Turbine blade and a method for its production

Fluid reaction surfaces (i.e. – impellers) – Specific blade structure – Coating – specific composition or characteristic

Reexamination Certificate

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Details

C427S275000, C427S318000, C427S556000

Reexamination Certificate

active

06402476

ABSTRACT:

BACKGROUND OF THE INVENTION
Field of the Invention
The invention relates to a method for producing a turbine blade from a nickel-based alloy for a gas turbine.
In order to drive gas turbines, hot combustion gases are applied directly to turbine blades. In the process, they are subject to both thermal and mechanical stresses during operation of the gas turbine. Particles that are carried by the hot gases and can be produced, for example, by erosion of ceramic combustion chamber linings, travel at considerable speeds so that they are able to remove material from the surfaces of the turbine blades, by striking the blade surface. In very poor conditions, the loss of material may be so great that the turbine blades-are no longer fully serviceable after just a few months.
SUMMARY OF THE INVENTION
It is accordingly an object of the invention to provide a turbine blade and a method for its production that overcome the above-mentioned disadvantages of the prior art devices and methods of this general type, whose surfaces are optimally protected against the removal of material.
With the foregoing and other objects in view there is provided, in accordance with the invention, a method for producing a turbine blade for a gas turbine. The method includes the step of: forming an initial turbine blade from a nickel-based alloy; melting down surfaces of the initial turbine blade to a predetermined depth for forming a defined amorphous region on a crystalline structure of the nickel-based alloy; and cooling down the surfaces at a predetermined temperature reduction rate per unit time.
The turbine blade according to the invention is initially manufactured from a nickel-based alloy, in a manner known per se. Its surfaces are then melted with the beam, for example of a CO
2
laser, down to a depth of 0.001 to 3 mm. The liquefied material is then cooled down again at a cooling rate of 10
10
to 10
15
K/s, by switching off the radiation source or by additional cooling measures.
This high cooling rate results in the surface of the turbine blade being provided with an amorphous solid structure on the side facing the hot gas. Furthermore, by appropriate selection of the cooling rate, the amorphous structure can be provided with closed pores. The amorphous structure merges smoothly and to a greater extent into the original crystalline structure of the base alloy, the greater the distance from the blade surface. The transition to the liquid state ensures that no discontinuous, abrupt boundary surfaces, which could lead to the well known separation of layers in conventional blade coatings, are formed between the amorphous structure and the original, crystalline structure of the nickel-based material, which is not changed or is changed only gradually by the laser radiation. The laser modification thus gives the surfaces treated in this way the character of gradient layers with continuous, non abrupt transitions from an amorphous structure to the original crystalline structure underneath it. It thus requires no additional, adhesion-promoting intermediate layers, which are required in conventional blade coatings in order to improve the adhesion of thermal insulation layers placed above.
The amorphous layer also has the character of a functional layer, since the structural and material composition of the layer is optimized to avoid particle impact erosion. The radiation intensity, its duration, the cooling rate and a supply of material which can also be provided during the melting process and is described below are chosen such that, once it has solidified, the amorphous structure has as high a ratio as possible of elastic to plastic deformation. At the same time, the energy transferred on particle impact is intended to be locally absorbed to a sufficient extent to prevent the removal of material at the impact point, and the propagation of compression zones and pressure waves into the blade material away from the impact point.
The radiation intensity and its duration must be chosen so as to ensure that the surface melts within microseconds down to a depth of 0.001 to 3 mm. Both parameters thus depend on the radiation absorbence and the thermal conductivity of the blade material in the solid state, and then in the liquid state. These parameters are defined on the basis of known heat transfer rules, taking account of phase changes, that is to say the progress of a melting zone front into the depth of the blade material, and subsequent convection of the liquid components under the influence of the laser radiation. The cooling rate is governed by the solidification behavior of the blade material and the solidification behavior of additional materials (as described below) which can be added during the melting process. For nickel-based materials, it is advantageously in the range of 10
10
to 10
15
K/s.
Initially, the amorphous structure is in principle suitable for absorption of the particle impact energy due to a high level of local damping of the mechanical oscillation energy transferred on impact. Owing to the regular lattice structure, a crystalline solid-state lattice, on the other hand, would assist the propagation of pressure waves, which can lead to material being able to separate directly underneath the impact point as well as away from this damage, if the impact energy transferred into it there is greater than the binding energy of the solid-state components which form the blade material.
This characteristic of the amorphous layer can be optimized by adding further materials to the melted base material during the process of producing it, in order to form alloys, cermets, or mixed ceramics. Such materials may be added in the form of strips, wires, powders, fibers, or from the gas phase. Any materials that have a high ratio by weight of cations to anions may be used for this purpose, such as zirconium dioxide, barium oxide, titanium oxide or yttrium oxide, or other ceramics whose thermal conductivity is poor and which are stable at high temperatures.
The amorphous surfaces formed in this way may also have a large number of closed pores down to their depth of 0.001 to 3 mm. Such pores can assist in further reducing the propagation of pressure waves in the solid material, since they damp such waves by multiple reflection on the pore structures and/or cell structures. Such, structures have highly different mechanical (elastic) constants, which lead to a high level of dispersion of the mechanical oscillations and pressure waves, and thus to their absorption. The closed pores thus help in preventing particle impact erosion since they break down the impact energy directly at or under the impact point. Since porous solid bodies or solid layers also have a lower thermal conductivity than homogeneous solid bodies or solid layers, the amorphous, porous structure close to the blade surface will also act as a heat insulation layer.
Pores are formed when the vapor pressure of the base material and the vapor pressure of the additional materials at the temperatures achieved during the process of melting the blade surface are sufficiently high that they exceed the respective liquid pressure and the pressure caused by the surface tension of the liquid material and which, overall, acts on a bubble. The high vapor pressure results in bubbles or other catheters that cause the amorphous layer to have a porous structure. Suitable additives include, for example, metals in the form of mercury, cesium, potassium, sodium or lithium, which have a considerably lower melting point than the nickel-based material. If the cooling down process is very rapid, then this prevents not only the recrystallization of the base material and of the materials which have been additionally fed in, or the alloys which are formed from the base material and the additives, but also prevents collapse of the bubble-like structure components and the liquid material merging once again to form a homogeneous (amorphous) solid body. The production of the pores is assisted by ensuring a high level of convection of the liquid material during the melting process,

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