KR20150094386A - Sirroco fan - Google Patents

Abstract

A sirocco fan of the present invention comprises: a motor; an impeller including a plurality of blades on a main plate connected to the motor, having a rim connected to the plurality of blades; and a scroll housing having the impeller stored to be rotated, wherein the scroll housing including an expansion part convex in a direction opposite to the main plate on a scroll part, and the expansion part includes a protrusion part on an inner surface, such that the expansion part and the protrusion part minimizes friction loss of a movement, thereby having an advantage of minimizing noise and consumption power.

Description

Sirroco fan {Sirroco fan}

The present invention relates to a sirocco fan, and more particularly to a sirocco fan having a concave portion formed in a scroll housing.

In general, a sirocco fan is a fan having a plurality of short front curved blades (hereinafter, referred to as " all-round type blades ") and is widely used in ventilation devices or air conditioners due to its low noise.

The sirocco fan may include an impeller having a plurality of full-bodied blades and a scroll housing enclosing the impeller. The scroll housing may have a bell mouth for guiding air suction on at least one side of the left and right sides of the impeller.

KR 2000-0011426 (July 05, 2000)

The blower according to the related art reduces noise by the concave and convex portions formed between 300 and 360 degrees from the reference angle, but the inner static pressure generated by the rotation of the blades rises due to frictional loss generated when the inner flow is in friction with the inner surface of the scroll portion And the fan efficiency is low.

The present invention relates to a motor vehicle, An impeller having a plurality of blades formed on a main plate connected to the motor and a rim connected to the plurality of blades; The scroll housing has a scroll portion formed with a convex extension in a direction opposite to the impeller, and the extension portion has a concavo-convex portion formed on an inner surface thereof.

 The concavo-convex portion may be formed long along the scroll portion.

  The concave-convex portion may have a saw-toothed cross-sectional shape.

The extension part may be positioned between the cut-off part and the straight part of the scroll part, and the concave-convex part may be formed long in the extension part and the straight part.

The present invention has the advantage that the frictional loss of the flow together with the extension part and the concave-convex part can be minimized, and noise and power consumption can be minimized.

FIG. 1 is a view showing an example in which one embodiment of a sirocco fan according to the present invention is applied to an air conditioner,
Figure 2 is a side view of one embodiment of a sirocco fan in accordance with the present invention;
3 is a sectional view taken along the line AA in Fig. 2,
4 is a diagram of a sirocco fan embodiment according to the present invention,
FIG. 5 is a graph showing a noise according to an air volume of a sirocco fan according to an embodiment of the present invention,
FIG. 6 is a graph showing the power consumption according to the air volume of the sirocco fan embodiment according to the present invention, together with the power consumption according to the air volume of the comparative examples.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a view showing an example in which a sirocco fan embodiment according to the present invention is applied to an air conditioner.

The air conditioner shown in Fig. 1 comprises a cabinet 2; A heat exchanger (4) installed inside the cabinet (2); And a sirocco fan 6 for passing air through the heat exchanger 4 and sucking the air passing through the heat exchanger 4 to blow air.

The air conditioner may be one of a stand type air conditioner, a wall-mounted type air conditioner, a ceiling type air conditioner and a duct type air conditioner. When the air conditioner is constituted by a duct type air conditioner, the cabinet 2 can be connected to a suction duct guided to suck the air in the air-conditioning room into the heat exchanger 4, and the cabinet 2 or the sirocco fan 6 A discharge duct guiding the air blown from the sirocco fan 6 to be discharged to the room to be air-conditioned can be connected.

The sirocco fan 6 includes a motor 12, an impeller 14 rotated by the motor 12, and a scroll housing 16 in which the impeller 14 is rotatably received.

The motor 12 is a driving source for rotating the impeller 14. The rotating shaft 13 can be directly connected to the impeller 14 and the rotating shaft is connected to the impeller 14 via a power transmitting member such as a belt or a pulley. .

The sirocco fan 6 may be configured so that one motor 12 rotates one impeller 14. [ In this case, the impeller 14 is connected to a rotation shaft protruding to one side of the left and right sides of the motor 12, and one impeller 14 may be surrounded by one scroll housing 16.

  The sirocco fan 6 is configured such that one motor 12 rotates a plurality of impellers 14. [ In this case, the motor 12 may be composed of a biaxial motor positioned between the pair of impellers 14. [ The rotating shaft protruding to the left side of the motor 12 can be connected to at least one impeller positioned on the left side of the motor 12 and the rotating shaft projected to the right side of the motor 12 can be connected to at least one And each of the impellers 14 may be surrounded by a respective one of the scroll housings 16.

  Fig. 2 is a side view of one embodiment of a sirocco fan according to the present invention, and Fig. 3 is a sectional view taken along line A-A in Fig.

The impeller 14 includes an abacus 22, a plurality of blades 24, and a rim 30. The impeller 14 has a plurality of blades 24 formed on a main plate 22 connected to a motor 12 and a rim 30 connected to a plurality of blades 24.

The main plate 22 may be formed with a rotation axis coupling portion to which the rotation axis 13 of the motor 12 is coupled.

Each of the plurality of blades 24 may be constituted by a full-wave type blade bent forward in the rotating direction and the distance between the one end and the rotational center axis X of the impeller 14 may be the same as the rotational center of the impeller 14 X may be different.

The plurality of blades 24 has a leading edge 25 having a relatively short distance from the rotational center axis X of the impeller 14 and a relatively long distance from the rotational center axis X And the other end is a trailing edge 26 (trailing edge). The impeller 14 may have an inner diameter of the blade 24 connecting the leading edge 25 of the plurality of blades 24 and an outer diameter of the blade 24 connecting the trailing edge 26 of the plurality of blades 24 .

The plurality of blades 24 may be formed on one and the other surface of the main plate 22, respectively. The plurality of blades 24 may be arranged at regular intervals in the main plate 22. [ The plurality of blades 24 can be spaced apart from the main plate 22 at regular intervals on the surface facing the bell mouth I and air flows through the gap between the blades 24, Direction.

The plurality of blades 24 are disposed on one side of the main plate 22 and on the other side of the main plate 22 with the main plate 22 interposed therebetween so that air can be sucked in two directions of the impeller 14.

The plurality of blades 24 includes a main plate 22, a plurality of first blades 24A formed on one surface of the main plate 22, and a first rim 30A connecting the plurality of first blades 24A. 1 impeller portion E1 can be formed.

The plurality of blades 24 includes a main plate 22, a plurality of second blades 24B formed on the other surface of the main plate 22 and a second rim 30B connecting the plurality of second blades 24B. 2 impeller E2 can be formed.

  The rim 30 may function as a support member for supporting a plurality of blades 24 by connecting a plurality of blades 24. [

  The scroll housing 16 may include a pair of side plates 42 and 44 and a scroll portion 46 connecting the pair of side plates 42 and 44. The scroll housing 16 can be formed with a pair of side plates 42 and 44 facing each other with a scroll part 46 interposed therebetween.

And bell mouths 43 and 45 may be formed on the side plates 42 and 44, respectively. Hereinafter, the side plates 42 and 44 will be described as the left side plate 42 and the right side plate 44 for convenience.

The scroll housing 16 may further include a straight portion 48 extending in the air discharge direction from the scroll portion 46 and connecting the left and right side plates 42 and 44. The scroll housing 16 may further include a discharge guide 50 which is spaced apart from the plate body 48 toward the air discharge direction and connects the left and right side plates 42 and 44 to each other. The scroll housing 16 is provided with an air outlet 43 and an air outlet 43. The scroll housing 16 can be an air intake port for each of the bell mouths 43 and 45 and is provided between the left and right side plates 42 and 44, (O) may be formed.

The scroll part (46) is formed to be rounded in the rotating direction of the impeller (14). One end of the scroll portion 46 can be connected to the cutoff CF and the other end can be connected to the straight portion 48. [ The scroll portion 46 may be formed to be gradually away from the impeller 14 as it approaches the straight line portion 48 in the cutoff CF.

The scroll portion 46 may be formed with an enlarged portion 52 which is convex in the direction opposite to the impeller 14.

The extension 52 may be positioned between the cutoff CF of the scroll portion 46 and the straight portion 48.

The extension 52 can be formed entirely between the cutoff CF of the scroll portion 46 and the straight portion 48. [ The extension 52 can be formed only in a part between the cutoff CF of the scroll part 46 and the straight part 48. [

The extension portion 52 can be rounded convexly in the direction Y perpendicular to the rotation center axis X of the impeller 14. [ The extension portion 52 may have a different distance from the impeller 14 in the direction Y perpendicular to the rotation center axis X of the impeller 14. [ As the distance from the side plates 42 and 44 increases, the expanding portion 52 can be convex in a shape that the distance from the impeller 14 is increased.

The extending portion 52 has a largest distance L1 from the main plate 22 to the extending portion 52 in a direction perpendicular to the rotational center axis X of the impeller 14. [ The distance L2 from the rim 30 to the extension 52 in the direction orthogonal to the rotation center axis X of the impeller 14 extends from the main plate 22 to the extension 52 May be shorter than the distance L1 between the two ends.

The extension portion 52 can be formed on the entirety of the scroll portion 46 and can be formed on a part of the scroll portion 46. The extension portion 52 can be formed only between approximately 140 and 360 degrees with reference to the reference angle O. [ The scroll portion 46 can include a non-expanding portion 51 and an expanding portion 52 in the rotational direction of the impeller 14. [ The scroll portion 46 may have a recessed portion 60 formed on the inner surface of the non-expanded portion 51. The scroll portion 46 may have a recessed portion 60 formed on the inner surface of the expanded portion 52.

   The concave and convex portions 60 can be alternately formed with the groove portions 62 and the protruding portions 64 in a direction parallel to the rotational center axis X of the impeller 14. [ The concave and convex portions 60 may be formed long along the scroll portion 46. The groove portion 62 may be formed between the projecting portions 64. The groove portion 62 may be recessed in the direction toward the outer surface of the scroll portion 46. The concave-convex portion 60 may have a saw-toothed cross-sectional shape.

  The concave and convex portion 60 can be formed only in the extended portion 52 and the straight portion 48 out of the extended portion 52.

The concave and convex portions 60 can be formed in the extended portion 52 and the straight portion 48 together. The concave-convex portion 60 may be formed to extend from the extending portion 52 to the straight portion 48. The concave and convex portion 60 can be formed long from one end 48A to the other end 48B of the straight portion 48. [ When the concave and convex portion 60 is formed in the straight portion 48, it can be formed long in the longitudinal direction of the straight portion 48, that is, in the direction parallel to the air discharge direction.

 FIG. 4 is a view showing a sirocco fan according to an embodiment of the present invention, together with comparative examples. FIG. 5 is a graph showing the noise according to the air volume of the sirocco fan according to the present invention, And FIG. 6 is a graph showing power consumption according to the air flow rate of the sirocco fan according to the present invention, together with power consumption according to the air flow rate of the comparative examples.

4B is a first comparative example in which neither the extension portion nor the concavo-convex portion is formed on the scroll portion 46 '.

4C is a second comparative example in which only the enlarged portion 52 "is formed in the scroll portion 46" and the concave / convex portion is not formed in the enlarged portion 52 ".

FIG. 4D is a sirocco fan embodiment according to the present invention.

The comparative example 1 shown in FIG. 4 (B) differs only in the presence or absence of the extension part 50 and the concavo-convex part 60, and all other configurations are the same as those of the sirocco fan embodiment of the present invention. In Comparative Example 1 shown in FIG. 4B, the scroll portion 46 'may be formed parallel to the rotation center axis X of the impeller 14, and the inner surface of the scroll portion 46' And is hereinafter referred to as a non-expanding sirocco fan for convenience.

 Comparative Example 2 shown in FIG. 4 (C) differs only in the presence or absence of the concavo-convex portion 60, and all other configurations are the same as those of the sirocco fan embodiment of the present invention. 4 (C), the expansion portion 52 '' is formed in the scroll portion 46 '' in a direction perpendicular to the rotation direction of the impeller 14 and the rotation center axis X of the impeller 14 Convex portion is not formed on the inner surface of the extending portion 52 ". Hereinafter, for convenience, the non-convex sirocco fan will be described.

4 (D), the expansion part 52 of the scroll part of the present invention is arranged in a direction perpendicular to the rotation direction of the impeller 14 and the rotation center axis X of the impeller 14 Convex portion 60 is formed on the inner surface of the enlarged portion 52 in the longitudinal direction of the scroll portion 46. [

5 is a graph in which the shape and size of the impeller 14, which may affect the noise, in addition to the expansion portion 52 and the concavo-convex portion 60 are all the same. 5 is a variation of noise according to the air volume of the non-expanding sirocco fan, and M in Fig. 5 is a variation of noise according to the air volume of the non-irregular sirocco fan. N in Fig. 5 is a sirocco fan according to the present invention It is a change of noise according to air volume.

Referring to FIG. 5, it can be seen that each of the non-expanding sirocco fan, the non-irregular sirocco fan, and the sirocco fan of the present invention has higher noise as the air flow rate increases. On the other hand, the non-uneven sirocco fan has a smaller noise than the unexpanded sirocco fan based on the same air volume standard, and the sirocco fan of the present invention can be confirmed to have a smaller noise than the non-uneven sirocco fan based on the same air volume standard. That is, the presence or absence of the expansion portion 52 and the presence or absence of the recessed portion 60 can affect the noise reduction, and the expansion portion 52 is formed in the scroll portion 46, It can be confirmed that the one embodiment of the sirocco fan of the present invention in which the portion 60 is formed has a smaller noise than that of each of the non-expanded sirocco fan and the non-expanded sirocco fan.

6 is a result of measuring the shape and size of the impeller 14, which may affect the power consumption, in addition to the expansion portion 52 and the concavo-convex portion 60 in the same state. 6 is a variation of power consumption according to the air flow rate of the non-expanding sirocco fan, and Q in Fig. 6 is a variation of power consumption depending on the air flow rate of the non-irregular sirocco fan. In Fig. 6, R is a sirocco fan Is a change in power consumption according to the air volume of the embodiment.

  Referring to FIG. 6, it can be seen that each of the unexpanded sirocco fan, the uneven sirocco fan, and the sirocco fan of the present invention has higher power consumption as the air flow rate increases. It is confirmed that the uncoiled sirocco fan has lower power consumption than the unexpanded sirocco fan on the basis of the same air volume and that the one embodiment of the sirocco fan of the present invention consumes less power than the non-uneven sirocco fan on the same air volume basis. That is, the presence or absence of the enlarged portion 52 and the presence of the concave and convex portions 60 can influence the power consumption reduction, and the enlarged portion 52 is formed in the scroll portion 46, It is possible to confirm that the power consumption of the sirocco fan of the present invention in which the concave and convex portions 60 are formed is smaller than that of each of the non-expanded sirocco fan and the non-expanded sirocco fan.

Table 1 shows the noise and power consumption ratios of the unexpanded sirocco fan, the uneven sirocco fan, and the sirocco fan of the present invention based on the same air volume.

noise Power consumption ratio Non-expanding sirocco fan Reference noise (dB) 100% Non-irregular sirocco fan Reference noise (dB) - 2.7 (dB) 85% Examples of the present invention Reference noise (dB) - 3.1 (dB) 83%

Referring to Table 1, it can be seen that when the noise of the non-expansion sirocco fan is set as the reference noise, the noise of the non-expansion sirocco fan is 2.7 (dB) less than that of the non-expansion sirocco fan and the power consumption is reduced by 15% .

Referring to Table 1, it can be seen that the embodiment of the sirocco fan of the present invention has a noise of 3.1 (dB) smaller than that of the non-expanded sirocco fan and the power consumption is reduced by 17%. It can be seen that the embodiment of the sirocco fan of the present invention has a noise of 0.4 (dB) smaller and a power consumption of 2% less than that of the non-irregular sirocco fan.

6: Sirocco fan 12: Motor
14: impeller 16: scroll housing
22: abacus 24: blade
30: rim 42,44: shroud
46: scroll part 48: straight part
50: Discharge guide 50:
60: concave portion CF: cut-off
X: rotation center axis of the impeller

Claims (4)

A motor;
An impeller having a plurality of blades formed on a main plate connected to the motor and a rim connected to the plurality of blades;
A scroll housing in which the impeller is rotatably received,
The scroll housing has a scroll portion formed with a convex extension in a direction opposite to the impeller,
Wherein the extension portion has a recessed portion formed on the inner surface thereof. The method according to claim 1,
Wherein the concave-convex portion is elongated along the scroll portion. The method according to claim 1,
Wherein the concave-convex portion has a saw-toothed cross-sectional shape. The method according to claim 1,
Wherein the extension is positioned between the cutoff and the straight portion of the scroll portion,
Wherein the concave-convex portion is elongated in the extending portion and the straight portion.

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