WO2017169496A1 - 回転機械 - Google Patents
回転機械 Download PDFInfo
- Publication number
- WO2017169496A1 WO2017169496A1 PCT/JP2017/008277 JP2017008277W WO2017169496A1 WO 2017169496 A1 WO2017169496 A1 WO 2017169496A1 JP 2017008277 W JP2017008277 W JP 2017008277W WO 2017169496 A1 WO2017169496 A1 WO 2017169496A1
- Authority
- WO
- WIPO (PCT)
- Prior art keywords
- upper half
- flange portion
- lower half
- compartment
- bolt
- Prior art date
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Classifications
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F04—POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
- F04D—NON-POSITIVE-DISPLACEMENT PUMPS
- F04D29/00—Details, component parts, or accessories
- F04D29/08—Sealings
- F04D29/083—Sealings especially adapted for elastic fluid pumps
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F04—POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
- F04D—NON-POSITIVE-DISPLACEMENT PUMPS
- F04D17/00—Radial-flow pumps, e.g. centrifugal pumps; Helico-centrifugal pumps
- F04D17/08—Centrifugal pumps
- F04D17/10—Centrifugal pumps for compressing or evacuating
- F04D17/12—Multi-stage pumps
- F04D17/122—Multi-stage pumps the individual rotor discs being, one for each stage, on a common shaft and axially spaced, e.g. conventional centrifugal multi- stage compressors
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F04—POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
- F04D—NON-POSITIVE-DISPLACEMENT PUMPS
- F04D29/00—Details, component parts, or accessories
- F04D29/40—Casings; Connections of working fluid
- F04D29/42—Casings; Connections of working fluid for radial or helico-centrifugal pumps
- F04D29/4206—Casings; Connections of working fluid for radial or helico-centrifugal pumps especially adapted for elastic fluid pumps
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F04—POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
- F04D—NON-POSITIVE-DISPLACEMENT PUMPS
- F04D29/00—Details, component parts, or accessories
- F04D29/26—Rotors specially for elastic fluids
- F04D29/28—Rotors specially for elastic fluids for centrifugal or helico-centrifugal pumps for radial-flow or helico-centrifugal pumps
- F04D29/284—Rotors specially for elastic fluids for centrifugal or helico-centrifugal pumps for radial-flow or helico-centrifugal pumps for compressors
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F04—POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
- F04D—NON-POSITIVE-DISPLACEMENT PUMPS
- F04D29/00—Details, component parts, or accessories
- F04D29/40—Casings; Connections of working fluid
- F04D29/42—Casings; Connections of working fluid for radial or helico-centrifugal pumps
- F04D29/44—Fluid-guiding means, e.g. diffusers
- F04D29/441—Fluid-guiding means, e.g. diffusers especially adapted for elastic fluid pumps
- F04D29/444—Bladed diffusers
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F05—INDEXING SCHEMES RELATING TO ENGINES OR PUMPS IN VARIOUS SUBCLASSES OF CLASSES F01-F04
- F05D—INDEXING SCHEME FOR ASPECTS RELATING TO NON-POSITIVE-DISPLACEMENT MACHINES OR ENGINES, GAS-TURBINES OR JET-PROPULSION PLANTS
- F05D2250/00—Geometry
- F05D2250/50—Inlet or outlet
- F05D2250/52—Outlet
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F05—INDEXING SCHEMES RELATING TO ENGINES OR PUMPS IN VARIOUS SUBCLASSES OF CLASSES F01-F04
- F05D—INDEXING SCHEME FOR ASPECTS RELATING TO NON-POSITIVE-DISPLACEMENT MACHINES OR ENGINES, GAS-TURBINES OR JET-PROPULSION PLANTS
- F05D2250/00—Geometry
- F05D2250/70—Shape
Definitions
- the present invention relates to a rotating machine.
- a centrifugal compressor which is a rotating machine, generally has a rotating body including a rotating shaft and a stationary body including a casing body provided around the rotating body, and is sucked from an inlet by an impeller provided on the rotating body. The compressed gas is compressed and discharged from the discharge port.
- the vehicle compartment body In addition to the so-called barrel type with vertical division, the vehicle compartment body has an upper half compartment and a lower half compartment, and the flanges of these two compartments are bolted together and can be divided vertically. There is a horizontal division type.
- a centrifugal compressor for a nitric acid plant sucks in a process gas of about 50 ° C., but the process gas is heated to about 200 ° C. as the pressure is increased.
- thermal deformation occurs due to the temperature difference from the outlet to the bearing in addition to the temperature difference from the inlet to the outlet of the process gas. If it does so, there exists a possibility that the division
- Patent Document 1 discloses a flange structure of a casing body of an upper half casing and a lower half casing as a technique for preventing high-pressure gas from leaking from a dividing surface of an upper half casing and a lower half casing.
- the upper flange portion provided in the upper half compartment is provided with a groove
- the lower flange portion provided in the lower half compartment is provided with a protrusion incorporated into the inlay in the groove of the upper flange portion.
- Patent Document 1 if an opening is generated in the dividing surface of the passenger compartment, gas is likely to accumulate in the uneven portions of the inlay structure, and the accumulated gas may cause corrosion in the upper flange portion and the lower flange portion. . For this reason, it is desirable that the contact surfaces of the upper flange portion and the lower flange portion have no irregularities.
- an object of the present invention is to provide a rotating machine capable of preventing high-pressure gas from leaking from a divided surface without providing irregularities on the contact surfaces of the upper flange portion and the lower flange portion.
- the rotating machine of the present invention includes a rotor having a casing, a rotatable rotating shaft located inside the casing, a plurality of impellers fixed to the outer periphery of the rotating shaft, and a plurality of impellers, respectively.
- the discharge volute spreads inward in the axial direction with respect to the position on the extension of the flow of the process gas flowing out from the final stage impeller.
- the vehicle compartment has an upper half vehicle compartment and a lower half vehicle compartment, and the upper half flange portion and the upper outer peripheral portion of the upper half wall portion connected to the upper half flange portion in the upper half vehicle compartment.
- a base that is axially adjacent to the upper half wall portion and is taller than the upper half flange portion, and the lower half wall portion that is connected to the lower half flange portion and the lower half flange portion in the lower half casing.
- the lower outer peripheral portion is formed, and the upper half flange portion and the lower half flange portion are fixed by the first fixing portion.
- the second fixing portion is fixed with a bolt through the base and the lower outer peripheral portion.
- the first fixing portion fixes the upper half flange portion and the lower half flange portion with a stud bolt.
- the position of the seat surface of the through bolt that fixes the base and the lower outer peripheral portion is higher than the position of the seat surface of the implanted bolt.
- FIG. 3 shows a schematic configuration of a centrifugal compressor according to an embodiment of the present invention, and is a longitudinal sectional view taken along line AA in FIG. 2. It is a figure which fractures
- FIG. 5 shows a schematic configuration of a centrifugal compressor as a comparative example, and is a longitudinal sectional view taken along line AA of FIG. 4. It is a figure which fractures
- the rotating machine of the present embodiment is a single-shaft multi-stage centrifugal compressor 1 including a plurality of impellers 4.
- the centrifugal compressor 1 includes a rotor 2, a diaphragm group 5, a seal device 6, and a passenger compartment assembly 100.
- the centrifugal compressor 1 is characterized in that the surface pressure is ensured up to the end of the flange by diversifying the types and positions of the bolts that fix the lower half casing 200 and the upper half casing 300.
- the rotor 2 rotates about the axis O.
- the rotor 2 includes a rotating shaft 3 that forms a rotor body extending along the axis O, and a plurality of impellers 4 that rotate together with the rotating shaft 3.
- the rotating shaft 3 is connected to a driving source such as a motor.
- the rotary shaft 3 is rotationally driven by this drive source.
- the rotary shaft 3 has a cylindrical shape centered on the axis O and extends in the axial direction Da in which the axis O extends.
- the rotating shaft 3 is rotatably supported at both ends in the axial direction Da by a bearing (not shown).
- the impeller 4 is fixed to the outer periphery of the rotary shaft 3.
- the impeller 4 rotates together with the rotating shaft 3 to compress the process gas (working fluid) that is the object of compression using centrifugal force.
- the impeller 4 is provided in a plurality of stages in the axial direction Da with respect to the rotating shaft 3.
- the impeller 4 of the present embodiment is disposed between bearings disposed on both sides of the rotational axis 3 in the axial direction Da.
- the impeller 4 is a so-called closed impeller including a disk 4a, a blade 4b, and a cover 4c.
- the impeller 4 defines a flow path through which process gas flows by the disk 4a, the blade 4b, and the cover 4c.
- An impeller group is constituted by a plurality of impellers 4 arranged in the same direction along the axial direction Da.
- the centrifugal compressor 1 of the present embodiment has one impeller group.
- the diaphragm group 5 covers the rotor 2 from the outside.
- the diaphragm group 5 includes a plurality of diaphragms 51 (inner casings) arranged in the axial direction Da corresponding to each of the plurality of impellers 4.
- the diaphragm 51 has a larger diameter than the impeller 4 and a plurality of diaphragms 51 are arranged so as to be stacked in the axial direction Da.
- the diaphragm 51 includes members 51 ⁇ / b> A and 51 ⁇ / b> B connected via return vanes 561.
- the impeller 4 is accommodated on the inner peripheral side of the diaphragm 51.
- the diaphragm 51 and the inner wall 101 ⁇ / b> W of the vehicle interior 101 define a flow path through which the process gas flows together with the flow path of the impeller 4.
- the flow path formed by the diaphragm 51 and the inner wall 101W will be described in order from the upstream U that is one side in the axial direction Da.
- the suction port 52, the suction flow channel 53, the plurality of diffuser flow channels 54, the plurality of bent flow channels 55, the plurality of return flow channels 56, the discharge volute 57, and the like exists in order from the upstream U where the process gas flows.
- the upstream U and the downstream L of the flow of the process gas used in the present embodiment indicate a relative positional relationship.
- the suction port 52 allows the process gas to flow into the suction flow path 53 from the outside.
- the suction flow path 53 allows process gas that has flowed in from the outside of the passenger compartment 101 to be described later to flow into the passenger compartment 101.
- the suction flow path 53 allows the process gas to flow into the impeller 4 arranged on the most upstream side U among the plurality of impellers 4 arranged in the axial direction Da.
- the suction channel 53 is an annular space extending from the suction port 52 to the inside in the radial direction Dr.
- the suction flow channel 53 is connected to an inlet facing the upstream U side of the impeller 4 while changing its direction from the radial direction Dr to the downstream L that is the other side of the axial direction Da.
- the radial direction Dr is a direction orthogonal to the axis O.
- the diffuser flow path 54 is connected to an outlet that faces the outer side of the radial direction Dr of the impeller 4.
- the diffuser flow path 54 extends from the outlet of the impeller 4 toward the outside in the radial direction Dr, and is connected to the curved flow path 55.
- the curved flow path 55 turns the flow direction of the process gas from the direction toward the outside of the radial direction Dr to the direction toward the inside of the radial direction Dr. That is, the curved channel 55 is a channel having a U-shaped longitudinal section as shown in FIG.
- the curved channel 55 is formed by an outer peripheral surface on the radially outer side of the diaphragm 51 and an inner peripheral surface of an upper outer peripheral portion 371 of the vehicle interior 101 described later.
- the return flow path 56 allows the process gas flowing through the curved flow path 55 to flow into the impeller 4 at the next stage.
- the return flow path 56 gradually increases in width while extending toward the inside in the radial direction Dr.
- the return flow path 56 changes the flow direction of the process gas so as to go downstream in the axial direction Da inside the radial direction Dr of the diaphragm group 5.
- a plurality of return vanes 561 are arranged in the return channel 56 at intervals in the circumferential direction.
- the discharge volute 57 is formed in an annular shape over an upper half casing 300 and a lower half casing 200 described later.
- the discharge volute 57 is formed so as to extend outward in the axial direction Da, but on the contrary, it extends so as to extend inward in the axial direction Da. Is formed.
- the casing 101 has a structure expanding outward in the axial direction Da, as compared with the comparative example shown in FIGS.
- the upper half wall portion 370 is shorter than the upper outer peripheral portion 371 in addition to the upper outer peripheral portion 371 and the upper bearing housing portion 373, and has an upper half flange.
- the structure has a pedestal 372 that is taller than the portion 310.
- the inclined surface 374 via the upper outer peripheral portion 371 and the pedestal 372 is formed on the inner side in the axial direction Da compared to the upper outer peripheral portion 371 and the wall surface 375 via the upper bearing housing portion 373 shown in FIGS. ing.
- the inclined surface 374 in FIG. 1 constitutes an end surface on the downstream side L of the upper outer peripheral portion 371.
- the sealing device 6 prevents the process gas from leaking from the inside of the passenger compartment 101 to the outside.
- the sealing device 6 seals the outer peripheral surface of the rotating shaft 3 over the entire circumference.
- a labyrinth seal is used as the sealing device 6 of the present embodiment.
- the vehicle compartment assembly 100 accommodates the rotor 2, the diaphragm group 5, and the sealing device 6 inside.
- the vehicle compartment assembly 100 includes a lower half compartment 200, an upper half compartment 300, a fixing part 400, a seal housing holder 500, and a seal member 600.
- the lower half passenger compartment 200 is fixed on the floor surface.
- a suction port 52 that opens downward in the vertical direction Dv and a suction flow path 53 that is connected to the suction port 52 are formed.
- a portion (lower half) of the discharge volute 57 formed in the lower half casing 200 is connected to a discharge port 58 that opens downward in the vertical direction Dv.
- the lower half passenger compartment 200 is combined with the upper half passenger compartment 300 to form the passenger compartment 101.
- the vehicle interior 101 forms the exterior of the centrifugal compressor 1.
- the vehicle interior 101 is formed in a cylindrical shape.
- the vehicle interior 101 is formed such that the central axis coincides with the axis O of the rotation shaft 3.
- the vehicle interior 101 accommodates a plurality of impellers 4 and a diaphragm group 5 therein.
- a more specific configuration of the vehicle interior 101 will be described.
- the lower half vehicle compartment 200 and the upper half vehicle compartment 300 have substantially the same configuration except that the arrangement positions thereof are different.
- the upper half passenger compartment 300 will be described as an example.
- the upper half passenger compartment 300 has a half-divided shape, and is disposed on the lower half passenger compartment 200 as shown in FIG.
- the upper half casing 300 is opened downward in the vertical direction Dv.
- the suction port 52 and the discharge port 58 described above are formed in the lower half vehicle compartment 200 and not in the upper half vehicle compartment 300, the suction flow formed in the upper half vehicle compartment 300 is provided.
- Neither a part of the passage 53 nor a part of the discharge volute 57 formed in the upper half passenger compartment 300 communicates with the outside.
- the shape of the upper half casing 300 when viewed from below in the vertical direction Dv is substantially the same as the shape when the lower half casing 200 is viewed from above in the vertical direction Dv.
- the upper half casing 300 includes an upper half flange portion 310, an upper half accommodating recess 350, and an upper half wall portion 370.
- the upper half flange portion 310 is a horizontal plane that faces downward in the vertical direction Dv.
- the upper half flange portion 310 corresponds to a dividing surface when the vehicle interior 101 is divided in the vertical direction.
- the upper half flange portion 310 has a pair of first upper half flange portions 311 and a pair of second upper half flange portions 312.
- the pair of first upper half flange portions 311 are formed away from each other in the width direction Dw across the axis O when viewed from above in the vertical direction Dv.
- the first upper half flange portion 311 is a plane that extends long in the axial direction Da.
- a flange surface similar to the first upper half flange portion 311 is provided in the lower half casing 200.
- the second upper half flange portion 312 is formed on both sides of the first upper half flange portion 311 in the axial direction Da.
- the second upper half flange portion 312 is a plane continuous with the first upper half flange portion 311.
- the second upper half flange portion 312 is disposed on the inner side in the width direction Dw than the first upper half flange portion 311 when viewed from above in the vertical direction Dv.
- a flange surface similar to the second upper half flange portion 312 is provided in the lower half casing 200.
- a plurality of insertion holes 420 through which fixing bolts are inserted are formed in the first upper half flange portion 311 and the second upper half flange portion 312.
- the insertion hole 420 penetrates the upper half flange portion 310 in the thickness direction.
- the insertion hole 420 is formed so as to be aligned with the fixing hole on the lower half compartment 200 side when the upper half compartment 300 is combined with the lower half compartment 200.
- the upper half wall portion 370 of the upper half passenger compartment 300 is recessed upward from the upper half flange portion 310 in the vertical direction Dv.
- the upper half accommodating recess 350 is a space covered with the inner peripheral surface of the upper half wall 370 when viewed from below in the vertical direction Dv.
- an accommodation space that is formed of a similar recess formed in the lower half passenger compartment 200 and an upper half accommodation recess 350 and extends around the axis O is formed. It is formed inside the passenger compartment 101.
- Members such as the diaphragm group 5 and the sealing device 6 provided on the plural stages of impellers 4 are arranged in the housing space.
- the upper half accommodating recess 350 includes an upper half large diameter recess 351, an upper half small diameter recess 352, and an upper half step surface 353.
- the upper half large-diameter recess 351 is a space in which the diaphragm group 5 and the like are accommodated together with the same space of the lower half passenger compartment 200.
- the upper half large-diameter recess 351 is a space formed around the axis O.
- the upper half large-diameter recess 351 is formed inside the width direction Dw so as to be sandwiched between the two first upper half flange portions 311 when viewed from below in the vertical direction Dv.
- the upper half large-diameter recess 351 is an upper half angle located on the side adjacent to the upper half small-diameter recess 352 in the axial direction Da and on the outer side of the upper half small-diameter recess 352 in the width direction Dw.
- a region 351a is included.
- the upper half small-diameter concave portion 352 is a space in which the sealing device 6 is accommodated together with the same concave portion of the lower half passenger compartment 200.
- the upper half small diameter recess 352 is adjacent to the upper half large diameter recess 351 in the axial direction Da and extends in the axial direction Da.
- the upper half small-diameter recesses 352 are formed on both sides in the axial direction Da with the upper half large-diameter recess 351 interposed therebetween.
- the upper half small-diameter recess 352 is a space formed around the axis O.
- the upper half small-diameter recess 352 is formed between the two second upper half flange portions 312 when viewed from below in the vertical direction Dv.
- the upper half small-diameter recess 352 is formed to have a smaller size in the radial direction Dr than the upper half large-diameter recess 351.
- the upper half step surface 353 is a surface formed between the upper half large-diameter concave portion 351 and the upper half small-diameter concave portion 352 on the downstream side L and spreading in the radial direction Dr.
- the upper half stepped surface 353 is a part of the inner surface that defines the upper half large-diameter recess 351.
- the upper half step surface 353 is a part of the inner surface facing the inner side in the axial direction Da of the upper half casing 300, and a predetermined region on the axis O side is recessed toward the downstream side L. (FIGS. 1 and 2).
- the upper half step surface 353 reaches the upper half flange portion 310 and is a surface that is continuous with a similar step surface of the lower half compartment 200 when the upper half compartment 300 and the lower half compartment 200 are combined. .
- the upper half wall portion 370 (FIGS. 1 and 2) encloses the upper half housing recess 350 and is connected to the upper half flange portion 310 at the periphery.
- the upper half wall portion 370 includes an upper outer peripheral portion 371 and an upper bearing housing portion 373 whose dimension in the vertical direction Dv is smaller than that of the upper outer peripheral portion 371 in a side view.
- a pedestal 372 that is taller than the upper half flange portion 310 is provided adjacent to the upper outer peripheral portion 371 in the axial direction Da.
- the pedestal 372 is shorter than the upper outer peripheral portion 371, that is, the dimension in the vertical direction Dv is smaller than that of the upper outer peripheral portion 371 in a side view.
- the upper outer peripheral portion 371 and the pedestal 372 are connected via an inclined surface 374, and the pedestal 372 and the upper bearing housing portion 373 are connected via a wall surface 376.
- the inclined surface 374 (FIG. 1) is necessary to withstand the pressure during operation of the centrifugal compressor 1 as the upper half step surface 353 is recessed toward the downstream side L in the axial direction Da as described above. In order to ensure a sufficient wall thickness, it is inclined from the upstream side U to the downstream side L in the axial direction Da so as to gradually approach the axial line O.
- the upper outer peripheral portion 371 is formed in a semi-cylindrical shape, but the pedestal 372 is formed so that the top surface thereof is substantially parallel to the upper half flange portion 310. As shown in FIG. 2, the pedestal 372 is formed on each side of the width direction Dw with the axis O interposed therebetween.
- the pedestal 372 is provided with a through hole 440 through which the through bolt 430 is inserted so as to penetrate vertically.
- the through-hole 440 is closer to the inner side in the axial direction Da than the insertion hole 420L in FIG. 4 located near the seal housing holder 500 on the downstream side L in the same manner as the through-hole 440 in the comparative example (FIG. 4), and In the width direction Dw, that is, in the vicinity of the inclined surface 374 via the upper outer peripheral portion 371 and the pedestal 372.
- the through-hole 440 is formed so that the position of the through-hole formed in the same manner on the side of the lower half-chamber 200 when the upper half-chamber 300 is combined with the lower half-chamber 200 is matched.
- the lower half passenger compartment 200 has a lower half wall portion 270 connected to the lower half flange portion 210, similarly to the upper half wall portion 370 of the upper half passenger compartment 300.
- the lower half wall portion 270 includes a lower outer peripheral portion 271 and a lower bearing housing portion 273 having a smaller diameter than the lower outer peripheral portion 271. These are connected from the upstream U to the downstream L via the step surface in the order of the lower outer peripheral portion 271 and the lower bearing housing portion 273.
- a suction port 52 is formed on the upstream side U so as to open downwardly in the vertical direction Dv, and on the downstream side L so as to open downwardly in the vertical direction Dv.
- a discharge port 58 is formed.
- the discharge volute 57 of the present embodiment has a portion formed in the upper half wall portion 370 of the upper half vehicle compartment 300 with respect to a position on the extension of the diffuser passage 54 through which high-pressure gas flows.
- it is formed so as to expand toward the inner side in the axial direction Da.
- the position on the extension of the diffuser flow path 54 corresponds to the position on the extension of the flow of the process gas flowing out from the flow path of the impeller 4 at the final stage.
- the part formed in the lower half wall part 270 of the discharge volute 57 is also formed so that it may expand toward the inner side of the axial direction Da with respect to the position on the extension of the diffuser flow path 54 immediately before.
- the discharge volute 57 is formed so as to expand outward in the axial direction Da with reference to the position on the extension of the diffuser channel 54 as in the comparative example shown in FIGS. 3 and 4, the discharge volute 57 is
- the side wall 101L (including the inclined surface 374) on the downstream side L of the passenger compartment 101 is positioned on the downstream L side as compared with the present embodiment (FIG. 1) by the amount of expansion toward the outside. Therefore, if the through bolt 430 is provided at the insertion position B in the vicinity of the wall surface 375 of the upper half compartment 300 shown in FIG. 3, the through bolt 430 is formed at the periphery of the discharge port 58 formed in the lower half compartment 200. It will interfere with the part.
- the side wall 101L of the passenger compartment 101 is located on the downstream side L as compared with the configuration shown in FIG.
- the discharge volute 57 is formed so as to expand toward the inner side in the axial direction Da
- the vicinity of the inclined surface 374 via the upper outer peripheral portion 371 and the pedestal 372 is set as the insertion position B.
- the through bolt 430 when the through bolt 430 is inserted through the through hole 440, it does not interfere with the peripheral portion of the discharge port 58 formed in the lower half casing 200. Therefore, a through bolt 430 can be adopted as a bolt to be inserted into the through hole 440, and an increase in the length of the rotating shaft 3 can be avoided. Since the rotation shaft 3 is shorter than that of the comparative example, the rotation shaft 3 can have sufficient rigidity, and the diameter of the rotation shaft 3 can be reduced while the rigidity is ensured to reduce the size of the vehicle interior 101. You can also.
- the fixing portion 400 is formed so that the upper half flange portion 310 and the flange surface of the similarly formed lower half casing 200 are in contact with each other so as to form an accommodation space.
- the chamber 300 is fixed.
- the fixing portion 400 of this embodiment is inserted into the insertion hole 420 formed in the upper half flange portion 310, the fixing hole formed in the lower half flange portion 210 in the same manner as the insertion hole 420, and the insertion hole 420.
- a first fixing portion including a planting bolt 410 that is screwed into the fixing hole in a state where the fixing bolt is engaged.
- the stud bolt 410 is a screw that is threaded at both ends.
- the through hole 440 formed in the base 372 and the upper half vehicle compartment 300 are combined with the lower half vehicle compartment 200, the lower outer periphery of the lower half vehicle compartment 200 is aligned with the through hole 440.
- the position of the seat surface 431 of the base 372 where the fixed through bolt 430 is located is higher than the position of the seat surface 411 of the stud bolt 410. Since the seat surface 431 is high, the thickness of the upper half passenger compartment 300 can be secured.
- the inclined surface 374 is inclined from the upstream U toward the downstream L so as to gradually approach the axis O.
- the through bolt 430 does not have to have a part of the inclined surface 374. Can be placed at a desired position.
- the tightening force is difficult to disperse, the surface pressure increases around the bolt, and the upper half flange portion 310 and the upper half There is a possibility that the surface pressure cannot be secured to the end of the mating surface of the lower half flange portion 210 corresponding to the flange portion 310.
- the fastening force of the through bolt 430 is widely dispersed, and the surface pressure can be secured up to the end of the mating surface of the upper half flange portion 310 and the lower half flange portion 210.
- One seal housing holder 500 is provided on each of one side and the other side in the axial direction Da of the accommodating space.
- the seal device 6 (FIG. 1) is fixed.
- the seal housing holder 500 has a cylindrical shape with the axis O as the center.
- the rotary shaft 3 is inserted through the seal housing holder 500 while the seal device 6 is held inside.
- the seal housing holder 500 is fixed to the lower half passenger compartment 200 and the upper half passenger compartment 300 via a seal member 600.
- the seal member 600 seals the space between the lower half passenger compartment 200 and the upper half passenger compartment 300 and the seal housing holder 500.
- the seal member 600 is provided on the outer peripheral surface on the radially outer side of the seal housing holder 500 and is in contact with the inner peripheral surface of the upper half small-diameter recess 352 and the inner periphery of a similar recess provided in the lower half casing 200.
- the seal member 600 of this embodiment is an O-ring.
- the upper half passenger compartment 300 is placed from above in the vertical direction Dv on the lower half passenger compartment 200 in a state where the rotor 2 and the diaphragm group 5 are arranged.
- the planting bolt 410 is inserted into the insertion hole 420 of the upper half casing 300, and the tip (lower end) portion of the planting bolt 410 is screwed into the fixing hole on the lower half casing 200 side.
- the through bolt 430 is inserted into the through hole 440 of the base 372, and the nut 450 is screwed into the threaded portion of the through bolt 430 that has passed therethrough.
- the centrifugal compressor 1 which has the compartment assembly 100 and the rotor 2 arrange
- the problem of opening the dividing surface can be caused by the temperature rise accompanying the pressure increase of the process gas.
- the process gas at about 50 ° C. is heated to about 200 ° C. as the pressure increases. Accordingly, a temperature difference occurs between the upstream side U and the downstream side L of the process gas in the passenger compartment 101. According to the centrifugal compressor 1, thermal deformation is avoided even by such a temperature difference, and the upper half It can prevent that an opening arises in the division surface of the vehicle interior 300 and the lower half vehicle interior 200.
- the centrifugal compressor 1 of the present embodiment has the following characteristic configuration in order to prevent leakage of high-pressure gas from the passenger compartment.
- both the part formed in the upper half casing 300 of the discharge volute 57 and the part formed in the lower half casing 200 of the discharge volute 57 are formed so as to expand inside the axial direction Da. Yes.
- the side wall 101L (side wall of the upper half wall portion 370 and the lower half wall portion 270) of the casing 101 having a thickness corresponding to the required rigidity is set so as to recede inward in the axial direction Da as much as possible. be able to.
- the lower half compartment 200 and the upper half compartment 300 are connected to each other near the seal device 6 on the downstream side L.
- the position of the bolt used for assembling can be set inside the axial direction Da from the position of the insertion hole 420L of the comparative example (FIG. 4) in which the discharge volute 57 is formed so as to expand outside the axial direction Da. Since the side wall 101L does not exist there, the position of the bolt can be set closer to the axis O, that is, set in the width direction Dw inside the position of the insertion hole 420L of the comparative example (FIG. 4).
- a base 372 higher than the upper half flange portion 310 is provided to secure the necessary thickness on the side wall 101L, and the base 372 and the lower half wall portion 270 are fastened using a through bolt 430. is doing.
- the through bolt 430 the fastening force is widely dispersed, and the surface pressure can be secured up to the end of the mating surface of the upper half flange portion 310 and the lower half flange portion 210, which is high. Sealability can be secured.
- the fastening position (420L) in the comparative example FIG.
- the centrifugal compressor 1 can more reliably suppress leakage of a high-pressure fluid such as a working fluid that circulates inside.
- the through-bolts 430 are provided at one place on each of the pair of bases 372 and 372 located on both sides in the width direction Dw, and are provided at two places in total.
- the number of remote bolts 430 is not limited, and a plurality of remote bolts 430 may be provided on one pedestal 372 in order to sufficiently suppress the leakage of process gas.
- the centrifugal compressor 1 is described as an example of the rotating machine, but the present invention is not limited to this.
- the rotating machine may be a supercharger or a pump.
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Abstract
Description
その車室体には、垂直分割のいわゆるバレル型の他に、上半車室と下半車室を有し、この二つの車室のフランジをボルト締結しており、上下方向に分割可能な水平分割型がある。
その際、水平分割型の遠心圧縮機では、プロセスガスの入口から出口にかけての温度差に加えて、出口から軸受にかけての温度差によって熱変形が生じる。そうすると、二つの分割された車室の分割面が開口するおそれがある。
図1に示すように、本実施形態の回転機械は、複数のインペラ4を備える一軸多段式の遠心圧縮機1である。遠心圧縮機1は、ロータ2と、ダイアフラム群5と、シール装置6と、車室組み立て体100と、を備えている。
遠心圧縮機1は、下半車室200と上半車室300を固定するボルトの種類と位置を多様化させることで、フランジの端部まで面圧を確保するところに特徴がある。
なお、本実施形態において用いるプロセスガスの流れの上流側U、下流側Lは、相対的な位置関係を示している。
下半車室200は、上半車室300と組み合わされることで、車室101を形成している。
以下、車室101についてより具体的な構成を説明するが、下半車室200と上半車室300は配置される位置が異なることを除けば、ほぼ同様の構成を備えているので、以下では上半車室300を例にして説明する。
ここで、上述した吸込口52および吐出口58は、下半車室200に形成されており、上半車室300には形成されていないので、上半車室300に形成されている吸込流路53の一部、及び、上半車室300に形成されている吐出ボリュート57の一部は、いずれも、外部と連通していない。
上半車室300の鉛直方向Dvの下方から見た際の形状は、下半車室200を鉛直方向Dvの上方から見た際の形状とほぼ同じ形状をなしている。上半車室300は、図2に示すように、上半フランジ部310と、上半収容凹部350と、上半壁部370とを有する。
上半フランジ部310は、一対の第一上半フランジ部311と、一対の第二上半フランジ部312とを有する。
傾斜面374(図1)は、上述したように上半段差面353が軸線方向Daの下流側Lに向けて凹んでいるのに伴い、遠心圧縮機1の運転時の圧力に耐えるのに必要な肉厚を確保するため、軸線方向Daの上流側Uから下流側Lに向けて、次第に軸線Oに近づくように傾斜している。
さらに下半車室200には、上流側Uに、鉛直方向Dvの下方を向いて開口するように吸込口52が形成され、下流側Lに、鉛直方向Dvの下方を向いて開口するように吐出口58が形成されている。
そして、吐出ボリュート57の下半壁部270に形成されている部分も、直前のディフューザ流路54の延長上の位置に対して、軸線方向Daの内側に向けて拡がるように形成されている。
これに対し、吐出ボリュート57が軸線方向Daの内側に向けて拡がるように形成されている本実施形態では、上外周部371と台座372を介する傾斜面374の近傍を挿通位置Bとしても、図1に示すように、通しボルト430が貫通孔440を挿通する際に、下半車室200に形成されている吐出口58の周縁部に干渉しない。そのため、貫通孔440に挿通させるボルトとして、通しボルト430を採用することができ、回転軸3が長くなることも避けられる。比較例に対して回転軸3が短いことで、回転軸3の剛性を十分に確保することができ、剛性を確保しつつ回転軸3の径を小さくすることで車室101の小型化を図ることもできる。
本実施形態の固定部400は、上半フランジ部310に形成されている挿通孔420と、下半フランジ部210に挿通孔420と同様に形成されている固定孔と、挿通孔420に挿通された状態で固定孔に螺合される植え込みボルト410とからなる第一固定部を有する。植え込みボルト410とは、両端にねじが切られているものをいう。
具体的には、傾斜面374は、上述したように、上流側Uから下流側Lに向けて、次第に軸線Oに近づくように傾斜している。そのため、傾斜面374の近傍に植え込みボルト410を配置させる際に、通しボルト430の座面431の位置の高さが、植え込みボルト410の座面411の位置と略同じになるように配置すると、通しボルト430の頭が配置される場所を確保するために、傾斜面374の一部をえぐったような形状にする必要があり、上半車室300の肉厚が薄くなってしまう。
ところが、通しボルト430の座面431の位置が植え込みボルト410の座面411の位置よりも高くなっていることにより、傾斜面374の一部をえぐったような形状にしなくても、通しボルト430の頭を所望の位置に配置させることができる。
以下、本実施形態の遠心圧縮機1により得られる効果を説明する。
遠心圧縮機1が運転されることで、高圧のプロセスガスが流通して、ダイアフラム群5等が配置されている空間に大きな圧力が生じる。このように大きな圧力が生じても、遠心圧縮機1によれば、下半車室200と上半車室300との間からプロセスガスが漏れるのを防ぐことができる。
まず、吐出ボリュート57の上半車室300に形成されている部分も、吐出ボリュート57の下半車室200に形成されている部分のいずれも、軸線方向Daの内側に拡がるように形成されている。このことにより、下流側Lで、必要な剛性に対応する肉厚を有する車室101の側壁101L(上半壁部370および下半壁部270の側壁)を軸線方向Daのなるべく内側に退いて設定することができる。
吐出ボリュート57を区画する側壁101Lが軸線方向Daの内側に退避して設定されていることに伴い、下流側Lのシール装置6の近くで、下半車室200と上半車室300とを組み付けるために用いられるボルトの位置を、吐出ボリュート57が軸線方向Daの外側に拡がるように形成されている比較例(図4)の挿通孔420Lの位置よりも軸線方向Daの内側に設定できるし、そこには側壁101Lが存在しないのでボルトの位置を軸線Oに近づけて、つまり比較例(図4)の挿通孔420Lの位置よりも幅方向Dwの内側に設定することもできる。
但し、ボルトを設けても側壁101Lに必要な肉厚を確保するため、上半フランジ部310よりも高い台座372を設け、さらに、通しボルト430を用いて台座372と下半壁部270とを締結している。
通しボルト430が使用されていることにより、締結力を広く分散させ、上半フランジ部310と下半フランジ部210の合わせ面の端部まで、面圧を確保することができるようになり、高いシール性が確保できる。しかも、比較例(図4)における締結位置(420L)と比べて、分割面(フランジ)の内端の近くで遠しボルト430が締結力を作用させるので、分割面の開口防止により十分に寄与できる。
したがって、遠心圧縮機1は、内部を流通する作動流体等の高圧な流体の漏れをより確実に抑えることができる。
2 ロータ
3 回転軸
4 インペラ
5 ダイアフラム群
51 ダイアフラム
51A,51B 部材
52 吸込口
53 吸込流路
54 ディフューザ流路
55 曲がり流路
56 リターン流路
57 吐出ボリュート
58 吐出口
6 シール装置
100 車室組み立て体
101 車室
101L 側壁
101W 内壁
200 下半車室
210 下半フランジ部
253 下半段差面
270 下半壁部
271 下外周部
273 下軸受収容部
300 上半車室
310 上半フランジ部
311 第一上半フランジ部
312 第二上半フランジ部
350 上半収容凹部
351 上半大径凹部
352 上半小径凹部
353 上半段差面
370 上半壁部
371 上外周部
372 台座
373 上軸受収容部
374 傾斜面
375 壁面
376 壁面
400 固定部
410 植え込みボルト(第一固定部)
411 座面
420,420L 挿通孔(第一固定部)
430 通しボルト(第二固定部)
431 座面
440 貫通孔(第二固定部)
450 ナット(第二固定部)
500 シールハウジングホルダ
600 シール部材
O 軸線
Da 軸線方向
Dr 径方向
Dv 鉛直方向
Dw 幅方向
Claims (6)
- 車室と、
前記車室の内部に位置する回転可能な回転軸と、前記回転軸の外周に固定される複数段のインペラと、を有するロータと、
前記複数段のインペラにそれぞれ設けられるダイアフラムからなるダイアフラム群と、
圧縮対象であるプロセスガスが流通し、前記インペラに対応して設けられるガス流路と、
前記ガス流路に繋がる吐出ボリュートと、を備え、
前記吐出ボリュートが、前記車室の軸線方向の内側に拡がって形成される、
ことを特徴とする回転機械。 - 前記吐出ボリュートは、最終段の前記インペラから流出した前記プロセスガスの流れの延長上の位置に対して、前記軸線方向の内側に向けて拡がっている、
請求項1に記載の回転機械。 - 前記車室は、上半車室と下半車室とを有し、
前記上半車室に、上半フランジ部と、前記上半フランジ部と繋がる上半壁部の上外周部と、前記上半壁部と前記軸線方向に隣接し、前記上半フランジ部よりも背が高い台座と、が形成され、
前記下半車室に、下半フランジ部と、前記下半フランジ部と繋がる下半壁部の下外周部と、が形成され、
前記上半フランジ部及び前記下半フランジ部が、第一固定部により固定され、
前記台座及び前記下外周部が、第二固定部により固定される、
請求項1または2に記載の回転機械。 - 前記第二固定部は、
前記台座と前記下外周部とを通しボルトで固定する、
請求項3に記載の回転機械。 - 前記第一固定部は、
前記上半フランジ部と前記下半フランジ部とを植え込みボルトで固定する、
請求項3又は請求項4に記載の回転機械。 - 前記台座と前記下外周部とを固定する通しボルトの座面の位置が、前記植え込みボルトの座面の位置よりも高い、
請求項5に記載の回転機械。
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EP17774041.2A EP3421808B1 (en) | 2016-03-28 | 2017-03-02 | Rotary compressor machine |
JP2018508844A JP6655712B2 (ja) | 2016-03-28 | 2017-03-02 | 回転機械 |
US16/089,067 US11022126B2 (en) | 2016-03-28 | 2017-03-02 | Rotary machine |
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CN111566352A (zh) * | 2018-01-10 | 2020-08-21 | 西门子股份公司 | 涡轮机内壳体 |
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US20200300253A1 (en) | 2020-09-24 |
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US11022126B2 (en) | 2021-06-01 |
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