EP2295725A1 - Fluid flow engine with steam removal - Google Patents

Abstract

The turbo-engine has a rotor (5) rotatably supported around a rotational axis (6), and an internal inner housing (4) and an external inner housing (3) are arranged around the rotor. An outer housing (2) is arranged around the internal and external inner housings. A flow channel (7) for flow of a fluid medium is formed between the rotor and the internal and external inner housings. A sealing is arranged between the internal and the external inner housings. Tapping holes (16) for discharging fluid medium from the flow channel are arranged in the internal and external inner housings.

Description

The invention relates to a turbomachine comprising a rotor rotatably mounted about a rotation axis, an inner inner casing and outer inner casing disposed around the rotor, and an outer casing disposed around the inner and outer inner casings, the outer inner casing being arranged along a portion of the rotation axis around the inner inner casing is, wherein between the rotor and the inner and outer inner housing, a flow region for flowing a flow medium is formed.

Under a turbomachine, for example, a steam turbine is understood. A steam turbine usually has a rotatably mounted rotor and an inner housing which is arranged around the rotor. Between the rotor and the inner housing, a flow channel is formed. The housing of a steam turbine must be able to fulfill several functions. On the one hand, the guide vanes are arranged in the flow channel on the housing and on the other hand, the inner housing must withstand the pressure and the temperatures of the flow medium for all load and operating conditions. In a steam turbine, the flow medium is steam. Furthermore, the housing must be designed such that inlets and outlets, which are also referred to as taps, are possible. Furthermore, the housing must be designed such that the shaft ends are feasible through the housing. The high voltages, pressures, and temperatures that occur during operation require that the materials be properly selected and that the design be selected to provide mechanical integrity and functionality. This requires that high-quality materials are used, in particular in the area of the inflow and in the area of the first guide vanes grooves.

In steam turbines as an embodiment of a turbomachine, it is usually necessary to remove flow medium from so-called taps from the flow area. In order to meet the requirements and thus the necessary bleed pressures of the flow medium to be taken is suitable, the bleed positions should be as freely as possible within the flow range. In a three-shell steam turbine design in which inner and outer housings are disposed about the rotor and a flow area is formed between the rotor and the outer and inner inner housings, the tap positions are located at the junction between the inner and outer housings. This means that the bleed steam is taken between the inner and outer inner casing. However, this greatly restricts the axial positioning of the tapping and can lead to increased heat consumption and reduced performance.

It would be desirable if the possibility were available to be able to freely choose the axial positioning of the tap.

At this point, the invention begins, whose task is to offer a steam turbine, in which the tap is variable in the axial direction.

This object is achieved by a turbomachine comprising a rotor rotatably mounted about a rotation axis, an inner inner housing disposed about the rotor, and an outer inner housing and an outer housing disposed about the inner and outer inner housings, the outer inner housing being disposed along a portion of the axis of rotation about the axis inner inner casing is arranged, wherein between the rotor and the inner and outer inner casing, a flow region for flowing a flow medium is formed, wherein a seal between the inner inner casing and the outer inner casing is arranged and in the inner and / or Outer inner housing a tapping hole for removing flow medium from the flow area is arranged.

An essential idea of the invention is not to remove the vapor at the joint between the inner and outer inner casing as before, but to arrange a seal between the inner inner casing and the outer inner casing and a tapping hole at the point in the inner and / or to arrange outer inner housing, which is suitable for removing the appropriate bleed steam. Due to the fact that now no more steam can be flowed at the joint between the inner and the outer inner casing, the axial position of the tapping bore can be selected substantially freely along the flow region.

Advantageous developments are specified in the subclaims.

Thus, in a first advantageous development, a labyrinth seal is arranged between the inner and the outer inner housing. On the one hand, labyrinth seals can be relatively easily incorporated into the inner and outer inner casings. For this purpose, only the so-called sealing lips are caulked in grooves. Furthermore, it is easier to mount an outer and inner inner housing made with labyrinth seals.

In a further advantageous development, a brush seal is arranged between the inner inner housing and the outer inner housing. Brush seals, which are not non-contact seals in comparison to labyrinth seals, have the advantage that they show a higher sealing effect than the labyrinth seals. Furthermore, a joint made with brush seals is easier to mount between the inner inner case and the outer inner case, resulting in an acceleration of assembly time and manufacturing time.

Advantageously, an I-ring seal is arranged between the inner inner housing and the outer inner housing. By means of an I-ring seal a very high tightness is achieved. However, an I-ring seal is comparatively difficult to manufacture.

In a further advantageous development, a gradation is performed at the joint between the inner inner housing and the outer inner housing. This means that the joint is not straight, but includes a step. This makes it possible to arrange turbine blade stages in the region of the joint, wherein there is a possibility of variation in the axial direction.

The invention will be explained in more detail with reference to an embodiment. Components with the same mode of operation are provided with the same reference numerals.

Figur 1

eine Schnittdarstellung durch eine dreischalige Dampfturbine;

Figur 2

eine vergrößerte Schnittdarstellung eines Teils der Dampfturbine aus Figur 1;

Figur 3

eine vergrößerte Darstellung einer Stoßstelle aus Figur 2;

Figur 4

eine alternative Ausführungsform einer Stoßstelle;

Figur 5

eine vergrößerte Darstellung der alternativen Ausführungsform der Stoßstelle.

Show it:

FIG. 1

a sectional view through a three-bladed steam turbine;

FIG. 2

an enlarged sectional view of a part of the steam turbine FIG. 1 ;

FIG. 3

an enlarged view of a joint FIG. 2 ;

FIG. 4

an alternative embodiment of a joint;

FIG. 5

an enlarged view of the alternative embodiment of the joint.

The in the FIG. 1 illustrated steam turbine 1 as an embodiment of a turbomachine comprises substantially an outer housing 2, a disposed within the outer housing 2 outer inner casing 3 and an inner inner casing 4 disposed within the outer inner casing 3.

Within the outer inner casing 3 and the inner inner casing 4, a rotor 5 is rotatably supported about a rotation axis 6. Between the outer inner casing 3 and the rotor 5 and between the inner inner casing 4 and the rotor 5, a flow channel 7 is formed. For clarity, individual runners and vanes are not shown in detail. The vanes are arranged on the inner inner casing 4 and on the outer inner casing 3. On the rotor 5, the blades are arranged such that in the flow channel 7, the thermal energy of a vapor can be converted into rotational energy.

Steam flows via a steam inlet region, not shown, first into a first flow region 8, which is arranged between the inner inner casing 4 and the rotor 5.

The steam flowing in the first flow region 8 flows in a flow direction 9 along the flow channel 7 FIG. 1 shown steam turbine 1 is formed in two columns, that is, that in the first flow region 8 of the steam flows both along a first flood and along a second flood. Between the outer inner casing 3 and the rotor 5, a second flow region 10 is formed. In the first flow region 8, the outer inner casing 3 is formed around the inner inner casing 4 with respect to the rotation axis 6. Outside the first flow region 8, the outer inner housing 3 is not arranged around the inner inner housing 4 relative to the axis of rotation 6. The first flow region 8 comprises the flow channel 7 up to the point at which the inner inner casing 4 stops.

The area in which the inner inner housing 4 and the outer inner housing 3 are adjacent to each other is also referred to as a joint 11. This joint 11 is by means of a seal, which in the FIG. 1 not shown in detail, sealed. This means that a steam located in the flow channel 7 can not flow between the outer inner casing 3 and the inner inner casing 4 at the joint 11.

In the FIG. 2 is an enlarged view of a section of the in FIG. 1 to recognize the illustrated steam turbine 1. The joint 11 is designed such that a labyrinth seal between the outer inner housing 3 and the inner inner housing 4 is arranged.

In the FIG. 3 an enlarged view of the joint 11 is shown. In this case, the labyrinth seal comprises individual sealing lips 12 which are grooved in grooves. In alternative embodiments, the joint can be sealed by means of brush seals. In another alternative embodiment, an I-ring seal may be used to seal the joint 11.

In the FIG. 4 an alternative embodiment of the joint 11 is shown. For reasons of clarity, the representation of the sealing lips for the labyrinth seal was dispensed with. The joint 11 is designed here stepped. This means that the outer inner housing 3 has a step 13, which rests in a complementarily formed second stage 14. As a result of this graduated embodiment of the joint, the position of turbine blade roots arranged in the outer inner housing 3 can be varied in an axial direction 15. For some applications, bleed vapors from the flow channel 7 are needed. These bleed vapors are removed via bleed bores 16 from the flow channel 7, since now the bleed steam is no longer necessarily removed at the joint 11 between the outer inner housing 3 and the inner inner housing 4, one is essentially free in the choice of the axial positioning of the tapping bores , The location of the tapping bores can therefore be selected according to the desired tapping temperatures and tapping pressures of the tapping steam. The in the FIG. 1 shown Location of the tap holes is a tap hole 16 in the vicinity of the joint 11 in the inner inner housing 4 and a further tap hole 16 shown in the outer inner housing, said tap hole 16 establishes a fluidic connection between the flow channel 7 and a between the inner inner housing 4 and the outer inner housing 3 formed gap.

The execution of the joint 11 with the gradation 13, 14 allows a better utilization of the axial length for the position of the blading with simultaneous optimal choice of the steam condition for the bleed steam.

Claims (5)

Turbomachine (1),
comprising a rotor (5) mounted rotatably about a rotation axis (6), an inner inner housing (4) arranged around the rotor (5) and an outer inner housing (3) and an inner housing arranged around the inner (4) and outer (3) Outer housing (2),
the outer inner housing (3) being arranged along a first flow region (8) of the axis of rotation (6) around the inner inner housing (4),
wherein between the rotor (5) and the inner (4) and outer (3) inner housing, a flow channel (7) is formed for flowing a flow medium,
characterized in that
a seal between the inner inner housing (4) and the outer inner housing (3) is arranged and
in the inner (4) and / or outer (3) inner housing a tapping hole (16) for removing flow medium from the flow channel (7) is arranged. Turbomachine according to claim 1,
wherein between the inner inner housing (4) and the outer inner housing (3) a labyrinth seal is arranged. Turbomachine according to claim 1,
wherein between the inner inner housing (4) and the outer inner housing (3) a brush seal is arranged. Turbomachine according to claim 1,
wherein between the inner inner housing (4) and the outer inner housing (3) an I-ring seal is arranged. Turbomachine according to one of the preceding claims,
wherein a joint (11) between the inner inner housing (4) and the outer inner housing (3) is arranged and the inner inner housing (4) and the outer inner housing (3) at the joint (11) stepped executed.

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