The invention relates to a machine component with a base body which is manufactured from a base material and which in a section of its surface is provided with a cladding consisting of a cladding material with a greater hardness in comparison to the base material. Furthermore, it relates to a gas turbine with a number of machine components of this type.
Turbines, especially gas turbines, are used in many areas for driving generators or driven machines. In this case, the energy content of a fuel is used to produce a rotational movement of a turbine shaft. For this purpose, the fuel is combusted in a combustion chamber, wherein air, which is compressed by an air compressor, is supplied. The working medium, which is produced in the combustion chamber by means of the combustion of the fuel, is guided in the process at high pressure and at high temperature through a turbine unit, which is connected downstream to the combustion chamber, where it is expanded, performing work.
For producing the rotational movement of the turbine shaft, in this case a number of rotor blades, which are customarily assembled to form blade groups or blade rows, are arranged on said turbine shaft and drive the turbine shaft via an impulse transmission from the working medium. For guiding the working medium in the turbine unit, moreover, stator blade rows, which are connected to the turbine casing, are customarily arranged between adjacent rotor blade rows.
A turbine of this type comprises a large number of component parts or machine components which are suitably positioned in the turbine, subject to predetermined measurements, shapes and/or tolerances. In many cases, it can be desirable in the process to minimize the contact of adjacent machine components or component parts with each other, in order to keep wear of the affected component parts especially low by such means. However, during the operation of the turbine, time and again actually unwanted contact between such component parts can develop, for example as a result of thermal expansions or else as a result of operation-induced vibrations or suchlike which occur, so that certain wear of such component parts occurs. As such machine components, for example a so-called flame tube, a mixing chamber and an inner casing are customarily arranged adjacent to each other in the region of the combustion chamber of the gas turbine. Owing to their design, these machine components have such significant deformations and critical tolerances that during operation of the gas turbine contact between these component parts in some places is unavoidable. As a result of this contact, unwanted and possibly also critical wear, especially during long operating periods, arises, so that the component parts which are referred to have to be inspected at regular intervals and, if necessary, exchanged/repaired.
In order to keep the wear of the affected component parts or machine components especially low in such situations, the machine components can be manufactured in a so-called clad design, wherein the regions which are especially affected by the anticipated wear or the anticipated contacts with adjacent components are covered with a protective lining which is also referred to as cladding. Such a cladding in this case can be formed from a cladding material which in comparison to the base material of the respective components has a greater mechanical hardness, so that by means of such a suitable material selection contact-induced wear which occurs can already be reduced.
On account of the greater hardness of the cladding material which is customary for such application purposes, however, it On account of the greater hardness of the cladding material which is customary for such application purposes, however, it is also more brittle than the respective base material of the base body of the machine component. A further treatment of the base body which is provided with the cladding material, for example by bending or suchlike, is now only possible to a limited extent as a result. Furthermore, during a thermal expansion of the base body, crack formations or other damage can develop in the region which is provided with the cladding material, on account of the different thermal expansion behavior. Particularly for use in thermally comparatively highly stressed regions, such as in the inner region of the combustion chamber of a gas turbine, such clad machine components are only conditionally suitable as a result.
The invention, therefore, is based on the object of disclosing a machine component of the aforementioned-type which is also especially suitable for use in a thermally comparatively highly stressed region of a driven machine. Furthermore, a gas turbine with a number of such machine components is to be disclosed.
With regard to the machine component, this object is achieved according to the invention as claimed in the claims.
The invention in this case starts from the consideration that the machine component for a basic applicability should be provided with a suitable cladding, subject to low-wear operating conditions. In order to avoid the disadvantages which accompany this, especially with regard to the possibility of further treatment and also stability in relation to thermal stress, the lateral expansion of the cladding should be kept especially low. However, in order to be able to cover an adequately large section of the surface in the process, individual zones of the cladding should be designed in a manner in which they are decoupled from each other, in order to enable in this way adequate flexibility with respect to thermal deformation and suchlike. For this purpose, the cladding should be designed in segmented fashion.
In this case, especially component parts or machine components which are positioned adjacent to each other can also be designed in such a clad manner, wherein the clad section of the surface of a first machine component is arranged adjacent to the clad section of the surface of a second machine component. The cladding material of the first machine component in this case has a different hardness than the cladding material of the second machine component. By suitable material selection, therefore, it is possible, in the case of contact occurring between the two machine components to purposefully focus the wear on one of the two machine components, specifically that with the cladding of lesser hardness, wherein for this purpose especially the more easily exchangeable or repairable machine component can be selected.
The cladding segments can be applied to the base body of the machine component by means of suitable techniques. The cladding segments, however, are advantageously applied to the base body by means of weld surfacing, so that an especially intimate connection to the base body and, consequently, a high stability of the machine component is altogether achieved.
The cladding segments can be applied to an outer surface of the base body so that the contour which results from this basically has a multiplicity of projections on the surface of the rail component, which are formed by means of the cladding segments. However, in order to enable required measurements to be adhered to or else the provision of an externally smooth surface for the component part or the machine component, the cladding segments are advantageously introduced into or embedded in each case in associated recesses in the base body. As a result, an almost even overall surface of the machine component is altogether advantageously achievable, wherein especially the outer surface of the cladding segments and the outer surface of the strips of the base body which extend between the cladding segments form a continuous surface.
Machine components of the type mentioned are advantageously used in a gas turbine, especially as a flame tube of a combustion chamber, as a mixing chamber of a burner, and/or as an inner casing of a combustion chamber.
The advantages which are achieved by the invention are especially that, by means of the segmented design of the cladding of the machine component, attachment of the cladding to the base body is enabled really for the first time even in the case of only small tolerance ranges, wherein a distortion of the base body as a result of the high working temperatures during the weld surfacing can be largely avoided especially with regard to the segmented design of the cladding. By means of the segmented design of the cladding, moreover, crack formation during the application of the cladding, which could occur during continuous welding of the cladding, is avoided. Moreover, subsequent bending of the component part is enabled without the cladding material being too heavily stressed in the process. Furthermore, deformations and connecting welds during assembly and in operation are comparatively simple to carry out without fear of critical effects on the component part.
By means of the attachment of the cladding segments in recesses which are incorporated in the base body, the surface of the machine component can be homogenized in retrospect, wherein a possible projection after the weld surfacing can also be subsequently removed. In this case, the meeting of externally predetermined measurements can be ensured, especially in the case of matched component part geometry. The segmented application of the cladding, moreover, reduces the stressing of the component part during manufacture, assembly, and in operation.
Particularly in the application in turbines, especially gas turbines, moreover, by means of suitable material selection in the pair-wise cladding of component pairs by suitable selection of different hardnesses, the wear can be focused on one of the two paired components, so that subsequent maintenance and exchange of affected components can be made considerably easier.
An exemplary embodiment of the invention is explained in detail based on a drawing. In the drawing:
Like components in all the figures are provided with the same designations.
The gas turbine 1 according to
The combustion chamber 4 is equipped with a number of burners 10 for combusting a liquid or gaseous fuel. Furthermore, on its inner wall it is provided with heat shield elements, which are not shown in detail.
The turbine 6 has a number of rotor blades 12 which are rotatably connected to the turbine shaft 8. The rotor blades 12 are arranged on the turbine shaft 8 in ring form and in this way form a number of rotor blade rows. Furthermore, the turbine 6 comprises a number of stationary stator blades 14 which are fastened on an inner casing 16 of the turbine 6, similarly in ring form, forming stator blade rows. The rotor blades 12 in this case serve for driving the turbine shaft 8 by impulse transmission from a working medium M which flows through the turbine 6. The stator blades 14, however, serve for flow guiding of the working medium M between two rotor blade rows or rotor blade rings which are in series in each case when viewed in the flow direction of the working medium M. A pair in series, consisting of one ring of stator blades 14 or one stator blade row, and consisting of one ring of rotor blades 12 or one rotor blade row, in this case is also referred to as a turbine stage.
Each stator blade 14 has a platform 18, which for fixing of the respective stator blade 14 on the inner casing 16 of the turbine 6 is arranged as a wall element. The platform 18 in this case is a thermally comparatively heavily stressed component part, which forms the outer boundary of a hot gas passage for the working medium M which flows through the turbine 6. Each rotor blade 12 is fastened on the turbine shaft 8 in a similar fashion via a platform 20 which is referred to as a blade root.
Between the platforms 18 of the stator blades 14 of two adjacent stator blade rows, which platforms are arranged at a distance from each other, a guide ring 21 is arranged on the inner casing 16 of the turbine 6 in each case. The inner surface of each guide ring 21 in this case is also exposed to the hot working medium M which flows through the turbine 6, and by means of a gap 24 is at a distance in the radial direction from the outer end 22 of the rotor blades 12 of a rotor blade row which lie opposite it.
As can be gathered from the enlarged view in
The flame tube 30, the transition piece 34 and the inner casing 36 are interconnected in this case in the fashion of tubes which are fitted into each other, so that reliable media flow guiding from the flame tube 30 into the inner casing 36 of the combustion chamber 4 is ensured. The pipe ends which are fitted into each other in each case, subject to the predetermined measurements and tolerances, are positioned in this case as contact-free as possible from each other, so that wear on account of components which come into contact with each other and components which rub upon each other is avoided as far as possible. However, constantly recurring contact of these components with each other, which is operationally induced during operation of the gas turbine 1, cannot be avoided, so that in any case a residual wear needs to be taken into account. In order to take this wear into account, a regular check and, if necessary, an exchange of these components is necessary within the scope of maintenance and inspection operations.
In order to keep the operational cost of the gas turbine 1 especially low and to largely simplify the necessary inspection and maintenance operations, the components of the gas turbine 1 are designed to be as wear-resistant as possible. In order to take into account in this case the wear which is induced by contact between the machine components, being the flame tube 30, transition piece 34 and inner casing 36, and particularly to keep this wear especially low during occurring contacts of the components with each other, the machine components which are referred to are designed as clad components. For this purpose, each of the machine components, being the flame tube 30, transition piece 34 and inner casing 36, is constructed from a base body 40 which is manufactured from base material and which in a section of its surface, which is shown in
In order to avoid an impairment of the manufacture, assembly and also operation of the respective machine components as a result of the cladding 42, as it could occur, for example, as a result of the different thermal expansion behavior and crack formation associated with this during the actual welding process, or else during operation with increased thermal stress, the cladding 42 of the respective machine component is designed in segmented fashion. For this purpose, the cladding 42 comprises a plurality of cladding segments 44, wherein the dimensioning with regard to the dimensioning of the actual machine component and the materials which are used is selected in such a way that, as a result of the laterally limited expansion of the respective cladding segment 44, a too large impairment of the base body 40 by different thermal expansion behavior and suchlike is avoided.
As can be gathered from the view in
In
In
Number | Date | Country | Kind |
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06011629.0 | Jun 2006 | EP | regional |
This application is the U.S. National Stage of International Application No. PCT/EP2007/054029, filed Apr. 25, 2007 and claims the benefit thereof. The International Application claims the benefits of European application No. 06011629.0 filed Jun. 6, 2006, both of the applications are incorporated by reference herein in their entirety.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2007/054029 | 4/25/2007 | WO | 00 | 12/2/2008 |