DE10150674B4 - Process for the production of heavy-duty components made of TiAl alloys - Google Patents

Abstract

Process for producing highly stressed components from α + γ-titanium aluminum alloys, in particular for aircraft engines or stationary gas turbines, wherein
Encapsulated TiAl blanks of globular structure are preformed by isothermal primary deformation in the α + γ or α-phase region in the temperature range from 1000 ° C to 1340 ° C or in the α-phase region in the temperature range from 1340 to 1360 ° C by forging or extrusion,
- The preforms formed by at least one isothermal secondary forming process with simultaneous dynamic recrystallization in the α + γ or α-phase region in the temperature range of 1000 ° C to 1340 ° C by forging to components predeterminable contour,
- To adjust the microstructure solution-annealed the components in the α-phase region, and
- then cooled quickly.

Description

The The invention relates to a process for producing highly resilient Components made of α + γ-TiAl alloys, in particular of components for Aero engines or stationary Gas turbines.

TiAl-based alloys belong to the group of intermetallic materials which have been developed for applications in the area of the superalloy application temperature. With a density of about 4g / cm ³ , this new alloy class offers considerable potential for weight reduction and associated reduction of stresses on moving components at temperatures above 700 ° C. This weight and voltage reduction also has an effect on blades and disks of gas turbines or, for example, components of piston engines. The difficulty of working TiAl alloys by forming processes is due to high yield stresses and low fracture toughness and ductility at low and medium temperatures. Forming processes must therefore be carried out at high temperatures in the region of the α + γ or α-phase region in a protective atmosphere.

Of the US 6,110,302 A α + γ titanium alloys can be seen. Among other things, turbine disks for aircraft engines are dealt with. Preferably used are alloys with about 70% titanium, wherein the forging temperature is between 815 and 885 ° C moves. The forged part, including a turbine disk, should have β + α-β regions of different microstructures. Practical investigations have shown that turbine disks produced by this process do not meet the actual requirements in the operating state, in particular with regard to the desired fatigue strength.

The US 5,593,282 A discloses a rotor usable in engines, which may preferably be formed from a lightweight structural material, in this example a temperature resistant ceramic material or, alternatively, TiAl or NiAl materials.

In the DE 43 18 424 C2 A process for the production of shaped articles from titanium-aluminum-based alloys is described. A cast blank with a lamellar structure with a lamella thickness of up to 1 μm is produced. This is deformed in the temperature range of 1050 to 1300 ° C with a high degree of deformation, so that a dynamic recrystallization takes place with particle sizes up to 5 microns. Subsequently, the blank is cooled and superplastic formed in the temperature range of 900 to 1100 ° C at forming speeds of 10 ^-4 to 10 ^-1 / s to close to near-net shape moldings. The mentioned very fine-grained microstructure is produced by the addition of silicon up to 0.3% by mass. However, this silicon content leads to undesirable side effects, such as increased porosity and the formation of silicides, whereby the required mechanical strength is greatly impaired. The fine-grained structure required for this superplastic forming is to be adjusted by extrusion, which does not lead to the finely crystalline equiaxial structure described elsewhere and required for superplastic forming. The extent to which mechanical high-strength components can actually be produced by this process remains open, since in practice it has not yet been established.

The in the prior art addressed manufacturing method, under for other things TiAl components, lead due to the Umformtechnischen conditions shown here in technical Regards not to the necessary quality characteristics as they are for dynamic / thermal heavy-duty components are required.

Out EP 0 965 412 B1 a method for producing a poppet valve made of γ-TiAl-based alloy is known. The starting materials used there are those having a very inhomogeneous particle size distribution and a comparatively coarse lamellar grain structure. The preparation of the disk valve is carried out by primary and secondary forming, wherein the primary deformation can be carried out preferably by extrusion but also by round rollers or circular hammers, while the secondary deformation is done exclusively by extrusion.

outgoing Of the disadvantages mentioned in the prior art is the Invention, the object of a method for producing leichtbauender and heavy-duty components for the conventional and aviation technology made of TiAl alloys to provide, with which over the prior art a improved fatigue strength, reliability and increased operating life realized can be.

• – gekapselte TiAl-Rohlinge globularen Gefüges durch isotherme Primärumformung im α + γ- oder α-Phasengebiet im Temperaturbereich von 1000°C bis 1340°C oder im α-Phasengebiet im Temperaturbereich von 1340 bis 1360°C durch Schmieden oder Strangpressen vorgeformt,
• – die Vorformlinge durch mindestens einen isothermen Sekundärumformprozess unter gleichzeitiger dynamischer Rekristallisation im α + γ- oder α-Phasengebiet im Temperaturbereich von 1000°C bis 1340°C durch Schmieden zu Bauteilen vorgebbarer Kontur ausgeformt,
• – zur Einstellung des Mikrogefüges die Bauteile im α-Phasengebiet lösungsgeglüht, und
• – anschließend schnell abgekühlt werden.

This object is achieved by a method for producing high-strength components from α + γ-TiAl alloys, in particular components for aircraft engines or stationary gas turbines, in which

• Encapsulated TiAl blanks of globular structure are preformed by isothermal primary deformation in the α + γ or α-phase region in the temperature range from 1000 ° C to 1340 ° C or in the α-phase region in the temperature range from 1340 to 1360 ° C by forging or extrusion,
• - the preforms by at least one isothermal secondary forming process with simultaneous dynamic recrystallization in the α + γ- or α-phase region in the temperature range of 1000 ° C to 1340 ° C formed by forging to components predeterminable contour,
• - To adjust the microstructure solution-annealed the components in the α-phase region, and
• - then cooled quickly.

advantageous Further developments of the method according to the invention can be found in the dependent claims.

Deviating from the prior art according to US 6,110,302 A and DE 43 18 424 C2 TiAl blanks are now repeatedly formed in temperature ranges above the temperatures specified therein and achieve microstructural properties that bring compared to the prior art, an increased operating life with it. In addition, the performance properties, in particular the fatigue strength, can be significantly improved.

To the Use is made of very homogeneous TiAl blanks with globular grain structure, in a corresponding way a primary as well as at least one adjoining it secondary transformation in the α + γ or α-phase region be subjected.

The primary shaping can be done by forging or extrusion. The secondary deformation takes place advantageously by forging.

The Forging blanks are used in both primary and secondary forming encapsulated, among which the expert, inter alia, a shaping Tool with upper and lower part can understand.

The suitable forging windows are characterized by a pronounced flow / stress maximum, which in contrast to the prior art according to DE 43 18 424 C2 (Process window of superplasticity) stands. Characteristic of the forming process according to the invention is the dynamic recrystallization, which is associated with the high yield stress. To provide the microstructure, the components are solution-annealed in the α-phase region and then rapidly cooled. This rapid cooling from the α-phase region then leads to the desired fine-lamellar microstructure. Typical cooling rates are in the range of 10 ° C / s.

Advantageously, blanks of the composition (in atomic%) are used to produce the lightweight high-strength components for conventional and aviation technology
43-47%, especially 45-47% Al
5-10% Nb
Max. 8.0% B
Max. 0.5% C
Remaining titanium and impurities caused by melting
used.

silicon is not included in these alloys, since silicon is known to be true to the desired Grain refining is, on the other hand, to the already mentioned undesirable Accompanying effects, such as porosity and silicide formation.

The isothermal transformation (primary and / or secondary forming) advantageously takes place in heated molybdenum or graphite tools.

The The following example describes a method for the production of rotor disks, can be used for Aircraft gas turbines, although other heavy duty components than for the conventional and air traffic engineering, such as components of internal combustion engines (e.g., valves).

For use comes a blank of the chemical composition (in atomic%)
46% Al
7.5% Nb
0.3% C
0.5% B
Rest Ti

The blank is subjected in a first step to an isothermal primary forming at an α + γ temperature of 1200 ° C. A flat track system is used to generate so-called pancakes. The isothermal primary deformation takes place at a deformation rate of 10 ^-4 / s. In a second isothermal forging process, the pancakes are forged in a shaping forging tool with upper and lower parts ready to slices. The isothermal secondary deformation takes place in this example at an α + γ temperature of 1150 ° C and a forming rate of 10 ^-3 / s instead.

to Setting the later Useful properties of the rotor disks thus produced become the same at an α-temperature of 1360 ° C solution annealed and then in oil with a Cooling rate of 10 ° C / s quickly cooled. The finishing is done conventionally and is not subject matter this invention.

The The following example shows a method for the production of turbine blades. can be used in stationary Gas turbines.

For use comes a blank of the composition (in atomic%)
45% Al
8% Nb
0.2% C
Rest Ti

Of the first forging process of a base material for α + γ-TiAl blanks in this Example take place in that in a forging with a disk-shaped Engrave the volume distribution for A larger number of blanks (here 10 pieces) in the α + γ phase region is carried out at about 1150 ° C. The separation of the blanks should in this example in the high temperature range a cutting tool brought about become. By this measure will be a cooling the blanks with subsequent resist heating for the subsequent forming process dispensable.

In a second isothermal forging process, the blanks are forged in a shaping forging tool with upper and lower parts to blades ready. This secondary transformation takes place in this example in the α + γ phase region at about 1150 ° C and a forming rate of 10 ³ s ^-1 instead.

to Setting the later Use properties of the turbine blades thus produced are the same at an α-temperature solution-annealed at 1360 ° C and then rapidly in oil cooled.

manufacturing processes other components differ from this example only in their geometric training.

The previously described alloy composition and the selected temperature ranges for the primary and secondary Isothermal transformation are only examples.

Claims (6)

Process for the production of highly stressed components of α + γ-titanium aluminum alloys, in particular for aircraft engines or stationary Gas turbines, where - encapsulated TiAl blanks of globular structure through isothermal primary forming in the α + γ or α-phase region in the temperature range from 1000 ° C to 1340 ° C or in the α-phase region in the temperature range of 1340 to 1360 ° C by forging or extrusion preformed - the Preforms by at least one isothermal secondary forming process with simultaneous dynamic recrystallization in the α + γ or α-phase region in the temperature range of 1000 ° C up to 1340 ° C formed by forging to components predeterminable contour, - for adjustment of the microstructure the components in the α-phase region solution annealed, and - then quickly chilled become. Method according to claim 1, characterized in that that the forming process in a particular heated tool, made of molybdenum or graphite becomes. Method according to claim 1 or 2, characterized that blanks of a Ti-Al base alloy of the composition (in atomic%) for the Primary- and secondary deformation be used: 43-47% al 5-10% Nb Max. 1.0% B Max. 0.5% C Rest of titanium and melting Impurities. Method according to one of claims 1 to 3, characterized that the forming and solution annealing process in an inert atmosphere takes place. Method according to one of the preceding claims, characterized characterized in that the cooling with 10-20 ° C / s in oil. Component of α + γ titanium aluminum alloy, especially for an aircraft engine or a stationary gas turbine manufactured according to any one of the preceding claims.