WO2010052052A1 - Rotor for a turbomachine - Google Patents

Abstract

The invention relates to a rotor (2, 14) for a turbomachine, having a shaft (4, 16) and rotational elements arranged thereon, which are produced at least partially from steel. It is proposed that at least one of the rotational elements is produced at least partially from a steel having a light metal content of at least 20%. A rotor (2, 14) is produced having a lightweight and resistant rotational element.

Description

description

Rotor for a turbomachine

The invention relates to a rotor for a turbomachine with a shaft and rotational elements arranged thereon, which are at least predominantly made of steel.

In a turbomachine, such as a gas turbine, a steam turbine, an axial compressor or a centrifugal compressor rotates a large rotor with high speed, so that significant centrifugal forces act on rotational elements of the rotor. In the development of new turbomachinery, therefore, the selection of materials and the search for new suitable materials that can cope with the stresses associated with the centrifugal forces play an important role. Especially with the use of steam turbines, large-length blades are an effective means for improving the thermal efficiency of the steam turbine. Therefore, the trend is towards ever longer low pressure blades of the last stage. Such blades require a material of high strength and high toughness.

The longer the rotating elements, the higher the centrifugal force acting on them. The amount of centrifugal force depends directly on the specific weight of the material used. In the material of the rotor, the centrifugal force acts as a tension whose height must not exceed the yield strength of the respective material in order not to jeopardize the integrity of the machine. Therefore, the highest allowable speed of the machine is usually determined by the properties of the rotor material used. Decisive here is the ratio of yield strength and specific weight, the so-called specific strength.

In order not to overload particularly stressed rotating elements in turbines, high-strength material was used, such as superalloys in the form of titanium alloys and nickel alloy. requirements. However, these lead to high procurement and manufacturing costs. Additional costs are caused by the limitation of the number of possible joining methods, which are needed for cover disc wheels, for example. Alternatively, light metal alloys have been used, but they are less creep resistant and chemically resistant and also limit the joining processes. As a result of these disadvantages, steels are still the most widely used material.

Recently, steels have been known whose specific gravity could be lowered by a high proportion of light metals below 7 g / cm and which have high strength and toughness. Such steels are described in WO 03/029504 A2 and are used in vehicle construction for the production of body parts.

It is an object of the present invention to provide a rotor of a turbomachine, which is easy to manufacture and rotatable with high rotation.

This object is achieved by a rotor of the type mentioned, in which at least one of the rotational elements is at least partially made of a steel with a light metal content of at least 20%. By alloying a light metal, the specific weight of the steel compared to conventional steels can be significantly reduced, without the yield strength is reduced. This increases the specific strength, allowing higher speeds. Due to the use of steel common joining methods are applicable and a necessary creep resistance is also given.

The turbomachine is expediently a turbomachine and may be a gas turbine or steam turbine. Also possible is an axial compressor or a centrifugal compressor for power plant use. The rotor expediently has a maximum radius of at least 1 m, in particular at least 1.5 m. Light metals are all metals and their alloys. referred alloys whose density is less than 4.5 g / cm ³ . The steel with a light metal content of at least 20% preferably has a specific gravity below 7 g / cm ³ .

In general, a Fe-Mn-Al multi-substance system is advantageous. The aluminum can achieve an extraordinary reduction in specific gravity since aluminum causes a high lattice width through a large atomic radius of 0.147 nm, while the atomic radius of iron is 0.126 nm. Manganese also causes a lowering of the specific gravity by its still relatively large atomic radius of 0.134 nm and thus also an increase of the mesh width of the e.g. Automotive base cell (car: cubic face centered).

In an advantageous embodiment, the light metal content comprises at least 90% aluminum and manganese. Al and Mn thus form 90% of the light metal content. An alloy with these two light metals can achieve a particularly high toughness.

In an advantageous development of the invention, the steel with the light metal fraction is formed from an Fe-Mn-Al-C-tetravalent system, Fe-xMn-yAl-zC. By the carbon, which is uniform in particular in the solid solution as nano-sized κ-carbides, a high strength of the steel can be achieved.

A universally suitable steel with the light metal content advantageously comprises 18-28% manganese, 9-12% aluminum and 0.7-1.2% carbon in percentage by mass. Furthermore, a small proportion of metallic impurities can be present. Particularly suitable for applications with a particularly high stress is an alloy with 25 - 28% manganese, 10 - 12% aluminum and 0.9 - 1.2% carbon.

By a higher aluminum content, the specific gravity can be further reduced. Values of up to 30% aluminum still lead to a tough lightweight steel with a high Yield strength. Depending on the application, higher Al contents of up to 38% are conceivable, which indeed reduces the yield strength, but still provides an acceptable specific strength due to the low specific weight.

In a further advantageous embodiment of the invention, the light steel is a triplex steel. A triplex steel can be characterized by three solid phases present together. Due to the high number of phases, it is possible to achieve mechanical properties that are specifically geared to particular applications by specifically adjusting the proportions of the various light metals and, in particular, of the carbon.

Conveniently, the triplex steel comprises an austenitic γ-Fe phase with incorporated κ-carbides. These are advantageously in nano size. A unit cell of κ-carbides (Fe, Mn) ₃ AlC may comprise a dissolved C atom at octahedral sites in the center of the unit cell. Such a unit cell may have an average grid width of

0.38 nm, wherein the grid width depends essentially on the aluminum content.

It is also advantageous if the triplex steel has an additional α-Fe phase. The microstructure may be composed of an austenitic γ-Fe (Mn, Al, C) mixed crystal matrix having a fine dispersion of nano-sized κ-carbides and α-Fe (Al, Mn) ferrites in different volume parts. As a result, the austenite is very stable against formation of ε-martensite during deformation. Of the

Triplex steel has a low density between 6.5 and 7 g / cm with excellent mechanical properties, such as high strength between 700 and 1100 MPa. In addition, the mild steel has a particularly good cold workability, which simplifies machining of the steel. The light steel consists mainly of austenite, further 5 to 15 vo1% ferrites and 6 to 9 vol% κ carbons in nanoscale, which are finely distributed in the mixed carbon matrix.

The light steel is particularly advantageous in use as a material for a turbine blade of a gas or steam turbine. With the same advantage, the light steel can be used for the production of compressor blades of an axial compressor rotor. In both applications, due to the low specific weight of the light steel, particularly long blades of the last or first stage can be used in an energy-efficient manner, in particular in the range above 40 inches and above all above 48 inches.

In an alternative embodiment, the rotary element is a compressor radial impeller. These are by design provided with a relatively high mass in the radially outermost region, so that the low specific weight in this application can play a particularly high advantage.

Due to the high toughness and strength of the light steel, it is furthermore advantageously usable in the production of shaft elements, ie elements belonging to the shaft per se. Particularly noteworthy in this context would be a balance piston on the shaft and a shaft sleeve on the shaft.

A particularly good axial bearing of the shaft can be achieved by a large thrust washer, which is exposed by their radial size high centrifugal forces. These can be reduced by using the light steel compared to conventional steels, so that - with the same yield strength - greater radial expansions of the thrust bearing can be achieved.

Furthermore, advantageously at least a part of the shaft itself is made of lightweight steel. Particularly noteworthy Here, the production of the entire shaft made of light steel has to be lifted.

The invention will be explained in more detail with reference to exemplary embodiments, which are illustrated in the drawings.

Show it :

FI G 1 a radial compressor rotor with components and

FI G 2 an axial compressor rotor in a sectional view.

1 shows a schematic representation of a rotor 2 of a radial compressor with a shaft 4 on which a plurality of radial impellers 6 are attached. To accommodate or compensate for axial forces of the shaft 4, this carries a thrust washer 8 and a balance piston 10. In addition, the shaft 4 is provided with two shaft sleeves 12. The radial bearing wheels 6, the axial bearing disk 8 and the compensating piston 10 and the shaft sleeves 12 are made of a light steel steel with a light metal content of more than 20%. The shaft itself is made of such lightweight steel.

2 shows a schematic sectional view of a rotor 14 of an axial compressor with a shaft 16 and a plurality of blade rows, each having a plurality of blades 18. The shaft 16 and the blades 18 are made of lightweight steel.

In a further embodiment, FIG. 2 schematically illustrates a section through a rotor 14 of a steam turbine or gas turbine. In this case, the vanes 18 are turbine blades and serve to receive kinetic or thermal energy from steam or gas of the turbine for conversion into rotational energy of the turbine Rotor 14.

One for the shafts 4, 16, the shaft sleeves 12, the The same piston 10 and the thrust washer 8 used light steel is a triplex steel, which was prepared by induction melting in an argon atmosphere under 600 mbar partial pressure. The composition of the easily forgeable and rollable light steel is Fe-26Mn-12Al-1.2C. By a heat treatment after the forging or rolling at 1050 ⁰ C for 30 min, a recrystallization of the structure was achieved, so that a microstructure of an austenitic γ-Fe (Mn, Al, C) mixed crystal matrix with a fine dispersion of κ-carbides in nano size as well as α-Fe (Al, Mn) ferrites. A precipitation of the κ-carbides from the austenite structure during a cooling process was largely prevented by quenching with water.

For the compressor blades 18 was a triplex steel of

Composition Fe-20Mn-22Al-0, 9C chosen, although having a lower toughness, but it has a lower specific gravity. The mechanical properties of the triplex steel for the radial impellers 6 with the composition Fe-22Mn-18Al-l, OC lie between the first two mentioned triplex steels.

Claims

claims 1. rotor (2, 14) for a turbomachine with a shaft (4, 16) and arranged thereon rotation elements, which are at least partially made of steel, characterized in that at least one of the rotation elements at least partially made of a steel with a light metal content made of at least 20%. 2. rotor (2, 14) according to claim 1, characterized in that the light metal content comprises at least 90% aluminum and manganese. 3. rotor (2, 14) according to claim 1 or 2, characterized in that the steel 18 - 28% manganese, 9 - 12% aluminum and 0.7 - 1.2% carbon. 4. rotor (2, 14) according to any one of the preceding claims, characterized in that the steel with the light metal share is a triplex steel. 5. Rotor (2, 14) according to claim 4, characterized in that the triplex steel has an austenitic γ-Fe phase with embedded κ-carbides. 6. rotor (2, 14) according to claim 5, characterized in that the triplex steel has an additional α-Fe phase. 7. rotor (2, 14) according to any one of the preceding claims, characterized in that the rotary element is a blade (18) of a turbine. 8. rotor (2, 14) according to any one of the preceding claims, characterized in that the rotary element is a compressor radial impeller (6). 9. rotor (2, 14) according to any one of the preceding claims, characterized in that the rotational element is a compensating piston (10) on the shaft (4, 16). 10. rotor (2, 14) according to any one of the preceding claims, characterized in that the rotational element is a shaft sleeve (12) on the shaft (4, 16). 11. rotor (2, 14) according to any one of the preceding claims, characterized in that at least a part of the shaft (4, 16) is made of steel with the light metal content. 12. Rotor (2, 14) according to any one of the preceding claims, characterized in that the rotational element is an axial bearing disc (8) of the shaft (4, 16).