KR100269375B1 - scroll in sirocco fan - Google Patents

Abstract

PURPOSE: A scroll of sirocco fan is provided to obtain a constant air volume even when the rotation frequency of the impeller is decreased, and reduce noise of the fan by increasing the diameter of scroll and impeller. CONSTITUTION: A sirocco fan comprises a scroll(2) forming an outer periphery of the sirocco fan; an impeller(3) installed within the scroll, and which rotates so as to suck and discharge an air; an inlet port(4) formed at the scroll; an outlet port(5) formed at the scroll; a cut-off(7) formed at a side of the outlet port; a suction surface(8) formed at the scroll; and a bottom surface(9) formed to oppose to the suction surface of the scroll. The suction surface and bottom surface of the scroll are formed to be inclined with respect to a vertical line. The outlet port of the scroll has a width with a wide upper portion and narrow lower portion when viewed from the front. The spacing formed between the suction surface and bottom surface of the scroll, gradually increases according to the change of angle from the air outlet direction.

Description

Sirocco fan's scroll {scroll in sirocco fan}

The present invention relates to a sirocco fan, and more particularly to a scroll of 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.

As illustrated in FIG. 1, the sirocco fan 1 has an impeller that sucks and discharges air while being rotated according to a driving force of a motor (not shown) installed inside the scroll 2 and the scroll 2. (3), an inlet port (4) formed in the scroll (2) to suck air, a discharge port (5) formed in the scroll (2) to discharge air, and provided on the inlet port (4) side A bell mouse 6 coupled to the scroll 2 to guide the air being sucked and to protect the impeller 3, a cutoff 7 formed on the scroll 2, and the scroll 2. The suction surface 8 is formed in the suction surface 8 is located, and the bottom surface 9 formed at a position opposite to the suction surface 8 on the scroll (2).

In the conventional sirocco fan 1 configured as described above, when the impeller 3 installed in the scroll 2 is rotated by a driving force of a motor (not shown), the suction surface 8 of the scroll 3 is caused by the rotational force of the impeller 3. Air is sucked into the scroll 2 through the suction port 4 formed in the), and the sucked air flows into the scroll 2 by the rotational force of the impeller 3 which is continuously rotated. It is discharged to the outside of the scroll 2 through the formed discharge port 5.

Design factors of the sirocco fan 1 are the outer diameter and width of the impeller 3, the inflation angle α _exp of the scroll 2 and the position and shape of the cutoff 7 at which the scroll 2 starts, Once these basic design factors are determined, the area of the operating point to be operated is determined. Therefore, it is necessary to examine whether the values of these design factors are properly selected when designing for the intended use.

The sirocco fan 1 has the impeller 3 because the suction surface 8 and the bottom surface 9 formed on the scroll 2 are parallel to each other, that is, the width W ₁ of the scroll 2 is constant. The air sucked into the scroll 2 through the suction port 4 by the rotation of) is obtained by a predetermined amount of dynamic pressure in the radial direction and is discharged to the outside of the sirocco fan 1 through the discharge port 5.

The air discharged to the outside of the sirocco fan 1 travels along the scroll 2 in which the radius increases with the increase of the angle θ that changes the dynamic pressure to the static pressure, and part of the dynamic pressure is restored to the static pressure. .

The process is absolutely and is related to the scroll expansion angle (α _exp) is defined as the rate of change of the radius of the angle increasing ", the scroll expansion angle (α _exp) is a very important impact on the performance of the sirocco fan 1 This is because this value becomes a function that defines the cross-sectional area perpendicular to the flow direction according to the angle θ that actually changes the dynamic pressure to the static pressure.

In general, the equation of the scroll 2 using the algebraic spiral is as follows.

γ _cutoff is the distance between the cutoff and the impeller center, γ _imp is the outer diameter of the impeller, θ is the angle to change dynamic pressure to static pressure, and α _exp is the scroll expansion angle.

The sirocco fan 1 is designed to be as large as possible within the range considering the scroll inflation angle α _exp in the predetermined space, so that the effect of lowering the number of revolutions while producing the same amount of air is absolute for low noise. It is advantageous.

However, since the suction surface of the scroll and the bottom surface, which are opposite positions of the suction surface, are formed in parallel with each other, the passage area becomes a function of only the scroll expansion angle when the flow progresses along the scroll.

Therefore, since the scroll inflation angle is generally designed to about 5 to 10 degrees, the size of the scroll and the impeller is limited within a predetermined space, thereby limiting the high air volume and the low noise of the sirocco fan.

The present invention has been made to solve such a problem in the prior art, by increasing the impeller diameter of the sirocco fan to increase the amount of air discharged through the discharge port even with a small number of revolutions of the impeller to increase the high air volume of the sirocco fan The purpose is to reduce noise and noise.

In order to achieve the above object, the present invention is a scroll installed on the outside of the sirocco fan, an impeller installed in the scroll to rotate to suck and discharge air, an inlet formed in the scroll, the discharge port formed in the scroll, A sirocco fan comprising a cutoff formed on one side of the discharge port, a suction surface formed on the scroll and a suction port positioned thereon, and a bottom surface formed on a position opposite to the suction surface on the scroll; The scroll of the sirocco fan is provided such that the width of the scroll becomes larger as the discharge port is formed.

Figure 1a is an exploded perspective view showing a conventional sirocco fan.

Figure 1b is a perspective view of a conventional sirocco fan.

Figure 2a is a schematic diagram showing the structure of a conventional sirocco fan.

Figure 2b is a side view showing a conventional sirocco fan.

FIG. 2C is a cross-sectional view taken along line II of FIG. 2A; FIG.

Figure 3 is a perspective view of the present invention sirocco fan.

Figure 4a is a schematic diagram showing the structure of the present invention sirocco fan.

Figure 4b is a side view showing the present invention sirocco fan.

4C is a cross-sectional view taken along the line II-II in FIG. 4A.

FIG. 5 is a diagram illustrating a scroll magnification angle α _exp of a sirocco fan using an algebraic spiral; FIG.

Explanation of symbols for main parts of the drawings

1: Sirocco fan 2: scroll

3: impeller 4: inlet

5: discharge port

Hereinafter, an embodiment of the present invention will be described in detail with reference to FIGS. 3 to 4C.

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 3 is a perspective view showing a sirocco fan of the present invention, Figure 4a is a schematic diagram showing the structure of the sirocco fan of the present invention, Figure 4b is a side view showing a sirocco fan of the present invention, Figure 4c is a sectional view II-II of Figure 4a. The present invention is a scroll (2) installed on the outside of the sirocco fan (1), an impeller (3) installed in the scroll (2) rotates to suck and discharge air, and a suction port formed in the scroll (2) (4), a discharge port (5) formed in the scroll (2), a cutoff (7) formed at one side of the discharge port (5), and a suction surface formed in the scroll (2) and the suction port (4) is located (8) and the bottom surface 9 formed in the position which opposes the suction surface 8 to the said scroll 2.

The width W ₂ of the scroll 2 is formed to increase gradually toward the side on which the discharge port 5 is formed.

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

First, when the impeller 3 installed in the scroll 2 of the sirocco fan 1 is rotated by the driving force of a motor (not shown), the suction surface 8 of the scroll 2 is driven by the rotational force of the impeller 3. Air is sucked into the scroll 2 through the formed suction port 4, and the sucked air flows in the scroll 2 by the rotational force of the impeller 3, which is continuously rotated, and the discharge port formed in the scroll 2. Discharged to the outside of the sirocco fan 1 through (5).

At this time, since the width W ₂ of the scroll 2 for restoring a constant amount of dynamic pressure obtained through the impeller 3 to the positive pressure is formed to gradually increase toward the side where the discharge port 5 is formed, into the scroll 2. The air that is sucked in and flows is decelerated while passing through a section gradually expanding with time, so that a certain amount of dynamic pressure is gradually changed to a static pressure.

The scroll expansion angle α _exp , which is a value increasing along the rotational direction of the impeller 3 from the cutoff 7, is the radius r of the scroll 2 in the advancing direction of air flowing in the scroll 2. Value increases, the cross-sectional area of the scroll 2 gradually increases.

As such, the important value in the process is the cross-sectional area A _θ of the scroll 2 at an arbitrary angle _θ , so that the scroll 2 in the state where the width W ₁ of the scroll 2 is formed to have a constant length ) And the size of the impeller 3, but the distance between the scroll 2 and the impeller 3 is reduced and the width W ₂ of the scroll ₂ , ie the suction surface 8 and the bottom surface 9. Increasing the spacing between the two to moderate values maintains the cross-sectional area A _θ of the scroll 2 at an arbitrary angle θ.

Therefore, in the state in which the size of the impeller 3 is kept constant, the transverse length L of the scroll 2 can be reduced, and the impeller in the state where the transverse length L of the scroll 2 is constant. Since the size of (3) can be increased, more air volume can be obtained at the same rotational speed of the impeller 3, and conversely, the rotation speed of the impeller 3 is reduced when obtaining the same airflow as in the prior art. .

The cross-sectional area of the scroll 2, i.e. the width W of the scroll 2, may not be constant with respect to the entire scroll 2, or the value may change only for some ranges.

By applying this method, the same effect can be obtained by applying not only the design of the scroll 2 using algebraic spirals but also the scroll 2 using an exponential spiral.

Here, the sirocco fan 1 is an indoor unit or a ceiling type (including a ceiling cassette type) of an indoor unit of a package air conditioner or a window type air conditioner, an air conditioner and a fan coil unit for an air conditioner, a vehicle indoor air conditioner, and a kitchen appliance. And all devices in which the sirocco fan 1 is used, such as for cooling and ventilation used in office equipment.

As described above, the present invention is formed such that the scroll width of the sirocco fan becomes larger and larger toward the side on which the discharge port is formed, so that the horizontal length of the scroll can be reduced while the size of the impeller is kept constant, and the horizontal width of the scroll Since the size of the phase impeller is increased in a constant direction length, the same amount of air can be obtained at a low rotational speed of the impeller, and the noise of the sirocco fan is reduced.

Claims (1)

A scroll provided on the outside of the sirocco fan, an impeller installed in the scroll to rotate to suck and discharge air, an inlet formed on the scroll, an outlet formed on the scroll, a cutoff formed on one side of the discharge port, A sirocco fan having a suction surface formed on a scroll and a suction port positioned thereon, and a bottom surface formed at a position opposite to the suction surface of the scroll; The suction surface and the bottom surface of the scroll are not parallel to each other and are formed to be inclined at a predetermined angle with respect to the vertical line, and the width of the discharge port of the scroll is lower than the lower side when the discharge port is viewed from the front. And a gap width between the suction surface and the bottom surface of the scroll becomes larger as the angle (θ) changes from the discharge direction of air.