has received the most interest and applications.

Applications of gamma-TiAl[]

Pole figures displaying crystallographic texture of gamma-TiAl in a rolled sheet of alpha2-gamma alloy, as measured by high energy X-rays.^[2]

Gamma TiAl has excellent mechanical properties and oxidation and corrosion resistance at elevated temperatures (over 600 °C), which makes it a possible replacement for traditional Ni based superalloy components in aircraft turbine engines.

TiAl-based alloys have potential to increase the thrust-to-weight ratio in aircraft engines. This is especially the case with the engine's low-pressure turbine blades and the high-pressure compressor blades. These are traditionally made of Ni-based superalloy, which is nearly twice as dense as TiAl-based alloys. Some gamma titanium aluminide alloys retain strength and oxidation resistance to 1000 °C, which is 400 °C higher than the operating temperature limit of conventional titanium alloys.^{[not specific enough to verify]}^[3]

General Electric uses gamma TiAl for the low-pressure turbine blades on its GEnx engine, which powers the Boeing 787 and Boeing 747-8 aircraft. This was the first large-scale use of this material on a commercial jet engine^[4] when it entered service in 2011.^[5] The TiAl LPT blades are cast by Precision Castparts Corp. and Avio s.p.a.. Machining of the Stage 6, and Stage 7 LPT blades is performed by Moeller Manufacturing.^[6]^{[citation needed]} An alternate pathway for production of the gamma TiAl blades for the GEnx and GE9x engines using additive manufacturing is being explored.^[7]

In 2019 a new 55 g lightweight version of the Omega Seamaster wristwatch was made, using gamma titanium aluminide for the case, backcase and crown, and a titanium dial and mechanism in Ti 6/4 (grade 5). The retail price of this watch at £37,240 was nine times that of the basic Seamaster and comparable to the top of the range platinum-cased version with a moonphase complication.^[8]

Alpha 2-Ti₃Al[]

TiAl₃[]

References[]

^ Voskoboinikov, R.E.; Lumpkin, G.R.; Middleburgh, S.C. (2013). "Preferential formation of Al self-interstitial defects in γ-TiAl under irradiation". . 32: 230–232. doi:10.1016/j.intermet.2012.07.026.
^ Liss KD, Bartels A, Schreyer A, Clemens H (2003). "High energy X-rays: A tool for advanced bulk investigations in materials science and physics". 35 (3/4): 219–52. doi:10.1080/07303300310001634952.
^ "Processing and Characterization of TiAl-based Alloys : Towards an Industrial Scale". Cite journal requires |journal= (help)
^ Bewlay BP, Nag S, Suzuki A, Weimer MJ (2016). "TiAl alloys in commercial aircraft engines". . 33 (4–5): 549–559. doi:10.1080/09603409.2016.1183068. S2CID 138071925.
^ "GE Aviation Rolls Out its 1,000th GEnx Engine". AviationPros. 21 October 2015. Retrieved 10 August 2017.
^ Moeller Manufacturing, Aerospace Division, in Wixom, Michigan, USA
^ Heidi Milkert (18 August 2014). "GE Uses Breakthrough New Electron Gun For 3D Printing – 10X's More Powerful Than Laser Sintering". 3D Print.com.
^ Tim Barber (31 August 2019). "The new Omega Seamaster Aqua Terra is made of titanium and weighs just 55g". Wired.

External links[]

Machining Gamma Titanium Aluminide Components - Moeller Manufacturing
Titanium Aluminide Applications in the HighSpeed Civil Transport
Titanium Aluminides - Intermetallics on azom.com.
Power House (GEnx TiAl LPT Blade Announcement)
Edward A. Loria (2001). "Quo vadis gamma titanium aluminide". Intermetallics. 9 (12): 997–1001. doi:10.1016/S0966-9795(01)00064-4.
Donachie, Matthew J (2000). Titanium: a technical guide. p. 131. ISBN 978-0-87170-686-7.
Kassner, Michael E; Pérez-Prado, María-Teresa (2004). Fundamentals of creep in metals and alloys. p. 175. ISBN 978-0-08-043637-1.

[1] Voskoboinikov, R.E.; Lumpkin, G.R.; Middleburgh, S.C. (2013). "Preferential formation of Al self-interstitial defects in γ-TiAl under irradiation". . 32: 230–232. doi:10.1016/j.intermet.2012.07.026.

[Liss-2] Liss KD, Bartels A, Schreyer A, Clemens H (2003). "High energy X-rays: A tool for advanced bulk investigations in materials science and physics". 35 (3/4): 219–52. doi:10.1080/07303300310001634952.

[3] "Processing and Characterization of TiAl-based Alloys : Towards an Industrial Scale". Cite journal requires |journal= (help)

[4] Bewlay BP, Nag S, Suzuki A, Weimer MJ (2016). "TiAl alloys in commercial aircraft engines". . 33 (4–5): 549–559. doi:10.1080/09603409.2016.1183068. S2CID 138071925.

[5] "GE Aviation Rolls Out its 1,000th GEnx Engine". AviationPros. 21 October 2015. Retrieved 10 August 2017.

[6] Moeller Manufacturing, Aerospace Division, in Wixom, Michigan, USA

[7] Heidi Milkert (18 August 2014). "GE Uses Breakthrough New Electron Gun For 3D Printing – 10X's More Powerful Than Laser Sintering". 3D Print.com.

[8] Tim Barber (31 August 2019). "The new Omega Seamaster Aqua Terra is made of titanium and weighs just 55g". Wired.

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