EP1138881A2 - Turbine casing for an axial gas turbine - Google Patents

Abstract

The turbine housing has a hot gas chamber (5) between compressor stage (7) and turbine stage (6), and outer shell (1) and an internal part (2). This separates the hot gas chamber from the outer shell via an intermediate chamber (3). The internal part is connected to the outer shell via two axial joints (4) so that the intermediate chamber is sealed against the hot gas chamber. Outer shell and internal part consists of different materials, so that sufficient surface contact pressure is generated at the joints during operation of the gas turbine.

Description

Technical field

The present invention relates to a turbine housing for an axially flowing gas turbine, at least a hot gas space between a compressor stage and encloses a turbine stage and an outer shell as an outer boundary and an inner component has the hot gas space over an intermediate space separates from the outer shell.

State of the art

In the case of gas turbines with axial flow, in the Rule the one or more compressor stages and the one or more turbine stages on a single one Shaft arranged. The flowing out of the compressor highly compressed and heated air becomes one within of the turbine housing between the compressor stage and the turbine stage lying combustion chamber supplied. Because of the high pressure values occurring in this area and Temperatures is the turbine housing of a high load exposed.

The development of high compression compressors with increasing compressor end temperatures leads to ever higher ones Mechanical and thermal requirements Stability of the turbine housing. For those with increasing Pressure ratio increasing thermal and mechanical Stress must constantly find higher quality materials and be used. At the same time always larger flange connections for the turbine housing be provided to withstand these loads. Both make the systems considerably more expensive.

Another limiting factor is that in the industrial gas turbine sector manufacturing processes used, in which the outer shells forming the turbine housing be poured. With such casting processes Turbine housings manufactured are system-dependent limited in their mechanical and thermal resilience.

Presentation of the invention

The object of the present invention is therein, a turbine housing for an axially flow To provide gas turbine that can be manufactured inexpensively is and very high pressures and temperatures withstands. So the turbine housing should be in the range of one Compressor end pressure of over 30 bar at temperatures can be operated from 550 to 570 ° C without any problems.

The task is with the turbine housing according to claim 1 solved. Advantageous embodiments of this Housing are the subject of the dependent claims. The invention Turbine housing that has at least one hot gas space between a compressor stage and a turbine stage encloses and an outer shell as an outer boundary has a separate from the outer shell provided internal component that the hot gas space over a Separate the space from the outer shell. The inner component is like this over two axial interfaces connected to the outer shell that the space is sealed against the hot gas space.

The turbine housing according to the invention is thus out an outer shell and an inner component. By arranging the two components points between the inner component and the outer shell formed a lower pressure and a space lower temperature than that enclosed by the inner component Hot gas room. This is particularly through the sealing of the space from the hot gas space enables. About suitable feeders to this space a predefinable pressure can be set.

By dividing the turbine housing according to the invention in the outer shell and inner component the thermal and mechanical loads during of the company divided between the two components. Here is the inner component, hereinafter also called the hot gas component referred to, designed so that it both the circumferential stresses due to the pressure difference between the hot gas space and the space as well as the high one withstands the temperature in the hot gas chamber. This hot gas component is therefore preferably made of one high quality material.

The outer shell only needs to be sufficient have a rigid construction around the static ones Forces of the gas turbine transmitted and on the other hand the pressure difference between the gap and the To be able to withstand the surrounding atmosphere. The temperature, that acts on the outer shell is due to the Separation from the hot gas space via the inner component and the space significantly reduced. This temperature load can be done by a suitable cooling air duct in the between the inner component and the outer shell formed space can also be counteracted. This also reduces that in steam and gas turbines known phenomenon of the so-called usually caused by a deformation of the stator becomes.

Due to the construction of the turbine housing according to the invention this can be done at compressor end pressures of over 30 bar and the associated high temperatures operate. Due to the reduced requirements this can be attached to the outer shell using conventional Manufacture casting methods and simple materials while high quality materials only for the high temperature and internal areas exposed to pressure areas required are.

In a very advantageous embodiment of the Turbine housing according to the invention is the inner component by surface pressure acting in the axial direction connected to the outer shell. Here, the outer shell preferably two inward circumferential Projections or webs as axial interfaces, on which the inner component is placed. The inner component this requires sufficient flexibility in the axial direction have to over the entire operating cycle of the gas turbine at the axial interfaces to the outer housing sufficient surface pressure for the sealing effect to be achieved build up. The sealing effect is preferred achieved by metallic sealing, both the axial interfaces as well as those in contact coming surfaces of the inner component metallic sealing surfaces exhibit. Of course, the outer shell with the webs a sufficiently rigid construction have the due to the surface pressure for to absorb metallic sealing occurring axial forces. This configuration allows the invention Turbine housing realized in a very simple way become.

In a further embodiment of the turbine housing the materials for the outer shell and that Inner component selected such that during operation sufficient surface pressure between the interfaces the components for sealing are available. The thermal coefficient of linear expansion of the material lower is preferably chosen for the inner component than that for the outer shell. Different thermal Strains due to the effects on both components different temperatures can be compensated become. The materials are in any case chosen so that the sealing effect between the inner component and the outer shell during operation subsides.

By appropriately feeding a medium under Pressure in the space between the inner component and the outer shell can, for example, at a pressure of 32 bar in the hot gas space a pressure of 16 bar in the space be respected. Inner component and outer shell must in this case only a pressure difference of Can withstand 16 bar.

The turbine housing according to the invention enables further that even at high pressure ratios of the Compressor and large component diameters smaller Flange fittings as well as simpler materials and geometries for the outer shell and the inner component can be chosen. This also leads to a reduction in the cost of providing a such turbine housing.

Another advantage is the simple manufacture of the housing, in which the inner component only clamped between the two axial interfaces must become. Other joining techniques that lead to thermal stresses or cracks might not be necessary.

Brief description of the invention

Figur 1

schematisch einen Schnitt durch ein beispielhaftes Turbinengehäuse; und

Figur 2

das Turbinengehäuse aus Figur 1 in perspektivischer Schnittansicht.

The turbine housing according to the invention is explained again below without restricting the general inventive concept using an exemplary embodiment in conjunction with the drawings. Here show:

Figure 1

schematically shows a section through an exemplary turbine housing; and

Figure 2

the turbine housing of Figure 1 in a perspective sectional view.

Ways of Carrying Out the Invention

An example of a turbine housing for an axial Flow through gas turbine is shown schematically in Figure 1. The figure shows the upper part of the Housing structure arranged symmetrically about a central axis 8. The central axis corresponds to the axis the gas turbine along which the shaft with the turbine and compressor blades. The housing is there from the outer shell 1 and the inner component 2. In the present case, both enclose the hot gas space 5 ring-like. It closes on the right (not shown) compressor stage 7, on the left Expansion space 6 side with the (not shown) Turbine stage. The combustion chamber wall is in the hot gas chamber 5 9 (only schematically) indicated. Form the combustion chamber can be any. Here you can both ring combustion chambers and multi-stage combustion chambers, as they are known from the prior art, be provided. The hot gas chamber 5 contains the compressor stages 7 incoming compressed air at high Temperature and those escaping from the combustion chamber are called gases.

The hot gas chamber 5 is enclosed by the inner component 2. Between the inner component 2 and the outer shell 1 an annular space 3 is formed, which over the axial interfaces 4 sealed by the hot gas chamber 5 is. The interfaces 4 are in the form of metallic sealing surfaces formed on the end faces of the inner member Press 2 so that a surface pressure is applied to the metallic densities is effected. The inner component 2 is here during assembly with a defined assembly gap clamped between the two interfaces 4. In the transient driving area, during the start and parking, takes on an additional element (e.g. a built-in membrane seal) the sealing function. In normal operation, the outer shell 1 and the inner component 2 clamped together. The interfaces themselves are in this case as radial revolutions or webs, the sealing surfaces of which are vertical run to the central axis 8. Both outer shell 1 as well as inner component 2 have a in this area domed shape. With this form the Clamping the inner component 2 between the two axial interfaces 4 supported.

The seal between the hot gas chamber 5 and the Annulus 3 enables significantly different pressure conditions in the annulus than those in the hot gas space. The Inner component 2 must therefore only the pressure difference between Wear hot gas space and annulus while the outer shell 1 only the pressure difference between Annulus 3 and the environment 10, that is, the atmospheric pressure, as well as the static forces of the gas turbine has to withstand. The separation of the outer shell 1 from Hot gas space 5 via the inner component 2 and the annular space 3 further reduces the temperature load on the outer shell 1, so this is made of normal heat resistant Material can be made.

For example, the outer shell 1 can be made of Stg41T can be made during higher temperature loads exposed inner component 2 for example is made from the material Stg10T.

In the case of conventionally designed turbine housings the entire case would have to be made of the higher quality material be formed. In this case, too such a molded housing may be the high one Cannot withstand internal pressures.

In contrast, in the turbine housing according to the invention only the inner part made of high quality heat-resistant material are formed, while the outer shell is cast in a conventional manner can be. On the one hand, this reduces costs others, this design holds a higher compressor end pressure was standing.

Figure 2 shows the same embodiment again in a perspective sectional view. In this view is the curved shape of the outer shell 1 and the inner component 2 with the intermediate Annulus 3 can be seen very well. The two are the same axial interfaces 4 through by the outer shell 1 inward circumferential webs are formed, evident. These interfaces 4 are preferred made integrally with the outer shell.

The outer shell 1 of such a turbine housing can be made very easily with a casting technique become. That separating the hot gas space 5 from the annular space 3 Inner component 2 then only has to be between the two Interfaces 4 are clamped.

Suitable material differences between the material of the inner component 2 and the material of the outer shell 1 enable an almost temperature-independent Surface pressure of the inner component 2 on the axial Interfaces 4. In the figure are the feeders for the supply of a medium, for example a cooling medium like air, not recognizable in the annular space 3. A prescribable pressure can be set via these feeds maintained in the annulus.

Reference list

1

Outer shell

2nd

Internal component

3rd

Annulus

4th

Axial interface

5

Hot gas room

6

Expansion space (turbine stage)

7

Compressor stage

8th

Central axis

9

Combustion chamber wall

10th

Surroundings

Claims (7)

Turbine housing for an axially flow-through gas turbine, which encloses at least one hot gas space (5) between a compressor stage (7) and a turbine stage (6) and has an outer shell (1) as an outer boundary and an inner component (2) which defines the hot gas space via an intermediate space (3) separated from the outer shell (1),
the inner component (2) being connected to the outer shell (1) via two axial interfaces (4) such that the intermediate space (3) is sealed off from the hot gas space (5). Turbine housing according to claim 1,
characterized in that the inner component (2) is clamped between the axial interfaces (4) so that the connection to the outer shell (1) takes place by surface pressure acting in the axial direction. Turbine housing according to claim 2,
characterized in that the outer shell (1) and the inner component (2) are formed from materials which are so different that during operation of the gas turbine there is sufficient surface pressure at the axial interfaces (4) to close the intermediate space (3) against the hot gas space (5 ) to seal. Turbine housing according to one of claims 1 to 3,
characterized in that the axial interfaces (4) are designed as metallic sealing surfaces. Turbine housing according to one of claims 1 to 4,
characterized in that the outer shell (1) and inner component (2) surround the hot gas space (5) in a ring. Turbine housing according to one of claims 1 to 5,
characterized in that the inner component (2) has an outwardly curved shape. Turbine housing according to one of claims 1 to 6,
characterized in that the outer shell (1) has one or more openings for the supply of a medium to the intermediate space (3).

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