JP6672827B2 - Rotating machinery - Google Patents

Description

  The present invention relates to a centrifugal compressor and a rotary machine.

  Patent Document 1 discloses a casing having a gas inflow channel extending in an axial direction and a diffuser channel extending to an outer peripheral side, and an impeller rotatably disposed between the gas inflow channel and the diffuser channel inside the casing. And a centrifugal compressor comprising:

JP-A-2002-70570

  Here, in the above-described centrifugal compressor, a bearing that receives a load in the thrust direction of the rotating shaft is provided. In such a bearing, when the thrust force generated by the impeller increases, the bearing load increases. Therefore, it has been required to reduce the thrust force in order to reduce the bearing load.

  Therefore, an object of the present invention is to provide a centrifugal compressor that can reduce a thrust force acting on an impeller.

  A centrifugal compressor according to one aspect of the present invention includes a casing having a gas inflow channel extending in an axial direction and a diffuser channel extending to an outer peripheral side, and rotating between the gas inflow channel and the diffuser channel inside the casing. A first impeller disposed so as to be capable of being disposed, a first back wall portion is provided on a back side of the first impeller, and a back surface of the first impeller; A first back flow passage communicating with the diffuser flow passage is formed between the first back wall and the back wall portion, and a bleed flow passage communicating with the first back flow passage is formed on the first back wall portion. The first back wall portion has a continuous surface from the entrance of the first back flow passage to a position extending to the bleed flow passage.

  In this centrifugal compressor, a first back flow passage communicating with the diffuser flow passage is formed between the back surface of the first impeller and the first back wall portion. In the first back wall portion, a bleed flow passage communicating with the first back flow passage is formed. Further, the first back wall portion has a continuous surface from the entrance of the first back flow passage to a position reaching the bleed flow passage, and no other flow passage or the like is formed. As described above, by extracting gas from the first back flow path, it is possible to generate a gas flow on the back side of the first impeller. Therefore, by reducing the pressure on the back side of the first impeller, the thrust force acting on the first impeller can be reduced.

  In the centrifugal compressor according to one aspect of the present invention, the bleed passage may supply the bleed gas to a bearing that supports a rotating shaft of the first impeller. Accordingly, the bearing can be cooled using the flow of gas generated by the first impeller without separately providing a mechanism for cooling the bearing.

  Further, in the centrifugal compressor according to one aspect of the present invention, the bleed passage may be formed at a position facing the outer diameter portion on the back surface of the first impeller. Thereby, bleeding can be performed at a high pressure, and a low-temperature gas can be supplied to the bearing as a cooling gas.

  Further, a rotary machine according to one aspect of the present invention includes the centrifugal compressor described above and a second impeller supported on a rotation shaft of the first impeller, and a second impeller is provided on a rear side of the second impeller. 2 back wall portion is provided, and a second back flow passage is formed between the back surface of the second impeller and the second back wall portion, from the bleed flow passage to the second back flow passage. A supply channel that extends and communicates may be formed. Thus, by extracting gas from the first back channel through the bleed channel, the pressure on the back side of the first impeller is reduced, and the bleed channel causes the extracted gas to pass through the second back channel. By supplying to the flow path, the pressure on the back side of the second impeller can be increased. The second impeller is supported by a rotation shaft of the first impeller, and a back surface of the second impeller is axially opposed to a back surface of the first impeller. Therefore, by increasing the pressure on the back side of the second impeller, the second impeller can apply the thrust force via the rotary shaft in a direction to cancel the thrust force acting on the first impeller. Thereby, the thrust force acting on the first impeller can be reduced.

  Further, in the rotary machine according to one aspect of the present invention, a pressure adjusting valve for adjusting the pressure of the extracted gas may be provided between the bleed passage and the supply passage. Thereby, the pressure of the gas extracted and supplied to the second back channel can be adjusted.

  Further, in the rotating machine according to one aspect of the present invention, a labyrinth seal may be provided in the second back channel on the outer peripheral side of a connection portion with the supply channel. This makes it difficult for the gas supplied to the second back flow path to flow to the outer peripheral side by the labyrinth seal. Therefore, the pressure in the second back channel can be efficiently increased.

  According to the present invention, the thrust force acting on the impeller can be reduced.

FIG. 1 is a sectional view of a turbocharger including the centrifugal compressor according to the present embodiment. FIG. 2 is a schematic sectional view showing the configuration of the centrifugal compressor according to the present embodiment. FIG. 3 is a schematic sectional view showing the configuration of the rotary machine according to the present embodiment. FIG. 4 is an enlarged cross-sectional view of the back channel of the centrifugal compressor shown in FIG. 3 and the back channel of the impeller having the impeller structure. FIG. 5 is a view of an impeller-side back wall of the centrifugal compressor shown in FIG. 3 and an impeller-side back wall of the impeller structure as viewed from the axial direction.

  Hereinafter, an embodiment of a centrifugal compressor according to the present invention will be described in detail with reference to the drawings. In the description of the drawings, the same components or corresponding components will be denoted by the same reference numerals, and duplicate description may be omitted.

  As shown in FIG. 1, a turbocharger 50 to which a centrifugal compressor 100 according to the present embodiment is applied has a structure in which a turbine housing 1 and a compressor housing 2 are integrally connected via a bearing housing 3. In this turbocharger 50, a turbine wheel 4 in a turbine housing 1 and an impeller 5 in a compressor housing 2 are connected by a turbine shaft 6 rotatably supported by journal bearings in a bearing housing 3. . The turbocharger 50 rotates the impeller 5 through the turbine shaft 6 by rotating the turbine wheel 4 by exhaust of the engine, and compresses intake air to supply the engine.

  In the centrifugal compressor 100, an oil drain having irregularities on its surface is provided outside the turbine shaft 6 on which the impeller 5 is mounted in the compressor housing 2. A compressor-side thrust bearing 16 is fitted around the outer periphery of the oil drain. The seal plate 17 is attached to the bearing housing 3 such that the inner peripheral surface is in contact with the compressor-side thrust bearing 16. A thrust collar 18 and a turbine-side thrust bearing 14 are fitted to the turbine shaft 6 at a position on the turbine side with respect to the compressor-side thrust bearing 16. The turbine-side surface of the compressor-side thrust bearing 16 is a positive thrust (thrust in a direction in which the turbine shaft 6 is moving toward the compressor) bearing surface, and the compressor-side surface of the turbine-side thrust bearing 14 is a counter thrust (turbine shaft). Reference numeral 6 denotes a thrust (bearing) surface in a direction toward the turbine side.

  The configuration of the centrifugal compressor 100 will be described in more detail with reference to FIG. As shown in FIG. 2, the centrifugal compressor 100 includes a compressor housing (casing) 2 having a gas inflow passage 33 extending in the axial direction and a diffuser passage 32 extending to the outer peripheral side, and a gas inflow flow inside the compressor housing 2. An impeller (first impeller) 5 rotatably disposed between the path 33 and the diffuser flow path 32.

  The impeller 5 includes a hub 30 connected to the turbine shaft 6 and fins 31 provided on the outer peripheral surface 5b of the hub 30. The outer peripheral surface 5b of the hub 30 extends substantially parallel to the axial direction on the gas inflow channel 33 side and is curved so as to expand in the radial direction toward the diffuser channel 32. The hub 30 has a back surface 5a on the opposite side in the axial direction with respect to the gas inflow passage 33. The back surface 5a extends from the turbine shaft 6 toward the outer periphery. The hub 30 has an outer peripheral surface 5c at an end on the diffuser channel 32 side. With the above configuration, the air (flow of A1) flowing from the gas inflow passage 33 and flowing in the axial direction is compressed by the impeller 5 and flows toward the outer periphery. Thereby, the compressed air flows toward the outer peripheral side in the diffuser flow path 32 (flow of A2).

  A back wall portion (first back wall portion) 35 is provided on the back side of the impeller 5. In the present embodiment, the back wall portion 35 includes the seal plate 17 illustrated in FIG. 1 and a part of the compressor housing 2 that supports the seal plate 17. However, any component provided on the back side of the impeller 5 may constitute the back wall portion 35.

  The back wall portion 35 includes an opposing surface 35a that opposes the back surface 5a of the impeller 5 in the axial direction. The facing surface 35a is a surface that spreads from the turbine shaft 6 side to the outer peripheral side. The facing surface 35a may be appropriately changed according to the shape of the back surface 5a of the impeller 5, and may be configured by a flat surface, an inclined surface, a curved surface, or a combination thereof. Further, in the embodiment shown in FIG. 2, the back wall portion 35 includes an opposing surface 35 b that radially opposes the outer peripheral surface 5 c of the impeller 5.

  A back flow path (first back flow path) 42 communicating with the diffuser flow path 32 is formed between the back surface 5 a of the impeller 5 and the back wall 35. The back channel 42 is a channel formed by a gap space between the back surface 5a and the facing surface 35a of the back wall 35. The back channel 42 is a space that extends from the turbine shaft 6 side to the outer peripheral side. In addition, between the outer peripheral surface 5c of the impeller 5 and the back wall portion 35, an inlet flow passage 41 which communicates with the diffuser flow passage 32 and functions as an inlet for guiding air to the back flow passage 42 is formed. The inlet channel 41 is a channel formed by a gap space between the outer peripheral surface 5c and the facing surface 35b of the back wall 35. The inlet passage 41 is an annular space that communicates with the diffuser passage 32 in the vicinity of the boundary with the impeller 5 and extends toward the back surface 5a along the axial direction.

  In the back wall portion 35, a bleed passage 34 communicating with the back passage 42 is formed. The bleed passage 34 extracts air flowing through the back passage 42. The bleed passage 34 is constituted by a tubular internal space formed in the back wall 35. Note that one or more bleeding channels 34 may be provided around the central axis. The bleed passage 34 is formed at a position separated from the outer peripheral surface 5c of the impeller 5 by a predetermined amount toward the inner peripheral side so as to generate a flow through on the back side. The bleed passage 34 is formed at a position facing an outer diameter portion of the back surface 5a of the impeller 5, that is, a portion near the outer peripheral surface 5c. Note that the bleed passage 34 may be formed in the inner diameter portion of the back surface 5a, that is, in the portion near the center axis.

  The back wall portion 35 has a continuous surface (opposing surfaces 35a, 35b) from the inlet of the back flow passage 42 to a position extending to the bleed flow passage 34. That is, in the radial direction, in the region on the outer peripheral side of the bleed passage 34, the opposing surfaces 35a and 35b are continuously widened. The continuous surface is a surface in which no other flow path or the like is formed from the inlet of the back flow path 42 to a position extending to the bleed flow path 34 and the flow of air is sealed. In the present embodiment, the inlet of the inlet channel 41 corresponds to the inlet of the back channel 42. Therefore, the opposing surfaces 35a and 35b are configured as continuous surfaces from the inlet to the bleed passage 34.

  In addition, even when the back wall portion 35 is configured by a combination of different members, and the facing surface 35a is configured by a surface of a different member, air flow is prevented by sealing between the members. It is a “continuous surface”. For example, as shown in FIG. 1, even if the “opposing surface” is constituted by the surface of the seal plate, the surface of the compressor housing 2 and the surface of the bolt, if these members are sealed, “ Continuous surface ". In addition, even if air is slightly leaked due to mechanical joining due to strict sealing treatment, it must be something that actively creates air by forming a flow path. For example, it may be recognized as a “continuous surface”.

  The bleed passage 34 supplies the extracted air as cooling air to bearings (bearings) 14 and 16 that support the turbine shaft 6 via the line L1. Thereby, the bearings 14 and 16 are cooled. The configuration and route of the line L1 are not particularly limited, and any configuration may be used as long as cooling air can be supplied to the bearings 14 and 16.

  As described above, the centrifugal compressor 100 has a configuration in which the cooling air is extracted from the back channel 42 by the extraction channel 34 (flow of A5). Therefore, a part of the compressed air is taken into the inlet flow passage 41 (the flow of A3) from the main flow of the compressed air flowing in the diffuser flow passage 32 (the flow of A2), and a through-flow is generated in the back flow passage 42 (A4). Flow of). Then, the air in the back channel 42 is extracted from the extraction channel 34 as cooling air (flow of A5) and supplied to the bearings 14 and 16.

  Next, the operation and effect of the centrifugal compressor according to the present embodiment will be described.

  In the centrifugal compressor according to the present embodiment, a back flow path 42 that communicates with the diffuser flow path 32 is formed between the back surface 5 a of the impeller 5 and the back wall 35. The back wall portion 35 is formed with a bleed passage 34 communicating with the back passage. The back wall portion 35 has a continuous surface (opposing surfaces 35a, 35b) from the inlet of the back channel 42 to a position extending to the bleed channel 34, and no other channels are formed. As described above, by extracting the gas from the back channel 42, the gas can flow through on the back side of the impeller 5. Therefore, by reducing the pressure on the back side of the impeller 5, the thrust force (indicated by F in FIG. 2) acting on the impeller 5 can be reduced.

Specifically, when ΔP is a pressure drop, C is a resistance coefficient, ρ is an air density, and Vr is a through-flow velocity, the following equation (1) holds. As understood from the equation (1), in the centrifugal compressor 100 according to the present embodiment, the provision of the bleed passage 34 allows the through-flow velocity Vr to be increased, so that the pressure drop ΔP on the rear side of the impeller 5 is reduced. Can be increased. Thus, the thrust force F acting on the impeller 5 can be reduced. Thus, by reducing the thrust force F, the bearing load on the compressor-side thrust bearing 16 can be reduced, and bearing loss can be reduced. In addition, since the amount of cooling air can be reduced by reducing the bearing loss, the compressor efficiency of the centrifugal compressor 100 can be improved as a result.

^{ΔP = C · (ρVr 2/} 2) ... (1)

  Further, in the centrifugal compressor 100 according to the present embodiment, the bleed air passage 34 supplies the extracted air to the bearings 14 and 16 that support the turbine shaft 6 of the impeller 5. Thus, the bearings 14 and 16 can be cooled using the flow of air generated by the impeller 5 without separately providing a mechanism for cooling the bearings 14 and 16.

  Further, in the centrifugal compressor 100 according to the present embodiment, the bleed passage 34 is formed at a position facing the outer diameter portion of the back surface 5 a of the impeller 5. Thus, bleeding can be performed at a higher pressure than when bleeding is performed on the inner diameter side, and low-temperature air can be supplied to the bearings 14 and 16 as cooling air.

  The present invention is not limited to the above embodiment.

  For example, in the above-described embodiment, the cooling air extracted in the extraction channel 34 is supplied to the bearings 14 and 16. However, the supply destination of the air extracted in the extraction channel 34 is not particularly limited. For example, the air extracted in the extraction channel 34 may be supplied to a coaxially connected turbine or the like for cooling.

  In addition, the configurations of the impeller 5 and the back wall 35 of the centrifugal compressor 100 according to the above-described embodiment are merely examples, and may be changed as appropriate, and the shape of the back channel and the like is changed accordingly.

  The centrifugal compressor 100 may be applied to a rotating machine as shown in FIG. The rotary machine 200 shown in FIG. 3 includes the centrifugal compressor 100 and an impeller structure 150. In addition, the rotary machine 200 may be a turbocharger as shown in FIG. 1, and in this case, the impeller structure 150 is configured by a turbine. Alternatively, the rotary machine 200 may be a multi-stage compressor, and in this case, the impeller structure 150 is configured by a compressor different from the centrifugal compressor 100.

  In the centrifugal compressor 100, the gas inflow passage 33, the diffuser passage 32, the compressor housing 2, the impeller 5, the back wall 35, the back passage 42, and the bleed passage 34 are the same as those shown in FIGS. Since it has the same meaning as that of the centrifugal compressor 100 according to the embodiment, the description is omitted.

  The impeller structure 150 includes a casing 102 having a first flow path 133 extending in the axial direction and a second flow path 132 extending to the outer peripheral side, and a first flow path 133 and a second flow path 132 inside the casing 102. (A second impeller) 105 rotatably disposed between the first and second impellers. The impeller 105 is supported by a rotation shaft 106 of the impeller 5. The back surface 105a of the impeller 105 is axially opposed to the back surface 5a of the impeller 5. The back surface 105a of the impeller 105 and the back surface 5a of the impeller 5 are opposed to each other via the back wall portions 35, 135 and the like. A back wall portion 135 is provided on the back surface 105a side of the impeller 105. A back channel 142 is formed between the back surface 105 a of the impeller 105 and the back wall 135.

  A supply flow path 134 extending from the bleed flow path 34 of the centrifugal compressor 100 to the back flow path 142 and communicating with the back flow path 142 is formed. The bleed passage 34 of the centrifugal compressor 100 supplies the extracted gas to the back passage 142 via the supply passage 134. That is, the supply channel 134 supplies the gas flowing from the bleed channel 34 to the back channel 142. The supply channel 134 is constituted by a tubular internal space formed in the back wall 135. One or more supply flow paths 134 may be provided around the central axis (in the example shown in FIG. 5 described later, a plurality of supply flow paths are provided). The supply flow path 134 is formed at a position separated from the outer peripheral surface of the impeller 105 by a predetermined amount toward the inner peripheral side. The supply channel 134 is formed at a position facing the outer diameter portion of the back surface 105a of the impeller 105, that is, a portion near the outer peripheral surface. Note that the supply flow path 134 may be formed at an inner diameter portion of the back surface 105a, that is, a portion near the center axis.

  The back wall 135 may have a continuous surface from the inlet of the back channel 142 to the position extending to the supply channel 134, similarly to the back wall 35 of the centrifugal compressor 100. That is, in the radial direction, the surface of the impeller 105 facing the back surface 105a may be continuously widened in a region on the outer peripheral side of the supply flow path 134.

  A pressure adjusting valve 62 for adjusting the pressure of the extracted gas is provided between the bleed passage 34 and the supply passage 134. In the present embodiment, the flow path on the upstream side of the pressure control valve 62 is referred to as the bleed flow path 34, and the flow path on the downstream side of the pressure control valve 62 is referred to as the supply flow path 134. However, the bleed passage 34 includes an internal space formed in the back wall 35, and the supply passage 134 may include an internal space formed in the back wall 135. It is possible to arbitrarily determine to what extent the tube extending outward from the back wall portions 35 and 135 belongs to the bleed passage 34 and how far the tube belongs to the supply passage 134. The pressure regulating valve 62 may be electrically connected to a control unit (not shown). The control unit may detect the discharge pressure of the impeller 5 or the back pressure of the impeller 5 and adjust the pressure adjusting valve 62 based on the detection result.

  Next, the detailed structures of the centrifugal compressor 100 and the impeller structure 150 will be described with reference to FIGS. As shown in FIG. 4, a labyrinth seal 65 is provided in the back channel 42 on the outer peripheral side of a connection portion with the bleed channel 34 (a portion where the bleed channel 34 is open). The labyrinth seal 65 is formed by providing a plurality of annular grooves on the surface of the back wall 35. The labyrinth seal 66 is provided in the back channel 142 on the outer peripheral side of the connection portion with the supply channel 134 (the portion where the supply channel 134 is open). The labyrinth seal 66 is formed by providing a plurality of annular grooves on the surface of the back wall 135.

  As shown in FIG. 5, a plurality of (four in this case) bleeding channels 34 are provided on the back wall 35 at equal intervals in the circumferential direction. The bleed passage 34 is inclined with respect to the direction in which the rotating shaft 106 extends in accordance with the rotating direction of the impeller 5. Specifically, when the opposing surface 35a of the back wall 35 is viewed from the axial direction, when the bleeding passage 34 extends in the thickness direction of the back wall 35 from the opposing surface 35a, It extends to incline. Here, a straight line L7 passing through the center C1 of the back wall portion 35 and the center C2 of the bleed flow path 34 on the facing surface 35a is set. Further, a straight line L2 passing through the center C2 and perpendicular to the straight line L7 is set. At this time, the angle θ between the axis L3 of the bleed passage 34 and the straight line L2 is set to 30 to 40 °. With such a configuration, the direction in which the gas in the back channel 42 that rotates with the rotation of the impeller 5 is the same as the direction in which the gas in the extraction channel 34 flows from the upstream side to the downstream side, The gas in the back channel 42 smoothly flows into the bleed channel 34.

  The back wall 135 is provided with a plurality (four in this case) of supply channels 134 at equal intervals in the circumferential direction. The supply flow path 134 is inclined with respect to the axial direction according to the rotation direction of the impeller 105. Specifically, when the opposing surface 135a of the back wall 135 is viewed from the axial direction, when the supply flow path 134 extends in the thickness direction of the back wall 135 from the opposing surface 135a, the supply channel 134 is on the opposite side in the rotation direction. It extends to incline. Here, a straight line L4 passing through the center C1 of the back wall 135 and the center C3 of the supply flow path 134 on the facing surface 135a is set. Further, a straight line L5 passing through the center C2 and perpendicular to the straight line L4 is set. At this time, the angle formed by the axis of the supply flow path 134 and the straight line L5 is set to 30 to 40 ° similarly to the angle θ described above. With such a configuration, the turning direction of the gas in the back flow path 142 that turns with the rotation of the impeller 105 and the direction in which the gas flows from the upstream side to the downstream side in the supply flow path 134 are the same. The gas supplied from the supply channel 134 flows into the back channel 142 smoothly.

  Note that the bleed passage 34 may be configured by a portion of a through hole formed in the back wall 35 and a pipe connected to the through hole outside the back wall 35. The pipes drawn out from the plurality of through holes may be integrated into one pipe. The supply channel 134 may be configured by a portion of a through hole formed in the back wall 135 and a pipe connected to the through hole outside the back wall 135. The pipes drawn out from the plurality of through holes may be integrated into one pipe. The pressure adjustment valve 62 may be provided at a portion where the pipes integrated in the bleed flow path 34 and the pipes integrated in the supply flow path 134 are connected.

  As described above, the rotating machine 200 includes the centrifugal compressor 100 and the impeller 105 supported by the rotating shaft 106 of the impeller 5. A back wall 135 is provided on the back surface 105a side of the impeller 105, and a back flow path 142 is formed between the back wall 105a of the impeller 105 and the back wall 135. A supply channel 134 extending from the bleed channel 34 to the back channel 42 and communicating therewith is formed. The bleed channel 34 of the centrifugal compressor 100 transfers the extracted gas to the back channel 142 via the supply channel 134. Supplying. Thereby, by extracting gas from the back channel 42 in the bleed channel 34, the pressure on the back surface 5 a side of the impeller 5 is reduced, and the bleed channel 34 transfers the extracted gas to the back channel 42. By supplying the pressure, the pressure on the back surface 105a side of the impeller 105 can be increased. The impeller 105 is supported by the rotating shaft 106 of the impeller 5, and the back surface 105 a of the impeller 105 faces the back surface 5 a of the impeller 5 in the axial direction. Therefore, by increasing the pressure on the back surface 105a side of the impeller 105, the impeller 105 can apply the thrust force F2 via the rotary shaft 106 in a direction to cancel the thrust force F1 acting on the impeller 5 (see FIG. 3). ). Thus, the thrust force F1 acting on the impeller 5 can be reduced.

  In the rotary machine 200, a pressure adjusting valve for adjusting the pressure of the extracted gas may be provided between the bleed passage 34 and the supply passage 134. Thus, the pressure of the gas extracted and supplied to the back channel 142 can be adjusted.

  In the rotary machine 200, the labyrinth seal 66 is provided in the back channel 142 on the outer peripheral side of the connection with the supply channel 134. This makes it difficult for the gas supplied to the back channel 142 to flow to the outer peripheral side by the labyrinth seal 66. Therefore, the pressure in the back channel 142 can be efficiently increased. In addition, a labyrinth seal 65 is provided in the back channel 42 on the outer peripheral side of the connection portion with the bleed channel 34. Here, when the gas passes through a narrow portion such as the labyrinth seal 65, the pressure decreases due to resistance. If a similar pressure drop is to be obtained only by bleeding, a larger bleeding flow rate is required. Therefore, the pressure can be effectively reduced by providing the labyrinth seal 65 on the back channel 42 side.

  Note that the rotating machine is not limited to the configuration shown in FIGS. 3 to 5, and the size, the shape, and the positional relationship of each component may be changed as needed. For example, the bleed passage 34 and the supply passage 134 may extend straight in the axial direction. In addition, the centrifugal compressor may be arranged on the upstream side and the impeller structure may be arranged on the downstream side with respect to the flow of gas in the rotating machine, but depending on the pressure relationship, the centrifugal compressor may be arranged on the upstream side. The impeller structure may be arranged on the upstream side. That is, if the back flow path of the centrifugal compressor has a higher pressure than the back flow path of the impeller structure, and the bleeding flow path of the centrifugal compressor has a relationship capable of supplying gas to the back flow path of the impeller structure, each configuration is established. The arrangement of the elements is not particularly limited.

2 Compressor housing (casing)
5 Impeller (first impeller)
6 Turbine shaft (rotary shaft)
14,16 Bearing
32 diffuser passage 33 gas inflow passage 34 bleed passage 35 back wall (first back wall)
35a, 35b Opposing surface 42 Back flow path (first back flow path)
100 Centrifugal compressor 105 Impeller (second impeller)
134 supply flow path 135 back wall (second back wall)
142 back flow path (second back flow path)
150 Impeller structure 200 Rotary machine

Claims (4)

A casing having a gas inflow channel extending in the axial direction and a diffuser channel extending to the outer peripheral side,
A first impeller rotatably arranged between the gas inflow passage and the diffuser passage inside the casing, a centrifugal compressor comprising:
A first back wall portion is provided on a back side of the first impeller,
A first back flow path communicating with the diffuser flow path is formed between the back surface of the first impeller and the first back wall portion,
In the first back wall portion, a bleed flow passage communicating with the first back flow passage is formed,
The first back wall portion has a continuous surface from an entrance of the first back flow passage to a position reaching the bleed flow passage ,
The bleed passage is formed at a position facing an outer diameter portion of the back surface of the first impeller, and is formed at a position further away from the outer peripheral surface of the hub of the first impeller toward the inner peripheral side. that, and the centrifugal compressor,
A second impeller supported by a rotation shaft of the first impeller,
A back surface of the second impeller faces the back surface of the first impeller in the axial direction;
A second back wall portion is provided on the back side of the second impeller,
A second back flow path is formed between the back surface of the second impeller and the second back wall portion,
A rotary machine, wherein a supply flow path extending from the bleed flow path to the second back flow path and communicating with the second back flow path is formed. The rotating machine according to claim 1 , wherein a pressure adjusting valve that adjusts a pressure of the extracted gas is provided between the bleed passage and the supply passage. 3. The rotating machine according to claim 1 , wherein a labyrinth seal is provided in the second back flow path on an outer peripheral side of a connection portion with the supply flow path. 4. A casing having a gas inflow channel extending in the axial direction and a diffuser channel extending to the outer peripheral side,
A first impeller rotatably arranged between the gas inflow passage and the diffuser passage inside the casing, a centrifugal compressor comprising:
A first back wall portion is provided on a back side of the first impeller,
A first back flow path communicating with the diffuser flow path is formed between the back surface of the first impeller and the first back wall portion,
In the first back wall portion, a bleed flow passage communicating with the first back flow passage is formed,
A centrifugal compressor, wherein the first back wall portion has a continuous surface from an inlet of the first back flow passage to a position reaching the bleed flow passage ;
A second impeller supported by a rotation shaft of the first impeller,
A back surface of the second impeller faces the back surface of the first impeller in the axial direction;
A second back wall portion is provided on the back side of the second impeller,
A second back flow path is formed between the back surface of the second impeller and the second back wall portion,
A supply flow path extending from the bleed flow path to the second back flow path and communicating with the second back flow path is formed,
A rotary machine , wherein a labyrinth seal is provided in the second back flow path on the outer peripheral side of a connection portion with the supply flow path .

Images