CENTRIFUGAL COMPRESSOR

Information

  • Patent Application
  • 20090214334
  • Publication Number
    20090214334
  • Date Filed
    October 30, 2008
    16 years ago
  • Date Published
    August 27, 2009
    15 years ago
Abstract
A centrifugal compressor can be provided with which frequency of noise produced by rotation of the impeller having a plurality of blades does not resonate with natural frequency of vibration of gas in a plurality of axial slots which serve to increase gas flow rate in an operation range of increased gas flow rate and broaden stable operation range in an operation range of decreased gas flow rate resulting in reduction of noise caused by rotation of the impeller. The axial slots are formed between the peripheral part of the inlet passage of the compressor housing by the peripheral surface of the inlet passage and an annular ring part of the housing supported by a plurality of struts extending from the peripheral surface, four or more struts are provided to support the annular ring part, and all but one of them are located at positions which will be determined when all the struts are located at circumferentially equal spacing and one of the struts is shifted circumferentially from one of said positions by a certain central angle.
Description
BACKGROUND OF THE INVENTION

1. Field of the Invention


The present invention relates to a centrifugal compressor for an exhaust turbo charger, etc., a compressor housing of which has an inlet passage having a diameter larger than the diameter of an annular inlet area of the impeller of the compressor, and a plurality of slots are formed in the housing near the annular inlet area of the impeller so that gas introduced from the inlet passage can be introduced into the impeller through the slots at the outer periphery of the leading edge parts of the blades in addition to gas introduced into the impeller from the annular inlet area of the impeller or gas introduced from the annular inlet area can be bleed from the impeller through the slots to the inlet passage to be again sucked into the impeller from the annular inlet area, particularly a centrifugal compressor in which said plurality of slots are arranged circumferentially concentrically with the center of rotation of the impeller.


2. Description of the Related Art


A centrifugal compressor of an exhaust turbocharger has a stationary housing and an impeller supported for rotation in the housing, the impeller being rotated by a turbine rotor driven by exhaust gas of an engine. Air sucked in from the inlet passage of the housing is introduced into the impeller through the annular inlet area of the impeller, compressed therein by centrifugal force exerting on the gas sucked in the impeller, and discharged from the peripheral outlet area of the impeller to the outlet passage of the housing to be supplied to the engine therefrom.


It is demanded in the field of the centrifugal compressor of the exhaust turbocharger to broaden stable operation range of the compressor. In Document 1 (Japanese Laid-Open Patent Application No. 2004-27931) is disclosed a centrifugal compressor in which a plurality of slots are formed in the compressor housing near the annular inlet area of the impeller so that gas introduced from the inlet passage can be introduced into the impeller through the slots at the outer periphery of the leading edge parts of the blades in addition to gas introduced into the impeller from the annular inlet area of the impeller in an operation range of increased gas flow rate or gas introduced from the annular inlet area can be bleed from the impeller through the slots to the inlet passage to be again sucked into the impeller from the annular inlet area in an operation range of decreased gas flow rate, said plurality of slots being arranged circumferentially concentrically with the center of rotation of the impeller and formed to open to the spaces between the blades of the impeller at meridional distance from the leading edge of the blade in the range of 2˜21% of the meridional length along the contoured outer tip of the blade from the annular inlet area to the peripheral outlet area of the impeller, that is, from the leading edge to the trailing edge of the blade along the outer tip thereof, and said plurality of slots being formed between the inner surface of the inlet passage of the housing near the annular inlet area of the impeller and the outer periphery of an annular ring part, the inner periphery of which composes the outer periphery of the annular inlet area of the impeller, with the annular ring part supported by a plurality of struts extending from the inner surface of the inlet passage of the housing radially inwardly, thus the slots being partitioned by the struts.


However, there is a possibility that the noise produced by rotation of the impeller having a plurality of blades for compressing the gas sucked in the impeller, frequency of the noise being determined by the number of blades and rotation speed of the impeller, resonates with the vibration of gas in the slots, of which the natural frequency is determined by the length of the slot, and excessive noise is produced. Strength of the noise is influenced by the number of the struts partitioning the slots and circumferential location of the struts.


SUMMARY OF THE INVENTION

The present invention was made in light of the problems of the prior art, and the object of the invention is to provide a centrifugal compressor with which frequency of noise produced by rotation of the impeller having a plurality of blades does not resonate with natural frequency of vibration of gas in a plurality of axial slots which serve to increase gas flow rate in an operation range of increased gas flow rate and broaden stable operation range in an operation range of decreased gas flow rate resulting in reduction of noise caused by rotation of the impeller.


To attain the object, the present invention proposes a centrifugal compressor comprising: a stationary housing and an impeller supported rotationally in the housing, the housing having an inlet passage of diameter larger than that of an annular inlet area of the impeller including a plurality of radially outwardly directed blades thereon, each blade including a leading edge, a trailing edge, and an outer tip, a plurality of slots being formed in a peripheral part of the inlet passage of the housing near the annular inlet area of the impeller between an annular ring supported by a plurality of struts extending axially inwardly from a surface of the peripheral part such that the plurality of slots are partitioned by the struts and arranged circumferentially concentrically with the center of rotation axis of the impeller, an end of each of the slots being opened to the inlet passage at the peripheral part thereof and the other end being open to gas flow space of the impeller at the outer tip near the leading edge via an annular slit behind the annular ring part,


wherein four or more struts are provided to support the annular ring part such that all the struts except one strut are located at positions which are determined when all the struts are to be located at circumferentially equal spacing and said one strut is located at a position shifted circumferentially from one of said equally spaced positions by a certain central angle.


It is suitable that positions are determined to locate the plurality of struts plus one strut circumferentially at equal spacing, and the plurality of struts are located at said determined positions excluding said one strut so that no strut is provided at one of said equally spaced positions.


This situation corresponds to a situation that said certain central angle is 360°/(T+1), where T is the total number of struts. It means that no strut is provided at one of positions determined for (T+1) struts when (T+1) struts are to be located at circumferentially equally spacing.


It is suitable to locate a plurality of struts as follows:


(1) The annular ring part is supported by 4 struts, and one


of them is located at a position shifted circumferentially by a central angle of =((180/T)×(½−⅓))° from one of positions which are determined when all 4 struts are to be provided at circumferentially equal spacing, where T is total number of struts.


Particularly, it is preferable that the annular ring part is supported by 4 struts, and one of them is located at a position shifted circumferentially by a central angle of 18° from one of positions which are determined when all 4 struts are to be provided at circumferentially equal spacing, where T is total number of struts.


(2) The annular ring part is supported by 5 or 6 struts, and one of them is located at a position shifted circumferentially by a central angle of ((180/T)×(½))° from one of positions which are determined when all struts are to be provided at circumferentially equal spacing, where T is total number of struts.


(3) The annular ring part is supported by 7 or more struts, and one of them is located at a position shifted circumferentially by a central angle of (180/T)° from one of positions which are determined when all struts are to be provided at circumferentially equal spacing, where T is total number of struts.


According to the invention, the annular ring part is supported by 4 or more struts, and one strut is shifted circumferentially by a central angle from one of positions which will be determined when all struts are provided at circumferentially equal spacing, or one of the struts is not provided at one of positions which will be determined when the plurality of struts plus one strut are provided at circumferentially equal spacing, so unequally spaced portion of the struts is produced, vibration exciting force components of frequency of integral multiple of the number of the struts decreases as compared with the case all the struts are located at equal circumferential spacing, and increase of vibration exciting force components of frequency other than integral multiple of the number of the struts can be suppressed to the minimum.





BRIEF DESCRIPTION OF THE DRAWINGS


FIG. 1 is a sectional view of a substantial part of a centrifugal compressor according to the invention.



FIG. 2 is an external view of a centrifugal compressor viewed from an air inlet side.



FIG. 3 is a drawing showing location of struts for partitioning slots according to the first embodiment of the invention.



FIG. 4 is a drawing showing location of struts for partitioning slots according to the second embodiment of the invention.



FIG. 5 is a drawing showing location of struts for partitioning slots according to the third embodiment of the invention.



FIG. 6 is a drawing showing location of struts for partitioning the slots according to the fourth embodiment of the invention.



FIG. 7 is a drawing showing location of struts for partitioning slots according to the fifth embodiment of the invention.



FIG. 8 is a graph showing vibration exciting force obtained from an experiment in the case of the third embodiment.



FIG. 9 is a graph showing vibration exciting force obtained from an experiment in the case of the fifth embodiment.





DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Preferred embodiments of the present invention will now be detailed with reference to the accompanying drawings. It is intended, however, that unless particularly specified, dimensions, materials, relative positions and so forth of the constituent parts in the embodiments shall be interpreted as illustrative only not as limitative of the scope of the present invention.


The First Embodiment


FIG. 1 is a sectional view of a substantial part of a centrifugal compressor according to the invention, and FIG. 2 is an external view of the centrifugal compressor viewed from an air inlet side. FIG. 3 is a drawing showing location of struts for partitioning slots according to the first embodiment of the invention.


Referring to FIG. 1, a centrifugal compressor 100 includes a compressor housing 7, an impeller 8 supported for rotation in the housing and a diffuser 4. The impeller 8 has a plurality of radially outwardly directed blades 8a on a hub 8c thereof, each including a leading edge, a trailing edge, and a contoured outer tip, the outer tip being free and located in close spaced relationship with a part of the inner surface of the compressor housing 7 shrouding the contoured outer tip of each blade. Reference numeral 100a indicates center of rotation of the impeller 8 and an inlet passage 7d of the housing 7.


Reference numeral 8b indicates a leading end region of the contoured outer trip of the blade 8a.


Referring to FIG. 1 and FIG. 2, an annular ring part 2 is supported by a plurality of struts 1 extending from an inner surface 7a of the housing 7 near annular inlet area of the impeller 8 so that a plurality of slots 7b are formed between the inner surface 7a and the outer periphery of the annular ring part 2. One end of each slot 7b is opened to the peripheral region of the inlet passage 7d via an opening C and the other end thereof is opened to the space between the blades of the impeller 8 at the leading end region of the contoured outer tip of the blade 8a via an annular slit 7c. Thus, the plurality of slots 7b are arranged circumferentially concentrically with the center of rotation of the impeller 8 partitioned by the plurality of struts 1 with each slot 7b communicating to the air flow space of the impeller 8 at the leading end region 8b of the contoured outer tip via the annular slit 7c.


When the compressor 100 is operated at a large air flow rate range, pressure in the leading end region 8b is lower than that in the inlet passage 7d, so air flowing in the inlet passage 7d in the peripheral region thereof is sucked through the slots 7b and annular slit 7c into the air flow space in the impeller, i.e. spaces between the blades in the impeller as shown by a broken line in addition to air sucked into the air flow space through the annular inlet area of the impeller 8. Therefore, pressurized air supplied by the compressor is increased as compares with conventional compressor not provided with the slots 7b and annular slit 7c.


When the compressor 100 is operated at a low air flow rate range near the surging line, pressure in the leading end region 8b is higher than that in the inlet passage 7d, so air in the air flow space in the impeller flows out through the annular slit 7c and slots 7b toward the inlet passage 7d and this air is again sucked into the air flow space through the annular inlet area of the impeller 8 as shown by an arrow B. Therefore, pressurized air discharged from the compressor decreases and the surge line is shifted toward lower air flow rate, resulting in widened stable operation range.


In FIG. 2 showing an external view of the centrifugal compressor viewed from the air inlet side, one of eight struts positioned at equal circumferential spacing is removed, which one being indicated by 1a. This location of struts is shown in FIG. 3 as a first embodiment. In FIG. 3, circumferentially equally spaced eight positions are indicated by reference numerals 1A's and 1a, seven struts are provided at seven positions indicated by 1A's, and no strut is provided at the position 1a.


Result of measurement of noise in the case of the first embodiment showed that vibration exciting force components of frequency of integral multiple of the number of the struts decreased by about 10% as compared with the case the eight struts was positioned at equal circumferential spacing. By this, increase of vibration exciting force components of frequency other than integral multiple of the number of the struts can be suppressed to the minimum.


Hereunder, second to fifth embodiments are described in which one of a plurality of struts equal to or greater than 4 is shifted circumferentially from a circumferentially equally spaced position.


The Second Embodiment


FIG. 4 is a drawing showing location of the struts for partitioning the slots according to the second embodiment.


In the second embodiment, the annular ring part 2 is supported by 4 struts, and one strut is shifted circumferentially in clockwise direction by a central angle α1 (=((180/T)×(½-⅓))°) from a position 1a which is one of positions determined when all struts are to be provided at circumferentially equal spacing, where T is total number of struts.


Result of measurement of noise showed that, by shifting one of 4 struts circumferentially by the central angle α1 to produce unequally spaced portion of the struts, vibration exciting force components of frequency of integral multiple of the number of the struts decreased by about 50% or less as compared with the case the 4 struts was positioned at equal circumferential spacing.


The Third Embodiment


FIG. 5 is a drawing showing location of the struts for partitioning the slots according to the third embodiment.


In the third embodiment, the annular ring part 2 is supported by 5 or 6 struts (in the example of FIG. 5, the number of struts is 5), and one strut is shifted circumferentially in clockwise direction by a central angle α2 (=((180/T)×(½))) from a position 1a which is one of positions determined when all 4 struts are to be provided at circumferentially equal spacing, where T is total number of struts.


Result of measurement of noise in the case of the third embodiment when the number of struts is 5 is shown in the graph of FIG. 8. By shifting one of 5 struts to produce unequally spaced portion of the struts, vibration exciting force components of frequency of integral multiple of the number of the struts decreased by about 40% or less as compared with the case the 5 struts was positioned at equal circumferential spacing. In the graph, the coordinate represents vibration exciting force and abscissa represents shift angle α2 of one of the struts as shown in FIG. 5. In FIG. 5, “A” indicates vibration exciting force when α2=0, i.e. when all 5 struts are located at equally spaced positions, the vibration exciting force at “A” being taken as reference value. When the number of struts is 5 and they are equally spaced, the central angle between adjacent struts is 72 degrees. Change of vibration exciting force when shift angle α2 of one of the struts is changed is shown in FIG. 8. It is recognized from FIG. 8 that vibration exciting force is minimum when α2 is 18 degrees and 54 degrees. Thus, it is understood that vibration exciting force can be reduced by about 40% by shifting one of the struts by a central angle of 18 degrees or 54 degrees as compared with a case all the struts are located at equal circumferential spacing when 5 struts are provided to support the annular ring part 2. In FIG. 8, “B” indicates when α2 is 72 degrees, that is, one of the 5 struts is removed.


The Fourth Embodiment


FIG. 6 is a drawing showing location of the struts for partitioning the slots according to the fourth embodiment.


In the fourth embodiment, the annular ring part 2 is supported by 7 or more struts (in the example of FIG. 6, the number of struts is 7), and one strut is shifted circumferentially in clockwise direction by a central angle α4 (=(180/T)°) from a position 1a which is one of positions determined when all struts are to be provided at circumferentially equal spacing, where T is total number of struts.


Result of measurement of noise in the case of the fourth embodiment showed that vibration exciting force components of frequency of integral multiple of the number of the struts decreased by about 30% or less by shifting one strut circumferentially by the central angle α4 from the position 1a as compared with the case the 7 or more struts was positioned at equal circumferential spacing.


The Fifth Embodiment


FIG. 6 is a drawing showing location of the struts for partitioning the slots according to the fifth embodiment.


In the fifth embodiment, the annular ring part 2 is supported by 4 struts, and one strut is located at a position shifted circumferentially by a central angle α3 of 18° from a position 1a which is one of positions determined when all 4 struts are to be provided at circumferentially equal spacing.


Result of measurement of noise showed that, by shifting one of 4 struts circumferentially by a central angle of 18° to produce unequally spaced portion of the struts, vibration exciting force components of frequency of integral multiple of the number of the struts decreased by about 50% or less as compared with the case the 4 struts was positioned at equal circumferential spacing.


A result of the measurement is shown in the graph of FIG. 9. The graph shows when 4 struts are provided. When 4 struts are located at circumferentially equal spacing, the central angle between adjacent struts is 90 degrees. In FIG. 9, “A” indicates vibration exciting force when α3=0, i.e. when all 4 struts are located at equally spaced positions, the vibration exciting force at “A” being taken as reference value. In the case 5 struts are provided of which the result is shown in FIG. 5, vibration exciting force changes in a sinusoidal curve as angle α2 increases, whereas vibration exciting force does not change in that way as angle α3 increases in the case in which 4 struts are provided. In this case, vibration exciting force is decreased when angle α3 is 18 degrees and 72 degrees, and the vibration exciting force is symmetrical in relation to an ordinate passing a 3 of 45 degrees.


Vibration exciting force at a point “one strut is removed” at 90 degrees on the abscissa corresponds to that when α3 is 90 degrees and the number of struts are 3.


Vibration exciting force at a point “one strut is added” indicates that when one strut is added so that total number of struts is 5.


Vibration exciting force at point “B” indicates that in the case of 5th embodiment shown in FIG. 7 in which 4 struts are provided and strut shift angle α3 is near 18 degrees or 72 degrees.


According to the invention, location of a plurality of struts for forming a plurality of slots to communicate the peripheral region of the inlet passage of the compressor housing to the gas flow space of the impeller of the compressor by supporting the annular ring part located near the annular inlet area of the impeller, can be determined so that frequency of noise produced by the rotation of the impeller to pressurize gas does not resonate with natural frequency of vibration of gas in the axially extending slots depending on the number of the struts, and a centrifugal compressor of this type decreased in noise by preventing resonance of noise produced by the rotation of the impeller with vibration of gas in the slots can be provided.

Claims
  • 1. A centrifugal compressor comprising: a stationary housing and an impeller supported rotationally in the housing, the housing having an inlet passage of diameter larger than that of an annular inlet area of the impeller including a plurality of radially outwardly directed blades thereon, each blade including a leading edge, a trailing edge, and an outer tip, a plurality of slots being formed in a peripheral part of the inlet passage of the housing near the annular inlet area of the impeller between an annular ring supported by a plurality of struts extending axially inwardly from a surface of the peripheral part such that the plurality of slots are partitioned by the struts and arranged circumferentially concentrically with the center of rotation axis of the impeller, an end of each of the slots being opened to the inlet passage at the peripheral part thereof and the other end being open to gas flow space of the impeller at the outer tip near the leading edge via an annular slit behind the annular ring part, wherein four or more struts are provided to support the annular ring part such that all the struts except one strut are located at positions which are determined when all the struts are to be located at circumferentially equal spacing and said one strut is located at a position shifted circumferentially from one of said equally spaced positions by a certain central angle.
  • 2. A centrifugal compressor according to claim 1, wherein positions are determined to locate the plurality of struts plus one strut circumferentially at equal spacing, and the plurality of struts are located at said determined positions excluding said one strut so that no strut is provided at one of said equally spaced positions.
  • 3. A centrifugal compressor according to claim 1, wherein the annular ring part is supported by 4 struts, and one of them is located at a position shifted circumferentially by a central angle of =((180/T)×(½˜⅓))° from one of positions which are determined when all 4 struts are to be provided at circumferentially equal spacing, where T is total number of struts.
  • 4. A centrifugal compressor according to claim 1, wherein the annular ring part is supported by 4 struts, and one of them is located at a position shifted circumferentially by a central angle of 18° from one of positions which are determined when all 4 struts are to be provided at circumferentially equal spacing, where T is total number of struts.
  • 5. A centrifugal compressor according to claim 1, wherein the annular ring part is supported by 5 or 6 struts, and one of them is located at a position shifted circumferentially by a central angle of ((180/T)×(½))° from one of positions which are determined when all struts are to be provided at circumferentially equal spacing, where T is total number of struts.
  • 6. A centrifugal compressor according to claim 1, wherein the annular ring part is supported by 7 or more struts, and one of them is located at a position shifted circumferentially by a central angle of (180/T)° from one of positions which are determined when all struts are to be provided at circumferentially equal spacing, where T is total number of struts.
Priority Claims (1)
Number Date Country Kind
2008-046930 Feb 2008 JP national