KR19990080984A - Crossflow fan blower with improved stabilizer - Google Patents

Abstract

The disclosed crossflow fan blower has a crossflow fan, a motor, a rear guide and a stabilizer. In the crossflow fan, a plurality of unit fans having a plurality of blades arranged at regular intervals on the circumference are installed in series along the rotation axis direction. The motor is for providing driving force to the cross flow fan, and the rear guide provides a flow path of air blown by the cross flow fan. In addition, the stabilizer is provided on one front side of the crossflow fan, and has a shape in which its minimum interval point moves linearly between the upper and lower limits on the virtual circumference. The stabilizer is shaped such that its minimum spacing point linearly moves or reciprocates between the upper and lower limits on the virtual circumference with respect to one unit fan of the crossflow fan. Alternatively, the minimum spacing point of one unit fan of the cross flow fan may have a shape that linearly moves from one side to the other side of the upper limit and the lower limit on the virtual circumference. According to this, the noise generated between the crossflow fan and the stabilizer is distributed according to the position of the stabilizer. Therefore, the overall noise of the blower can be greatly reduced.

Description

Crossflow fan blower with improved stabilizer

The present invention relates to a crossflow fan blower for use in an air conditioner and the like, and more particularly, to a crossflow fan blower having an improved stabilizer so as to greatly reduce noise without deteriorating overall performance.

Generally, in a crossflow fan blower used in an air conditioner, a vortex is generated inside the fan by the rotation of the crossflow fan. In addition, since a backflow occurs on one side of the fan, this backflow causes a great deterioration in the performance of the entire fan.

Therefore, in the general crossflow fan blower, a scroll and a stabilizer are used to stabilize the vortex to occur uniformly, thereby preventing the performance of the crossflow fan.

However, since the conventional stabilizer has a uniform shape along the longitudinal direction, the vortex is simultaneously generated at the same position along the axial direction of the cross flow fan. Accordingly, the blade passing frequency noise generated between the crossflow fan and the stabilizer is greatly increased, and thus, the noise of the blower is increased.

As an effort to overcome this disadvantage, Japanese Patent Laid-Open No. 63-14020 (named "cross-flow blower") is mentioned.

According to this (see FIG. 1), the tongue ridge 5a of the stabilizer 5 maintains a constant distance from the outer periphery of the cross flow fan 2, and at the same time cross-flow along its longitudinal direction, that is, the axial direction of the cross flow fan 2. The virtual circumferential image centering on the axis of the fan 2 is formed so as to continuously and irregularly move.

However, such a blower has a disadvantage that it is very difficult to form the tongue ridgeline 5a of the stabilizer 5 so as to be irregularly moved in the longitudinal direction while maintaining a constant distance from the outer periphery of the crossflow fan 2. In addition, since the shape is irregular, it is impossible to predict the effect of reducing noise, and thus there is a disadvantage in that the effect cannot be guaranteed.

The present invention has been made to solve these shortcomings, and the object of the present invention is to improve the shape of the stabilizer to have a certain regularity, so that it is easy to manufacture and obtain a certain noise reduction effect.

1 is a perspective view showing a conventional crossflow fan blower.

Figure 2 is a perspective view of the crossflow fan blower according to the present invention.

3A to 3C are cross-sectional views taken respectively of different portions of FIG. 2.

FIG. 3D is a view overlapping FIGS. 3A to 3C;

Figure 4 is a perspective view showing a stabilizer which is the main part of the present invention.

Figure 5 is a graph comparing the noise measurement test results of various embodiments of the present invention and a conventional stabilizer.

Explanation of symbols on the main parts of the drawings

10; Crossflow fan 10a; Axis of rotation

11; Unit fan 20; Rear guide

30; Stabilizer 31; Opposition

31a; Minimum clearance point 32; Virtual circumference

The crossflow fan blower according to the present invention for achieving the above object, has a crossflow fan, a motor, a rear guide and a stabilizer.

In the crossflow fan, a plurality of unit fans having a plurality of blades arranged at regular intervals on the circumference are installed in series along the rotation axis direction.

The motor is for providing driving force to the cross flow fan, and the rear guide provides a flow path of air blown by the cross flow fan.

In addition, the stabilizer is provided on one front side of the crossflow fan, and has a shape in which its minimum interval point moves linearly between the upper and lower limits on the virtual circumference.

Here, the stabilizer has a shape in which its minimum spacing point linearly moves or reciprocates between the upper and lower limits on the virtual circumference with respect to one unit fan of the cross flow fan. Alternatively, the minimum spacing point of one unit fan of the cross flow fan may have a shape that linearly moves from one side to the other side of the upper limit and the lower limit on the virtual circumference.

According to this, the noise generated between the crossflow fan and the stabilizer is distributed according to the position of the stabilizer. Therefore, the overall noise of the blower can be greatly reduced. In addition, since the stabilizer has a shape according to a predetermined rule, its production is easy.

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

The crossflow blower according to one embodiment of the invention is shown in FIGS. 2 to 4.

As shown, the crossflow blower according to one embodiment of the present invention includes a crossflow fan 10, a motor (not shown), a rear guide 20, and a stabilizer 30.

The crossflow fan 10 has a plurality of unit fans 11 installed in series along its rotation shaft 10a, and each unit fan 11 has a plurality of blades 11a centered on the rotation shaft 10a. It is arranged at regular intervals along the circumference.

A motor (not shown) has its drive shaft connected to the rotating shaft 10a of the cross flow fan 10 to rotate the cross flow fan 10 with its driving force.

The rear guide 20 is installed at the rear of the cross flow fan 10, and provides a flow path of air blown by the rotation of the cross flow fan 10. In addition, when the rear guide 20 is applied to an indoor unit of a room air conditioner, the rear guide 20 also serves as a rear case of the indoor unit.

On the other hand, the stabilizer 30 provided in the front lower side of the cross flow fan 10 has the opposing part 31 of the semicircular cross section at the position facing the cross flow fan 10. As shown in FIG.

Here, the point 31a (hereinafter, referred to as a minimum spacing point) having a minimum spacing with the crossflow fan 10 in the opposing portion 31 is the rotation shaft 10a of the crossflow fan 10 as shown in FIG. 3A. It is located on a virtual circumference 32 (hereinafter referred to as a virtual circumference) centered on the circumference. And this minimum space | interval point 31a changes the position on the virtual circumference 32 according to the position of the stabilizer 30 in the longitudinal direction, ie, the direction of the rotating shaft 10a of the crossflow fan 10. As shown in FIG.

In other words, the minimum spacing points 31a have different positions on the virtual circumference 32 as shown in Figs. 3A to 3C according to the longitudinal position at the opposing portions 31 of the stabilizer 30. will be. 3d to 3c are simultaneously shown in FIG. 3d for better understanding.

As such, the position on the virtual circumference 32 of the minimum spacing point 31a of the stabilizer 30 is on the virtual circumference 32 relative to the constant length of the stabilizer 30, as shown in more detail in FIG. 4. It has regularity to move linearly between the top and bottom of the minimum gap point 31a.

By this configuration, since the position of the minimum spacing point 31a of the stabilizer 30 changes along the axial direction of the crossflow fan 10 when the crossflow fan 10 is rotated, the crossflow fan 10 and the stabilizer 30 The vortices generated between are sequentially generated along the axial direction of the cross flow fan 10. Therefore, the frequency noise is distributed along the axial direction of the cross flow fan 10, it is possible to obtain the effect that the noise is reduced as a whole.

Here, the stabilizer 30 may have a shape in which its minimum spacing point 31a moves linearly from one side of the upper and lower ends on the virtual circumference 32 to the other side with respect to one unit fan 11. It may have a shape that linearly reciprocates therebetween. Alternatively, the minimum spacing point 31a may be linearly moved or linearly reciprocated between the upper and lower ends of the virtual circumference 32 with respect to the two or more unit fans 11.

Experimental measurements were made on the noise level of various shape stabilizers. Experimental results for some of them are shown in FIG. 5 as compared to conventional stabilizers having a uniform shape.

According to the results shown graphically in FIG. 5, the minimum spacing point 31a of the stabilizer 30 has a shape of linearly reciprocating between the upper end and the lower end on the virtual circumference 32 with respect to one unit fan 11. In the case of (2), it is possible to obtain an effect of reducing noise of approximately 10 dB compared to the conventional stabilizer (5) having a uniform shape shown in the graph.

In addition, when the minimum spacing point 31a has a shape in which the minimum gap point 31a moves linearly from one side of the upper and lower ends of the virtual circumference 32 to the other side with respect to one unit fan 11 (③), and two unit fans A satisfactory result can be obtained even when the minimum spacing point 31a has a shape (4) linearly moving from one side of the upper and lower ends of the virtual circumference to the other side with respect to (11). For reference, ⑤ is a case in which the minimum spacing point 31a moves linearly from one side of the upper and lower ends of the virtual circumference to the other side with respect to four unit fans. In this case, the noise reduction effect was not obtained very much. .

Based on this result, the stabilizer according to the embodiment of the present invention has a minimum spacing point 31a linearly from one side to the other of the top and bottom of the virtual circumference 32 with respect to one unit fan 11. It has a shape of moving or reciprocating, or having a shape in which the minimum gap point 31a moves linearly from one side of the upper and lower ends on the virtual circumference 32 to the other with respect to the two unit fans 11. desirable.

In the present invention as described above, the stabilizer has a minimum distance from the crossflow fan and changes linearly along the direction of the rotation axis of the crossflow fan on an imaginary circumference around the rotational axis of the crossflow fan. Therefore, the noise generated between the crossflow fan and the stabilizer is dispersed according to the position of the stabilizer, so that the overall noise of the blower can be greatly reduced. In addition, since the stabilizer has a shape according to a predetermined rule there is an advantage that the production is easy.

In the above, certain preferred embodiments of the present invention have been illustrated and described. However, the present invention is not limited to the above-described embodiments, and various modifications can be made by those skilled in the art without departing from the gist of the present invention as claimed in the claims. .

Claims (5)

A plurality of unit fans having a plurality of blades arranged at regular intervals on the circumference are installed in series along the rotation axis direction, a motor for providing a driving force to the cross flow fan, and air blown by the cross flow fan. In the crossflow fan blower which has the rear guide which provides a flow path, and the stabilizer provided in the front one side of the said crossflow fan, And wherein said stabilizer has a minimum spacing with respect to said crossflow fan at regular intervals along a direction of rotational axis of said crossflow fan on an imaginary circumference about said axis of rotation. 2. The crossflow fan blower of claim 1 wherein the stabilizer has a shape such that its minimum spacing point moves linearly between an upper limit and a lower limit on the imaginary circumference. 3. The crossflow according to claim 2, wherein the stabilizer has a shape in which its minimum spacing point linearly reciprocates between an upper limit and a lower limit on the virtual circumference with respect to one unit fan of the crossflow fan. Blower. 3. The stabilizer according to claim 2, wherein the stabilizer has a shape in which its minimum spacing point moves linearly from one of the upper limit and the lower limit on the virtual circumference to the other side with respect to one unit fan of the crossflow fan. Crossflow blower having a. 3. The stabilizer of claim 2, wherein the stabilizer has an improved stabilizer having a shape in which its minimum spacing point moves from one side of the upper and lower limits of the virtual circumference to the other side with respect to the two unit fans of the crossflow fan. Crossflow blower.