[0001] This invention relates to vacuum cleaners and particularly to impellers and diffusers
in vacuum cleaners.
[0002] In conventional electric blowers of household vacuum cleaners such as shown in JP-A-59-74396,
the configurations of the diffuser vane, return guide vane, etc. of the centrifugal
impeller are analogous to those of a large-size blower or compressor, but such components
are limited in size and shape in the case of an electric blower used in the vacuum
cleaner. In general in centrifugal blowers or compressors, the angle formed between
the flow coming out of the impeller and the circumferential direction is of the order
of 10 to 30°, and the inlet angle of the diffuser vane is designed correspondingly.
However, the specific speed of the electric blower for use in the vacuum cleaner is
low (a small flow rate is provided in spite of a high pressure with respect to a relative
rotational speed) and generally, the outlet width of the impeller is designed to be
small; therefore, since the friction loss within the impeller becomes large as the
outlet width of the impeller is decreased, the width and outlet angle of the vanes
are made comparatively large. Accordingly, in the electric blower for use in a household
vacuum cleaner, the outlet absolute flow angle of the impeller is designed to be about
6°, and the inlet angle of the diffuser is set to as large as 5° in practice.
[0003] The object of the present invention is at least partly to avoid the disadvantages
described above, and to improve the air flow efficiency through the blower of a vacuum
cleaner.
[0004] The present invention is set out in claim 1.
[0005] Embodiments of the invention will now be described by way of non-limitative example
with reference to the accompanying drawings, in which:-
Fig. 1 is a side view, partly in cross section, of an electric blower including motor
and blower, embodying the present invention;
Fig. 2 is an axial sectional view of part of the blower of Fig. 1;
Fig. 3 is an axial sectional view showing another embodiment of the blower according
to the present invention;
Fig. 4 is an axial view of the impeller and diffuser of the electric blower shown
in Fig. 1; and
Fig. 5 is an enlargement of the circled part of Fig. 4 showing the diffuser vanes;
Fig. 6 is a graph showing the characteristic of electric blowers when the inlet angle
of the diffuser is varied;
Fig. 7 is a graph showing the characteristic of electric blowers when the ratio of
diffuser vane throat width to a diffuser inner diameter is varied;
Fig. 8 is a graph showing the characteristic of electric blowers when the ratio of
the total area of the diffuser vane throats to the diffuser inlet area is varied;
Fig. 9 is an axial view showing diffuser vanes of yet another embodiment of the present
invention; and
Fig. 10 is a graph showing the aerodynamic characteristic of the embodiment of Fig.
9.
[0006] Embodiments of impellers and vacuum cleaner blowers of the invention will now be
described. They may be fitted in conventional vacuum cleaners. Examples of vacuum
cleaners in which they may be mounted are shown in European Patent Applications 91303152.2
and 91303496.3.
[0007] The electric vacuum cleaner blower shown in Figs. 1 and 2 is composed of a blower
portion 80 and a motor portion 81. Disposed inside a housing 81a of the motor portion
81 are a rotor 83 secured to a rotating shaft 82 and a stator 85 including coils 84a
and 84b. The housing 81a has a bearing-retaining portion 81b formed at the centre
of its end wall, and a bearing 86a for rotatably supporting one end of the rotating
shaft 82 is disposed in the bearing-retaining portion 81b. The housing 81a also has
exhaust ports 81c in its peripheral surface. The housing 81a has an end bracket 87
at the opposite end, and this end bracket 87 connects the blower portion 80 and the
motor 81 together.
[0008] The end bracket 87 has a bearing retaining portion 87a at its centre and a flat portion
87b around its circumference. The flat portion 87b is formed with suction ports 88
through which the air from the blower 80 is sent into the motor 81 to cool it. Disposed
in the bearing-retaining portion 87a is a bearing 86b for rotatably supporting the
other end of the rotating shaft 82. The end bracket 87 carries a diffuser 89, and
on the upstream side of the diffuser, a centrifugal impeller 90 is secured to the
rotating shaft 82 by means of a nut 91. The centrifugal impeller 90 and the diffuser
89 are covered by a blower casing 92 pressure-fitted to the circumference of the end
bracket 87. The blower casing 92 has a suction port 93 formed in its central portion
to provide an inlet to the central inlet region of the impeller.
[0009] The diffuser 89 is composed of a plurality of diffuser vanes 94 arranged radially
outside the circumference of the centrifugal impeller 90. A plurality of return guide
vanes 95 are arranged on the back of a wall 89a lying adjacent the impeller 90 and
supporting the diffuser vanes 94. The wall 89a has a rounded outer peripheral edge
to smooth the air flow from the diffuser vanes 94 to the return guide vanes 95, and
in conjunction with the wall 89a and the end bracket 87, the return guide vanes 95
define a return guide passage through which the air flow is guided to the suction
ports 88.
[0010] The general operation of the electric blower in the embodiment will now be described.
When the motor 81 is energized so that the impeller 90 is rotated, air flows as indicated
by the arrows in the drawing, through the suction port 93 and into the impeller 90.
After discharge from the impeller 90, the air passes between the diffuser vanes 94,
and after passing through the return guide passage, goes through the suction ports
88 into the housing 81a. The air flow introduced into the housing 81a cools the rotor
83, passes through an air passage defined by the stator 85 and the inner surface of
the housing 81a, cools the coils 84a and 84b, and goes through the exhaust ports 81c
formed in the periphery of the housing 81a to the outside.
[0011] Fig. 2 shows the configuration of the centrifugal impeller 90 and the diffuser region
in more detail. The impeller 90 is composed of a plurality of vanes 96, a shroud plate
97 and hub plate 98. Each vane 96 has on each edge three protrusions which are fitted
in holes formed in the shroud plate 97 and the hub plate 98 and then caulked or upset,
so that these components are rigidly and tightly secured together at these connection
points. As Fig. 6 shows, the vanes 96 are curved as they extend outwardly, but for
convenience this is not indicated in Fig. 2.
[0012] For further description of the shroud plate 97 and its shape, reference may be made
to EP-A-467557 which is the publication of the application from which the present
application is divided.
[0013] Another embodiment of the present invention will be described with reference to Fig.
3 showing a blower in partial sectional view. The shroud plate 97 is straight in its
outer diameter portion, as viewed in the axial plane, and has a rounded portion 97a
inwardly from the innermost point of connection 99, as in Fig. 2. The shroud plate
97 in this case is provided with a cylindrical portion 97b extending axially from
the end of the rounded portion 97a. Furthermore, the blower casing 101 has an inwardly
bent flange 101a at its inner diameter region, so that the gap 100 is left between
the flange 101a and the cylindrical portion 97b of the impeller 90. Since the length
of the gap 100 is much larger than the thickness of the shroud plate 97, the friction
loss of the leak flow can be made very large, the leak flow can be reduced remarkably,
and the efficiency of the electric blower can be improved.
[0014] Figs. 4 and 5 show the diffuser 89 of Figs. 1 and 2 with its vanes 94, as viewed
from the suction port 93 of the electric blower. In this embodiment there are seventeen
diffuser vanes 94 and eight return guide vanes 95. The inlet angle β₃ of the diffuser
vane 94 as shown in Fig. 5 is 3°. The inlet angle β₃ is the angle between the inner
face of the vane at its leading edge and the tangential line at this point. The throat
width ws is 2.2 mm, and its ratio to the inner diameter of the diffuser is 0.02. The
radius of the rounded leading edge of the vane 94 is 0.5 mm. The air flow coming out
of the impeller 90 is decelerated in a semi-vaneless space of the vaned diffuser 89
and further decelerated in each passage defined between two vanes 94. In the foregoing
embodiment, the air discharge velocity of the blower can be made large, particularly
about 0.8 times the peripheral speed of the impeller. Accordingly, the size of the
impeller can be reduced.
[0015] Fig. 6 shows the relative efficiency of an electric blower including the impeller
according to the embodiment of Figs. 3 to 5, relative to a varying diffuser inlet
angle β
3. The efficiency under the condition that the diffuser inlet angle β₃ is 5° was taken
as a reference. Where the diffuser inlet angle β₃ is smaller than 2°, the length of
the semi-vaneless space is longer, the friction loss increases, and the efficiency
decreases. Where the diffuser inlet angle β₃ is larger than 3°, it tends to come out
of the flow angle from the impeller; thus, the performance degrades. As will be appreciated,
where the diffuser inlet angle β₃ is within the range of 2 to 3°, the efficiency is
about 2% greater than that in the prior art based on an angle of 5°, and even where
the diffuser inlet angle is within the range of 1 to 2° or within the range of 3 to
4°, the efficiency is 1% greater.
[0016] Fig. 7 shows the efficiency of the same electric blower relative to a varying throat
width ws. Where the ratio of the throat width ws to the diffuser inner diameter is
smaller than 0.017, the deceleration is insufficient in the semi-open portion but
increases in the passages defined between two vanes 94; thus, the flow breaks away
in such a passage, thereby decreasing the efficiency. Where the ratio of the throat
width ws to the diffuser inner diameter is larger than 0.025, the deceleration becomes
too significant in the semi-open portion; thus, the flow deviates remarkably as it
flows into each passage defined between two vanes, thereby decreasing the efficiency.
In the embodiment, where the ratio of the throat width ws to the diffuser inner diameter
is 0.02, the efficiency is high. In addition, since the flow angle of the air discharged
from the impeller 90 is small and the air discharged from it travels a long distance
until it enters the diffuser 89, the inlet diameter of the diffuser can be reduced
as shown in Figs. 4 and 5, and the energy loss compared with a diffuser with no vanes
can be reduced. Further, since the relative velocity at the outlet of the impeller
can be decreased, noise can be reduced.
[0017] Fig. 8 shows the relative efficiency of this electric blower obtained when varying
the ratio

given by

where
- Zvd
- = number of diffuser vanes,
- b₃
- = axial width of diffuser vanes,
- ws
- = diffuser vane throat width,
- D₃
- = diffuser vane inlet diameter,
- β₃
- = diffuser vane inlet angle.
When this ratio is smaller than 1.75, since the number of the diffuser vanes increases,
the throat width decreases, surging occurs at a low flow rate, and pressure loss increases
at a large flow rate, tending to narrow the serviceable range. When this ratio is
larger than 3.5, the number of vanes of the diffuser 89 decreases, tending to cause
interference with the number of blades of the impeller, so that a peak sound is generated,
and the noise level is increased. When this ratio is 2.1 as in the actual embodiment,
the efficiency is high.
[0018] Fig. 9 shows the diffuser 89 in another embodiment of the present invention. Each
passage of the diffuser is defined by the vane portions overlapped. The outer end
of each vane 94 is rounded while the inner end is tapered, and by this tapering, the
throat width ws can be kept within an optimum range. The air discharged from the impeller
90 flows along the vane 94 at about the set flow rate, but the air flow at a small
flow rate breaks away in the semi-vaneless space, as indicated by the arrows in the
drawing, on the suction pressure side of the diffuser vane; therefore, the direction
of the air stream is forcibly changed by the taper portion on the pressure side of
the adjacent vane, thereby alleviating the broken air stream, so that the zone of
surge generation is shifted more to the side of a small flow rate.
[0019] Fig. 10 shows the result of experiments on the relationship between the flow rate
and pressure (static pressure) of the electric blower, in which the solid curve corresponds
to the case including a diffuser based on the embodiment of Fig. 9. The broken curve
corresponds to the case for comparison including a diffuser whose inlet angle is 5°.
Although the comparison case shows the surge generation zone in the vicinity of a
design point, the embodiment with a diffuser inlet angle of 3° can shift the surge
generation zone to a small flow rate range.
1. A vacuum cleaner having an impeller (90), a blower motor (81) coupled to the impeller
(90) and a diffuser (89) having a plurality of diffuser vanes (94) arranged radially
outside the impeller, characterised in that the inlet angle of said diffuser vanes
(94) is in the range 1 to 4°.
2. A vacuum cleaner according to claim 1 wherein the ratio of the throat width (ws) between
adjacent pairs of said diffuser vanes (94) to the inlet diameter of said diffuser
vanes (94) is in the range 0.017 to 0.025.
3. A vacuum cleaner according to claim 1 or claim 2 having a return guide passage for
guiding air from said diffuser vanes to said blower motor for cooling the motor.
4. A vacuum cleaner according to claim 3 wherein said return guide passage extends radially
inwardly and is separated from the region of said impeller (90) and said diffuser
vanes (94) by a wall (89a) having a rounded outer peripheral edge.
5. A vacuum cleaner according to any one of claims 1 to 4 wherein the ratio

given by

is in the range 1.75 to 3.5,
where
Zvd = number of diffuser vanes,
b₃ = axial width of diffuser vanes,
ws = diffuser vane throat width,
D₃ = diffuser vane inlet diameter,
β₃ = diffuser vane inlet angle.