REPAIR METHOD FOR TURBINE BLADES

Abstract

Disclosed is a repair method for guide blades of a gas turbine. The method comprises: providing at least one guide blade to be maintained; capturing the actual geometry of the guide blade to be maintained with application of at least one measuring method; comparing the actual geometry captured by the contactless measuring method to a predetermined desired geometry for a corresponding guide blade type; calculating a target geometry for the guide blade to be maintained, which corresponds as much as possible to the desired geometry, such that using optimization parameters, the desired geometry of the guide blade to be maintained is approximated at least in sections along its flow contour; applying material and removing material by machine on the guide blade, such that the calculated target geometry is produced.

Claims

1. A repair method for guide blades of a gas turbine, wherein the method comprises: providing at least one guide blade to be maintained; capturing an actual geometry of the guide blade to be maintained with application of at least one measuring method; comparing the actual geometry captured by the at least one measuring method to a predetermined desired geometry for a corresponding guide blade type; calculating a target geometry for the guide blade to be maintained, which corresponds as much as possible to the desired geometry, such that using optimization parameters, the desired geometry of the guide blade to be maintained is approximated at least in sections along its flow contour; applying material and removing material by machine on the guide blade to be maintained, such that the calculated target geometry is produced.

2. The repair method of claim 1, wherein the target geometry of the guide blade to be maintained is in such a way calculated and reestablished in such a way that a flow contour in a region of an A4 cross section of the guide blade to be maintained approximates a flow contour of the desired geometry in the region of the A4 cross section as well as possible.

3. The repair method of claim 1, wherein application and removal of material are performed along a suction side of a flow contour of the guide blade from a front edge up to a rear edge of the guide blade.

4. The repair method of claim 1, wherein removal of material is carried out by automated milling and/or grinding and/or by another automated cutting method.

5. The repair method of claim 1, wherein application of material is performed by soldering.

6. The repair method of claim 5, wherein application of material is performed by diffusion soldering.

7. The repair method of claim 1, wherein application of material is carried out as a function of captured actual geometry and of target geometry.

8. The repair method of claim 1, wherein after application of material to the guide blade, a further calibration is carried out to position the guide blade for removal of material.

9. The repair method of claim 1, wherein the desired geometry is an approximation to an original geometry of the guide blade.

10. The repair method of claim 1, wherein the desired geometry is an original geometry of the guide blade.

11. The repair method of claim 9, wherein the desired geometry is determined by a measuring method which is carried out on a guide blade in like-new condition.

12. The repair method of claim 10, wherein the desired geometry is derived from design data of a guide blade.

13. The repair method of claim 10, wherein the desired geometry is defined based on a new development.

14. The repair method of claim 1, wherein the provided guide blade is taken from a high-pressure turbine.

15. The repair method of claim 13, wherein the provided guide blade is taken from a first high-pressure turbine stage, which directly adjoins a combustion chamber.

16. The repair method of claim 1, wherein method steps are carried out repeatedly until all guide blades of a guide blade ring of a turbine stage are repaired.

17. The repair method of claim 16, wherein the turbine stage is a high pressure turbine stage.

18. A guide blade of a gas turbine, wherein the guide blade has at least one repaired region, which has been produced by the repair method of claim 1.

19. A repair system for maintaining turbine blades of a gas turbine, wherein the system comprises at least one receptacle unit, which is configured to hold at least one turbine blade to be maintained; at least one measuring device, which is configured to capture an actual geometry of the turbine blade to be maintained; at least one automatic processing device, which is configured to apply material to the turbine blade to be maintained and/or to remove material, at least one computer unit, which is configured to control the measuring device and/or the processing device, store a desired geometry of a corresponding turbine type in an assigned memory, calculate a target geometry on the basis of optimization parameters and based on a comparison of actual geometry and desired geometry, control the processing device such that the target geometry of the turbine blade to be maintained is reestablished in at least one cross-sectional region with reference to the calculated optimization parameters.

20. The repair system of claim 19, wherein the at least one automatic processing device comprises a milling unit and/or a grinding unit.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0052] The invention will be described hereafter by way of example and in a nonrestrictive manner with reference to the appended drawings.

[0053] FIG. 1 shows a simplified schematic cross-sectional illustration of two guide blades of a guide blade ring, wherein the guide blades have an original flow contour.

[0054] FIG. 2 shows a simplified schematic cross-sectional illustration of two guide blades of a guide blade ring, wherein the guide blades have a worn flow contour.

[0055] FIG. 3 shows, on the basis of simplified schematic cross-sectional illustrations, the steps of a method for repairing guide blades to be repaired from FIG. 2.

[0056] FIG. 4 shows a simplified schematic cross-sectional illustration of two guide blades of a guide blade ring, wherein the guide blades are repaired and have a flow contour which corresponds to an optimized desired geometry.

DETAILED DESCRIPTION OF EMBODIMENTS OF THE INVENTION

[0057] The particulars shown herein are by way of example and for purposes of illustrative discussion of the embodiments of the present invention only and are presented in the cause of providing what is believed to be the most useful and readily understood description of the principles and conceptual aspects of the present invention. In this regard, no attempt is made to show details of the present invention in more detail than is necessary for the fundamental understanding of the present invention, the description in combination with the drawings making apparent to those of skill in the art how the several forms of the present invention may be embodied in practice.

[0058] FIG. 1 shows, by way of example, two turbine blades 10 and 10′ arranged in the circumferential direction UR of a turbine stage. The turbine blades can be part of a guide blade ring and can be designed as guide blades 10, 10′. The guide blades 10, 10′ are shown in FIG. 1 and also in the following Figures as simplified schematic cross sections. Both guide blades 10, 10′ have a flow contour 12, 12′, having a pressure side 14, 14′ and a suction side 16, 16′. The pressure sides 14, 14′ and the corresponding suction sides 16, 16′ are each connected to one another by a front edge 18, 18′ and a rear edge 20, 20′.

[0059] In the situation shown in FIG. 1 of two adjacent guide blades 10, 10′ of a guide blade ring of a gas turbine, the so-called A4 cross section is formed in each case between all adjacent guide blades. This A4 cross section can also be referred to as the distance between two adjacent guide blades 10, 10′, which is measured in a specific region. As is apparent from FIG. 1, the A4 cross section QS is measured between the pressure side 14 of the guide blade 10 and the suction side 16′ of the guide blade 10′. In this case, the A4 cross section line QS extends from a rear region of the guide blades 10, approximately in the region of the rear edge 20, to a middle region of the suction side 16′ of the guide blade 10′. This A4 cross section represents an important variable for the flow conditions prevailing in the turbine stage. Deviations from this A4 cross section result in changed flow conditions and can negatively influence the efficiency of the gas turbine.

[0060] In FIG. 1, the crossed shading shows two guide blades 10, 10′, the flow contour 12, 12′ of which is shown in an original state. One can also say that the two guide blades 10, 10′ are in like-new condition. The A4 cross section QS or the corresponding distance between the two guide blades is also in an original dimension because of the like-new condition of the guide blades 10, 10′, so that optimum operation is possible.

[0061] After a certain number of operating hours, changes arise on the flow contour 12, 12′ on the guide blades 10, 10′ as a result of the high temperatures and the high pressure of the hot gas flowing through. For example, material is also successively eroded away on the suction side 16, 16′ or other damage also occurs, such as cracks or holes. The A4 cross section QS changes due to such wear of the guide blades 10, 10′, wherein it is enlarged by an amount VG. In the state shown in FIG. 2, the A4 cross section is thus QS plus VG, so that the flow cross section between the two guide blades 10, 10′ is enlarged, which has a disadvantageous effect on the flow conditions and the efficiency of the gas turbine. Components in which such wear occurs have to be restored or repaired accordingly for further operation.

[0062] A method which is explained hereafter on the basis of FIG. 3 can be used for this purpose. The following description only mentions the guide blade 10 by way of example in each case, although the method can also be carried out for the adjacent guide blade 10′ and further guide blades. The guide blade 10 or all guide blades of a turbine stage are firstly provided. Depending on the construction of a turbine stage, the guide blades can be provided individually, or multiple guide blades can be part of a guide blade segment, which has multiple guide blades connected to one another, in particular integrally.

[0063] An actual geometry of the worn guide blade 10, which is shown on the top left in FIG. 3, is firstly captured (I) by means of a contactless method, in particular an optical method. Methods such as contactless 3D scanning or the like can be used in particular here. This actual geometry, which is represented in the present application by the flow contour 12, is compared to a desired geometry. The desired geometry SG is indicated in simplified and schematic form on the top right in FIG. 3 as a dotted flow contour. Target geometries can be calculated from the comparison between the actual geometry and the desired geometry SG by means of optimization parameters, which approximate the flow contour, in the region of the A4 cross section, in the best possible manner to the desired geometry.

[0064] In a next step (II), material 22 is applied to the guide blade 10. In the present example, an application of material 22 from the front edge 18 to the rear edge 20 along the suction side 16 is shown. Of course, material 22 can optionally also be applied to the pressure side 14, although this is not explicitly described in the present example. The application of material 22 is performed in particular by soldering or welding, preferably by diffusion soldering, to ensure an optimum connection between the application material 22 and the guide blade 10 to be restored. The application of material 22 can be performed manually and/or automatically. The quantity and/or the positions along the guide blade or the flow contour 12 can be established, for example, on the basis of the optimization parameters, which have been previously ascertained on the basis of the comparison of actual geometry and desired geometry.

[0065] After the application of material 22, the flow contour 12 (target geometry ZG) of the guide blade 10 to be repaired is reestablished by automatic removal of excess material 22 (see III). The guide blade 10 is moved for this purpose into a reference position in relation to a processing unit. The processing unit is configured in this case to carry out an exact removal of material 22 based on the optimization parameters or data about the desired geometry to be achieved. The removal of material 22 is preferably performed in this case by grinding or milling. After the removal by cutting of excess material 22, the guide blade 10 has a flow contour 12 which substantially again corresponds to the desired geometry, wherein the guide blade 10 contains a part made of original material and a part made of additionally applied material 22.

[0066] If one observes two adjacent repaired guide blades 10, 10′ after such a repair method carried out substantially automatically, as shown in FIG. 4, it is apparent that the A4 cross section QS substantially again corresponds to the original A4 cross section QS and the original flow contour (FIG. 1). The enlargement VG of the flow cross section (FIG. 2) was therefore canceled out by the application of material 22 in the corresponding regions of the guide blades 10, 10′, so that optimum operation of the gas turbine is again possible using the repaired guide blades 10, 10′.

[0067] It is to be noted that individual optimization parameters can be calculated based on the capture of the actual geometry for each guide blade, which parameters are dependent on the wear state which the corresponding guide blade to be restored has reached. Because the further steps of the repair can preferably be made dependent on the actual geometry, it can be ensured that the required material application and an automated material removal can be performed in a manner optimized for each guide blade, and the desired geometry can be reestablished for each guide blade. The automated processing also results in an overall improved result for all repaired or restored guide blades if repaired guide blades are compared to one another, because approximately the same desired geometry is reestablished for all guide blades and all guide blades can be substantially automatically processed on the basis of calculated optimization parameters.

[0068] The method proposed here can be carried out, for example, at various stations of a maintenance workshop. In the performance of automated steps, for example the detection of the actual geometry, the comparison of actual geometry and desired geometry, the calculation of optimization parameters, the automated removal of applied material, at least one computer unit is preferably used, which is configured to control corresponding capture devices or tool devices, in particular based on the captured or calculated data for the desired geometry.

[0069] Data which represent the desired geometry of a guide blade can be captured, for example, in that the geometry of a guide blade in like-new condition is externally captured by means of corresponding capture devices, for example by contactless 3D scanning, in particular optical capture methods. Alternatively, the data of the desired geometry can also be derived from design data, which are available for a specific guide blade type and which form the basis for producing a guide blade in like-new condition.

LIST OF REFERENCE NUMERALS

[0070] 10 turbine blade or guide blade [0071] 12 flow contour [0072] 14 pressure side [0073] 16 suction side [0074] 18 front edge [0075] 20 rear edge [0076] 22 material [0077] QS A4 cross section [0078] DG desired geometry [0079] VG enlargement