EP3561242A1 - Welded turbine housing segment and turbine housing - Google Patents

Abstract

The invention relates to a welded turbine housing segment (1) comprising a wall plate (2) and a flange strip (3) welded to the wall plate (2), the flange strip (3) forming a parting joint surface (4). The flange strip (3) is designed in such a way that the flange strip (3) continues on the turbine housing segment inner side (5) in the direction of the parting joint surface (4). The invention also relates to a turbine housing with at least two corresponding turbine housing segments (1, 1 ').

Description

The invention relates to a welded turbine housing segment according to the preamble of independent claim 1 and to a turbine housing with such a welded turbine housing segment.

Turbine housings, for example steam turbine housings, are usually formed from a plurality of turbine housing segments. As a rule, the turbine housing is formed from two turbine housing segments, namely a turbine housing upper part and a turbine housing lower part. The multi-part design of the turbine housing facilitates or allows only the assembly of the rotor in the turbine housing. The turbine housing upper part and the turbine housing lower part each have parting surfaces, with which they rest against each other. By means of partial joint screws, the turbine housing upper part and the turbine housing lower part are clamped against each other at the part joint surfaces and thus sealed the parting line. The individual turbine housing segments can be cast or manufactured as welded components. Where technically possible, welded turbine housing segments are used because they are much cheaper to manufacture. At high internal pressure and / or high temperatures, high contact pressures in the area of the parting line must be achieved in order to reliably prevent leaks in the area of the parting line. Because of the simpler material and the smaller wall thicknesses, which contribute significantly to the cost reduction, not so high contact pressures in the area of the parting line are to be realized in welded turbine housing segments. This can lead to leaks in the region of the parting line during operation, so that the working fluid, for example hot steam in the case of a steam turbine, can escape through the parting line to the outside. The internal pressure penetrates into the parting line and has an opening. In spite of the limited contact pressure To grant a Teilfugendichtigkeit, is currently trying to keep the roughness of the joint surface area as low as possible. However, the corresponding processing of the joint surfaces is thereby complicated and expensive, so that the cost advantage of the welded turbine housing segments is partially used up by this.

Starting from the prior art, it is therefore an object of the present invention to form a welded turbine housing segment, which ensures an improved Teilfugendichtigkeit. Furthermore, it is an object of the present invention to provide a turbine housing with such a welded turbine housing segment.

The object is achieved with respect to the welded turbine housing segment by the features of independent claim 1. With regard to the turbine housing, the object is solved by the features of independent claim 4.

Further embodiments of the invention, which are used individually or in combination with each other, are the subject of the dependent claims.

The welded turbine housing segment according to the invention comprising a wall plate and a flange strip welded to the wall plate, the flange strip forming a parting surface, is characterized in that the flange strip is designed such that the flange strip tapers on the inner side of the turbine housing segment towards the parting surface. By the taper of the flange, the bearing surface is reduced and thus increases the contact pressure with the same screw force and thus achieves a better sealing effect. In addition, by tapering the flange strip on the turbine housing segment inner side, the parting screw moves closer to the inner contour of the turbine housing segment, which reduces the leverage and effectively prevents the Teilfugenflansches levering can be. Overall, the tapering of the flange strip on the inner side of the turbine housing segment thus results in a markedly increased sealing effect, which leads to a significant increase in the operating limits (for example, vapor pressure, steam temperature, temperature difference across the nozzle carriers). The welded turbine housing segment according to the invention thus makes it possible to achieve an approximately identical sealing effect as in a cast turbine housing segment, with significantly reduced production costs.

An inventive embodiment of the invention provides that the taper is formed by means of a chamfer on the flange. Such beveling / chamfering can be produced inexpensively by simple means.

A further embodiment of the invention provides that the taper is formed by a rounding on the flange. The rounding can have the same radius as the wall plate of the turbine housing segment or have a different radius from the wall plate. A deviating from the circular arcuate taper is conceivable.

The turbine housing according to the invention is characterized in that the turbine housing has at least two turbine housing segments according to one of the preceding claims, wherein the turbine housing segments abut against each other at the parting surfaces. As already stated, the tapering of the respective flange strips leads to a reduction of the contact surface of the parting joints and thus to a significantly increased sealing effect at the same contact pressure. As a result of the fact that the partial joint screws also move closer to the inner contour of the turbine housing segments as a result of the solution according to the invention, the leverage effect is reduced by the internal pressure in the turbine housing and the levering of the partial joint flange is effectively prevented. An embodiment of the turbine housing according to the invention is characterized in that the turbine housing is a steam turbine housing with two turbine housing segments and the turbine housing segments lie against each other at horizontal parting lines. Especially in steam turbines, there is often a high vapor pressure associated with high steam temperatures. These lead to a thermal expansion of the turbine housing halves and thus to a levering of Teilfugenflansches. By means of the turbine housing segments according to the invention, the levering in the area of the parting joint flanges can be effectively prevented, thereby making it possible to use the steam turbine with higher steam parameters.

• Figur 1: ein erstes Ausführungsbeispiel eines erfindungsgemäßen geschweißten Turbinengehäusesegmentes;
• Figur 2: ein zweites Ausführungsbeispiel eines erfindungsgemäßen geschweißten Turbinengehäusesegmentes;
• Figur 3: ein Ausführungsbeispiel eines erfindungsgemäßen Turbinengehäuses

Embodiments and further advantages of the invention are explained below with reference to the figures. It shows:

• FIG. 1 a first embodiment of a welded turbine housing segment according to the invention;
• FIG. 2 a second embodiment of a welded turbine housing segment according to the invention;
• FIG. 3 : An embodiment of a turbine housing according to the invention

The figures are schematic and not necessarily to scale representations, in which only the essential components necessary for the invention are shown. The same or functionally identical components are cross-figured with the same reference numerals.

FIG. 1 shows a first embodiment of a welded turbine housing segment 1. The welded turbine housing segment 1 is, for example, the upper housing part of a steam turbine. The turbine housing segment 1 comprises a wall plate 2 and a flange strip 3 welded to the wall plate 2. The flange strip 3 has a parting surface 4. With the parting surface 4, the turbine housing segment 1 rests against a further, not shown, part-joint surface of a housing lower part and forms with it a parting line. The flange 3 has a chamfer 6 on the turbine housing segment inside 5. In this case, the Flanschleiste 3 tapers in the direction of the part of the joint surface 4. This results in comparison to the conventional flange to a reduction in the part of the joint surface 4. By reducing the part of the joint surface 4 is achieved with the same contact pressure, a higher sealing effect. Due to the chamfer 6, the bore 10 moves closer to the inner contour of the turbine housing segment 1 for receiving the part-joint screws. This reduces the leverage effect, so that a levering of the Teilfugenflansches can be reduced or completely prevented. The increased sealing effect also increases the field of application of a turbine housing designed in this way, that is, for example, significantly higher steam parameters can be realized for a steam turbine.

FIG. 2 shows a second inventive inventive welded turbine housing segment 1. Again, the flange 3 tapers in the direction of the part of the joint surface 4. The taper is in this case formed by a rounding 7 on the flange 3. The rounding can be formed such that the radius of the rounding corresponds to the radius of the wall plate 2, so that the inner contour of the wall plate 2 is continued in the flange 3. In principle, however, the rounding can also be formed by means of a radius which is repellent from the wall plate 2. As described in the first embodiment, it comes through the taper of the flange to a reduction of the part of the joint surface 4, whereby at the same contact force of the contact pressure and thus the sealing effect increases. In addition, in this embodiment, the bore for the parting screw is brought closer to the inner contour of the turbine housing segment 1, which in turn reduces the leverage and a levering of the Teilfugenflansches can be prevented due to the pressure prevailing in the turbine housing internal pressure.

FIG. 3 shows a turbine housing 8 according to the invention. The turbine housing 8 has a first turbine housing segment 1 and a second turbine housing segment 1 '. The turbine housing segments 1, 1 'may be those in FIG. 1 or 2 act turbine segments described in detail. In the present embodiment, the turbine housing consists of a turbine housing segment 1, which is designed as a turbine housing upper part and a turbine housing segment 1 ', which is designed as a turbine housing lower part. The parting line 9 is formed as a horizontal parting line 9. By tapering the Flanschleiste 3 on the Turbinengehäusesegmentinnenseite in the direction of Teilfugenflächen 4, the parting surface 4 and thus the parting line 9 is reduced, whereby at the same contact pressure of the contact pressure increases and the sealing effect is increased.

By means of the present invention, for the first time when using a welded turbine housing segment and using simpler materials, it is possible to form a turbine housing which has the same or improved partial joint tightness with respect to a cast turbine housing. The formation of the taper can be achieved in a simple and cost-effective manner, for example, with cutting process.

Claims (5)

Welded turbine housing segment (1), comprising a wall plate (2) and a flange strip (3) welded to the wall plate (2), the flange strip (3) forming a parting surface (4),
characterized in that
the flange strip (3) is designed such that the flange strip (3) tapers on the turbine housing segment inner side (5) in the direction of the parting surface (4). Welded turbine housing segment (1) according to claim 1,
characterized in that
the taper is formed by means of a chamfer (6) on the flange strip (3). Welded turbine housing segment (1) according to claim 1, characterized in that
the taper is formed by means of a rounding (7) on the flange strip (3). Turbine housing (8),
characterized in that
the turbine housing (8) has at least two turbine housing segments (1, 1 ') according to one of the preceding claims and wherein the turbine housing segments (1, 1') abut against each other at the parting surfaces (4). Turbine housing (8) according to claim 4,
characterized in that
the turbine housing (8) is a steam turbine housing with two turbine housing segments (1, 1 ') and the turbine housing segments (1, 1') adjoin horizontal parting lines (9).

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