DE19526344C1 - Rotor blade for turbo engine - Google Patents

Abstract

The blade consists of directionally solidified metal alloy with columnar structure and long grain boundaries, and has rows of perforations connecting outer blade surface and internal hollow chambers. It also has monocrystal columns in the row area, or is without grain boundaries in this area. The rows consist of laser-cut bores, and extend in longitudinal direction of the blade. The bores act as cooling air bores in front edge and pressure edge areas of the blade.

Description

The invention relates to a component with cavities, preferably an airfoil for Turbo engines made of directionally solidified metal alloys with columnar structure and elongated grain boundaries with rows of holes that line the outer surface of the component connect the cavities.

Such components are today preferably used as blades for a turbo engine used, the rows of holes perform a wide variety of tasks and with the various processes, such as laser drilling or electrochemical drilling be brought. The elongated grain boundaries interfere especially when the The distance between the holes becomes smaller because of grain boundary defects and Grain boundary deposits represent corrosion crack nuclei which are caused by crack migration Weaken material between the holes, resulting in high mechanical and thermal Stresses can lead to premature component failure and the lifespan of a Reduce turbo engine disadvantageously and thus the inspection and maintenance intervals can increase.

These disadvantages have a particularly serious effect when the rows of holes are introduced by means of Laser technology, especially in the case of a columnar crystallized component, the position of the Grain boundaries is unpredictable. That is the location of the elongated grain boundaries Result of the stochastic nucleation processes on a cooling plate from which the Solidification front of the metallic melt in a molded shell for a component Furthermore, the location of the grain boundaries is different from the crystallographic Orientation of the germs with reference to the locally effective temperature gradients dependent, which results in a natural grain selection. Grains with a 001 orientation parallel to the temperature gradient are growth kinetically preferred, which leads to the fact that grow only a few grains out of a starter or from a cooling plate.  

Grain boundaries form between the grains, which weaken the material, which is why the metal alloy melt for such components grain boundary strengthener such as C, B or Zr are added, which are preferred at the grain boundaries when the melt solidifies excrete and lower the melting point by up to 100 ° C.

If such grain boundaries are hit during laser drilling, this is particularly the case larger wall thicknesses and drill lengths lead to problems because on the one hand deposits of laser-evaporated material up to a few hundred micrometers in which cracks form and, on the other hand, melting and tearing of grain boundaries depths of up to 100 micrometers can occur. The cracking of the deposit and the Grain boundaries can unite and severely weaken the component cause a turbo engine to fail. That is why it is inexpensive Laser drilling of components from inexpensively directed solidified materials Columnar structure excluded, especially for dynamically stressed Blades in a turbo engine. Here, the specialist is therefore forced to to use much more expensive single-crystal materials, the manufacture of which DE 29 49 446 A1 is known. Such methods and devices are more complex and deliver increased reject rates.

With thin walls, there is a risk of deposits forming when laser drilling less, but there is a risk of bringing in close neighbors Cooling air holes, which are intended to protect the thinner material from thermal overload, that the grain boundary cracks introduced during laser drilling in cooperation with the neighboring cooling air holes weaken the component.

DE 19 11 049 B2 also discloses a gas turbine blade and a method known their manufacture, the blade made of a composite material made of ceramic and Metal rods as a solid material and has no cavities, since the cavities in Filled in the form of bores with metallic single crystals grown in there will.  

The object of the invention is a generic component and to specify a process for its production that despite kolum crystal structure and with elongated grain boundaries and positioning of rows of holes weakening the component  excludes and allows the component from inexpensive Material consists and rows of holes, which cost favorable procedures can be introduced.

The task is performed using a directionally solidified component solved, the single-crystalline columns in the area of the rows of holes has or in the area of the hole rows free of grain boundaries is.

The introduction of the rows of holes in single-crystalline columns is not obvious because the location of the grain boundaries at conventional materials is unpredictable and the location of the rows of holes for components of turbo engines precalculated fluid mechanically optimized criteria straightens and not according to a random grain boundary structure of an inexpensive columnar solidified material changed or can be relocated. Therefore, a new material discloses the single-crystalline columns in the area of the rows of holes has, so that the disadvantages in the prior art over become wounds and grain boundary cracks and related component Defects cannot occur.

In a preferred embodiment of the invention extend the rows of holes in the longitudinal direction of the airfoil. That has at first fluid mechanical reasons, but also delivers one Compatibility with the single-crystalline column according to the invention in the area of a row of holes, so that the single-crystalline column in full length of a row of holes is available.  

In a further preferred embodiment of the invention the rows of holes consist of laser-drilled holes. Since the Materials used in turbo engines and especially in the flow channel, are of such high strength, that conventional cutting drilling methods are not used rows of holes can be electrochecked from very fine bores mixed creates what is extremely complicated, time consuming and knockout is extremely intensive for the conventional material without grain Boundary freedom was inevitable in the area of the row of holes. Laser drilled holes are advantageously faster and cheaper manufacture, so that the invention with an inexpensive material inexpensive holes for the production of the invention Component.

The task of a method for producing the generic Component is specified by a method with the following ver Steps solved:

• a) Prepare the mold with windows to fix the Cores for cavities by means of cross beams in the windows be fitted
• b) arranging additional windows for additional cross members, so that two closely adjacent windows each, leaving the spaces narrower Melting and crystallization channels between the cross beams be formed,  
• c) directional solidification of the casting with formation in each case of a large volume columnar single crystal region in the growth direction over the enamel and crystallisa tion channels in areas of the laser borehole to be drilled rows,
• d) Laser drilling of rows of holes in the single crystal and thus columnar areas solidified without grain boundaries Component.

The inventive method has the advantage that a existing and applied aid for fixing the posi tion of the casting core, which is used for the production of the cavity a hollow component is required is used to make this to enable another function. By design and Moving a cross member together with an additional cross member for the casting core is advantageously narrow passages and in one preferred embodiment of the invention even winding passages created for the melt, which is a preferred crystallorie Select the selection so that at the exit of the passage between the a single-crystal column grows in both crossbeams. To the To take full advantage of the invention, the cross members and Additional crossbeam in the directional solidification in the lower Area of the component in which no rows of holes are required, arranged so that a narrow space between the cross girders are created just where for a later hole  row a single crystalline column in the columnar structure of the Material should grow.

However, the invention is also independent of the carrying and Fixing function of the cross member can be carried out by in the lower Area of the shape corresponding to narrow melt passages to the Ankei of single-crystal columns in areas of the later hole rows are extended.

The component is preferably a rotor blade shovel used, the laser drilled holes as cooling air holes in the leading edge area and in the pressure area of the Airfoil are arranged. This is thermally highly stressed The area of a component for turbo engines is characterized by the cooling air flowing out of the rows of holes with a cooling film see that protects the airfoil.

In a further preferred use, the component is used as Blade of a rotor blade used, the laserge drilled holes to influence the detachment of the boundary layer are arranged on the suction side of the airfoil. In the like cases increase rows of holes with outflowing or inflowing Cooling air advantageously increases the efficiency of an engine by the airfoil profile is changed aerodynamically.

In a further preferred use, the component is used as Blade of a turbine blade used, the laser-drilled holes as outflow openings of a cooling film  Increased efficiency are trained. The efficiency is advantageously increased because the turbine with a higher inlet temperature can be driven.

The accompanying drawings illustrate preferred embodiments embodiments of the invention.

Fig. 1 shows a blade according to the invention with a row of holes.

Fig. 2 shows a conventional blade with row of holes.

Fig. 3 shows an enlarged section of a row of holes with closely adjacent holes with conventional blade material.

Fig. 4 shows two crossbars with a narrow passage

Fig. 5 shows two crossbars with a curved passage.

Fig. 1 shows a blade 1 according to the invention with hole row 2. This row of holes 2 connects the cavities in the interior of the blade 1 with the external environment. Such blades 1 are preferably used in the flow channel of turbo engines and consist of directionally solidified metal alloys with columnar structure and elongated grain boundaries 3 . The directionally solidified component consists of single-crystalline columns, which are surrounded by the grain boundaries 3 , whereby according to the invention, in the area of the row of holes 2, no grain boundary occurs specifically in this blade 1 . This is prevented by two windows 4 and 5 . These cross members 6 and 7 extend across the mold in the area below the blade root 8 and carry the casting core, which fills the cavities of the component during casting.

In this illustration it can be clearly seen that the melt in the area of windows 4 and 5 is narrowed to a narrow passage 9 . After the melt has been poured into the casting mold (not shown), the melt solidifies in a preferred orientation 001 on a cooling plate 10 at the base of the blade root. The solidification front proceeds upwards under the influence of a vertical temperature gradient and has to overcome the crossbeams in windows 4 and 5 , whereby in the narrow passage 9 extremely favorable growth conditions for the preferred orientation 001 prevail, so that at the upper end 11 of this passage , which is shown enlarged in Fig. 4, only one crystal of the preferred direction remains, so that it grows over a completely single-crystalline column, into which a row of holes can subsequently be introduced by means of laser drilling in a grain-free area. The passage 9 between the crossbeams 6 and 7 or between the windows 4 and 5 , which form as soon as the crossbeams 6 and 7 are pulled out after the solidification of the melt, is positioned such that the single-crystalline column 12 is exactly in the area bil det, in which the row of holes 2 is introduced later.

A stronger selection of the preferred orientation is achieved when the passage is curved, as shown in FIG. 5. To do this, only the cross sections of the crossbars must be formed with at least one curved side surface and the crossbars 6 and 7 narrowed to a small space.

FIG. 2 shows a conventional blade 20 with a row of holes 22 from the in-house prior art, which has columnar grain boundaries 3 that have grown as desired. Fig. 3 shows an enlarged section of a hole row 22. By introducing the holes 22 at grain boundaries, as shown in section B with FIG. 3, micro-cracks 23 , which can be up to 100 micrometers long, arise from each hole along the grain boundaries. If the center distance between two holes is 1 mm and the bore diameter is 0.8 mm, then the component can tear open along the grain boundary 3 under low load and the blade can fail.

Claims (7)

1. Component with cavities, preferably a blade for turbo engines made of directionally solidified metal alloys with columnar structure and elongated cluster clusters or elongated grain boundaries with rows of holes that connect the outer surface of the component with the cavities, characterized in that the directionally solidified component in the area of the single-crystal columns Has rows of holes or is free of grain boundaries in the area of the rows of holes. 2. Component according to claim 1, characterized in that the Row of holes in the longitudinal direction of the airfoil extend. 3. Component according to claim 1 or 2, characterized in that the rows of holes consist of laser-drilled holes.   4. A method for producing a component with cavities, preferably a blade for turbo engines made of directionally solidified metal alloys with columnar structure and elongated grain boundaries with rows of holes that connect the outer surface of the component with the cavities, characterized by the following process steps:

• a) preparing the casting mold with windows for fixing the cores for cavities by means of cross members which are fitted into the windows,
• b) arranging additional windows, so that two closely adjacent windows are formed between the windows with free, narrow melting and crystallization channels, or using suitable ceramic cores for the production of wax models when using the lost wax process,
• c) directional solidification of the casting, each forming a large-volume columnar single-crystal area in the growth direction above the melting and crystallization channels in areas of the rows of laser boreholes to be drilled,
• d) Laser drilling of rows of holes in the single-crystalline and thus grain boundary-free solidified columnar areas of the component.

5. Use of the component according to claims 1 to 3 as an airfoil of a rotor show fel, the laser drilled holes as cooling air holes in the leading edge area and in the pressure area of the blade Leaf are arranged. 6. Use of the component according to claims 1 to 3 as an airfoil of a rotor show fel, the laser-drilled holes to influence the Detachment of the boundary layer on the suction side of the blade Leaf are arranged. 7. Use of the component according to claims 1 to 3 as an airfoil Turbine blade, the laser-drilled holes as Outflow openings of a cooling film to increase the Efficiency are trained.