EP1965036A1 - Turbomachine with adjustable shroud contour - Google Patents

Abstract

The turbo machine (1) has a rotating blade with rotor, a housing (2), and a fixed flow contour. A positioning system (8) has units, by which the relative position of the flow contour is displaced from the housing into the circumferential direction. The position of the flow contour is displaced or determined from the rotor.

Description

The invention relates to a turbomachine in particular Heißgasexpander with a rotor blade comprising a rotor, a housing, and a non-rotating flow contour, which limits flow channels in the region of the blades on one side.

Such turbomachines or geared machines are characterized by a multi-shaft arrangement with different rotational speeds to a central drive wheel. This provides a compact unit for multi-stage compaction / expansion for a variety of media, preferably gaseous media.

Such gear machines expand the medium, which may have an inlet temperature of up to 300 ° C or, in a preferred embodiment, an inlet temperature of over 300 ° C. At a media inlet temperature of more than 300 ° C one speaks of so-called hot gas expanders.

These Heißgasexpander have at least one inlet housing, in which the spiral insert is arranged. The spiral insert carries an adjustable Eintrittsleitapparat having a collar, vanes and bolts, wherein the bolts serve as a rotation axis for adjusting the vanes.

The guide vanes are therefore rotatably struck on the bolt, wherein the guide vanes are simultaneously connected via a driver with the adjusting ring. If now the adjusting ring is rotated in a desired angular amount, the drivers cause a forced adjustment of the guide vanes, so that the adjustment of the guide vanes influencing the direction and / or the speed of the medium flow to the blade or the impeller is effected.

The spiral insert thus has two functions. On the one hand, the spiral insert carries the adjusting mechanism (adjusting ring, etc.), with the spiral insert on the other also carries the contour ring.

The spiral insert with the associated inlet guide and the contour ring is pre-assembled outside of the inlet housing and used as a unit in this.

Due to the high thermal load, in particular with hot gas expanders, however, it is observed that the different component components expand or expand differently due to the thermal effect. Due to the usually rigid connection of the spiral insert with the associated components to the inlet housing, the unit to be used must therefore be performed during assembly with relatively large-ßem radial clearance to the inlet housing or the impeller to avoid jamming due to different thermal expansion and axial To ensure freedom of movement.

As a result, but the contouring gap between the contour ring surface and the corresponding blade edge of the impeller is sized so large that the efficiency of the hot gas expander is significantly reduced by extremely high gap losses.

The invention is therefore based on the object to improve a turbomachine of the type mentioned, in particular a hot gas expander, by simple means to the effect that the gap losses are reduced, so that the efficiency can be significantly increased.

According to the invention the object is achieved in that by means of at least one adjustment system, by means of which the relative position of the flow contour to the housing in the circumferential direction is adjustable, the position of the flow contour to the rotor is in each case adjustable and / or detectable.

Due to the adjustment system according to the invention, the flow contour, in particular a spiral insert movable to the housing or to the inlet housing mountable, wherein the spiral insert is preferably seen in the radial direction movable adjustable or alignable. Of course, with the respective movement of the spiral insert also the associated components such. the adjustable Eintrittsleitapparat and the contour ring according adjusted in the radial direction with or aligned.

Favorable for the purposes of the invention is when the adjustment system has a sliding element which is arranged in a recess or a groove of the spiral insert. The sliding element may for example be designed as a sliding plate, which is made of a suitably suitable material, but the sliding element may also be provided with a corresponding coating.

For radial adjustment or alignment of the position of the spiral insert with the associated components in the inlet housing, it is expedient for the purposes of the invention, when the adjustment system has an eccentric. In a preferred embodiment, the eccentric is designed as an eccentric sleeve, that is to say as an eccentrically drilled sleeve which has a bore with a bore axis offset relative to the center axis of the adjustment system, so that the eccentric sleeve has a wall thickness which changes in the circumferential direction at its insertion section.

To connect the spiral insert with the inlet housing is advantageously provided that the adjustment system has a connecting element for frictional connection of the spiral housing with the inlet housing. The connecting element may be, for example, a stud bolt, which with its threaded portion in a corresponding Tapped hole engages in the inlet housing, with its bolt head rests against a contact flange of the eccentric.

The spiral insert is preassembled with its associated components outside the inlet housing and used as a unit in the inlet housing. For a first sufficient attachment or connection of the spiral insert with the inlet housing, it is sufficient if first the bolt or the connecting element is loosely screwed into the inlet housing, wherein the inserted into the bore of the slide plate eccentric with its abutment on both the sliding plate and the Bolt head is applied or is sufficiently braced for the following orientation.

By rotating the eccentric over the abutment flange so the desired and required installation position of the spiral insert can be adjusted in the radial direction, so that the contouring gap between the contour ring or its outer side and the blades or their edges is minimized. After the required installation position, i. a minimal Konturringspalt is set, the position or the setting by means of the bolt screw fixed in position.

Conveniently, it is provided that the spiral insert three adjustment systems are assigned, which are seen in the circumferential direction respectively mounted at 3,6 and 9 o'clock.

The eccentric advantageously allow a very simple and accurate installation of the spiral insert or the associated components, in particular the contour ring, so that the contouring gap can be designed extremely minimal. Due to the advantageous arrangement of the adjustment to 3.6 and 9 o'clock a centric position of the spiral insert in the radial direction is guaranteed even when heated to 510 ° C (inlet temperature). In addition, the spiral insert can advantageously move axially over the sliding plates, which is why the sliding elements have a correspondingly low friction Material can be made or coated with this.

Overall, thus, the contouring gap between the impeller and the fixed contour ring can be adjusted or aligned, which can be set to a minimum level. This reduces the gap losses, which at the same time increases the efficiency of the hot gas expander. Of course, it is possible to predict thermal expansion of the individual components beforehand, i. before adjusting the spiral insert, to calculate in the required position in the inlet housing for each component and to predict what is taken into account in the design of the individual components.

Fig. 1

einen Querschnitt durch einen beispielhaft dargestellten Heißgasexpander, und

Fig. 2

ein Einstellsystem als Einzelheit.

Further advantageous embodiments of the invention are disclosed in the subclaims and the following description of the figures. Show it:

Fig. 1

a cross section through a exemplified hot gas expander, and

Fig. 2

a setting system as a detail.

In the different figures, the same are always provided with the same reference numerals, which is why these are usually described only once.

FIG. 1 shows a turbomachine, such as a gear machine, which is designed in the illustrated embodiment as a hot gas expander 1 with a Eintemperatur a preferably gaseous medium of up to 510 ° C. The hot gas expander 1 has an inlet housing 2, in which a spiral insert 3 is arranged. The spiral insert 3 is assigned to an inlet guide 4 and a contour ring 6. The inlet housing 2 is further associated with a diffuser 7.

The spiral insert 3 is connected via an adjustment system 8 with the inlet housing 2, wherein in FIG. 1 due to the selected section, only a single adjustment system 8 can be seen. Not shown in FIG. 1 are two other adjustment systems 8, wherein the preferred way three provided adjustment system 8 are seen in the circumferential direction respectively mounted at 3,6 and 9 o'clock. This in FIG. 1 recognizable adjustment system 8 is mounted eg at 3 o'clock. The adjustment system, which is mounted at 9 o'clock, is not recognizable. The adjustment system 8, which is mounted at 6 o'clock, is also not visible in the selected section. The exemplified number of three adjustment systems should not be limited to this number is of course possible to provide less or more than three adjustment 8.

The adjustment system 8 has a sliding element 9, an eccentric 11 and a connecting element 12 ( FIG. 2 ). The eccentric 11 is designed as eccentrically drilled sleeve.

The sliding element 9 can also be referred to as a sliding plate, which is arranged in a recess 13 or groove of the spiral insert 3, so that the spiral insert 3 is guided radially via the three sliding plates or three adjustment systems 8. The sliding elements 9 are designed in such a way that they bear on the one hand against the inlet housing 2 and protrude somewhat beyond the spiral insert 3. Of course, the sliding elements 9 with their outside also flush with the spiral insert 3 complete. In the sliding member 9, a bore 14 is arranged, the center line X1 is arranged congruent to a bore 15 and the center line X2 in the inlet housing 2 when the spiral insert 3 is inserted or inserted in the inlet housing 2. The bore 15 has an internal thread, which is designed corresponding to an external thread of the connecting element 12. The connecting element 12 may for example be a bolt screw.

In the bore 14 of the eccentric 11 is set with its insertion portion 16. The eccentric 11 is shown in the Embodiment designed as an eccentric sleeve with a through hole 17 whose center line X3 is offset to the congruent center lines X1 and X2 of the two holes 14 and 15. As a result, the eccentric 11 seen on its wall in the circumferential direction has a changing wall thickness, wherein in FIG. 2 in the left plane of the drawing a minimum wall thickness and opposite to the right drawing plane a maximum wall thickness is shown.

With his abutment flange 18 of the eccentric 11 and the eccentric sleeve is located on the sliding member 9, wherein the bolt head 19 of the connecting element 12 abuts against an opposite side of the abutment flange 18 and is clamped therewith. At its opposite to the abutment flange 18 spigot end of the eccentric 11 is spaced from the inlet housing 2, so that a gap 20 is formed.

The exemplified hot gas expander 1 also has an impeller 21, the blades 22 are spaced with their edges to a corresponding or to the blade edges opposite surface 23 of the contour ring 6, so that a contouring gap 24 is formed ( FIG. 1 ).

Now, if the spiral insert 3 is inserted into the inlet housing 2 and connected via the adjustment system 8 with the inlet housing 2, causes a rotation of the eccentric 11 via its abutment flange 18 a radial adjustment or orientation of the spiral insert 3 with the associated components, in particular the contour ring 6 the blades 22 and their edges, so that the contouring gap 24 can be minimized. Of course, the minimum adjustment of the contouring gap 24 in the radial direction is achieved by an actuation or adjustment of all three adjustment systems 8.

For example, causes a rotation of the eccentric 11 in the in FIG. 1 recognizable adjustment system 8, which at 3 o'clock is mounted, as well as the adjustment system 8 which is mounted at 9 o'clock an orientation perpendicular to the sheet plane, ie in the radial direction out of this or into it. A rotation of the eccentric 11, not shown, which is mounted at 6 o'clock, causes an adjustment or alignment parallel to the sheet plane in the radial direction.

The adjustment systems 8, in particular the eccentrics 11, thus make possible a very simple and accurate installation, wherein the position of the adjustment systems 8 at 3, 6 and 9 o'clock ensures a heating up to 510 ° C. of the individual components in particular, the spiral insert 3 seen in the radial direction remains centric.

Of the FIG. 1 further advantageous embodiments of the hot gas expander 1 can be removed. For example, the hot gas expander 1, a clamping system 26 and a suitable sealing system 27 may be assigned. By means of the clamping system 26, the spiral insert 3 can be movably axially adjustable via the sliding elements 9, so that the spiral insert 3 can move axially over the sliding elements 9. The contour ring 6 can be sealed by the suitable sealing system 27 to the diffuser 7.

Claims (6)

Flow machine,
especially hot gas expanders,
with a rotor-comprising rotor, a housing, and a non-rotating flow contour,
which flow channels in the region of the rotor blades are limited on one side,
characterized in that
by means of at least one adjustment system (8) by means of which the relative position of the flow contour to the housing (2) is adjustable in the circumferential direction, the position of the flow contour to the rotor is in each case adjustable and / or detectable. Turbomachine according to claim 1,
characterized in that
the adjusting system (8) comprises a sliding element (9) which is arranged in a recess (13) of the spiral insert (3). Turbomachine according to claim 1 or 2,
characterized in that
the adjusting system (8) has an eccentric (11). Turbomachine according to claim 3,
characterized in that
the eccentric (11) is designed as eccentrically drilled sleeve. Turbomachine according to claim 3 or 4,
characterized in that
the eccentric (11) has a circumferentially changing wall thickness at its insertion section (16). Turbomachine according to one of the preceding claims,
characterized in that
the adjusting system (8) has a connecting element (12) for frictional connection of the flow contour, in particular a spiral insert (3) with the inlet housing (2).

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