The present invention relates to a method for coating a component.
The component to be coated can be provided, in particular, for a turbomachine, such as, for instance, a turbojet or turbofan engine. In functional terms, this type of turbomachine is divided into a compressor, a combustion chamber, and a turbine. In the case of an engine, for example, inflow air is compressed by the compressor and undergoes combustion with admixed kerosene in the downstream combustion chamber. The hot gas that is formed, which is composed of a mixture of combustion gas and air, flows through the downstream turbine and thereby undergoes expansion.
For example, in general, in the case of the coating in question here, what can be involved is a protective coating, such as, for instance, for thermal and/or mechanical protection of a surface arranged in the compressor or hot-gas channel. However, the coating can also be applied to a blade tip in particular and, as an especially hard layer, can serve in a run-in lining for running-in. This is intended to illustrate a preferred field of application, but not to limit the subject initially in terms of its generality.
The present invention is based on the technical problem of presenting an advantageous method for coating a surface of a component.
This problem is solved in accordance with the invention by the method according to claim 1. In this case, the coating is applied to a first surface of the component, wherein, beforehand, an edge by which the first surface adjoins a second surface is rounded. During coating, the prior rounding can prevent any excess accumulation of material at the edge, which could ensue, for example, in a galvanic deposition process from a concentration of field lines at the unrounded, sharp edge. The inventors have observed that a lateral overhang of the coating, which would result from such an excess application of material, can later be detrimental in regard to the strength of the component, in particular under dynamic load (for example, vibrational fatigue strength). In the overhang, it is possible under a vibrational excitation, for example, for the mechanical strain to be relatively higher owing to the geometry and, in particular, for the strain/amplitude ratio to be large. It is then possible, for example, for an initial site for the emergence of a crack to lie there, which ultimately can propagate into the component and can lead to the failure thereof.
In terms of the example in the introduction, the first surface can be the blade tip surface and the second surface can be a side surface of the blade body, that is, the suction side surface and/or pressure side surface. The vibrational excitation can then, in particular, take place through the adjacent blade cascade, as a result of which the blade body is caused to vibrate, whereby the vibrational pattern can include elements in all spatial directions. The component produced in accordance with the method can find application advantageously when modes with high vibrational strains arise in the region of the coating. The vibrational fatigue strength can be detected, for example, by a high-cycle fatigue test, in which the blade is caused to vibrate by root point excitation in the resonance frequency range and is thereby fatigued. Regardless of the investigation details, it is possible by way of the rounding to at least reduce the overhang and this can be of advantage in terms of structural mechanics, particularly in the case of a relatively hard coating. Such a coating can, namely, be especially prone to cracks on account of its higher rigidity.
Preferred embodiments are found in the dependent claims and in the entire disclosure, whereby the description of the features does not always distinguish in individual instances between the device and method aspects; in any case, the disclosure is to be read implicitly in terms of all claim categories. If, for example, a component that has been processed/coated in a certain way is described, this is to be understood at the same time as being a disclosure of a corresponding method, and vice versa.
In general, “a” and “an” are to be read in the scope of the present disclosure, unless explicitly stated otherwise, as the indefinite article and accordingly always implicitly also as “at least one.” The first surface can adjoin a further surface of the component in a further edge, for example; in the case of the blade body, for example, the blade tip surface can adjoin the suction side surface and also the pressure side surface at a respective edge. Preferably, all edges in which the first surface adjoins another respective surface are rounded prior to the coating. The second surface or surfaces remains/remain preferably uncoated; that is, the coating is only applied to the first surface.
In accordance with a preferred embodiment, a rounding introduced in step i) has, as viewed in section, a radius of curvature R that corresponds to at least 0.5 times a thickness d of the coating. Further and especially preferably, the radius of curvature can correspond to at least 0.7 or 0.8 times the layer thickness. Advantageous upper limits, which, in general, may be of interest independently of the lower limits and are to be disclosed, lie, increasingly preferably in order of mention, at 5, 4, 3, or 2.5 times the thickness d. By way of a corresponding radius R, it is possible, for example, to limit a lateral overhang of the coating with respect to the second surface or even to completely prevent it.
The section or sectional plane here lies perpendicular to the edge or edge line, which determines the edge in accordance with the edge that is present prior to step i) and is removed with the rounding. The rounding here need not necessarily have a single radius, but can also be composed of a plurality of segments. Preferably, in any case, one of the segments then has a corresponding radius; especially preferably, the radius lies in a corresponding range for all segments.
In a preferred embodiment, the first surface is processed prior to the rounding by material removal, preferably by grinding. The material-removing processing, by way of which, for example, the first surface can be prepared for the coating as such, in this case produces the (sharp) edge, which is then removed again in step i) in a targeted manner.
In accordance with a preferred embodiment, the rounding of the edge comprises a processing with a brush, in particular with an industrial brush. A combined process is preferred, namely, if the rounding introduced using the brush is subsequently additionally processed by grinding. The rounding can accordingly be smoothed, for example, in a vibratory grinding process. By way of the combined steps, it is possible to produce a very gentle, smoothly extending contour. As viewed in section, the rounding extends in each case tangentially in the respective surface, which is generally preferred (even independently of the combination of brushing and grinding).
In a preferred embodiment, the application of the coating in step i) occurs in a galvanic manner, that is, as an electrochemical deposition. In this case, the component or the surface to be coated is placed in a bath and a current is applied to it as an electrode, such as, for example as a cathode for the accumulation of positive metal ions. By way of the rounding, it is thereby possible to prevent a concentration of electrical field lines and thus any excess material deposition; see also the above comments. In general, however, the coating can also take place by a chemical coating that does not involve an external current or by soldering.
In a preferred embodiment, the coating comprises a metal matrix, preferably one made up of nickel with incorporated particles of boron nitride as hard material; this can involve, in particular, a so-called Ni/cBN coating. The boron nitride, on the one hand, may be of interest on account of its high strength, in particular for the preparation of blade tips for running-in. On the other hand, the brittle material may as such be prone to cracking or cBN crystals may be present in the coating and, on account of their edged structure, may represent sites for initiation of crack propagation. Through the reduction or prevention of the overhang of the coating by way of the rounding, it is possible to diminish at least the risk of initiation of cracks. Instead of the particles of cBN hard material, it is also possible to use similarly hard particles, such as, for example, diamond particles or carbides.
As already mentioned, the component preferably involves a blade body for a turbomachine that is therefore arranged in the gas channel thereof. Preferably, the blade body is part of a rotating blade and the radially outer-lying blade tip surface thereof is the “first” surface. The then rounded edge accordingly lies between the blade tip surface and a suction side surface or pressure side surface; preferably, both edges are rounded. In general, a use for compressor guide vanes as well as in the turbine region is also conceivable; what is preferably involved is a compressor blade.
The invention also relates to a method for the production of such a component, in particular of a blade body, preferably of a rotating blade/compressor blade, and, namely, by coating in accordance with the present disclosure.
The invention further relates to a component for a turbomachine that has been produced in a corresponding method, in particular a blade body of a rotating blade/compressor blade. The coating applied to the first surface is here at most flush with the second surface as viewed in section, that is, it does not overhang outward (it can be slightly displaced inward).
The invention is described in detail below on the basis of exemplary embodiments, whereby the individual features in the scope of the dependent claims can also be a key part of the invention in another combination and, here, too, no distinction is made in detail between the different claim categories.
Shown in detail are:
Number | Date | Country | Kind |
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10 2021 113 698.9 | May 2021 | DE | national |
10 2021 132 256.1 | Dec 2021 | DE | national |