[0001] This invention relates generally to centrifugal compressor wheels or impellers of
the general type used commonly with turbochargers, superchargers, and the like. More
specifically, this invention relates to an improved 'centrifugal compressor wheel
and its method of manufacture, wherein the compressor wheel is designed for substantially
prolonged fatigue life.
[0002] Centrifugal compressor wheels in general are well known for use in turbochargers,
superchargers, and the like wherein the wheel comprises an array of aerodynamically
contoured impeller blades supported by a central hub section which is in turn mounted
on a rotatable shaft for rotation therewith. In the context of a turbocharger, by
way of example, the hub section conveniently includes a central axial bore through
which the shaft extends, and a nut is fastened over the shaft at the nose end of the
wheel to hold' the hub section tightly against a shaft shoulder or other diametrically
enlarged structure rotatable with the shaft. The shaft thereby rotatably drives the
compressor wheel in a direction such that the contoured blades axially draw in air
and discharge that air radially outwardly at an elevated pressure level into a volute-shaped
chamber of a compressor housing. The pressurized air is then supplied from the chamber
to the air intake manifold of a combustion engine for admixture and combustion with
fuel, all in a well-known manner.
[0003] In recent years, improvements in compressor technology and design have resulted in
progressive increases in compressor efficiencies and flow ranges, together with more
rapid transient response characteristics. For example, compressor wheels for turbochargers
are well known wherein the impeller blades exhibit compound and highly complex curvatures
designed for optimum operational efficiency and flow range. Such complex blade shape
is most advantageously and economically obtained by a casting process wherein the
wheel hub section and blades are integrally formed desirably from a lightweight material,
such as aluminum or aluminum alloy chosen for its relatively low rotational inertia
for achieving the further advantage of rapid accelerative response during transient
operating conditions.
[0004] Cast compressor wheels of this general type, however, have a relatively short, finite
fatigue life resulting in undesired incidence of fatigue failure during operation.
More specifically, when the compressor wheel is rotated at operating speeds up to
100,000 rpm or more, the cast aluminum material is subjected to relatively high tensile
loading in a radial direction particularly in the hub region of the wheel which must
support the radial wheel mass. The impact of this tensile loading can be especially
severe when the wheel is operated in a relatively high-speed, rapid speed cycle environment,
such as, for example, turbochargers used with earth-moving equipment, front-end loaders,
back hoes, and the like. Unfortunately, the hub region of the cast wheel includes
a major void, namely, the central bore for reception of the rotatable shaft, wherein
this central bore acts as a major stress riser rendering the wheel highly susceptible
to fatigue failure in the hub region. This fatigue problem is compounded by the presence
of metallurgical imperfections such, as dross, voids, and inclusions, which occur
inherently as part of the casting process and which tend to congregate in the hub
region of the wheel.
[0005] It is known that fatigue failures in compressor wheels can be significantly reduced,
or alternately stated, the fatigue life of the compressor wheel can be substantially
prolonged by forming the wheel from a noncast material, such as a forged or wrought
aluminium or aluminium alloy, thereby avoiding the internal imperfections inherently
resulting fr6m a casting process. However, such noncast compressor wheels have not
been practical from a cost or manufacturing standpoint primarily due to the complex
machining requirements to form the impeller blades with the desired aerodynamic contours.
[0006] According to the present invention, a compressor wheel assembly for mounting onto
a rotating shaft comprises a boreless compressor wheel having a boreless hub supporting
a circumferentially arranged array of impeller blades, and an attachment member mounted
on the hub generally at one axial end.
[0007] The invention solves the problem discussed above by avoiding a bore for the shaft
and thus avoiding a source of weakness while enabling the wheel to be cast so that
complicated blade shapes can be readily formed of a light material such as an aluminium
alloy.
[0008] The attachment member would comprise a steel sleeve internally threaded for easy
mounting on the end of a correspondingly threaded shaft.
[0009] The attachment member which is conveniently inertia welded to the hub portion of
the compressor wheel may incorporate bearing surfaces and seal means for co-operating
with components of a compressor housing, and in particular with surfaces of a bore
in a wall separating a compressor housing from a shaft housing.
[0010] The compressor wheel is conveniently cast and preferably with the impeller blades
integral with the hub . Conveniently it is cast from aluminium or an aluminium alloy
or other light material whereas the attachment member is conveniently of steel or
other wear resistant material which may be hardened on bearing surfaces.
[0011] The impeller blades may have a forward blade rake generally adjacent the wheel nose,
and at least some backward curvature generally adjacent the periphery of a wheel back
plate disc. In one embodiment of the invention, the wheel nose has an axially presented
generally polygonal profile for engagement by a-spanner.
[0012] The invention may be carried into practice in various ways, and one embodiment will
how be described by way of example with reference to the accompanying drawings in
which:
FIGURE 1 is a perspective view illustrating a centrifugal compressor wheel for use
with a turbocharger or the like;
FIGURE 2 is an exploded perspective view illustrating an initial step in the formation
of an improved co mpressor wheel assembly embodying the novel features of the invention;
FIGURE 3 is an enlarged vertical section of the compressor wheel assembly in completed
form ready for installation into a turbocharger or the like; and
FIGURE 4 is a fragmented vertical section illustrating the compressor wheel assembly
of FIGURE 3 installed into a turbocharger.
[0013] As shown in the exemplary drawings, a compressor wheel assembly referred to generally
by the reference numeral 10 is provided for use as a centrifugal impeller in a turbocharger,
a supercharger, or the like. The compressor wheel assembly 10 comprises a boreless
compressor wheel 12 having a hub 14 integrally supporting a circumferential array
of contoured centrifugal impeller blades 16, wherein the hub is attached to a cylindrical
thrust spacer sleeve 18 adapted for facilitated connection to the rotatable shaft
20 of a turbocharger or the like.
[0014] The compressor wheel assembly 10 of this invention provides substantial improvements
in wheel fatigue life over conventional centrifugal compressor wheels of the type
used in turbochargers, superchargers, and the like, without sacrificing efficiency
and flow range in accordance with a preferred aerodynamic contouring of the impeller
blades 16. This blade contouring includes complex and compound blade curvatures which
effectively prohibit manufacture of the blades by any means other than a casting process,
such as a rubber pattern or lost wax process. Alternately stated, this complex blade
contouring renders other forming techniques, such as forging, machining, and the like,
impossible or economically unfeasible. Accordingly, in the past, centrifugal compressor
wheels for turbochargers have been formed from a unitary casting wherein the blades
are cast integrally with a wheel hub. However, a central axial bore is then formed
in the cast wheel as by drilling for reception of and installation onto the rotating
shaft of a turbocharger or the like, all in a well-known manner. To minimize rotational
inertia of the compressor wheel and thereby achieve a desired rapid response to transient
operating conditions, the cast wheel is normally formed from aluminum or a lightweight
aluminum alloy.
[0015] However, cast wheels of aluminum or aluminum alloy including the central bore for
mounting purposes are susceptible to fatigue failures in response to tensile loading
acting in a radial direction as the wheel is rotatably accelerated and decelerated
during operation. Such failures occur most frequently in the region of the central
bore whereat tensile loading is highest and further wherein the bore itself acts as
a major stress riser. Moreover, in a cast wheel, metallurgical imperfections, such
as dross, voids, and inclusions, are inherently created and.tend to congregate near
the central bore to provide additional initiation sites for stress cracks.
[0016] The compressor wheel assembly 10 of this invention advantageously avoids formation
of any bore or other cavity formed internally within the compressor wheel 12 thereby
removing from the wheel the most prominent stress riser and resulting in a substantial
increase in wheel fatigue life. The boreless compressor wheel 12 is provided with
alternative means in the form of the thrust spacer sleeve 18 for attachment to the
rotating shaft 20 of a turbocharger or the like, wherein the sleeve 18 permits such
attachment quickly, easily, securely, and in a manner consistent with high production
requirements.
[0017] More particularly, with reference to FIGURES
'1-3, the compressor wheel assembly 10 comprises the compressor wheel 12 formed from
a relatively low inertia material, such as aluminum or a selected aluminum alloy preferably
by a casting process to include the hub 14 blending smoothly in an axial direction
between a diametrically enlarged backplate disk 22 at one axial end and a relatively
blunt nose 24 at an opposite axial end. The hub 14, which is formed without an internal
bore, is cast integrally with the circumferential array of centrifugal impeller blades
16 which project generally therefrom in a radially outward direction with a complex
and smoothly curved shape to draw air or the like axially in at the nose end and to
discharge that air radially outwardly from the backplate disk 22. The specific blade
contouring typically includes a forward blade rake generally adjacent the nose
f 24 for at least some of the blades 16, as illus- traced by arrow 26 in FIG. 1, and
at least some backward curvature near the periphery of the backplate disk, as referred
to by arrow 28.
[0018] The cast boreless compressor wheel 12 is secured to the thrust spacer sleeve 18 which
is in turn adapted for connection to the rotating shaft of a turbocharger or the like.
More particularly, the thrust spacer sleeve 18 is provided as a cylindrical component
formed as by machining from a relatively wear-resistant metal, such as tool steel
or the like, and is secured to the base or back side of the wheel backplate disk 22
in a position generally centered on a central axis 30 of the wheel 12. In this regard,
as shown in FIG. 2, the base side of the backplate disk 22 has a generally planar
configuration at this stage of manufacture to facilitate attachment of the sleeve
18 to the wheel.
[0019] While various attachment techniques are possible, the highly preferred method comprises
inertia welding wherein, for example, the compressor wheel 12 is held stationary in
a suitable fixture (not shown) while the thrust spacer sleeve 18 is advanced on a
rotating tool (also not shown) in the direction of arrow 32 in FIG. 2 into friction
contact with the base side of the wheel. The thrust spacer sleeve is rotated in friction
contact with the compressor wheel to generate sufficient heat for fusion of the annular
interface therebetween. This results in a high quality, substantially uninterrupted
welded bond over substantially the entire contact areas between the wheel 12 and the
sleeve 18.
[0020] After the welding step, the base side of the wheel backplate disk 22 is machined
to a desired aerodynamic surface contour and surface finish, as illustrated in FIG.
3, and further to remove any upset or flash material which may have been generated
during welding. The thrust spacer sleeve 18 is also machined at its inner and outer
diameters for relative concentricity' and coaxial centering on the central axis 30
of the compressor wheel 12. In addition, a portion of the inner diameter of the thrust
spacer sleeve 18 is internally threaded, as illustrated by arrow 34 in F
IG. 3, - and one or more relatively shallow annular grooves 36 are formed into the
outer diameter of the sleeve.
[0021] The thus-formed compressor wheel assembly 10 including the cast compressor wheel
12 and the attached thrust spacer sleeve 18 is installed quickly and easily into a
turbocharger or the like. More particularly, as shown in FIG. 4, the thrust spacer
sleeve threadably receives a threaded end 38 of the rotatable shaft 20 which terminates
generally within a shaft opening 40 in a compressor backplate wall 42 separating a
compressor housing 44 encasing the compressor wheel 12 and a so-called center housing
46 which includes a thrust bearing assembly 48 and journal bearings 50 (one of which
is illustrated) for rotatably supporting the shaft 20. Conveniently, threaded installation
of the wheel assembly 10 onto the shaft 20 is facilitated by forming the wheel nose
24 with a polygonal shape, such as a hexagon, (FIG. 1) or the.like for engagement
by an appropriate wrench or other suitable tool.
[0022] The thrust spacer sleeve 18 is threaded onto the shaft 20 into axially bearing engagement
with a shoulder, such as a thrust collar 52 or the like, forming a portion of the
thrust bearing assembly 48 and rotatable with the shaft. The sleeve 18 thereby spaces
the compressor wheel 12 axially relative to the thrust collar 52. In addition, the
sleeve 18 advantageously receives seal rings 54 in its outer diameter grooves 38 wherein
these seal rings engage the inner diameter surface of the backplate wall shaft opening
40 to prevent lubricant passage from the center housing 46 into the compressor housing
44. In this regard, the thrust spacer sleeve 18 is desirably heat treated to provide
a relatively hardened, wear-resistant outer diameter, wherein the heat-treating step
is conveniently performed prior to inertia welding of the sleeve to the compressor
wheel.
[0023] In operation, the compressor wheel 12 is positioned within the compressor housing
44 to draw in air through an inlet 55 and to discharge that air radially outwardly
into a volute-shaped compressor chamber 56 in the compressor housing 44. This air
movement occurs in response to rotational driving of an exhaust gas turbine (not shown)
which drivingly rotates the turbocharger shaft 20 to correspondingly rotate the compressor
wheel 12 at a relatively high rotational speed. Importantly, in accordance with the
present invention, the compressor wheel 12 does not include any internal bore which
would act as a stress riser during rotation whereby the compressor wheel 12 has a
substantially prolonged fatigue life in comparison with conventional unitary cast
wheels having a, central bore. Moreover, the sleeve material has sufficient strength
to support the assembly in a stable manner on the rotating shaft 20, and the relative
direction of the engaged threads is chosen to prevent the assembly from coming off
the shaft during opertion. Overall efficiency and flow range of the compressor wheel,
however, is not impaired, since the impeller blades 14 are formed from a casting process
for optimum aerodynamic blade contour.
[0024] A variety of modifications and improvements to the invention described herein are
believed to be apparent to one of ordinary skill in the art. For example, further
improved fatigue life characteristics may be obtained by securing the thrust spacer
sleeve 18 described herein to a composite compressor wheel of the type described in
concurrently filed
Application No.................(Case 361)
entitled 'Composite Compressor Wheel For Turbochargers", wherein the composite wheel
includes a forged or wrought hub insert secured into a cast blade shell. In the present
invention, however, the thrust spacer sleeve 18 . would be secured to the composite
wheel without requiring formation of any central axial bore in the composite wheel.
Accordingly, no limitation on the invention is intended, except by way of the appended
claims.
1. A compressor wheel assembly for mounting onto a rotating shaft of a turbocharger
or the like comprising a boreless compressor wheel (12) having a boreless hub (14)
supporting a circumferentially arranged array of impeller blades (16); and an attachment
member (18) mounted on said hub generally at one axial end thereof in a position generally
centered on a central axis (30) of said hub, said attachment member including means
(34),for example a thread,for attachment to a rotating shaft.
2. A wheel assembly as claimed in Claim 1 in which the wheel is cast , for example
of aluminium, aluminium alloy, or other low inertia material.
3. A wheel assembly as claimed in Claim 1 or Claim 2 in which the attachment member
has been inertia welded to the compressor wheel.
4. A wheel assembly as claimed in any of the preceding claims in which the boreless
hub blends smoothly between a diametrically enlarged back plate disc (22) at one end
and a nose (24) of reduced diameter at the other end .
5. A wheel assembly as claimed in any of the preceding claims in which the attachment
member comprises a cylindrical thrust spacer sleeve secured to the hub of the compressor
wheel at one axial end and preferably having at least one annular groove (36) formed
in its outer diameter surface.
6. A wheel assembly as claimed in any of the preceding claims in which the impeller
blades are centrifugal impeller blades and are formed integrally with their hub.
7. A compressor assembly comprising a rotatable shaft (20), a shaft housing (46) including
a bearing (48,50) for the shaft, a compressor housing (44,) a wall (42) separating
the housings, and a compressor wheel assembly as claimed in any of the preceding claims
with the attachment member mounted on the shaft which extends through an opening (40)
in the wall.
8. A compressor assembly as claimed in Claim 7 in which the attachment member comprises
a thrust spacer sleeve having a groove for a sealing ring (54) sealing within the
opening in the wall, and preferably having a surface for axial engagement with a shoulder
within the shaft housing and constituting a part of the bearing.
9. A method of making'a compressor wheel assembly for mounting onto a rotating shaft
of a turbocharger or the like, comprising the steps of forming, for example by casting,
a boreless compressor wheel having a boreless hub supporting a circumferentially arranged
array of impeller blades; and mounting an attachment member adapted for connection
to the rotating shaft to one axial end of the boreless hub in a position generally
centered in a central axis of the hub.-'
10. A method as claimed in Claim 9 in which the attachment member is mounted on the hub of the compressor wheel by inertia
welding.