RU178569U1 - UNIT FOR FASTENING THE NOZZLE APPARATUS IN THE EXTERNAL TURBINE HOUSING - Google Patents

Abstract

The utility model relates to the field of gas turbine engines (GTE) and gas turbine units (GTU), in particular to turbine designs, and can be used in attachment points of the nozzle apparatus in the outer turbine casing. The technical result of the proposed utility model is to reduce the mass and overall dimensions of the nozzle stages apparatus and, consequently, the engine turbine, as well as reducing leakage of the working fluid above the nozzle apparatus, and reducing the time of routine maintenance for inspection (or repair), replacing alley and nodes of the nozzle apparatus and the turbine, since all work is carried out without dismantling the massive rotor. The technical result is achieved by the fact that the attachment unit of the nozzle apparatus in the outer casing of the turbine, including the outer casing with a horizontal connector, the nozzle apparatus, consisting of blocks of nozzle blades and rotor inserts, nozzle blade blocks and rotor inserts are fixed in the outer turbine casing using a ring-type fastener, in contrast to the known one, the fastener consists of even the number of segments that form the ring and are interconnected with circumferential gaps to compensate for thermal expansion, to reduce gas flow through the circumferential gaps in grooves made from the adjacent side ends of adjacent segments, sealing plates are installed, nozzle blade blocks are installed on the inside of each segment with nadrotorny inserts, each segment is installed on the inner side of the outer turbine housing, for fixing each segment in the radial and axial direction with ext at least two annular grooves are made in the morning side of the housing, in which reciprocal cylindrical collars of segments are located, and on the outer side of the cylindrical collars in the grooves of the housing there are radial clearances to allow the segments to move freely in the circumferential direction when assembling / disassembling the nozzle apparatus, also in the outer case opposite the inlet and outlet parts of each segment, elements of clamping the segment to the cylindrical surfaces of the grooves of the core are installed on the outside of the housing pus in the direction to the axis of the engine, in the circumferential direction, each segment is fixed using a radial pin element mounted in the outer casing from its outer side.

Description

The utility model relates to the field of gas turbine engines (GTE) and gas turbine units (GTU), in particular to turbine structures, and can be used in attachment points of the nozzle apparatus in the outer turbine casing.

Known stator of a gas turbine, comprising a housing with a horizontal connector, guide vanes with sealing elements, and the blade blocks are fixed in the housing using fixing elements, such as pins (RF Patent No. 2342541 from 04.06.2007, IPC F01D 25/24, F01D 9/04 , published on December 27, 2008, Bulletin No. 36).

The closest is the attachment unit of the nozzle apparatus in the outer casing of the turbine, including the outer casing with a horizontal connector, the nozzle apparatus, consisting of blocks of nozzle blades and rotor inserts, nozzle blade blocks and nadrotorny inserts are fixed in the outer casing of the turbine using a ring type attachment device. (US 2009/0226327 dated March 7, 2008, IPC F01D 5/14, published September 10, 2009).

The disadvantages of the presented designs is the relatively large weight of the turbine stator structure, due to the presence of nozzle holders with a flange horizontal connector, which require large dimensions of the outer casing to accommodate; low tightness of the axial joints of the nozzle holder clips of adjacent steps, due to the need for mobility and, as a result, the absence of flange fastenings of these joints to enable the lower halves of the nozzle device clips to be separately removed from the outer casing of any of the steps without removing the rotor, the difficulty of excavating the lower halves of the nozzle holder clips from the housing for repair without removing the rotor associated with the large dimensions and the mass of half the holders of the nozzle apparatus.

The technical result of the proposed utility model is to reduce the mass and overall dimensions of the steps of the nozzle apparatus and, consequently, the engine turbine, as well as reduce leakage of the working fluid over the nozzle apparatus, and reduce the time for routine inspection (or repair), replacement of parts and components of the nozzle apparatus and turbine, since all work is carried out without dismantling the massive rotor.

The technical result is achieved in that the attachment unit of the nozzle apparatus in the outer turbine casing, including the outer casing with a horizontal connector, the nozzle apparatus consisting of nozzle blade blocks and rotor inserts, nozzle blade blocks and rotor inserts are fixed in the turbine outer casing using a mounting device ring type, in contrast to the known, the mounting device consists of an even number of segments forming a ring and installed between themselves with circumferential clearances for the computer thermal expansion, to reduce the flow of gas through the circumferential gaps in the grooves made from the adjacent side ends of adjacent segments, sealing plates are installed, nozzle blades with nadrotorny inserts are installed on the inside of each segment, each segment is installed on the inside of the turbine’s outer casing, for fixing each segment in the radial and axial direction from the inner side of the housing, at least two annular grooves are made in which the reciprocal cylindrical collars of segments, and on the outside of the cylindrical collars in the grooves of the casing there are radial clearances to allow free movement of the segments in the circumferential direction when assembling / disassembling the nozzle apparatus; also, in the outer casing opposite the input and output parts of each segment, clamp elements are installed on the external side of the casing segment to the cylindrical surfaces of the grooves of the housing in the direction to the axis of the engine, in the circumferential direction, each segment is fixed using radial Nogo pin member installed in the outer casing with the outside thereof.

The figures show:

FIG. 1 - General view of the turbine;

FIG. 2 - Horizontal connector of the outer turbine housing;

FIG. 3 - Layout of the bearing segments of the nozzle apparatus;

FIG. 4 - Fixation of the bearing segment in the outer casing of the turbine.

The turbine (Fig. 1) includes an outer casing 1 with a horizontal connector (Fig. 2) a nozzle apparatus 2, consisting of blocks of nozzle vanes 3, on which sectors of the diaphragms (not shown) are fixed, and rotor inserts 4. Blocks of nozzle vanes 3 and rotor the inserts 4 are fixed in the outer casing 1 of the turbine using a mounting device.

The mounting device consists of an even number of load-bearing segments 5 (Fig. 1), forming a ring (Fig. 3) and installed between themselves with circumferential gaps 6 (Fig. 2) to compensate for thermal expansions. To reduce the flow of gas through the circumferential gaps 6 in the grooves 7 made from the adjacent side ends of adjacent bearing segments 5, sealing plates 8 are installed (Fig. 2). Blocks of nozzle blades 3 with nadrotorny inserts 4 are installed on the inside of each bearing segment.

Each bearing segment 5 is installed on the inner side of the outer casing 1 of the turbine (Fig. 1). To fix each bearing segment 5 in the radial and axial direction from the inner side of the housing 1, at least two annular grooves 9 are made, in which mating cylindrical collars 10 of the segments 5 are located. On the outer side of the cylindrical protrusions 10 in the grooves 9 of the housing 1 there are radial clearances 11 for enabling free movement of the bearing segments 5 in the circumferential direction when assembling / disassembling the nozzle apparatus. In the outer casing 1 opposite the inlet and outlet parts of each bearing segment 5, there are mounted on the outside of the casing elements of a clamp 12 of the segment against the cylindrical surfaces of the grooves 9 of the casing 1 (Fig. 4) in the direction to the axis of the engine. In the circumferential direction, each segment 5 is fixed by means of a radial pin member 13 mounted in the outer casing 1 from its outer side.

Assembly is as follows.

Blocks of nozzle blades 3 with secured diaphragm sectors and nadrotorny inserts 4 are mounted on the inner side of the carrier segment 5 by any of the known methods. Each segment 5 assembled with blocks of nozzle blades 3 and nadrotorny inserts 4 is installed in the outer casing 1 from its inner side, while the cylindrical collars 10 of the segment 5 are included with the radial clearance 11 in the annular grooves 9 of the housing 1. Next, the segments 5 are fixed in the circumferential direction with the help of radial pin elements 13 passing through the housing 1 and installed on its outer side, they are pressed against the cylindrical surfaces of the grooves 9 of the housing 1 in the direction to the axis of the engine with the help of clamping elements 12, which also pass through the outer turbine housing 1. So the upper and lower parts of the stator of all stages of the turbine are assembled.

Then the turbine rotor is assembled and balanced. The assembled turbine rotor is installed in the rear engine mount assembly. Installation of the turbine stator can be carried out both in the vertical and horizontal positions of the parts of the detachable outer casing. In this case, the assembled halves of the turbine stator are alternately mounted on the front flange of the rear support housing and attached to it and to each other.

Turbine repair can be made without removing the engine from the station stand and is carried out as follows.

The upper part of the stator of the turbine is removed, while the lower part of the stator remains fixed in the engine, which ensures the preservation of the location of the engine mounts and the possibility of rotation of the rotor during its repair. In the absence of the need to repair the upper part of the stator, it can be temporarily mounted on the flanges of the longitudinal connector of the outer casing. If it needs repair (for example, replacing the blocks of nozzle vanes 3 or rotor inserts 4 of separate steps), this upper part of the stator must be reinstalled on the front or rear flange of the outer casing to provide access to the specified parts of the stator and the possibility of replacing them.

To ensure the possibility of replacing the working blades of the turbine stages, as well as to repair (replace) the parts of the nozzle apparatuses, the stator design allows the nozzle apparatuses of any of the indicated stages to be removed from its upper and lower parts. In this case, it is necessary to first remove the clamping bolts 12 and the fixing pins 13 of the fastening of the bearing segments 5 of the removable stage from the outer case 1, and then remove the bearing segments 5 assembled from the blades 1 of the blades 3 of the nozzle apparatus, diaphragm sectors and nadrotorny inserts 4, moving each the bearing segment 5 along the circumference along the annular grooves 9 of the housing 1. The mobility of the segments 5 along the grooves 9 of the housing 1 is provided for by the large radial clearances 11 provided between the parts s in these areas. Dismantling the segments 5 of the nozzle apparatus of each stage can be performed on both sides of each part of the detachable housing 1 — half the number of segments 5 installed in the housing part on each side.

The replacement of the working blades of the turbine stages in the proposed design option can be made with the upper part of the stator removed and after dismantling the corresponding and subsequent feet from its lower part of the nozzle devices. The absence of the nearest nozzle sectors, as well as the existing ability to rotor the rotor, make it possible to remove from the disk and install on it the whole set of working blades, including blades with retaining shelves.

The proposed turbine design allows to reduce the leakage of the working fluid, the mass and overall dimensions of the engine, as well as significantly reduce the time for routine inspection, replacement of engine parts and assemblies at the station, since all work is carried out without dismantling / mounting the massive rotor and the associated adjustments .

Claims (1)

The nozzle apparatus attachment unit in the turbine outer casing, including the outer casing with a horizontal connector, the nozzle apparatus, consisting of nozzle vane blocks and rotor inserts, nozzle vane blocks and rotor inserts are fixed in the turbine outer casing using a ring-type attachment device, characterized in that that the mounting device consists of an even number of load-bearing segments forming a ring and interconnected with circumferential gaps to compensate for thermal expansions, to reduce gas flow through circumferential gaps in grooves made from the adjacent side ends of adjacent bearing segments, sealing plates are installed, nozzle blades with nadrotorny inserts are installed on the inside of each bearing segment, each segment is installed on the inner side of the outer turbine casing, for fixing each of the segment in the radial and axial direction from the inner side of the housing, at least two annular grooves are made in which the reciprocal cylindrical collars are located segments, and on the outside of the cylindrical collars in the grooves of the housing there are radial clearances to allow free movement of the segments in the circumferential direction when assembling / disassembling the nozzle apparatus; also, in the outer casing opposite the input and output parts of each segment, the clamp elements of the segment are installed on the outside of the casing to the cylindrical surfaces of the grooves of the housing in the direction to the axis of the engine, in the circumferential direction, each segment is fixed using a radial pin element ment installed in the outer casing from its outer side.

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