EP2101042A1 - Steam turbine with shrink collars - Google Patents

Abstract

The turbine i.e. high-pressure partial turbine (20), has an inner housing (23) arranged around a rotatably supported rotor (22) and an outer housing (3) e.g. pot-shaped housing, arranged around the inner housing. The inner housing has an inner housing upper part (34) and an inner housing lower part. A shrink collar (4) is provided for compressing the inner housing upper and lower parts. A seal (9) is arranged on the collar, and seals a gap between the collar and outer housing. A segment (8) is provided before the collar. A blading region is provided between the rotor and inner housing.

Description

The invention relates to a steam turbine, comprising a rotatably mounted rotor, an inner housing arranged around the rotor and an outer housing arranged around the inner housing, wherein the inner housing has an inner housing upper part and an inner housing lower part, wherein shrink rings for compressing the inner housing lower part and the inner housing upper part are arranged.

The use of shrink rings in steam turbine construction is known. The shrink rings are in this case arranged around the inner casing of the steam turbine in order to hold this together at the high pressures occurring and to mechanically stabilize the inner casing.

The use of such shrink rings instead of fittings for holding together the inner casing of a steam turbine has long been known as the prior art. Shrink joints have over the screw advantages of a more favorable voltage curve and, an improvement in the symmetry, which experiences a comparatively strong disturbance compared to screw.

For very high live steam pressures from 250 bar to over 400 bar special constructions of the inner housing and the outer housing are necessary due to the large forces resulting from the pressure. One way to control such high forces is given by the use of so-called Topfbauarten. Here, the inner housing is arranged in a designed as a pot outer housing and closed with a lid, so to speak. The inner casing of a steam turbine must be very thick-walled at very large pressure differences between the incoming steam and the surrounding steam be, which leads to an enlargement of the Teilfugenflansche and the partial joint screws. However, large flanges and large part-joint screws lead to a disturbance of symmetry. Furthermore, a larger housing deformation and thus a greater radial play demand is to be expected.

The object of the invention is to provide a steam turbine which is suitable for very high live steam pressures.

This object is achieved by a steam turbine comprising a rotatably mounted rotor, an inner housing arranged around the rotor and an outer housing arranged around the inner housing, the inner housing having an inner housing upper part and an inner housing lower part, wherein shrink rings are arranged for compressing the inner housing lower part and the inner housing upper part, wherein a seal is disposed on at least one shrink ring, the seal sealing a gap between the shrink ring and the outer housing.

Thus, it is proposed to hold the inner housing together by means of shrink rings. As a result, large forces can be exerted on the inner housing. The seals between the shrink rings and the outer housing prevent hot vapor from flowing from an inflow area toward an outflow area between the inner housing and the outer housing. An increase in the temperature of the vapor between the inner housing and the outer housing is thereby effectively avoided.

Advantageous developments are specified in the subclaims.

Thus, it is advantageous to provide a segment in front of the shrink ring, wherein the segment is designed such that a displacement in the axial direction is effectively avoided. High-pressure turbine sections as an embodiment of a steam turbine are usually carried out single-flow, resulting in a in operation occurring axial force leads. This axial force is compensated by means of thrust balancing piston. In order that the pressure difference of the vapor in the space between the inner housing and the outer housing in the axial direction does not lead to a displacement of the shrink ring, segments are provided which effectively prevents movement of the shrink ring from a point of high pressure to a point of low pressure.

Advantageously, the segment is arranged in a groove mounted on the inner housing. This only requires a simple and quick to be carried out processing of the inner housing. As a result, a quick implementation of securing the shrink ring against axial displacement is possible.

Advantageously, at least a second shrink ring is provided, which comprises a seal to the outer housing. Between the first shrink ring and the second shrink ring, a first pressure space is formed.

In an advantageous development, a third shrink ring is arranged such that a second pressure space is formed between the third shrink ring and the second shrink ring. Thus, a plurality of pressure chambers may be formed to equalize the pressure differential from a first location between the inner housing and the outer housing and a downstream lower second location as seen in the axial direction at a lower pressure.

Between the rotor and the inner housing, a blading area is arranged, wherein this blading area comprises a plurality of guide vanes and rotor blades. Advantageously, bores are arranged in the inner housing, which fluidly connects the blading region with the first or second pressure chamber. This makes it possible to pressurize the pressure chamber with steam to form a certain pressure. By adjusting the pressure in the pressure chamber, suitable pressure conditions can be created, which makes the selection and configuration of the steam turbine components, such as. B. the outer housing and the inner housing, can be specifically selected. The number of pressure chambers may be greater or less than two.

The bores can also be mounted in the outer housing in an alternative embodiment. In this case, the bore is mounted in such a way in the outer housing, that a connection from the first or second pressure chamber to an external steam supply is formed.

In an advantageous development, an axial securing shrink ring is arranged around the inner housing, wherein the Axialsicherungsschrumpfring rests on the outer housing to prevent axial displacement of the inner housing relative to the outer housing. Since high axial forces, which can lead to a displacement of the inner housing, in particular in high-pressure turbine sections in single-flow construction, suitable precautions must be taken to prevent this. A suitable advantageous embodiment of the invention provides a solution, as a displacement of the inner housing can be effectively prevented. In this case, a Axialsicherungsschrumpfring is disposed against the outer housing such that a movement of the inner housing in an axial direction leads to a force which is transmitted via the shrink ring on the outer housing. The Axialsicherungsschrumpfring experiences a counter force from the outer housing, which effectively prevents displacement of the inner housing.

Advantageously, the outer housing has a projection, wherein the Axialsicherungsschrumpfring rests against the projection. The production of a projection is a comparatively easy way to accomplish a connection between the Axialsicherungsschrumpfring and the outer housing.

Advantageously, a seal is arranged between the projection and the axial securing shrink ring. This will prevents high-pressure, high-temperature steam from reaching an area designed for lower temperatures. The high temperatures could cause damage at these points.

In an advantageous development, the outer housing is designed as a pot housing. In this combination, the gradation of the pressures within the pot housing by means of, for example, piston rings which are arranged on the shrink rings, very well possible. The piston rings are not disturbed by any parting joints both in the shrink ring and on the sliding surface in the pot housing. The inner housing with the shrink rings and the rotor is in this case arranged in an assembly step in the form of a pot housing outer housing. The substantially axially symmetrical pot housing can naturally withstand a high internal pressure. Thus, such a trained steam turbine can be acted upon by a vapor which has very high temperatures and very high pressures. In a further assembly step, a lid is arranged so to speak on the pot and firmly connected with screws or similar connection means with the outer housing.

An embodiment of the invention will be explained in more detail with reference to the accompanying schematic drawing.

Figur 1

eine schematische Querschnittsansicht durch den oberen Teil einer Hochdruck-Teilturbine.

It shows:

FIG. 1

a schematic cross-sectional view through the upper part of a high pressure turbine part.

The FIG. 1 shows a cross-sectional view of a high pressure turbine part 20 as an embodiment of a steam turbine. The high-pressure turbine part 20 is formed substantially rotationally symmetrical to a rotation axis 21. Essential components of the high-pressure turbine part 20 are the rotor 22, the inner housing 23 and an outer housing 3. The inner housing 23 may be made of two different materials, which are welded together at a weld 24. The inner housing 23 thus has a first inner housing part 1 and a second inner housing part 2. The materials of the inner housing part 1 and the second inner housing part 2 are different. Since, during operation, the steam first flows in the inflow region 25 between the first inner housing part 1 and the rotor 22, it is subjected to a higher thermal load than the second inner housing part 2, since the steam in the axial direction in the flow direction 26 becomes more relaxed and cooler.

The material for the first inner housing part 1 should therefore have heat-resistant properties. The material of the second inner housing part 2 may be made of a lower heat-resistant material than with respect to the material of the first inner housing part 1.

The rotor 22 may also be formed of two different materials. To save material, only the thermally stressed area with a high temperature resistant material, such as nickel-based manufactured. For this purpose, the rotor is formed from an inflow rotor part 27 and two outer rotor parts 28, 29. The inflow rotor part 27 is welded to the outer rotor part 29 at a first rotor welding point 30. Furthermore, the inflow rotor part 27 is welded to the outer rotor part 28 at a second rotor welding point 31. The inflow rotor part 27 is made of a more heat-resistant material than the two outer rotor parts 28, 29.

In operation, steam flows via the inflow region 25 through the blading channel 32. For reasons of clarity, in the US Pat FIG. 1 the guide vanes, which are arranged on the rotor 22 and the guide vanes, which are arranged on the inner housing 23, not shown in detail. In the outflow region 33 of the high-pressure turbine section 20, the steam flows out of the high-pressure turbine section 20 usually to overheat the boiler and then to a medium-pressure turbine section.

The inner housing 23 is in this case divided into two and comprises an inner housing lower part, which is not shown in the figure, and an inner housing upper part 34. In order to control the high pressures prevailing in the Beschaufelungskanal 32, shrink rings 4 are arranged around the inner housing 23. In the FIG. 1 are a total of seven shrink rings 4, 5, 6 shown. Here are z. B. five shrink rings 4 are arranged in the region of the blading channel 32 and carry about half of the live steam pressure. The forces from the internal pressure of the live steam, which prevails in the blading channel 32, are absorbed by the shrink rings 4. In addition, 25 partial joint screws 7 can be attached in the region of the inflow. Between the shrink rings 4 and the outer housing 3 seals 9 are provided. In the space 11, which is located between the inner housing 23 and the outer housing 3, prevail the highest temperatures and the highest pressures. Therefore, it is necessary to separate the space 11 from the first pressure chamber 35 fluidly via the seal 9. Thus, the pressure in the space 11 in the flow direction 26 can be reduced via the seals 9, so that in the second pressure chamber 36, a substantially lower pressure than in the room 11 prevails.

The pressure in the first pressure chamber 35 and in the second pressure chamber 36 can be selectively adjusted by making bores in the inner housing 23 in fluid communication with the blading channel 32. The holes are in the FIG. 1 not shown in detail. The holes can be arranged distributed over the circumference. Another possibility is to provide the outer housing 3 with holes in order to establish a fluidic connection between the first pressure chamber 35 or the second pressure chamber 36 with an external steam supply.

A displacement of the shrink rings 4 in the flow direction 26 is prevented by segments 8. The segments 8 are in Flow direction 26 seen after a shrink ring 4 arranged in a groove 37. An axial displacement due to the pressure difference before and after the shrink ring 4 is thus effectively avoided.

The Axialsicherungsschrumpfring 5 is seen in the flow direction 26 arranged in front of the inflow 25 and takes over the function of the axial fixation of the inner housing 23 and is sealed by a seal 10 to the outer housing 3 out. The seal 10 may be, for example, a U-ring seal. A threaded ring 13 transmits from the inner housing 23 resulting axial thrust forces. Instead of the threaded ring 13 screws can be used.

The outer housing 3 is designed as a pot housing, which means that the outer housing 3 does not comprise an axial parting line. The outer housing 3 is closed by means of a lid 38.

Claims (10)

Steam turbine
comprising a rotatably mounted rotor (22),
an inner housing (23) arranged around the rotor (22) and an outer housing (3) arranged around the inner housing (23), the inner housing (23) having an inner housing upper part (34) and an inner housing lower part,
wherein shrink rings (4) are arranged for compressing the inner housing lower part and the inner housing upper part (34),
characterized in that
a seal (9) is arranged on at least one shrink ring (4),
wherein the seal (9) seals a gap between the shrink ring (4) and the outer housing (3). Steam turbine according to claim 1,
wherein segments (8) are provided in front of the shrink ring (4),
wherein the segment (8) is designed in such a way
that a displacement in the axial direction is effectively avoided. Steam turbine according to claim 2,
wherein the segment (8) is arranged in a groove (37) introduced on the inner housing (23). Steam turbine according to one of the preceding claims,
wherein a first and a second shrink ring (4) are arranged one behind the other in the axial direction,
a first pressure space (35) is formed between the first and second shrink rings (4). Steam turbine according to claim 4,
wherein a third shrink ring (4) is arranged such that a second pressure space (36) between the third shrink ring (4) and the second shrink ring (4) is formed. Steam turbine according to claim 4 or 5,
wherein between the rotor (22) and the inner housing (23) a Beschaufelungsbereich, comprising a plurality of guide and rotor blades is arranged,
wherein at least one bore in the inner housing (23) is arranged, which connects the blading region with the first or second pressure chamber (35, 36) fluidly. Steam turbine according to one of the preceding claims,
wherein an axial securing shrink ring (5) is arranged around the inner housing (23),
wherein the Axialsicherungsschrumpfring (5) on the outer housing (3) is applied to prevent axial displacement of the inner housing (23) relative to the outer housing (3). Steam turbine according to claim 7,
wherein the outer housing (3) has a projection, wherein the Axialsicherungsschrumpfring (5) rests against the projection. Steam turbine according to claim 8,
wherein between the projection and the Axialsicherungsschrumpfring (5) a seal (10) is arranged. Steam turbine according to one of the preceding claims, wherein the outer housing (3) is designed as a pot housing.

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