JP2018009564A - Turbomachine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a turbomachine.SOLUTION: A turbomachine comprises a rotor having a radial flow impeller (10), and a stator having a housing (11) and an insert piece (12) mounted on the housing (11). The insert piece (12) partitions, at least in a predetermined cross section, a flow duct for a working fluid of the machine, namely, a first flow passage (17) extending in the axial direction and a second flow passage (18) of the flow duct extending radially outward relative to the first flow passage (17). In the range of an insert piece flange (15), the insert piece (12) is fastened to a housing flange (16) of the housing (11) via connecting elements (14) such that the impeller (10) can be disassembled and assembled in a state that the housing (11) is mounted. An impact deformation body (20) is mounted on the housing (11) to surely prevent movement of the insert piece (12) in the case of bursting of the impeller (10).SELECTED DRAWING: Figure 1

Description

  The present invention relates to a turbomachine.

  From Patent Document 1, a turbomachine having a rotor and a stator is known. The rotor includes a radial flow impeller. The stator includes a housing and an insert piece mounted on the housing. The insert piece comprises, in a given cross-section, a flow duct for a turbomachine working fluid, i.e. a flow duct extending axially and an arcuate flow duct extending radially outward. And a flow path. According to Patent Document 1, an insert piece is mounted on a housing, specifically via a connecting element, and the connecting element includes an insert piece flange of the insert piece and a corresponding housing flange of the housing. It extends through. Here, the insert piece is fastened to the housing so that the impeller can be disassembled and assembled in a state where the housing is assembled. To access the impeller, simply remove the insert piece from the housing and there is no need to disassemble the housing. As already explained, the insert piece is fastened to the housing via a plurality of connecting elements that take an embodiment like a screw, and the connecting element that is interposed to fasten the insert piece to the housing is embodied as a screw. The prior art that is known enables so-called capacity securing.

German Patent No. 102010027762

  According to the prior art, if the impeller bursts during operation and the impeller fragment collides with the insert piece, the screw-designed connecting element between the insert piece and the housing absorbs these forces, i.e. I have to prevent it. Thus, the prior art requires a plurality of such connecting elements to connect the insert piece to the housing, some of which need to be embodied as high strength bolts.

  Thus, the present invention is based on the object of creating a turbomachine that can ensure a higher capacity. This object is solved through the turbomachine of claim 1. According to the present invention, the impact deformable body is mounted on the housing and reliably prevents the movement of the insert piece when the impeller is ruptured.

  Preferably, the impact deformable body is inserted into the groove of the housing at the first portion, and is connected to the housing via the connecting element at the first portion, at which time the impact deformable body is the housing at the second portion. The second portion covers the insert piece in the protruding region of the insert piece flange. These details allow simple assembly of the impact deformable body into the housing, retention of the insert piece in the housing when the impeller ruptures due to interconnection, and in addition to the impeller in the assembled state of the housing. Assembly and removal are possible.

  According to an advantageous further development, a gap is formed between the impact deformation body and the insert piece, preferably when the impeller is ruptured, there is a malfunction of the connecting element for fixing the insert piece to the housing. It is the dimension that the insert piece comes into contact with the impact deformable body for the first time after the occurrence. At the start of the impeller malfunction, the present invention according to this further development works on the insert piece by first utilizing the deformation path or shear path of the connecting element that is interposed when the insert piece 12 is mounted on the compressor housing 11. Transform power. After this, the insert piece is surely applied to the impact deformable body for the first time, thereby further absorbing the force acting on the insert piece and finally transmitting the force to the housing.

  Preferably, the impact deformable body is integrally formed. Alternatively, it consists of several parts of multiple parts. In particular, when the impact deformable body is integrally formed, it is desirable to provide a plurality of depressions around it. This is because it is inserted into the groove of the bayonet-like housing through these depressions. A shock absorber consisting of multiple parts of a multi-part design is a simpler design.

  The invention according to desirable further developments can be understood from the dependent claims and the detailed description of the invention. Embodiments of the present invention will be described in detail below through the drawings which are not intended to limit the present invention.

It is the figure which extracted the summary from the turbomachine in this invention.

  The present invention relates to a turbomachine, ie a radial turbomachine having a radial impeller. Here, the radial turbomachine may take an embodiment such as a radial compressor or a radial turbine.

  The invention will now be described with reference to the embodiment of FIG. 1 showing a radial turbomachine designed as a radial compressor.

  The radial compressor, whose excerpt is shown in FIG. 1, comprises a rotor having a radial flow impeller 10. The impeller 10 is exposed to axial inflow and radial outflow.

  Further, the turbomachine of FIG. 1 includes a stator assembly, and FIG. 1 shows a compressor housing 11 in the stator, an insert piece 12 attached to the compressor housing 11, and a diffusion ring 13. Yes.

  The insert pieces 12 are attached to the housing 11 via connecting elements 14 designed as screws, which on the one hand extend through the insert piece flanges 15 of the insert pieces 12. On the other hand, it extends through a corresponding housing flange 16 of the compressor housing 11.

  The insert piece 12 is attached to the compressor housing 11 so that the impeller 10 can be assembled and disassembled without accessing the compressor housing 11 after the insert piece 12 is removed from the compressor housing 11. Therefore, the impeller 10 can be assembled and disassembled in a state where the compressor housing 11 is assembled and the insert piece 12 is removed.

  The insert piece 12 located on the stator side defines a turbomachine flow duct for the working fluid in a predetermined cross section, specifically on the radially outer side with respect to the impeller 10 located on the rotor side.

  Thus, when the impeller 10 is exposed to axial inflow, the insert piece 12 defines a first flow path 17 of the flow duct extending in the axial direction in a predetermined cross section, which is This is useful for inflow into the impeller 10.

  Furthermore, the insert piece 12 defines a second flow path 18 of the flow duct for the working fluid, which extends radially outwards, i.e. adjacent to the impeller 10 radially outwards, In this region, the insert piece 12 is formed in an arc shape. When viewed in the flow direction, the diffusion ring 13 is along the downstream direction of the impeller 10 and the downstream direction of the insert piece 12, and preferably has a fixed diffusion guide blade 19.

  According to the present invention, the impact deformable body 20 is attached to the housing 11. In particular, when a problem occurs in the impeller 10 during operation of the impeller 10, that is, when the impeller 10 is ruptured, a force and a moment act on the insert piece 12, and the force and the moment cause the insert piece 12 to be compressed into the compressor. When a failure occurs in the connecting element 14 to be attached to the housing 11, it is absorbed by the impact deformable body 20 and transmitted to the compressor housing 11. In this process, the impact deformable body 20 reliably prevents the movement of the insert piece 12 when a failure occurs in the connecting element 14 for fixing the insert piece 12 to the compressor housing 11.

  As is clear from FIG. 1, the impact deformable body 20 covers the insert piece 12 in the region of the insert piece flange 15 that protrudes in the axial direction at least in a predetermined cross section. In particular, when a failure occurs in the connecting element 14 for attaching the insert piece 12 to the compressor housing 11 when the impeller 10 is ruptured as a result of the force acting on the insert piece 12, the insert having the insert piece flange 15 is provided. The piece 12 comes into contact with the impact deformable body 20 in a predetermined manner. As described above, the impact deformable body 20 absorbs the related force and transmits the related force to the compressor housing 11.

  In this case, the impact deformable body 20 is attached to the compressor housing 11 via a plurality of connecting elements 21.

  The impact deformable body 20 is inserted into the groove 22 of the compressor housing 11 in the first portion, that is, the radially outer portion, and protrudes from the groove 22 in the second portion, that is, the radially inner portion. In a state where the second radially inner portion protrudes from the groove 22, the impact deformable body 20 covers the insert piece 12 in the region of the insert piece flange 15 protruding in the axial direction.

  The connecting element 21 configured to attach the impact deformable body 20 to the compressor housing 11 extends through the compressor housing 11 on the one hand, and the first radial direction projects toward the groove 22 on the other hand. It extends through the outer part.

  The impact deformable body 20 may be integrally formed or may be composed of several parts of a plurality of portions. Particularly when the impact deformable body 20 is realized in an integrated manner, it preferably has a wavy contour on the first radially outer part, so that a bayonet-like one is sewn in the groove 22 of the compressor housing 11. This is because it is winding and moving forward. In particular, when the impact deformable body 20 is composed of several parts of a plurality of parts, the impact deformable body 20, that is, the plurality of parts can be inserted into the groove 22 of the compressor housing 11 more easily. It can be mounted on the housing 11.

  The impact deformable body 20 composed of one or a plurality of parts is preferably an integral steel plate or an assembled steel plate.

  In the preferred embodiment illustrated by FIG. 1, a gap 23 is formed between the insert piece 12, ie the insert piece flange 15 and the impact deformable body 20. Here, the gap 23 is dimensioned to receive the impact of the insert piece 12 having the insert piece flange 15 for the first time after the failure or shear of the connecting element 14 for attaching the insert piece 12 to the compressor housing 11 occurs. .

  In this case, in order to absorb the force acting on the insert piece 12 when the impeller 10 bursts, the deformation path or shear path of the connecting element 14 for attaching the insert piece 12 to the compressor housing 11 removes the force. In order to be utilized first. Then, after a failure occurs in the connecting element 14 for attaching the insert piece 12 to the compressor housing 11, that is, after the insert piece 12 comes into contact with the impact deformable body 20, the force is not applied by the impact deformable body 20 for the first time. It is absorbed and transmitted to the compressor housing 11.

  As described above, when the impeller 10 is ruptured, in the present invention, the insert piece 12 is securely held by the compressor housing 11, and the force acting on the insert piece 12 in the process is supplied via the impact deformable body 20 to the compressor housing 11. Can lead to. Further, the impeller 10 can be assembled and disassembled with the compressor housing 11 attached and the insert piece 12 removed from the compressor housing 11.

  A steel plate or ring attached to the compressor housing 11 via its own connecting element 21 preferably functions as the impact deformable body 20. When the impeller 10 is ruptured, the impact deformable body 20 transmits a force acting on the insert piece 12 to the compressor housing 11.

  As described above, the gap 23 is preferably provided between the impact deformable body 20 and the insert piece 12, and the connecting element 14 for attaching the insert piece 12 to the compressor housing 11 in the event of impeller 10 rupture. Initially dissipate energy until the coupling element 14 is sheared. Only after this, the insert piece flange 15 of the insert piece 12 comes into contact with the impact deformable body 20. For this reason, the axial path of the insert piece 12 is reliably determined, whereby the axial movement of the insert piece 12 is stopped, and as a result, the residual energy of the insert piece 12 is transferred to the compressor housing via the impact deformable body 20. 11 is transmitted.

10 impeller 11 housing 12 insert piece 13 guide grille / diffusion (ring)
DESCRIPTION OF SYMBOLS 14 Connection element 15 Insert piece flange 16 Housing flange 17 Flow path 18 Flow path 19 Diffusion guide blade 20 Impact deformation body 21 Connection element 22 Groove 23 Gap

Claims (8)

A turbomachine having a rotor with a radial impeller (10) and a stator with a housing (11) and an insert piece (12) attached to the housing (11),
The insert piece (12) has, at least in a predetermined cross-section, a flow duct for the working fluid, i.e. the first flow path (17) extending in the axial direction and the first flow path (17) in an arc. A second flow path (18) of the flow duct extending radially outward with respect to 17),
The insert piece flange (15) is connected via a connecting element (14) so that the insert piece (12) can be disassembled and assembled with the impeller (10) in a state where the housing (11) is attached. In the turbomachine fixed to the housing flange (16) of the housing (11) in the region of
A turbomachine characterized in that an impact deformable body (20) is attached to a housing (11) and reliably prevents movement of an insert piece (12) when the impeller (10) is ruptured.   The turbomachine according to claim 1, wherein the impact deformable body (20) covers the insert piece (12) in a protruding region of the insert piece flange (15). The impact deformable body (20) having a first part is inserted into the groove (22) of the housing (11) and is connected to the housing (11) via a connecting element (21) in the first part. And
The impact deformable body (20) having a second portion protrudes from the groove (22) of the housing (11), and the insert is inserted into the insert piece flange (15) by the second portion in the protruding region. The turbomachine according to claim 1 or 2, characterized in that it covers the piece (12).   The turbomachine according to any one of claims 1 to 3, wherein the impact deformable body (20) is integrally formed.   The turbomachine according to any one of claims 1 to 3, wherein the impact deformable body (20) comprises a plurality of parts and includes a plurality of parts.   The turbomachine according to any one of claims 1 to 5, wherein the impact deformable body (20) is formed as an integral steel plate or an assembled steel plate.   The turbomachine according to any one of claims 1 to 6, wherein a gap (23) is formed between the impact deformable body (20) and the insert piece (12).   The gap (23) allows the insert piece (12) to connect the insert piece (12) to the housing (11) when the radial impeller (10) is ruptured. The turbomachine according to claim 7, wherein the turbomachine is dimensioned to abut against the impact deformable body (20) for the first time after the occurrence of the problem (1).