The present invention relates to a sealing arrangement. The present invention also relates to a sealing arrangement preferably incorporated within a gas turbine engine. The present invention further relates to a sealing arrangement for sealing between a turbine nozzle and its neighborhood member or members in the gas turbine engine.
In the gas turbine, a compressor compresses air. The compressed air is supplied to combustors where it is combusted with fuel to generate high-temperature combustion gas. The generated combustion gas is supplied to a turbine where its energy is converted into a rotation power of a rotor. Accordingly, a leakage of the compressed air is needed to be avoided or minimized in order to effectively extract the rotation power in the gas turbine engine.
Practically, however, there exist gaps at connections between radially-inward and radially-outward annular members, e.g., between the turbine nozzle and annular members supporting the nozzle in the gas turbine engine, through which a part of the compressed air for cooling generated at the compressor may leak into a downstream section such as turbine. An increase of the leakage will result in a decrease in performance of the gas turbine engine.
JP 10-339108 discloses a sealing technique in which a rib is provided on a downstream flange surface of the stationary blade to make a linear sealing contact between a sealing surface of the rib and a stationary blade support ring to prevent the leakage of the compressed air. According to this technique, the seal can be maintained and, as a result, the leakage of the compressed air can be prevented, even where the stationary support ring inclines to its neighborhood member or members.
Disadvantageously, the structural members of the gas turbine engine are exposed to a high-temperature during its operation, which may vary relative positions or distances between the structural members in the radial and/or axial direction and, as a result, gaps between the neighborhood elements which may not be accommodated by the conventional sealing technique to result in the leakage of the compressed air.
Therefore, an object of the invention is to provide a sealing arrangement and a gas turbine engine incorporating the sealing arrangement, by which a seal is maintained in a stable manner even when the relative angles and/or positions between the structural members of the gas turbine engine were changed due to their thermal expansion or contraction and, as a result, the performance and the reliability of the gas turbine engine are increased.
To attain the object, an aspect of the sealing arrangement according to the embodiment of the invention is used in a mechanism. The mechanism comprises an inner annular member having a central axis and an outer annular member surrounding around the inner annular member; a plurality of segments disposed between the inner and outer annular members and peripherally around the central axis; an inner connecting mechanism connecting between the segment and the inner annular member; and an outer connecting mechanism connecting between the segment and the outer annular member. The inner connecting mechanism and/or the outer connecting mechanism has the sealing arrangement. The sealing arrangement comprises a first seal surface formed on the associated segment; a second seal surface formed on the annular member connected to the associated segment by the connecting mechanism; and an elastic seal member held between the first and second seal surfaces and extended linearly along a side of a polygon defined around the central axis.
In another aspect of the invention, the elastic sealing member is made of a strip-like metal plate, the metal plate being curved around a longitudinal axis so that one end and the other end of a cross-section of the elastic member are spaced away from each other to define an opening therebetween.
In another aspect of the invention, the elastic sealing member is positioned between a high-pressure zone and a low-pressure zone so that the opening is exposed to the high pressure zone.
In another aspect of the invention, the sealing arrangement in any one of claims 1-3, wherein the first seal surface or the second seal surface has a groove extending along the side of the polygon defined around the central axis and the elastic sealing member is disposed in the groove.
In another aspect of the invention, the elastic sealing member is compressively fitted in the groove.
In another aspect of the invention, the groove has a square cross-section and the elastic sealing member has a J-like configuration with a linear portion and a curved portion extending from a distal end of the linear portion. Also, the elastic sealing member is positioned in the groove so that a proximal end of the linear portion and an intermediate region of the curved portion are forced on an inner surface of the groove.
The invention further is directed to a gas turbine engine with the sealing arrangement, in which the inner annular member is an inner casing or an adaptor ring supported by the inner annular member; the outer annular member is an outer casing; and the segments are nozzle segments connecting between combustors and a turbine.
According to the sealing arrangement of the invention, even when an inclination or displacement is occurred between the member due to heat expansion or contraction, a reliable and stable seal is maintained between the members, which results in that the gas turbine engine with the sealing arrangement is capable of effectively using the compressed air generated by the compressor.
With reference to the accompanying drawings, a gas turbine engine and a sealing arrangement incorporated therein will be described below. Like reference numbers denote like or similar parts throughout the specification.
Referring to
In the embodiment, the compressor 3 is an axial-flow compressor and comprises a plurality stages of moving blades 13 securely mounted on an upstream outer peripheral surface of the rotor 11 supported for rotation about a longitudinal axis C by upstream and downstream bearings 33 and a plurality stages of stationary blades 17 securely mounted on an inner peripheral surface of a housing 15 surrounding the rotor 11, the moving and stationary blades 13 and 17 being arranged alternately in the axial direction so that the intake air IA from the intake cylinder 19 is compressed by the cooperation of the moving and stationary blades 13 an 17.
An inner casing (inner annular member) 21 is provided between the compressor 3 and the turbine 7 so as to surround and rotatably support an intermediate portion of the rotor 11. Also provided between the inner casing 21 and the housing 15 are a plurality of passages or diffusers 23 through which the compressed air CA is fed from the compressor 3 into respective combustors 5 and a turbine nozzle 25 (including the first stage stationary blade) through which the high-temperature and high-pressure combustion gas G are fed from the respective combustors 5 into the turbine 7.
The turbine 7 is provided inside the housing 15 and comprises a turbine casing (outer casing, outer annular member) 26 surrounding the downstream portion of the rotor 11. The inner peripheral surface of the turbine casing 26 has a plurality stages of turbine stationary blades 27 securely mounted thereon. Correspondingly, the outer peripheral surface of the rotor 11 has a plurality stages of turbine moving blades 29 securely mounted thereon so that the stationary and moving blades 27 and 29 are positioned alternately in the axial direction, which allows that the combustion gas G ejected from the combustors 5 are guided by the turbine stationary blades 27 and also effectively impinged on the turbine moving blades 29 to cause a rotational force of the rotor 11.
Referring back to
The outer peripheral wall portion 41 is connected to the turbine casing 26 through an outer connecting mechanism 42. The outer connecting mechanism 42 has a support flange 45 extending radially outwardly from the downstream outer peripheral surface of the outer peripheral wall 41 and a connecting member 46 connecting between the support flange 45 and the turbine casing 26.
The outer peripheral wall 41 and the inner peripheral wall 43 have an outer connecting flange 47 and an inner connecting flange 48 integrally formed therewith at upstream ends thereof and extending radially outwardly and inwardly therefrom, respectively. The outer connecting flange 47 and the inner connecting flange 48 have engaging portions 47a and 48a extending upwardly, respectively. As shown in the drawing, the engaging portions 47a and 48a are fitted in engaging grooves 51 and 53, respectively, formed at the downstream ends of the transition duct together with sealing members 55, which results in that the upstream ends of the turbine nozzle 25 are connected to the combustors 5. A sealing member which is commercially available from Nippon Valqua Industries, Ltd., under the trade name “Cord Seal”, is preferably used for the sealing member 55.
As shown in
The inner connecting mechanism 110 has an annular inner connector 111 mounted on an outer peripheral surface of the adaptor ring 57 and an annular outer connector 113 mounted on an inner peripheral surface of the inner peripheral wall 43 of the nozzle segment 35.
In the embodiment, the outer connector 113 has a peripheral flange 115 extending radially inwardly from the inner peripheral wall 43. The inner connector 111 has annular front wall 117 and back wall 119, opposed to and spaced way from each other in the axial direction indicated by arrow A to define an annular groove 121 between the front wall 117 and the back wall 119. As shown in
As shown in
In
As shown in
In the embodiment, in order to hold the elastic sealing member 153 in a stable manner, as shown in
Referring again to
With the sealing arrangement 151 so constructed, the elastic sealing members 153 made by bending the elastic metal plates are compressively fitted in respective sealing sites, which ensures that the gaps 135 and 137 between the connectors 111 and 113, even when enlarged due to heat expansions thereof, are sealed completely or substantially completely. In particular, according to the embodiment, each elastic sealing member 153 is accommodated in the grooves 151 and 163 with its distal ends and intermediate portions abutted against the side surfaces of the grooves 169 and 173 as it is compressed radially inwardly. This ensures that the elastic sealing member 153 is held by the grooves 161 and 163 in a stable manner and, as a result, the seals are maintained in a reliable manner over a long period of time. Also, the elastic sealing members 153 are retained by the nozzle segments 35 in a stable manner so as not to displace or drop off easily due to shocks at the assembling or the contacts with the other members and, as a result, to ensure reliable seals after the assembling thereof.
The elastic sealing member 153 is positioned so that the dead-end cavity 159 is exposed to the high-pressure zone H (upstream zone), which results in that the linear portion 155 and the curved portion 159 of the elastic sealing member 153 are forced away from each other by the high-pressure in the dead-end cavity 159, causing the linear and the curved portions 155 and 157 to be forced against the associated sealing surfaces (upstream and downstream surfaces) of the flange and the opposing downstream and upstream end surfaces of the front and back walls, respectively, to establish reliable seals thereat.
Also, as shown in
Further, the sealing member which seals between the connectors 111 and 113 is divided into plural seal elements or elastic sealing member 153 (See
Although several embodiments have been described above, they may be modified without departing from the gist of the invention and it should be understood that those modifications are still within the scope of the invention.
Although in the previous embodiment two elastic sealing members 153 are provided to seal the gaps 135, only one elastic sealing member may be provided.
Although the grooves are formed in the upstream and downstream end surfaces of the flange, only one groove is provided in the inner peripheral end surface 127 (see
Although the groove for receiving the elastic seal has a square in cross section, it is not restrictive and another configuration such as triangular, semi-circular, or semi-ellipsoidal configuration may be used instead.
The cross section of the elastic sealing member is not limited to that described in the previous embodiment and may be a semi-circular configuration, C-like configuration, or spiral configuration extending over 360 degrees so that one end overlaps the other end.
Although the grooves 161 and 163 are formed in the flange 115 of the nozzle segment 35, at least one groove is provided in the adaptor ring 57.
Although the groove 121 is formed in the adaptor ring 57 and the flange 115 of the nozzle segment 36 is positioned in the groove 121, a groove is formed in the nozzle segment 36 and a flange is formed in the adaptor ring 57 so that the flange of the adaptor ring is positioned in the groove of nozzle segment 36 for connection thereof.
Although the seal mechanism 151 is provided only for the inner connector 110, it may be provided for the inner connector 110 or the outer connector 42 or both.
Although the sealing arrangement according to the embodiment of the invention is provided for the support structure of the first stage stationary blade of the turbine 7, it may be used for another support mechanism in another stage stationary blade.
Number | Date | Country | Kind |
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2010-003657 | Jan 2010 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2011/050279 | 1/11/2011 | WO | 00 | 7/11/2012 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2011/086993 | 7/21/2011 | WO | A |
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Entry |
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English translation of the International Preliminary Report on Patentability and the Written Opinion of the International Searching Authority dated Aug. 16, 2012; International Application No. PCT/JP2011/050279. |
Apr. 5, 2011 International Search Report issued in International Patent Application No. PCT/JP2011/050279. |
Number | Date | Country | |
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20120294706 A1 | Nov 2012 | US |