EP2987952A1 - Steam turbine and method for operating a steam turbine - Google Patents

Abstract

The invention relates to a steam turbine (1) with a cooling possibility in which steam is taken from the flow channel, which cools the thrust balance intermediate bottom (16) and mixed with a little live steam and fed back to the flow channel.

Description

The invention relates to a steam turbine comprising an inner housing and an outer housing and a rotor which is rotatably mounted within the inner housing, wherein the outer housing is arranged around the inner housing, wherein the rotor arranged along a first flow direction high-pressure region and along a second flow direction having arranged medium-pressure region.

The invention further relates to a method for cooling a steam turbine, wherein the steam turbine has a high-pressure region and a medium-pressure region, wherein a rotor is arranged between the high-pressure region and the medium-pressure region and has a thrust balance intermediate bottom.

For the purposes of the present application, a steam turbine means any turbine or sub-turbine through which a working medium in the form of steam flows. In contrast, gas turbines are traversed with gas and / or air as the working medium, which, however, is subject to completely different temperature and pressure conditions than the steam in a steam turbine. In contrast to gas turbines has steam turbines z. As the one part turbine incoming working fluid with the highest temperature at the same time the highest pressure. An open cooling system, which is open to the flow channel, can also be implemented in the case of gas turbines without partial turbine-external supply of cooling medium. For a steam turbine, an external supply for cooling medium should be provided. The prior art relating to gas turbines can not therefore be used for the assessment of the present application subject.

A steam turbine typically comprises a rotor-mounted rotatably mounted rotor disposed within a housing. When flowing through the interior of the flow channel formed by the housing jacket with heated and pressurized steam, the rotor is rotated by the steam through the blade. The blades of the rotor are also referred to as blades. In addition, usually stationary guide vanes are suspended on the inner housing, which engage along an axial extent of the body in the interspaces of the rotor blades. A vane is typically held at a first location along an interior of the steam turbine casing. In this case, it is usually part of a stator blade row, which comprises a number of guide vanes which are arranged along an inner circumference on an inner side of the steam turbine housing. Each vane has its blade radially inward. A row of vanes at said first location along the axial extent is also referred to as a vane grille or ring. Usually, a number of vane rows are connected in series. Accordingly, at a second location along the axial extent behind the first location, a further second blade is held along the inside of the steam turbine housing. A pair of a vane row and a blade row is also referred to as a vane stage.

The housing jacket of such a steam turbine can be formed from a number of housing segments. The housing shell of the steam turbine is to be understood as meaning, in particular, the stationary housing component of a steam turbine or a partial turbine which has an interior in the form of a flow channel along the longitudinal direction of the steam turbine, which is provided for flowing through with the working medium in the form of steam. Depending on the steam turbine type, this can be an inner casing and / or a guide vane carrier. However, it may also be provided a turbine housing, which has no inner housing or no guide vane.

For efficiency reasons, the design of such a steam turbine for so-called "high steam parameters", ie in particular high steam pressures and / or high steam temperatures, may be desirable. However, in particular a temperature increase for reasons of material technology is not unlimited possible. In order to enable safe operation of the steam turbine even at particularly high temperatures, therefore, cooling of individual components or components may be desirable. Without efficient cooling, more expensive materials (e.g., nickel-based alloys) would become necessary as temperatures increase.

In the cooling methods known hitherto, in particular for a steam turbine body in the form of a steam turbine housing or a rotor, a distinction must be made between active cooling and passive cooling. With active cooling, cooling is provided separately by a steam turbine body, i. effected in addition to the working medium supplied cooling medium. In contrast, a passive cooling is done only by a suitable leadership or use of the working medium. So far, steam turbine bodies have preferably been passively cooled.

All previously known cooling methods for a steam turbine housing thus see, if it is at all active cooling method, at best, a targeted flow against a separate and to be cooled turbine part and are limited to the inflow of the working medium, possibly including the first vane ring. This can result in a load of conventional steam turbines with higher steam parameters to an acting on the entire turbine, increased thermal load, which could be reduced only insufficiently by a conventional cooling of the housing described above.

Embodiments of steam turbines are known which, in addition to a first flow channel, have a second flow channel have, wherein both the first flow channel and the second flow channel are arranged within a housing. Such designs are also referred to as compact turbines. Embodiments are known in which the first flow channel is designed for high-pressure blading and the second flow channel is designed for medium-pressure blading. The directions of flow of the first flow channel and the second flow channel in this case show in the opposite direction to thereby minimize the thrust balance. Essentially, such designs include a rotor formed with a high-pressure region and a medium-pressure region, which is mounted rotatably within an inner housing, wherein an outer housing is arranged around the inner housing. The high pressure area is designed for live steam temperatures. After flowing through the live steam through the high-pressure area, the steam flows to a reheater and is brought there to a higher temperature and then flows through the medium-pressure region of the steam turbine.

The application limits of such rotors are defined by areas subject to high thermal stress. With increasing temperatures, the relevant strength characteristic decreases disproportionately. This results in maximum permissible shaft diameters, which lead to restrictions, in particular in 60 Hertz applications, as far as the rotor dynamic slenderness of the rotor is concerned. Therefore, when operating limits are reached in a Monoblockrotor usually on the next better material is replaced, which withstands the thermal requirements or it is performed a rotor welded, with two materials are each designed for the thermal stresses.

It would be desirable to have effective cooling in a steam turbine component, especially for a high temperature steam turbine.

At this point, the invention begins, whose object is to provide a steam turbine and a method for their production, in which the steam turbine is cooled particularly effectively even in the high temperature range.

The object is achieved by a steam turbine according to claim 1 and by a method according to claim 9.

An essential idea of the invention is to form a passive cooling. The invention is geared to a steam turbine in the aforementioned compact design. This means that the steam turbine within a common outer housing has a high-pressure area and a medium-pressure area. The high pressure area is designed for live steam temperatures. The live steam temperatures are between 530 ° C and 720 ° C at a pressure of 80-350 bar. The medium pressure range is designed for temperatures in the input range of 530-750 ° C at a pressure of 30-120 bar.

In a steam power plant, a distinction is made between high-pressure and medium-pressure blading as follows: A live steam initially flows through a partial turbine designed for live steam. After flowing through the live steam through the high-pressure area, this flows to a reheater and is heated there to the medium-pressure inlet temperatures and then flows through the medium-pressure range. After flowing through the medium-pressure region of the steam flows to a low pressure region and there has lower steam parameters.

An essential idea of the invention is now to design the steam turbine in such a way that a thrust balance intermediate floor can be passively cooled. For this purpose, a branched off from the high-pressure flow channel at a suitable location from the flow channel, which is guided to a point for thrust balance intermediate floor. This steam can then in the area between thrust balance intermediate floor and the Inner case spread out. Another essential idea of the invention is that the aforementioned steam can mix with a part of the live steam, which can then be guided back to the first flow channel via a cross-return channel.

Advantageous developments are specified in the subclaims.

In a first advantageous development, the first high-pressure blade stage is arranged in front of the second high-pressure blade stage as seen along the first flow direction.

This means that the steam taken from the first high-pressure blade stage has higher steam parameters than the steam taken from the second high-pressure blade stage. As a result, a target-oriented suitable steam can be taken from the high pressure blading area.

In a further advantageous development, the first thrust balance piston intermediate floor space along the first flow direction is arranged in front of the second thrust balance intermediate floor space. Since the thermal load of the thrust balance intermediate floor is different, the invention provides that a better cooling possibility is possible if the first thrust balance intermediate floor space along the first flow direction is arranged in front of the second thrust balance intermediate floor space.

In a further advantageous development, a first brush seal is arranged between the inner housing and the thrust balance intermediate bottom along the second flow direction before the second thrust compensation intermediate floor space and a second brush seal along the second flow direction behind the first thrust compensation intermediate floor space.

In a particular advantageous development of the first cross recirculation channel is formed with return tubes. As a result, the thermal compensation can be optimized.

In a further advantageous embodiment, the connection is formed with connecting tubes, this also leads to an advantageous temperature compensation.

In a particular advantageous development, the steam turbine is formed with a second cross-return channel, which is arranged as a communicating tube between a third thrust balance intermediate bottom space formed between the thrust balance intermediate bottom and the inner housing and after a third high-pressure blade stage.

As a result, a further vapor in the space between the intermediate bottom and the inner housing can be used for cooling possibilities and for working relaxation.

Advantageously, as seen in the first flow direction, the third high-pressure blade stage is arranged behind the second high-pressure blade stage.

Thus, with the invention, the thrust balance intermediate floor can be optimally cooled.

As a result, an extension of the mechanical application limits of the rotor by lowering the temperature inside the shaft is possible. In addition, it is possible to ensure sufficient cooling of the thrust balance intermediate floor with potential use of brush seals. In addition, the thermally critically loaded region of the components is cooled by a passive system by the inventive arrangement.

The above-described characteristics, features, and advantages of this invention, as well as the manner in which they are achieved, become more clearly and clearly understood with the following description of the embodiments, which are explained in more detail in connection with the drawings.

Embodiments of the invention are described below with reference to the drawing. This is not intended to represent the embodiments significantly, but the drawing, including explanations useful, executed in a schematized and / or slightly distorted form. With regard to additions to the teachings directly recognizable in the drawing reference is made to the relevant prior art.

Figur 1

eine schematische Querschnittsansicht einer Dampfturbine,

Figur 2

einen Ausschnitt der in Figur 1 dargestellten Dampfturbine mit der erfindungsgemäßen Anordnung.

Show it:

FIG. 1

a schematic cross-sectional view of a steam turbine,

FIG. 2

a section of in FIG. 1 illustrated steam turbine with the inventive arrangement.

FIG. 1 shows a steam turbine 1 comprising an inner housing 2 and an outer housing 3 and a rotor 4. The rotor 4 is rotatably mounted within the inner housing 2. The storage is not shown in detail. The outer housing 3 is arranged around the inner housing 2. The rotor 4 is formed substantially rotationally symmetrical about the axis of rotation 5. Along a first flow direction 6, which runs essentially parallel to the axis of rotation 5, the rotor 4 has a high-pressure region 7. Arranged opposite to the first flow direction 6, the rotor 4 has a medium-pressure region 9 which is arranged along the second flow direction 8.

The inner housing 2 has in the high-pressure region 7 a plurality of high pressure guide vanes (not shown), which are arranged on the circumference about the axis of rotation 5. The high-pressure guide vanes are arranged such that along the first flow direction 6, a high pressure flow passage 10 is formed with a plurality of high pressure blade stages (not shown) each having a row of high pressure blades and a series of high pressure vanes.

Fresh steam flows into the steam turbine 1 via a first high-pressure inflow region 11 and then flows through the high-pressure flow channel 10. In the high-pressure flow channel 10, the steam expands, the temperature decreasing. The thermal energy of the steam is converted into rotational energy of the rotor 4. After the steam has passed through the high pressure flow passage 10, it flows from a high pressure discharge area 12 from the steam turbine 1 to a reheater (not shown). In the reheater, the cooled steam is brought back to a high temperature which is comparable to the live steam temperature in the high-pressure inflow region. However, the pressure in the inflow region 11 is significantly lower.

The inner housing 2 has in the central pressure region 9 a plurality of medium-pressure guide vanes (not shown), which are arranged such that along the second flow direction 8, a medium-pressure flow channel 13 with a plurality of medium-pressure blade stages (not shown), each having a series medium-pressure blades and a number of medium-pressure vanes is formed.

The steam after the reheater flows through the medium-pressure inflow region 14 through the medium-pressure flow channel 13. The thermal energy of the steam is converted into rotational energy of the rotor 4. After the medium-pressure flow channel 13, the steam flows out of the steam turbine 1 via an outlet 15. The steam is then forwarded to a low pressure turbine part (not shown) or a process steam process. The rotor 4 has between the high-pressure flow channel 10 and the medium-pressure flow channel 13 to a thrust balance intermediate bottom 16. This thrust balance intermediate bottom 16 has a larger diameter than the rotor 4th

The live steam temperature is 530 ° C - 720 ° C at a pressure of 80bar - 350bar. The mean pressure temperature is 530 ° C - 750 ° C at a pressure of 30bar - 120bar.

The FIG. 2 shows a section of the steam turbine 1 from FIG. 1 , wherein further features of the invention in FIG. 2 are shown. The inner housing 2 has a connection 17 which is arranged as a communicating tube between the high-pressure flow channel 10 after a first high pressure vane stage 18 and a first thrust balance intermediate bottom space 19, wherein the thrust balance intermediate bottom space 19 between the thrust balance intermediate bottom 16 and the inner housing 2 is arranged. The inner housing 2 has a plurality of segments 20 in the region of the thrust balance intermediate floor 16. The segments 20 each have a labyrinth seal (not shown).

The inner housing 2 further includes a first cross recirculation passage 21 disposed as a communicating tube between a second thrust balance intermediate floor space 19 (disposed between the thrust balance intermediate floor 16 and the inner housing 2) and after a second high pressure paddle stage 22.

The first high-pressure vane stage 18 is arranged in front of the second high-pressure vane stage 23 along the first flow direction 6.

The first thrust balance intermediate floor space 19 is arranged in front of the second thrust balance intermediate floor space 22 as seen along the first flow direction 6.

Between the inner housing 2 and the thrust balance intermediate floor 16 is a first brush seal 24 along the second flow direction 8 before the second thrust balance intermediate floor space 22 arranged. A second brush seal 25 is arranged along the second flow direction 8 behind the first thrust balance intermediate floor space 16.

The first cross recirculation passage 21 may be formed with tubes (not shown) in alternative embodiments. In the in the FIG. 2 illustrated embodiment, the cross return passage 21 is disposed in the inner housing 2.

The compound 17 is in the in FIG. 2 selected embodiment in the inner housing 2 is formed and in alternative embodiments, the connection 17 may be formed with connecting tubes.

The steam turbine 1 has a second cross recirculation channel 26, which is formed as a communicating tube between a third thrust balance intermediate bottom space 27 which is disposed between the thrust balance intermediate bottom 16 and the inner housing 2 and arranged after a third high-pressure blade stage 28 high-pressure inflow space in the high-pressure flow channel 10 ,

The third high-pressure blade stage 28 is arranged behind the second high-pressure blade stage 23 as seen in the first flow direction 6. The cross-return passage 26 may be formed in the inner housing 20. In alternative embodiments, the third cross return passage 26 may be formed as a tube.

Although the invention has been further illustrated and described in detail by the preferred embodiment, the invention is not limited by the disclosed examples, and other variations can be derived therefrom by those skilled in the art without departing from the scope of the invention.

Claims (10)

Steam turbine (1) comprising
an inner housing (2) and an outer housing (3) and a rotor (4) which is rotatably mounted within the inner housing (2),
wherein the outer housing (3) is arranged around the inner housing (2),
wherein the rotor (4) has a high-pressure area (7) arranged along a first flow direction (6) and a medium-pressure area (9) arranged along a second flow direction (8),
wherein the Inngengehäuse (2) in the high-pressure region (7) has a plurality of high pressure guide vanes,
which are arranged in such a way
in that a high-pressure flow channel (10) is formed along the first flow direction (6) with a plurality of high-pressure blade stages, each having a row of high-pressure blades and a row of high-pressure guide vanes, the inner housing (2) being in the medium-pressure region ( 9) has a plurality of medium-pressure guide vanes,
arranged such that along the second flow direction (8) a medium-pressure flow channel is formed with a plurality of medium-pressure blade stages, each having a row of medium-pressure blades and a row of medium-pressure vanes,
the rotor (4) having a thrust balance intermediate floor (16) between the high-pressure area (7) and the medium-pressure area (9),
the inner housing (2) having a connection (17) formed as a communicating tube between the high-pressure flow channel (10) after a first high pressure vane stage (18) and a first thrust equalization void space (19).
wherein the inner housing (2) has a first cross-return passage (21) acting as a communicating tube between a second thrust balance intermediate floor space (22) disposed between the thrust balance intermediate floor (16) and the inner housing (2),
and after a second high-pressure blade stage (23) arranged high-pressure inflow space in the high-pressure flow channel (10) is formed. Steam turbine (1) according to claim 1,
wherein the first high pressure vane stage (18) is disposed in front of the second high pressure vane stage (23) as seen along the first flow direction (6). Steam turbine (1) according to claim 1 or 2,
wherein the first thrust balance intermediate floor space (19) is arranged in front of the second thrust balance intermediate floor space (22) as seen along the first flow direction (6). Steam turbine (1) according to one of the preceding claims,
wherein between the inner housing (2) and the thrust balance intermediate floor (16) a first brush seal (24) along the second flow direction (8) before the second thrust balance intermediate floor space (22) and a second brush seal (25) along the second flow direction (8) behind the first Schubausgleichzwischenbodenraum (19) is arranged. Steam turbine (1) according to one of the preceding claims,
wherein the first cross-return passage (21) is formed with tubes. Steam turbine (1) according to one of the preceding claims,
wherein the connection (17) is formed with connecting tubes. Steam turbine (1) according to one of the preceding claims,
a second cross recirculation passage (26) arranged as a communicating tube between a third thrust balance intermediate floor space (27) disposed between the thrust balance intermediate floor (16) and the inner housing (2),
and after a third high-pressure blade stage (28) arranged high-pressure inflow space in the high-pressure flow channel (10) is formed. Steam turbine (1) according to one of the preceding claims,
wherein the third high-pressure vane stage (28) is arranged behind the second high-pressure vane stage (23) when viewed in the first flow direction (6). Method for cooling a steam turbine (1),
wherein the steam turbine (1) has a high-pressure area (7) and a medium-pressure area (9), wherein a rotor (2) between the high-pressure area (7) and the medium-pressure area (9) has a thrust balance intermediate floor (16). wherein steam is withdrawn from the high pressure area (7) and is supplied to a space between thrust balance intermediate floor (16) and inner casing (2) with steam from the space between the thrust balance intermediate floor (16) and the inner housing (2) via a first cross Return passage (21) is supplied to the high-pressure area (7). Method according to claim 9,
wherein another vapor is supplied between the thrust balance intermediate floor (16) and inner housing (2) via a second cross-return passage (26) in the high-pressure area (7).

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