KR100272540B1 - structure of bellmouth for sirocco fan - Google Patents

Abstract

PURPOSE: A bell mouth structure for sirocco fan is provided to reduce the suction noise of the fan and improve function of the sirocco fan by improving the shape of bell mouth of the fan. CONSTITUTION: A sirocco fan(1) comprises a fan housing(2) arranged at the outer periphery of the sirocco fan; an impeller(3) installed within the fan housing, and which rotates so as to suck and discharge an air; an inlet port(4) formed at the fan housing; a diffuser(5) formed at the fan housing; and a bell mouth(6) formed at the inlet port side, and which guides the sucked air and protect the impeller. The bell mouth has a side cross sectional surface protruded from the fan housing so as to form an arc shape. The bell mouth has an inner front end located at the same plane with the outer side surface of the fan housing, or beneath the outer side surface.

Description

Structure of bellmouth for sirocco fan

The present invention relates to the field of sirocco fans, and more particularly, to a bell mouse structure of a sirocco fan for smoothly absorbing and discharging air in a sirocco fan.

In general, the Sirocco fan is named after Sirocco, a strong monsoon of the Sahara Desert, and is widely used for ventilation or air conditioning by combining ducts, such as a multiblade fan.

The sirocco fan is a mechanism that delivers static pressure and dynamic pressure to the flow to overcome the flow resistance of other appliances and move the air where desired to cool the appliance or to move the heat source of cooled or heated air.

As illustrated in FIG. 1, the sirocco fan 1 is provided with a scroll-shaped fan housing 2 installed outside and rotated according to a driving force of a motor (not shown) installed in the fan housing 2. Impeller (3) for suctioning and discharging the air, an inlet (4) formed in the fan housing (2) for sucking air, and air flowing in the fan housing (2) formed in the fan housing (2) A diffuser (5) discharged, a bell mouse (6) installed at the suction port (4) side to guide the air sucked into the fan housing (2) and protecting the impeller (3), and the fan housing (2). And a cutoff (7) formed in the c) to divide the air sucked through the inlet.

The inner circumferential portion of the bell mouse 6 is bent into the fan housing 2, the bend of the bell mouse 6 is formed in a quarter arc shape, and an arc end of the bell mouse 6 is formed. The portion is formed with a straight portion (a) to ensure the straightness of the air to be sucked.

The arc diameter (r) of the bell mouse (6) is preferably formed to be 0.1 times the diameter of the impeller (r _imp ), but most are formed to be 0.05 to 0.15 times, and the inner diameter (r ₁ ) of the bell mouse (6). ) Is formed at 0.80 to 0.95 times the impeller diameter (r _imp ).

The distance (L) between the straight end of the arc of the bell mouse 6 and the impeller 3 is generally preferably reduced as much as possible within the allowable range, but is usually formed about 7 to 12 mm, and the diameter of the impeller 3 r _imp ) is formed regardless.

The conventional sirocco fan 1 configured as described above has an inlet formed in the fan housing 3 by the rotational force of the impeller 3 when the impeller 3 installed in the fan housing 2 is rotated by a driving force of a motor (not shown). Air (4) is sucked into the fan housing (2).

At this time, the inner periphery of the bell mouse (6) installed on the suction port (4) side to protect the impeller (3) is bent in a quarter arc shape in the inner direction of the fan housing (2), the bell mouse (6) Since the straight portion (a) is formed at the bent arc end of the air by the bell mouse (6) is guided into the fan housing (2) to be sucked smoothly.

The suctioned air flows through the fan housing 2 by the rotational force of the impeller 3 which is continuously rotated, and then the pressure is increased, and then the fan housing 2 is formed through the diffuser 5 formed in the fan housing 2. Is discharged to the outside.

Here, the sirocco fan 1, which is relatively high pressure in comparison with other types of fans, has a relatively complicated air flow therein, and the air flows through the diffuser 5 by the impeller 3 of the sirocco fan 1. When discharging, the flow direction of air should be perpendicular to the wing and side of the impeller 3 to ensure the flow of air parallel to the wall in the diffuser 5 so that less vortex occurs and due to collision and friction The flow loss of air can be minimized.

That is, in the sirocco fan 1, the inertial force when the flow of air flows from the front of the impeller 3 is greatly affected.

However, this conventional sirocco fan is disturbed by the air sucked into the fan housing through the inlet while flowing along the upper surface of the fan housing when air is sucked into the fan housing through the inlet as shown in FIG. Due to this, the air sucked into the fan housing is not sucked in a vertical state as a whole, and thus there is a problem in which suction noise is generated in the sirocco fan.

In addition, since the flow direction of the suctioned air is inconsistent, when the air is ejected from the impeller to the diffuser, the air hits the inner surface of the diffuser and is discharged through the diffuser, so that the vortex as shown in FIG. There was also a problem of deterioration.

The present invention has been made to solve such a problem in the prior art, by deforming the bell mouse shape of the sirocco fan to facilitate the intake and discharge of air into the sirocco fan to reduce the suction noise of the sirocco fan and The purpose is to improve the performance of the sirocco fan.

In order to achieve the above object, the present invention is a fan housing which is installed on the outside of the sirocco fan, an impeller installed in the fan housing is rotated to suck and discharge air, an inlet formed in the fan housing, the fan housing In the sirocco fan consisting of a diffuser formed in, and a bell mouse to guide the air suction is installed on the inlet side and to protect the impeller; The bell mouse is provided with a bell mouse structure of a sirocco fan, which is formed to protrude to the outside of the fan housing.

1 is a perspective view showing a conventional sirocco fan.

2 is a cross-sectional view of a bell mouse of a sirocco fan.

Figure 3 is a state diagram showing the flow direction of air sucked into the sirocco fan.

4 is a state diagram showing the air vortex distribution in the diffuser of the sirocco fan.

Figure 5 is a perspective view of the present invention sirocco fan.

6 is a cross-sectional view of a bell mouse of a sirocco fan.

Figure 7 is a state diagram showing the flow direction of air sucked into the sirocco fan.

8 is a state diagram showing the air vortex distribution in the diffuser of the sirocco fan.

9 is a graph comparing the performance of the sirocco fan.

10 is a graph comparing the noise of the sirocco fan.

Figure 11 is a first alternative embodiment showing a velmouth side cross-section of the sirocco fan of the present invention.

Figure 12 is a second alternative embodiment showing a velmouth side cross section of the sirocco fan of the present invention.

Figure 13 is a third alternative embodiment showing a belmouse side cross-section of the sirocco fan of the present invention.

Figure 14 is a fourth alternative embodiment showing a belmouth side cross-section of the sirocco fan of the present invention.

Explanation of symbols for main parts of the drawings

1: sirocco fan 2: fan housing

3: impeller 6: belmouth

Hereinafter, an embodiment of the present invention will be described in detail with reference to FIGS. 5 to 8.

Since the sirocco fan has been mentioned in the conventional configuration, overlapping portions thereof will be omitted, and only the same structure will be given the same reference numeral as in the prior art.

Figure 5 is a perspective view showing a sirocco fan of the present invention, Figure 6 is a cross-sectional view showing a bell mouse of the sirocco fan, Figure 7 is a state diagram showing the flow direction of the air sucked into the sirocco fan, Figure 8 is a diffuser of the sirocco fan As a state diagram showing the air vortex distribution of the present invention, the fan housing (2) is formed on the outer side of the sirocco fan (1), and the air is rotated in accordance with the driving force of a motor (not shown) in the fan housing (2) An impeller 3 for suctioning and discharging is provided.

An intake port 4 through which air is sucked is formed in the fan housing 2, and a diffuser 5 is formed in the fan housing 2 through which air flowing in the fan housing is discharged.

On the inlet 4 side of the fan housing 2, a bell mouse 6 is provided to guide the air sucked into the fan housing 2 and to protect the impeller 3, and the bell mouse 6 is provided. Is formed to protrude to the outside of the fan housing 2, the side cross-section of the bell mouse 6 is formed in a semicircle as shown in FIG.

A straight portion a is formed at the inner arc end of the bell mouse 6 to guide the air to be sucked in a vertical state through the inlet 4 of the fan housing 2.

The semicircle diameter r ₁ of the bell mouse 6 is formed at 0.01 to 0.20 times the impeller diameter r _imp , and the semicircle diameter r ₁ of the bell mouse 6 is the impeller 3 diameter r. _Imp less than 0.01 times of _imp ) not only reduces the air volume of the air sucked into the sirocco fan 1, but also reduces the noise reduction effect, the semicircular diameter (r ₁ ) of the bell mouse 6 is impeller (3) If greater than 0.20 times the diameter r _imp , the bell mouse 6 will be out of the outer dimension of the fan housing 1.

The inner diameter (r ₂₎ of the bell mouth 6 has an impeller (3) diameter is 0.8 to 1.0 times the formation of the (r _imp), and the inner diameter of the bell mouth (6) (r _2), the impeller (3) diameter ( is less than 0.8 times the r _imp) 1.0 times that of the sirocco fan 1, the air volume of the air is reduced to be drawn into the inner diameter (r _2), the impeller (3) diameter (r _imp) of the bell mouth 6 If larger, the inner diameter (r ₂ ) of the bell mouse (6) is larger than the impeller (3), so that the impeller (3) can be separated and the air sucked into the sirocco fan (1) is the inner diameter of the bell mouse (6). It will come out through the outside.

The distance (ℓ) between the arcuate inner edge portion and the impeller (3) of the bell mouth 6 has arcuate inner end of the impeller (3) 0.01 to 0.2 times the diameter and is formed of (r _imp), the bell mouth 6 the part and the impeller (3) between the distance (ℓ), an impeller (3) a diameter of 0.01 times the can is less than touches the outer surface of the impeller (3), the impeller (3) and the bell mouth (6) of the (r _imp) can be broken, the fan housing through the arcuate inner end portion and the impeller (3) between the distance (ℓ), an impeller (3) diameter of the bell mouth (6) is greater than 0.2 times of (r _imp) of the bell mouth 6 (2) The air sucked into it will come out again.

The side cross-section of the bell mouse 6 of another embodiment is formed in an elliptical shape as in FIG. 11 or in a double arc (r ₃ , r ₄ ) as in FIG. 12, or based on the circumference as in FIG. 13. It is formed into a 1/2 to 1/3 arc, or as shown in Fig. 14 is formed into a 1/2 to 2/3 arc based on the circumference.

The operation of the present invention configured as described above is as follows.

First, the shape of the bell mouse 6 installed on the suction port 4 side formed in the fan housing 2 of the sirocco fan 1 protrudes to the outside of the fan housing 2, and the protruding bell mouse 6. The side cross-section is formed in a semicircle, elliptical or double arc and 1/2 to 1/3 arc and 1/2 to 2/3 arc shape on the basis of the circumference, so that the motor (not shown) in the fan housing (2) When air is sucked by the rotational force of the impeller 3 rotated according to the driving force of the air flowing along the upper surface of the fan housing 2 is caught by the protruding bell mouse (6), so that the fan housing ( The air sucked into the inlet 4 of 2) is smoothly sucked into the fan housing 2 without being affected by the air flowing along the upper surface of the fan housing 2.

In addition, since the straight portion (a) is formed at the inner arc end of the bell mouse (6), the air sucked through the inlet (4) of the fan housing (2) is the straight portion (a) of the bell mouse (6). Guided by) and sucked in a vertical state.

As described above, the air sucked into the fan housing 2 flows through the fan housing 2 by the rotational force of the impeller 3 which is continuously rotated, and the pressure is increased and then the diffuser formed in the fan housing 2 ( 5) is discharged to the outside of the sirocco fan (1).

More specifically, as shown in FIGS. 7 and 8, the amount of air sucked into the inlet 4 is minimized along the upper surface of the fan housing 2, and the air is sucked in a vertical state through the inlet 4. The air flowing in the fan housing 2 by the rotational force of the impeller 3 flows in a vertical state when viewed from the side of the wing and the impeller 3 through the diffuser 5 through the sirocco fan 1 Since it is discharged to the outside of the diffuser 5, not only less vortex is generated, but also the flow of air is minimized by the collision with the inner surface of the diffuser 5 and the flow loss due to friction.

Here, a part of the air sucked into the space (s) of the inner circumferential surface of the bell mouse 6 is flown, and the flowed air is sucked back into the fan housing 2 through the suction port, so that the suction noise of the sucked air Reduce.

As described above, the present invention is formed by protruding the shape of the bell mouse installed on the suction port side to the outer side of the fan housing in an arc shape, thereby minimizing the amount of air sucked into the suction port along the upper surface of the fan housing the bell mouse Air is sucked into the fan housing in a vertical state, and the sucked air flows through the fan housing and is discharged in a vertical state when viewed from the wing and side of the impeller through the diffuser, thereby causing vortex generation in the diffuser. In addition to being reduced, there is an effect of minimizing the flow loss of air due to the collision and friction with the inner surface of the diffuser.

In addition, since the intake and discharge of air into the fan housing of the sirocco fan is performed smoothly, the flow loss of the air is reduced, and the performance of the sirocco fan is improved, and the suction noise of the sucked air is also reduced.

Claims (4)

A fan housing provided at an outer side of the sirocco fan, an impeller installed in the fan housing to rotate to suck and discharge air, an inlet formed in the fan housing, a diffuser formed in the fan housing, and installed at the intake side A sirocco fan comprising a bell mouse for guiding inhaled air and protecting an impeller; The bell mouse is formed to protrude to the outside of the fan housing so that the side cross-section is an arc, and the inner end of the bell mouse is located on the same plane or below the horizontal outer surface of the fan housing. The bell mouse structure of the sirocco fan characterized by. The method of claim 1, The semicircular diameter (r ₁ ) of the bell mouse is formed at 0.01 to 0.20 times the impeller diameter (r _imp ), and the inner diameter (r ₁ ) of the bell mouse is formed at 0.8 to 1.0 times the diameter of the impeller (r _imp ). Bell mouse structure of the sirocco fan, characterized in that the distance (L) between the arc inner end of the bell mouse and the impeller is formed at 0.01 to 0.2 times the impeller diameter (r _imp ). The method of claim 1, The side cross section of the bell mouse, A bell mouse structure of a sirocco fan characterized by forming an elliptical shape or a double arc shape formed by two circles having different radii. The method of claim 1, Side cross-section of the bell mouse, the bell mouse structure of the sirocco fan, characterized in that formed in a 1/2 to 2/3 arc shape on the basis of the circumference.