The present invention relates to a segmented ring for installation in a turbomachine.
The turbomachine may be, for example, a jet engine, such as a turbofan engine. The turbomachine is functionally divided into a compressor, a combustor and a turbine. In the case of the jet engine, for example, intake air is compressed by the compressor and mixed and burned with jet fuel in the downstream combustor. The resulting hot gas, a mixture of combustion gas and air, flows through the downstream turbine and is expanded therein. The turbine is typically divided into several modules; i.e., it may include, for example, a high-pressure turbine module and a low-pressure turbine module. Each of the turbine modules typically includes a plurality of stages, each stage being composed of a stator vane ring and a rotor blade ring downstream thereof.
The segmented ring in question is intended for installation in a turbomachine, for example in a turbine module. It may be mounted, for example, to a casing part and then carry a jacket ring segment disposed radially inwardly on the casing part. Such a jacket ring segment radially outwardly bounds the gas duct at the axial position of a rotor blade ring and may be provided radially inwardly with a sealing system or an abradable coating. This is intended to illustrate the present subject matter or a preferred application thereof, but initially not to limit the generality thereof (the segmented ring may also perform another mounting function in the turbomachine).
It is an object of the present invention to provide a particularly advantageous segmented ring.
The present invention provides a segmented ring that is adapted for installation or assembly from inside radially outward and for this purpose is circumferentially divided into segments. To reduce leakage, a sealing insert is inserted at a joint where two immediately circumferentially adjacent segments meet. To this end, each of the two segments has formed therein a pocket which is open toward the joint and in which the sealing insert is seated. The sealing insert is axially retained in the pockets and bridges the joint, and thus blocks clearance flows and increases tightness.
Furthermore, one of the mutually facing pockets is not only open toward the joint, but also in a radial direction. This is advantageous with respect to radial assembly of the segmented ring, in particular complete and/or closed segmented ring, since the corresponding segmented ring can be slid radially onto the sealing insert without requiring a simultaneous displacement in a non-radial direction and/or an axial direction for this purpose and/or in particular for providing the complete and/or closed segmented ring. The segmentation and the assembly from radially inside open up interesting mounting possibilities on the one hand, and since a joint formed between two segments is thereby additionally sealed, it is on the other hand nevertheless possible to limit possible leakage. Due to the inventive design of the pockets, the joint can be closed by a sealing insert, which provides efficient sealing while still allowing assembly from radially inside.
Preferred embodiments will be apparent from the dependent claims and the entire disclosure. In the description of the features, a distinction is not always drawn specifically between device, method and use aspects. In any case, the disclosure should be read to imply all claim categories. In particular, it should always be read as relating to both the segmented ring and an assembly or module having such a segmented ring, as well as to corresponding uses.
In the context of the present disclosure, “axial” generally relates to the ring axis of the segmented ring. In the installed state; i.e., when installed in the turbomachine or a module thereof, the ring axis typically coincides with the longitudinal axis of the turbomachine or the axis or rotation about which the rotor blade rings rotate. “Radial” refers to the radial directions that are perpendicular to the ring axis or longitudinal axis and point away therefrom; and a “circumference,” respectively “circumferential” or the “circumferential direction” relate to the rotation about the axis. “Forward” and “rearward” relate to the axial component of the direction of flow of the hot gas. Thus, the hot gas axially passes “forward” components before it passes “rearward” components. In the context of the present disclosure, “a” and “an” are to be read as indefinite articles and thus always also as “at least one,” unless expressly stated otherwise. Reference is primarily made to “a” joint and the pocket, which is radially open there. Overall, there is a plurality or multiplicity of joints around the circumference; and preferably, a sealing insert is disposed at each of the joints. In principle, this could also be achieved with pockets which are only circumferentially open at the other joints (the segment having the radially open pocket is positioned last), but preferably every one of the sealing inserts of the segmented ring is disposed in a respective radially open pocket.
The segmented ring; i.e., its segments, may be produced, for example, by turning and milling from a forged ring. However, the segments may also be cast parts (in conjunction with subsequent machining of the functional surfaces). Finally, additive manufacturing may also be used; i.e., the segmented ring or the segments may be additively built up layer by layer from a previously amorphous or shape-neutral material. The pockets may be taken into account already during the initial shaping process, but may also be formed by a material-removal process, such as, for example, by electrical discharge machining (spark machining).
The radially open pocket allows the corresponding segment to be slid radially onto the sealing insert. To this end, the pocket is oriented in the insertion direction in which the segment(s) are assembled. The insertion direction may generally also have an axial component (for example, when viewed in an axial section, it may be tilted from the radial direction by more than 30°); preferably, it is perpendicular to the axial direction. The radially open pocket could in principle also be open radially inwardly (and closed radially outwardly). During assembly, this segment would then be positioned first, and the other segment would subsequently be positioned together with the sealing insert which, in this process, would be disposed in the closed pocket thereof and would slide into the radially inwardly open pocket.
However, in a preferred embodiment, the radially open pocket is radially outwardly open and radially inwardly closed. Accordingly, the segment having this pocket can be slid from radially inside onto the sealing insert, which is already positioned in the pocket of the other segment. Unlike with a radially inwardly open pocket, in the installed state, the sealing insert is then secured from falling out radially inwardly and radially outwardly because the open pocket is oriented toward the casing wall.
In a preferred embodiment, the radially closed pocket is closed both radially inwardly and radially outwardly. Thus, preferably, the radially open pocket is open in exactly one radial direction, preferably radially outwardly, and the other pocket is closed in both radial directions. Thus, the sealing insert is already substantially captively retained in the closed pocket before the segments are assembled together. To provide protection against falling out, it is also generally possible to use a grease which holds the sealing insert like a glue.
With this also in mind, in a preferred embodiment, the closed pocket is dimensioned such that its depth taken perpendicular to the joint is at least 0.1 times its height taken parallel to the joint. The pocket is dimensioned so as to prevent the sealing insert from rotating out of position before the segments are assembled together. Further preferred lower limits of the depth are at least 0.2, 0.3 or 0.4 times the height, and possible upper limits (independent of the lower limits) may, for example, be at most 2, 1.5, 1 or 0.8 times the height.
In a preferred embodiment, the sealing insert is a sealing plate.
The sealing insert, in particular the sealing plate, which is, for example, a planar sealing plate, preferably seals the joint and/or an inter-segment gap the between immediately circumferentially adjacent segments in the axial direction. In the case of a planar sealing plate, the axial direction is preferably normal to the plane of the plate or at least substantially normal to this plane; i.e., has a maximum deviation of 10°, in particular 5°, from the exactly normal orientation.
In a preferred embodiment, a retaining ring is provided on which the segments of the segmented ring are seated and supported radially inwardly. To this end, the retaining ring may extend uninterruptedly in the circumferential direction. Preferably, the retaining ring is axially pressed into a receptacle in the segmented ring and retained by a press fit therein. At the receptacle, the segmented ring preferably forms a radially projecting projection behind which the retaining ring is axially form-fittingly retained. The projection is so dimensioned that the retaining ring can be axially pressed into place, but is then secured in the axially opposite direction. Preferably, this is assisted by a beveled face (saw-tooth profile) along which the retaining ring slides as it is pressed into place.
The embodiments described below relate to the orientation or extension of the abutting faces with which the segments of the segmented ring meet in a respective joint. Two immediately circumferentially adjacent segments have complementary abutting faces at the respective joint.
In a preferred embodiment, one of each two adjacent segments has abutting faces which are parallel to each other and thus parallel to an insertion direction of this segment (when viewed in the axial direction). Such a segment can be inserted radially outwardly, even when the two immediately circumferentially adjacent segments are already in position. Considered with respect to the segmented ring as a whole, the mutually parallel abutting faces are preferably oriented in such a way they or their projections toward the opposite side of the segmented ring frame its ring axis centrally therebetween.
In a preferred embodiment, such a segment having mutually parallel abutting faces has a pocket with a sealing insert therein at each of the two circumferential sides. Preferably, these two pockets are each radially outwardly open and radially inwardly closed. Preferably, every other segment in the circumferential direction has two mutually parallel abutting faces. Preferably, these segments are identical in construction among themselves, and the complementary segments interposed therebetween are also identical in construction among themselves, so that the entire segmented ring can be built using only two different types of segments.
In another preferred embodiment, the segment(s) is or are mounted in such a way that the segmented ring can ideally be built from only one type of segment. To this end, one of the segments that meet at the joint has an abutting face that is oblique to the radial direction there. Specifically, the oblique abutting face forms an angle α of at least 85° and no more than 110° with a connecting line extending diagonally through the segment to the outer corner of the oblique abutting face. Further preferred upper limits are no more than 100° or 95°; further preferred lower limits (independent of the upper limits) are at least 88° or 90° (with increasing preference in the respective order of mention). By suitably limiting the angle α, the segment can be inserted even when the immediately circumferentially adjacent segments are already in their installed positions. To this end, the segment can initially be placed in position with its opposite abutting face and then, as it were, rotated into engagement with the oblique abutting face (see
In a preferred embodiment, the segment is provided with the radially outwardly open (and radially inwardly closed) pocket at this oblique abutting face. As described in the preceding paragraph, such a segment may initially be hooked into place with its opposite abutting face and then rotated into its installed position, during which movement the sealing insert slides into the radially outwardly open pocket of the segment. Preferably, all segments are identical in construction, and thus rotationally symmetric about the ring or longitudinal axis. The handling of only one type of segment may simplify assembly and warehousing.
The present invention also relates to a segmented ring assembly including a segmented ring as disclosed herein and a mounting part, preferably a casing part. The segmented ring is axially form-fittingly mounted on the mounting part, and specifically on a form-fitting element thereof. To this end, the individual segments are each radially outwardly assembled with the form-fitting element. Preferably, a jacket ring segment is mounted radially inwardly on the casing part (see also the remarks made at the outset). In this connection, the segmented ring serves for the mounting of the jacket ring segment; the segmented ring is mounted on the casing part, and the jacket ring segment then rests and is supported radially inwardly thereon. This configuration may be advantageous with respect to the thermal gradients (in particular in the casing area) and, in addition, allows for installation and removal from an axially forward end.
The present invention also relates to a turbine module having a such a segmented ring assembly, where a rotor blade ring is disposed radially inwardly of the jacket ring segment. Preferably, the segmented ring assembly is provided at the axially forward end of the turbine module. During an overhaul, the modules can on the one hand be relatively easily separated from one another; and then they are each also accessible from an axially forward end; on the other hand, the components that are disposed at the axially forward end may be highly stressed and therefore require frequent overhauling.
The present invention also relates to the use of a turbine module or a segmented ring or a corresponding segmented ring assembly in a turbomachine, in particular in a jet engine, such as, for example, a turbofan engine.
The present invention will now be explained in more detail with reference to an exemplary embodiment. The individual features may also be essential to the invention in other combinations within the scope of the other independent claims, and, as above, no distinction is specifically made between different claim categories.
In the drawings,
In order to mount jacket ring segment 22 on casing part 21, a segmented ring 25 is provided which is circumferentially divided into a plurality of segments (see
Form-fitting element 26; i.e., the web of casing part 21, is provided with a bore 31, which is optional and may be used to supply a cooling fluid. Furthermore, the shielding plates 32 disposed radially between casing part 21 and jacket ring segment 22 are also optional; the inventive approach could also be implemented with an insulating material or the like between casing part 21 and jacket ring segment 22.
Pocket 51 in segment 36 is closed both radially inwardly and radially outwardly; sealing insert 46 is inserted in the circumferential direction. In contrast, pocket 50 in segment 35 is closed only radially inwardly, but open radially outwardly. During assembly, initially the segment 36 with the sealing insert 46 is positioned. Then, segment 35 with its mutually parallel abutting faces 35a can be inserted from radially inside, during which movement sealing insert 46 slides into the radially outwardly open pocket 50. The segment 35 is symmetrical in configuration, and thus has another radially outwardly open pocket at the other circumferential end.
Number | Date | Country | Kind |
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102018210601.0 | Jun 2018 | DE | national |
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