Profiled surface used as an abradable in flow machines

Abstract

The profiled surface is used as an abradable (1) in flow machines. In these machines blade tips (2) move over the profiled abradable in a predetermined direction (v). In so doing they produce a partial surface, an abraded surface (10), which is formed by material ablation. The profiling of the surface is formed by ribs (15) which surround chamber-like depressions (11). A rib direction can in each case be associated with the ribs. The abradable (1) forms a pattern which is built up of strip-like elements (5) and the elements of which lie in the directions of the ribs on connection lines (45) between corner points (41, 42; 43, 44) of a reference grid (40). Largely at each location of the abraded surface (10)—i.e. at least at more than 80 - 95% of the abraded surface—the rib direction differs from the direction of movement (v) of the blade tips (2). For at least two thirds of the abraded surface the direction of movement deviates from the rib direction by more than 30°, preferably more than 45°. The strip-like elements (5) of the abraded surface can be curved as well as discrete and/or partly connected strips.

Description

[0001] The invention relates to a profiled surface in accordance with the preamble of claim 1 which is used as an abradable in flow machines and to a flow machine with an abradable of this kind. The profiled surface which is used as an abradable will be named an abradable for short in the following.

[0002] In flow machines such as airplane propulsion units, stationary gas turbines, turbocompressors and pumps it is necessary for a high efficiency that at the periphery of a rotor carrying rotor blades a sealing gap between the blade tips and the housing be very narrow during operation. With the use of abradables on the inner surface of the housing over which the tips of the rotor blades move, it is possible to produce minimum sealing gaps without the blade tips thereby being damaged. For high operating temperatures, which lie above about 800° C., the abradables must be manufactured with a ceramic material, which is applied by means of thermal spraying methods, flame spraying or atmospheric plasma spraying. Through the admixing of a phase which can be burned out (polymer powder) to a ceramic spraying powder, a porosity of the abradable can be achieved thanks to which fine particles can be released from the surface of the abradable by the blade tips of the rotating rotor.

[0003] In ceramic abradables with non profiled surface the blade tips must usually be armored, for example through laser re-melting with the simultaneous addition of hard particles in order that they are not damaged during the abrasion. Released abrasion particles must be able to escape from the sealing gap without substantial resistance. An abradable with a profiled surface is known from EP-A-0 935 009. It was expected from the latter that abrasion particles could escape without problems from the sealing gap and that an armoring of the blade tips could be dispensed with. Tests showed however that material was abraded at the non armored blade tips during the abrasion in a manner which led to a corrugated edge of the blade tips. A material ablation of this kind at the blade tips can not be tolerated.

[0004] The object of the invention is to create an abradable which is suitable for non armored blade tips. This object is satisfied by the abradable which is characterized in claim 1.

[0005] The profiled surface is used as an abradable in flow machines. In these machines blade tips move over the profiled abradable in a predetermined direction. In so doing they produce a partial surface, an abraded surface, which is formed by material ablation. The profiling of the surface is formed by ribs which surround chamber-like depressions. A rib direction can in each case be associated with the ribs. The abraded surface forms a pattern which is built up of strip-like elements and the elements of which lie in the directions of the ribs on connection lines between corner points of a reference grid. Largely at each location of the abraded surface—i.e. at least at 80% to 95% of the abraded surface—the rib direction differs from the direction of movement of the blade tips. For at least two thirds of the abraded surface the direction of movement deviates from the rib direction by more than 30°, preferably more than 45°. The strip-like elements of the abraded surface can be curved as well as discrete and/or partly connected strips.

[0006] Thanks to the design of the profiling of the abradable in accordance with the invention, which is carried out taking the direction of movement of the blade tips into account, there results a lower material ablation at the non armored blade tips and in addition a material ablation which is uniformly distributed over the entire edge of a tip. In order to reduce the material ablation at the blade tips still further, it can also be provided to armor the blade tips.

[0007] Subordinate claims 2 to 7 relate to advantageous embodiments of the abradable in accordance with the invention. The subject of claims 8 to 10 is a flow machine with an abradable of this kind.

[0008] The invention will be explained in the following with reference to the drawings. Shown are:

[0009] FIG. 1 a cross-section through an abradable with a blade tip running over an abraded surface,

[0010] FIG. 2 an oblique view of the abradable,

[0011] FIG. 3 a first pattern of the abraded surface of an abradable in accordance with the invention,

[0012] FIGS. 4, 5 modifications of the first pattern,

[0013] FIGS. 6 - 10 patterns of further abraded surfaces in accordance with the invention,

[0014] FIG. 11 a reference grid with a “Penrose” structure comprising equilateral pentagons and rhombi,

[0015] FIG. 12 a corresponding pattern of an abraded surface and

[0016] FIG. 13 a blade tip with a shrouded blade.

[0017] The abradable 1 which is illustrated in FIG. 1 as a cross-section has a profiled surface, over which a blade tip 2 moves in a plane 20 in a predetermined direction v. Ribs 15 form the profiling of the surface; they surround chamber-like depressions 11. An original surface 10″ of the abradable 1 is indicated in chain-dotted lines. An abraded surface 10 in a plane 10′ has been formed by the blade tip 2 through material ablation. A narrow gap between the plane 20 and the abraded surface 10 is a sealing gap which is produced by the material ablation. The abraded surface 10 forms a pattern which can be imagined as being built up of strip-like elements 5. The abradable 1 with the abraded surface 10 and depressions 11 is illustrated in an oblique view in FIG. 2. The following FIGS. 3 to 12 show diverse patterns of the abraded surface 10, such as result through material ablation of the abradables 1 in accordance with the invention. The strip-like elements 5 of the abraded surface 10 can be curved; they can also be present as discrete and/or as partly connected strips.

[0018] The abradable 1 is applied to a metallic substrate 3 through thermal spraying, with a material being used which for example contains ceramic material for use at high temperatures and which can already be known for the use in non profiled abradables (see e.g. U.S. Pat. No. 5,434,210). The substrate 3 has a profiled surface with webs 35. This profiling can be present in different forms: as a cast profiling of a cast body; as a profiling which is produced on an originally flat metallic body by means of countersink erosion or by means of a mechanical cutting process; as a profiling of woven or individual metallic wires which are applied to a metallic body through soldering or by means of a laser welding or diffusion welding; or as a profiling in the form of ribs which are applied in a micro-casting manner through a laser application welding.

[0019] In order that a build-up of ribs 15 is possible in the thermal spraying onto the webs 35, it must be provided that the widths of the strip-like elements 5 are greater than about 1 mm. In order that no damage arises in the ablation of material from the abradable 1, these widths must be on the same order of magnitude as the cross-sectional width of the blade tip (width in the direction of travel v); they should not exceed one to three times this cross-sectional width.

[0020] The webs 35 have cross-sections which narrow in the direction towards a rump 30 of the substrate 3. They can also form gaps to the rump 30, as is known from the above named EP-A-0 935 009. As a result of this shaping the material which forms the abradable 1 is anchored in depressions 31 between the webs 35.

[0021] A rib direction can be associated in each case with the ribs 15. In accordance with the invention the rib direction must differ largely at each location of the abraded surface 10 from the direction of movement v of the blade tip 2. In this, the term “largely” is to be understood to mean that a like orientation of the blade movement and the ribs is present for at most 5 - 15% or 20% of the abraded surface 10. To which extent these orientations can be the same must be determined empirically. For at least two thirds of the abraded surface 10 the direction of movement v must deviate in accordance with the invention from the rib direction by more than 30°, preferably more than 45°. If these conditions are met, then a non armored blade tip 2 can be used.

[0022] In FIG. 3 a first pattern of the abraded surface 10 of an abradable 1 in accordance with the invention is shown. The pattern is built up of the strip-like elements 5. These elements 5 lie in the directions of the ribs 15 on connection lines 45 between corner points 41, 42 of a reference grid 40. Three axes x1, x2, y can be associated with each corner point 41 or 42 of the reference grid 40. Angles &agr;12, &agr;2, and &agr;1 respectively are subtended between these axes. Ribs 15, which are designated by a1, a2, b lie on the axes x1, x2 and y respectively. The ribs a1 and a2 are longer than the rib b by a factor of 2 or more. The angles &agr;1, &agr;2, a12 are in each case greater than 100° and less than 150° (total sum 360°). The pattern shown has a generalized honeycombed structure: connection lines 45 between in each case six corner points of the reference grid 40, namely three corner points 41 and three corner points 42, can be associated with the ribs 15 of the chamber-like depressions 11.

[0023] Each axis y is at least approximately parallel to a single y-direction. The direction of movement v of the blade tip 2 deviates from the y-direction by a small angle, which is 30° at the most. The rib b is preferably much smaller in comparison with the ribs a1, a2, namely by a factor which is greater than 3. The corner points 41 and 42 which are associated with the rib b can be so close to one another that the rib b is practically negligible, i.e. does not exist.

[0024] FIGS. 4 and 5 show modifications of the first pattern (FIG. 3). In FIG. 4 the pattern has a structure which resembles a covering with fish scales. The ribs 15 are curved. In FIG. 5 the pattern is composed of discrete elements 5. Only ribs a1 and a2 are present; instead of the ribs b there are gaps.

[0025] FIG. 6 again shows a pattern of the abraded surface 10 which is honeycomb-like. Elements 5′ are arranged like islands in the individual depressions 11. In FIG. 7 the strip-like elements 5 are arranged connectedly on zigzag lines. The angles between the rib directions and the direction of movement v is preferably 45° or else somewhat greater. The boundaries of the chamber-like depressions 11 can not be given here uniquely; they can for example be considered to be the rectangles 11′ which are drawn in chain-dotted lines. FIG. 8 again shows a pattern with discrete elements 5, as does FIG. 5. This pattern has a certain relationship with the zigzag pattern of FIG. 7 in that in this pattern every other element 5 of the zigzag pattern is removed and the remaining elements 5 are each prolonged at both ends. FIG. 9 shows a pattern with depressions 11 which are rectangular and are arranged to be displaced with respect to one another. A rhombic pattern is illustrated in FIG. 10 in which the one rib direction is perpendicular to the direction of movement v and the other rib direction subtends an angle of about 45° with the direction of movement v.

[0026] In the exemplary embodiments of FIGS. 3 to 10 the abraded surfaces 10 have in each case a profiling of which the reference grid 40 can be built up of periodically arranged elementary cells (hexagons or squares). A non periodic profiling is also possible, the reference grid 40 of which for example has a “Penrose structure” in accordance with FIG. 11. FIG. 12 shows a corresponding pattern of an abraded surface 10 with depressions 11′ and 11″ which are pentagonal or rhomboidal. This reference grid 40 comprises equilateral pentagons (angles between adjacent sides: 108°) and rhombi (angle: 36° and 144°). Whereas in the periodic grids two or three main directions are present, there are five main directions in the “Penrose structure”. The direction of movement v of the blade tips 2 advantageously deviates from one of these main directions by about 18°.

[0027] For a reference grid 40 which at least approximately has a “Penrose structure”, the following statements hold (cf. FIGS. 11, 12): Three axes x1, x2, y can be associated with each corner point 43 or 44 of the reference grid 40. Angles &agr;12, &agr;2, and &agr;1 respectively are subtended between these axes. Ribs a1, a2 lie on the axes x1, x2. The ribs a1 and a2 are largely equally long. The angles &agr;1, &agr;2, &agr;12 are in each case greater than 100° and less than 150° (total sum 360°). For one portion of the corner points, namely the corner points 43, one rib b lies on the axis y. For the further corner points 44 a branching about the axis y with two ribs b1, b2 is given in each case. The ribs b and, respectively, b1 and b2 are largely of length equal to that of a1 or a2. An angle &bgr;12 between b1 and b2 is greater than 30° and less than 45°. The direction of movement v of the blade tip 2 is substantially parallel to the axis y of one of the branchings.

[0028] The above described abradables can also be applied to a movable machine part instead of to a housing wall, namely when the blade is stationarily arranged, in particular is a rotor blade, and the sealing gap is located between the blade tip at rest and the moved machine part, with the machine part being in particular a rotor shaft. Abradables can also be applied to shrouded blades at the tips of stationary blades. The movement of the blade tip named in claim 1 is therefore to be understood as a relative movement.

[0029] A flow machine with an abradable 1 in accordance with the invention can also contain blades of which the tips 2 are in each case formed as a shrouded blade 21: see FIG. 13. The shrouded blade 21 has one or more lamella 22, 22′ which extend in the direction of movement v of the blade tip 2. When a plurality are present the lamella 22, 22′ form a labyrinth seal.

Claims

1. Profiled surface which is used as an abradable (1) in flow machines, in which blade tips (2) move over the profiled abradable in a predetermined direction (v) and in so doing produce a partial surface—an abraded surface (10)—which is formed by material ablation, with the profiling of the abradable being formed by ribs (15), with it being possible in each case to associate a rib direction with the ribs and with the abraded surface forming a pattern which is built up of strip-like elements (5) and the elements of which lie in the directions of the ribs on connection lines (45) between corner points (41, 42; 43, 44) of a reference grid (40), characterized in that largely at each location of the abraded surface (10)—i.e. at least at 80%, preferably at more than 90% of the abraded surface—the rib direction differs from the direction of movement (v) of the blade tips (2); in that for at least two thirds of the abraded surface the direction of movement deviates from the rib direction by more than 30°, preferably more than 45°; and in that the strip-like elements (5) of the abraded surface can be curved as well as discrete and/or connected or partly connected strips.

2. Profiled surface in accordance with

claim 1, characterized in that three axes x1, x2, y can be associated with each corner point (41, 42) of the reference grid (40) and angles &agr;12, &agr;2, and &agr;1 respectively are subtended between these axes; in that ribs a1, a2, b lie on the axes X1, X2 and y respectively, with a1 and a2 being longer by a factor of 2 or more in comparison with b and with the angles &agr;1, &agr;2, &agr;12 in each case being greater than 100° and less than 150°; in that all axes y are at least approximately parallel to one another, i.e. are oriented in a single y-direction; and in that the direction of movement (v) of the blade tip (2) deviates from the y-direction by a small angle, which is 30° at the most.

3. Profiled surface in accordance with

claim 1 or

claim 2, characterized in that connection lines (45) between in each case six corner points (41, 42) of the reference grid (40) can be associated with the ribs (15) of the chamber-like depression (11).

4. Profiled surface in accordance with claims 2 and 3, characterized in that a gap is present instead of the rib b; or in that the ribs a1, a2 are longer than the rib b by a factor of 3 or more; or in that the length of the rib b is practically negligible.

5. Profiled surface in accordance with

claim 1, characterized in that three axes x1, x2, y can be associated with each corner point (43, 44) of the reference grid (40) and angles &agr;12, &agr;2, and &agr;1 respectively are subtended between these axes; in that ribs a1, a2 lie on the axes x1, x2, with the ribs a1 and a2 being largely equally long and with the angles &agr;1, &agr;2, &agr;12 in each case being greater than 100° and less than 150°; in that for one portion of the corner points (43) one rib b lies on the axis y and for the further corner points (44) in each case a branching about the axis y with two ribs b1, b2 is given, with b and, respectively, b1 and b2 being largely of length equal to that of a1 or a2, with an angle &bgr;12 between b1 and b2 being greater than 30° and less than 45° and with the direction of movement of the blade tip being substantially parallel to the axis y of one of the branchings.

6. Profiled surface in accordance with any one of the

claims 1 to

5, characterized in that the widths of the strip-like elements (5) are greater than about 1 mm and are on the same order of magnitude as the cross-sectional width of the blade tip, in particular less than one to three times this width.

7. Profiled surface in accordance with any one of the

claims 1 to

6, characterized in that it is manufactured by thermal spraying onto a metallic substrate (3) with a material which is suitable for known, non profiled abradables and which in particular contains ceramic material, with the substrate having a profiled surface having webs (35) and with it being possible for the profiling to be present in different forms: as a cast profiling of a cast body; as a profiling of woven or individual metallic wires which are applied to a metallic body through soldering or by means of a laser welding or diffusion welding; or as a profiling in the form of ribs which are applied in a micro-casting manner through a laser application welding.

8. Flow machine, in particular a gas turbine, comprising a profiled surface which is used as an abradable (1) in accordance with any one of the

claims 1 to

7, characterized in that the blade tip (2) is part of a rotor blade.

9. Flow machine in accordance with

claim 8, characterized in that the blade tip (2) is formed by a shrouded blade which has one or more lamella which extend in the direction of movement (v) of the blade tip and are therein formed in particular as sealing lips of a labyrinth seal.

10. Flow machine, in particular a gas turbine, with a profiled surface which is used as an abradable (1) in accordance with any one of the

claims 1 to

7, characterized in that the blade tip (2) is part of a stationary guide blade and a sealing gap is located between the blade tip and a moved machine part, with it being possible for the abradable to be attached to a shrouded blade at the tip of the stationary blade or to the surface of a rotor shaft and the movement of the blade tip which is named in

claim 1 being understood as a relative movement.