Centrifugal compressor provided with a marker for measuring wear and a method of monitoring wear using said marker

Abstract

A device and method for precise measurement of erosion of compressors, without removing an engine, and with easy positioning. A centrifugal compressor of a gas turbine with a radial air inlet includes an impeller including blades and a casing for an air stream to flow in the blades of the impeller. The casing, covered with an abradable coating, includes an annular elbow zone in a substantially median part. Marking depressions of predetermined depths, preferably in groups, are machined in the abradable coating of the zone. Examinations by endoscopy are successively performed to provide an image signal of the markers. Processing the endoscopic signal supplies a number of remaining markers and a criterion for decision on removing the engine is applied thereto. Erosion occurs in the elbow of the casing and evolution thereof may enable monitoring of erosion of other components of the compressor, in particular the blades of the impeller.

Claims

1. A centrifugal compressor of a gas turbine with a radial air inlet, comprising: an impeller including vanes; and a casing for delimiting a flow of an air stream in the vanes, a central part of the casing including an annular zone forming an elbow, wherein the casing is covered with an abradable coating, wherein a marking depression of a predetermined depth as a marker is machined in the abradable coating in the annular zone forming the elbow, the marker includes a face and walls connecting a surface of the abradable coating to the face of marker, and a distance between the surface of the abradable coating and the face of the marker is equal to the predetermined depth, wherein the casing includes two groups, each group including two markers, the groups of markers being distributed along the annular zone forming the elbow of the casing, the groups of markers being distributed at a predetermined distance from each other, and wherein the markers of each group have different and quantified predetermined depths.

2. A centrifugal compressor according to claim 1, wherein the markers of each group are aligned in the annular zone forming the elbow, and installation of the markers of each group is chosen between a meridian, a radius, and a line inclined between the meridian and the radius.

3. A centrifugal compressor according to claim 2, wherein the markers of a same group are less than 10 mm apart to be configured to undergo a same type of erosion.

4. A centrifugal compressor according to claim 1, wherein the marker has a maximum aperture of less than 1 mm so as not to be blocked by ingestion of foreign bodies, or ingestion of grains of sand.

5. A centrifugal compressor according to claim 1, wherein the marker has a shape chosen from among a cylindrical shape, or a bore with a base which is circular or oblong, a spherical segment, a conical shape, and a grooving.

6. A method of monitoring wear on a centrifugal compressor, the method comprising: providing a casing with a central part of the casing including an annular zone forming an elbow, the casing being covered with an abradable coating; producing at least two markers by machining depressions of a predetermined depth in the abradable coating of the annular zone forming the elbow of the casing, each of the at least two markers including a face and walls connecting a surface of the abradable coating to the face of each of the markers, and a distance between the surface of the abradable coating and the face of the marker is equal to the predetermined depth; performing examinations by endoscopy successively over time; introducing, for each examination, an endoscope into the compressor, and positioning an active end of the endoscope facing each of the at least two markers to provide an image signal of each of the at least two markers; processing the image signal to determine a number of remaining markers; and applying a criterion for decision on removing the engine based on the number of remaining markers and comparative wear data, wherein the markers have different depths and a difference between closest two depths is determined according to a calibrated degree of advance of wear.

7. A method of monitoring wear according to claim 6, wherein the markers are distributed over a circumference of the annular zone forming the elbow of the casing at a predetermined distance from each other.

8. A method of monitoring wear according to claim 6, wherein a comparison between the number of remaining markers during successive examinations supplies a measurement of a speed of erosion and progress of wear on the casing and other parts of the compressor, based on extrapolating stored data relating to correlations of wear between parts of the compressor.

9. A method of monitoring wear according to claim 8, wherein for each examination, the decision criterion compares the number of remaining markers with a critical number established as a function of stored data, and an engine is removed for replacement of the worn parts when the critical number is reached.

Description

DESCRIPTION OF THE DRAWINGS

(1) Other data, characteristics and advantages of the present invention will become apparent by reading the following description, which is not limited, with reference to the appended drawings, in which, respectively:

(2) FIG. 1 shows a partial sectional view of a helicopter turboshaft engine including a compressor according to the invention;

(3) FIG. 2 shows a partial axial view of a casing according to the invention including two groups of three markers aligned on a radius and on a meridian of the elbow of the casing;

(4) FIG. 3 shows a general axial view of an example of a casing according to the invention including three groups of three markers aligned on a meridian, and

(5) FIGS. 4 and 5 show sectional and perspective views of three markers of one of the preceding groups, and

(6) FIG. 6 shows an example of a flow diagram of the steps for implementing the method of measuring wear according to the invention.

DETAILED DESCRIPTION

(7) The turboshaft engine 100 illustrated by the sectional view in FIG. 1 includes, substantially axially symmetrically about the central axis X′X: a centrifugal compressor 1; turbines 2 and 3 for driving the compressor 1 and power axes of the helicopter (propeller, transmission housing, etc.) via a through shaft 4; a radial inlet 5 of a sleeve 50 for circulating a fresh air stream F1, and a combustion chamber 6.

(8) More precisely, the centrifugal compressor 1 principally comprises a compression impeller 10 provided with blades 11 and supplied with air F1, a casing 12 limiting an annular channel in which the air stream F1 flows, and a radial diffuser 13 with fins 14.

(9) In operation, the air stream F1 is first drawn into the fresh air inlet 2, then compressed between the blades 11 of the impeller and the casing 12. The compressed air flow F1 then exits radially from the impeller 10.

(10) The air stream F1 then passes through the diffuser 13 formed on the periphery of the compressor 1, in order to be straightened by the curved blades and transported towards inlet channels 60 of the combustion chamber 6.

(11) In operation, the air stream F1 which contains foreign particles, for example grains of sand, will erode the main parts of the compressor: the rotary blades 11 of the impeller, the casing 12 and the blades 14 of the diffuser.

(12) In order to measure the progress of this erosion, the casing 12 is machined in order to produce marker depressions 14 as illustrated by FIG. 2. The casing 12 has in its central part an annular zone forming an elbow 12a. A first group G1 of three markers M1, M2, and M3 have been machined in this elbow 12a. The markers of the group G1 are aligned on a meridian 120 (represented by dotted lines) of the elbow 12a. Another example of alignment of the markers M1 to M3 is also illustrated. In this alignment, the markers M1 to M3 form a group G2 along a radius 121 (represented by dotted lines) of the elbow 12a.

(13) In this case, the markers have a cylindrical shape with a circular base. Alternatively, other shapes are possible: a bore with an oblong base, a spherical segment, a conical shape, or grooving.

(14) In general, the markers of one and the same group are sufficiently close together, less than 10 mm apart, to be able to undergo the same type of erosion. In addition, the markers have a maximum aperture of less than approximately 1 mm so as not to be blocked by the ingestion of foreign bodies, in particular grains of sand.

(15) The casing 12 is covered by a coating of a known abradable material, with a thickness of several millimetres, in order to avoid contact with the blades which would be detrimental to effective operation. The markers are machined in this abradable material.

(16) However, the casing is the part which is eroded by the air stream F1 and in particular the elbow 12a. In FIG. 2, the elbow 12a forms an eroded zone shown shaded in relation to the rest of the elbow. The wear on the casing and the elbow thereof in particular does not affect the effective functioning of the engine.

(17) With reference to the general axial view in FIG. 3, an example of a casing 12 according to the invention includes three groups G3 to G5 of three markers each, identical to the previously described markers M1 to M3. The markers are aligned on the meridian 120 and the groups G3 to G5 are regularly distributed at 120° over the circumference of the elbow 12a of the casing 12. Alternatively, the markers M1 to M3 can be aligned on a radius 121 as illustrated in FIG. 2.

(18) In the example, the markers have a substantially cylindrical shape and have different depths. The sectional and perspective views in FIGS. 4 and 5 show more precisely the three markers M1 to M3 and the different depths P1 to P3 thereof. The markers are cylindrical with polyhedral walls. They succeed one another with an increasing depth. The difference in depth between two adjacent markers is constant and quantified: it corresponds to a calibrated unit of advance of the wear. In the example, the depth quantum is 0.2 mm and the depths of the markers M1 to M3 are successively equal to 0.2, 0.4 and 0.6 mm. During examinations of the casing—by endoscopy for example—the degree of advance of the wear on the casing is between 0 and 0.2 mm if no markers have disappeared, between 0.2 and 0.4 mm if the marker M1 has disappeared, and between 0.4 and 0.6 mm if the marker M2 disappears.

(19) The disappearance of the marker M2 then leads to an inspection of the parts of the compressor in so far as such erosion of the casing signals, by extrapolation according to the type of engine and the use profile, critical erosion of the blades of the impeller. Such critical erosion corresponds to a limit of use which then necessitates a replacement of the eroded parts.

(20) In order to refine the measurement of the state of wear of the casing and therefore of the other parts, a larger number of markers per group with a lower quantification of depth, for example 0.1 mm, can be implemented.

(21) The flow diagram in FIG. 6 illustrates an example of a succession of steps which can be implemented in the context of the method of monitoring the wear on a given compressor according to the invention. In this example, markings—such as the groups of markers G3 to G5 comprising “i” markers Mi, “i” being equal to or greater than 3, for example equal to 4 or 5—are machined in the abradable coating of the elbow of the casing (step 100). More generally, more than three groups can be machined.

(22) Examinations by endoscopy are then performed successively over time (step 200), for example after each mission separated by durations Tj. For each examination, the endoscope is introduced into the compressor following intended routes until the active end of the endoscope reaches a position facing each of the three groups G3 to G5 in the example and supplies image signals of the markers Mi.

(23) A device for processing the signal DTS receives the endoscopic signals. The device then establishes the number of remaining markers Nr per group (step 300) and applies a decision criterion CD for removing the engine as a function of this number. The result of this application is supplied to an operator.

(24) During successive examinations over time, an erosion speed “Ve” and progress of the wear “Au” of the casing and the blades of the impeller are established by the device DTS on the basis of the number of remaining markers Nr and durations Tj. These data are also stored in the processing device (step 400).

(25) In order to do this, data DATA are also stored in the processing device relating to: the distribution of the erosion of the casing, the correlation of wear as a function of the configuration of the engines between the parts of the compressor making it possible to extrapolate that of the blades of the impeller from that of the casing, the profiles of the helicopter missions and the particle size of the foreign bodies ingested as a function of missions, the prior “Ve” and “Au” results relating to the engine examined as well as the “Ve” and “Au” results of engines as a function of their conditions of use.

(26) The criterion CD establishes a critical number of remaining markers “Nrc” and then interprets, as a function of the data DATA and the critical number of markers “Nrc”, the number of remaining markers “Nr” per group G3 to G5 in terms of the wear on parts, in particular the blades of the impeller, (step 500). For example, it may be that only the number of markers of the group G2 is critical. As long as this number is at least equal to two for the group G4, it is not necessary to remove the engine, even if the other groups G3 and G5 have a number of markers equal to one during an examination. Thus, for each engine, a critical number of remaining markers “Nrc”, at least equal to one, is established for each group of markers.

(27) During each examination, the number of remaining markers “Nr” per group G3 to G5 is predetermined. If this number “Nr” is equal to zero for at least one group, the decision criterion calls for the immediate removal of the engine “DEP” and the changing of the parts of the compressor exposed to wear (casing, blades of the impeller, fins of the diffuser). If the number Nr is equal to Nrc for the group in question, the removal is also decided on.

(28) Alternatively, the markers may not be distributed in groups, but for example regularly distributed along a meridian of the elbow. In this case, the number Nrc is simply equal to 1, unless the speed “Ve” or the advance of wear Au increases substantially: the number Nrc then becomes 2 in order to avoid any delayed replacement of components.

(29) The invention is not limited to the embodiments described and illustrated. Thus the markers may not be aligned with depressions in one and the same group, for example in accordance with the arrangements in a V, in a triangle, in a square, etc.