Material for a gas turbine component, method for producing a gas turbine component and gas turbine component

Information

  • Patent Grant
  • 8888461
  • Patent Number
    8,888,461
  • Date Filed
    Saturday, October 18, 2008
    16 years ago
  • Date Issued
    Tuesday, November 18, 2014
    10 years ago
Abstract
A material for a gas turbine component, to be specific a titanium-aluminum-based alloy material, including at least titanium and aluminum. The material has a) in the range of room temperature, the β/B2-Ti phase, the α2-Ti3Al phase and the γ-TiAl phase with a proportion of the β/B2-Ti phase of at most 5% by volume, and b) in the range of the eutectoid temperature, the β/B2-Ti phase, the α2-Ti3Al phase and the γ-TiAl phase, with a proportion of the β/B2-Ti phase of at least 10% by volume.
Description

This application claims the priority of International Application No. PCT/DE2008/001702, filed Oct. 18, 2008, and German Patent Document No. 10 2007 051 499.0, filed Oct. 27, 2007, the disclosures of which are expressly incorporated by reference herein.


BACKGROUND AND SUMMARY OF THE INVENTION

The invention relates to a material for a gas turbine component. In addition, the invention relates to a method for producing a gas turbine component as well as a gas turbine component.


Modern gas turbines, in particular aircraft engines, must meet extremely high demands with regard to reliability, weight, power, economy and service life. In recent decades, aircraft engines that fully meet the requirements listed above and have achieved a high level of technical perfection have been developed, especially in the civilian sector. The choice of materials, the search for suitable new materials and novel production methods, among other things, have played a decisive role in the development of aircraft engines.


The most important materials used nowadays for aircraft engines or other gas turbines are titanium alloys, nickel alloys (also called superalloys) and high strength steels. High strength steels are used for shaft parts, gear parts, the compressor housing and the turbine housing. Titanium alloys are typical materials for compressor parts. Nickel alloys are suitable for the hot parts of the aircraft engine.


Precision casting and forging are the main production methods known from the prior art as production methods for gas turbine components made of titanium alloys, nickel alloy or other alloys. All highly stressed gas turbine components such as, for example, components for a compressor, are forged parts. However, components for a turbine are usually designed as precision cast parts.


Fabricating gas turbine components from titanium-aluminum-based alloy materials is already known from practice. In this case, γ-TiAl-based alloy materials are used in particular, wherein forging these types of γ-TiAl-based alloy materials is problematic. Forged parts from these types of materials must be produced in practice by isothermal forging or hot-die forging of preformed, such as, for example, extruded, semi-finished products. Isothermal forging as well as hot-die forging requires quasi-isothermal extruded primary material, resulting in high production costs.


As a result, there is a need for an adaptive forging method that uses a new material for producing gas turbine components. This method should guarantee an improved process reliability with reduced production costs.


From this starting point, the objective of the present invention is creating a novel material for a gas turbine component, a novel method for producing a gas turbine component as well as a novel gas turbine component.


According to the invention, the material has a) in the range of room temperature, the β/B2-Ti phase, the α2-Ti3Al phase and the γ-TiAl phase with a proportion of the β/B2-Ti phase of at most 5% by volume; b) in the range of the eutectoid temperature, has the β/B2-Ti phase, the α2-Ti3Al phase and the γ-TiAl phase with a proportion of the β/B2-Ti phase of at least 10% by volume.


The material according to the invention, which is a γ-TiAl-based alloy material, allows forging within a greater temperature range. A cast material can be used as the primary material for forging, making it possible to dispense with expensive extrusion material.


The method according to the invention for producing a gas turbine component is defined in the claims and the gas turbine component according to the invention is defined in the claims.


Preferred further developments of the invention are disclosed in the following description. Without being limited hereto, exemplary embodiments of the invention are explained in greater detail on the basis of the drawing.





BRIEF DESCRIPTION OF THE DRAWING


FIG. 1 is a very schematized representation of a blade of a gas turbine produced from a material according to the invention by a method according to the invention.





DETAILED DESCRIPTION OF THE DRAWING

The present invention relates to a new material for a gas turbine component, to be specific a material based on a titanium-aluminum alloy. The material according to the invention includes several phases both in the range of room temperature as well as in the range of the so-called eutectoid temperature.


In the range of room temperature, the TiAl-based alloy material according to the invention has the β/B2-Ti phase, the α2-Ti3Al phase and the γ-TiAl phase, wherein the proportion of the β/B2-Ti phase at room temperature is at most or a maximum of 5% by volume. In the range of the eutectoid temperature, the TiAl-based alloy material according to the invention has the β/B2-Ti phase, the α2-Ti3Al phase and the γ-TiAl phase, wherein the proportion of the β/B2-Ti phase in the range of the eutectoid temperature is at least or a minimum of 10% by volume.


The material according to the invention is consequently a γ-TiAl-based alloy material. The material can be formed with conventional forging methods, and namely at a forging temperature within a relatively large temperature range. The forging temperature of the material according to the invention lies preferably between Te-50 K and Ta+100 K, wherein Te is the eutectoid temperature of the material and Ta is the alpha transus temperature of the material.


If the forging temperature or the forming temperature is below Ta, as well as in the range of the forging temperature or forming temperature as well as in the range of the eutectoid temperature and the room temperature, the β/B2-Ti, α2Ti3Al and γ-TiAl phases are in thermodynamic equilibrium.


The proportion of the body-centered cubic β/B2-Ti phase in thermodynamic equilibrium of the material according to the invention is less than 5% by volume in the range of room temperature. In the range of the eutectoid temperature, the proportion of the body-centered cubic β/B2-Ti phase is greater than 10% by volume.


In addition to titanium and aluminum, the γ-TiAl-based alloy material also features niobium, molybdenum and/or manganese as well as boron and/or carbon and/or silicon.


The titanium-aluminum-based alloy material preferably has the following composition:


42 to 45 atomic percent aluminum,


3 to 8 atomic percent niobium,


0.2 to 3 atomic percent molybdenum and/or manganese,


0.1 to 1 atomic percent, preferably 0.1 to 0.5 atomic percent, boron and/or carbon and/or silicon,


in the remainder of titanium.


To produce a gas turbine component from the material according to the invention, the procedure in terms of the method according to the invention is that, first of all, a semi-finished product or primary material made of the material in accordance with the invention is made available. In terms of the semi-finished product, this can be a cost-effective, cast semi-finished product. It can also be provided that the semi-finished product is a primary shaped component.


Then, in terms of the method according to the invention, the semi-finished product is formed from the γ-TiAl-based alloy material according to the invention by forging, to be specific at a forming temperature or forging temperature that is between Te-50 K and Ta+100 K. In this case, forging is carried out at a forming rate of at least 1 m/s. In a preferred further development, the semi-finished product is coated with a thermal barrier prior to forging.


Following the forging, a heat treatment of the component being produced is preferably carried out.


Then, if, according to FIG. 1, a rotor blade 10 for a compressor of an aircraft engine is supposed to be produced as a gas turbine component, in the case of the method according to the invention, the preferred procedure is such that single forging is used in the region of a blade pan 11 for making a rougher microstructure with high creep resistance available and multiple forging is used in the region of a blade root 12 for making a finer microstructure with high ductility available, wherein a heat treatment preferably follows the single forging as well as the multiple forging.


Gas turbine components according to the invention are fabricated with the aid of the method according to the invention from the material according to the invention. The gas turbine components according to the invention are preferably compressor components, thus, for example, rotor blades of a compressor of an aircraft engine or turbine components.

Claims
  • 1. A material for a gas turbine component, comprising: titanium; andaluminum;wherein: a) the material has, in a range of room temperature, a β/B2-Ti phase, a α2-Ti3Al phase, and a γ-TiAl phase, with a proportion of the β/B2-Ti phase of at most 5% by volume;b) and the material has, in a range of eutectoid temperature, the β/B2-Ti phase, the α2-Ti3Al phase, and the γ-TiAl phase, with a proportion of the β/B2-Ti phase of at least 10% by volume.
  • 2. The material according to claim 1, wherein a proportion of a body-centered cubic β/B2-Ti phase in the range of room temperature is less than 5% by volume.
  • 3. The material according to claim 1, wherein a proportion of a body-centered cubic β/B2-Ti phase in the range of eutectoid temperature is greater than 10% by volume.
  • 4. The material according to claim 1, wherein the β/B2-Ti, the α2-Ti3Al, and the γ-TiAl phases are present in the range of room temperature.
  • 5. The material according to claim 1, wherein the β/B2-Ti, the α2Ti3Al, and the γ-TiAl phases are in thermodynamic equilibrium in the range of eutectoid temperature.
  • 6. The material according to claim 1, further comprising: niobium;molybdenum and/or manganese; andboron and/or carbon and/or silicon.
  • 7. The material according to claim 6, wherein the material has: 42 to 45 atomic percent aluminum;3 to 8 atomic percent niobium;0.2 to 3 atomic percent molybdenum and/or manganese;0.1 to 1 atomic percent boron and/or carbon and/or silicon; anda remainder of titanium.
  • 8. The material according to claim 1, wherein a forming temperature of the material lies between Te−50 K and Ta+100 K, wherein Te is the eutectoid temperature of the material and Ta is the alpha transus temperature of the material.
  • 9. A method for producing a gas turbine component, comprising the steps of: a) making available a semi-finished product from the material according to claim 1; andb) forging the semi-finished product from the material into a component at a forming temperature between Te−50 K and Ta+100 K, wherein Te is the eutectoid temperature of the material and Ta is the alpha transus temperature of the material.
  • 10. The method according to claim 9, wherein the forging is carried out at a forming rate of at least 1 m/s.
  • 11. The method according to claim 9, wherein a heat treatment is carried out following the forging.
  • 12. The method according to claim 9, wherein a cast semi-finished product is used as the semi-finished product.
  • 13. A gas turbine component made of the material according to claim 1 and produced by the method according to claim 9.
  • 14. The gas turbine component according to claim 13, wherein the component is a blade, which is singly forged in a region of a blade pan for making a rougher microstructure with high creep resistance available, and which is multiply forged in a region of a blade root for making a finer microstructure with high ductility available.
Priority Claims (1)
Number Date Country Kind
10 2007 051 499 Oct 2007 DE national
PCT Information
Filing Document Filing Date Country Kind 371c Date
PCT/DE2008/001702 10/18/2008 WO 00 4/21/2011
Publishing Document Publishing Date Country Kind
WO2009/052792 4/30/2009 WO A
US Referenced Citations (8)
Number Name Date Kind
5232661 Matsuo et al. Aug 1993 A
5431754 Fujiwara et al. Jul 1995 A
H1659 Semiatin et al. Jul 1997 H
6051084 Tetsui Apr 2000 A
6174387 Bellows et al. Jan 2001 B1
6294132 Tetsui Sep 2001 B1
20100015005 Oehring et al. Jan 2010 A1
20120263623 Oehring et al. Oct 2012 A1
Foreign Referenced Citations (2)
Number Date Country
10 2004 056 582 Jun 2006 DE
592 189 Apr 1994 EP
Non-Patent Literature Citations (4)
Entry
R.M. Imayev, et al, “Alloy design concepts for refined gamma titanium aluminide based alloys”, Intermetallics, Jan. 29, 2007, XP005924292, pp. 451-460.
Satoru Kobayashi, et al., “Microstructure Control Using β-Titanium Phase for Wrought Gamma TIAL Based Alloys”, Gamma Titanium Aluminides 2003, Proceedings of [A] Symposium Held During The TMS Annual Meeting, Mar. 2-6, 2003, pp. 165-175, XP009110846, Minerals, San Diego, CA, U.S.A.
Volker Guether, et al., “Microstructure and Corresponding Tensile Properties of As-Cast, β-Solidifying, γ-TIAL Based TNM alloys”, Structural Aluminides for Elevated Temperatures; Gamma Titanium and Other Metallic Aluminides, Proceedings of [A] Symposium Held During [The] TMS Annual Meeting & Exhibition, Mar. 9-13, 2008, pp. 249-256, XP009110850, New Orleans, LA, U.S.A.
R.M. Imaev, et al., “Refining of the Microstructure of Cast Intermetallic Alloy Ti—43% Al—X (Nb, Mo, B) With the Help of Heat Treatment”, Metal Science and Heat Treatment, 2006, pp. 81-84, vol. 48, Nos. 1-2, XP002510776.
Related Publications (1)
Number Date Country
20110189026 A1 Aug 2011 US