KR102703624B1 - Impeller for reducing noise - Google Patents

Abstract

The impeller is arranged in a passage portion of the fan housing through which air passes, and includes a hub and a plurality of blades formed radially on an outer surface of the hub, the blades including a hub connection portion connected to the hub, a first side portion and a second side portion formed on both sides of the hub connection portion, and an outer surface portion connected to ends of the first side portion and the second connection portion and arranged to have a gap portion that is a gap with an inner surface of the passage portion of the fan housing, and at least one of the outer surfaces of the plurality of blades has a first region portion having a small area of the gap portion and a second region portion having a relatively large area of the gap portion compared to the first region portion, thereby reducing noise in a specific band and at high output.

Description

IMPELLER FOR REDUCING NOISE

The present invention relates to a noise-reducing impeller that reduces noise generated by air flow resistance in a specific band or when the amount of air blown increases.

In general, axial fans are those in which gas is introduced in the axial direction and discharged in the axial direction. They rotate at high speeds to increase the airflow, which increases the flow resistance or increases noise in a specific band.

The cause of noise in axial fans is separation or vortex, or when the airflow increases, flow resistance occurs between the fan housing and the axial fan, preventing air from passing smoothly.

In particular, in certain bands or when the airflow increases, the axial flow increases, so there is a problem that the gas hits the blades, causing flow resistance and increasing noise.

Patent Publication No. 10-0753025 (August 22, 2007) Publication of Patent Publication No. 10-2021-0070258 (June 14, 2021)

An object of the present invention is to provide a noise-reducing impeller that reduces noise by ensuring smooth air flow at high output or in a specific band.

Another object of the present invention is to provide a noise-reducing impeller capable of reducing noise while preventing a decrease in blowing force by simultaneously implementing a first region for generating blowing force on one blade and a second region for reducing flow resistance by facilitating airflow.

Another object of the present invention is to provide a noise-reducing impeller capable of minimizing noise in a specific band by forming the shapes of one blade and another blade arranged adjacent thereto non-uniformly.

The impeller is arranged in a passage portion of the fan housing through which air passes, and includes a hub and a plurality of blades formed radially on an outer surface of the hub, wherein the blades include a hub connection portion connected to the hub, a first side portion and a second side portion formed on both sides of the hub connection portion, and an outer surface portion connected to ends of the first side portion and the second connection portion and arranged to have a gap portion as a gap with an inner surface of the passage portion of the fan housing, and the outer surface portion of each of the plurality of blades has a first region portion having a small gap portion area and a second region portion having a larger gap portion area than the first region portion, so that the first region portion can play the role of generating blowing force and the second region portion can play the role of reducing flow resistance and thus reducing noise.

The first area portion of the blade outer surface is connected to the end portion of the first side surface, and the second area portion is connected to the end portion of the second side surface, so that the first area portion and the second area portion can be formed on one blade outer surface.

The first region portion and the second region portion are formed to have the same radius of curvature and different heights, so that the first region portion and the second region portion can be formed on the outer surface of one blade.

The first region portion is connected to the first side portion and the second side portion and is positioned at both edges of the outer surface portion, and the second region portion is positioned at the center of the outer surface portion between the first region portions, so that the first region portion and the second region portion can be formed on the outer surface portion of one blade.

The plurality of blades include a first blade and a second blade arranged adjacent to the first blade, and the outer surface of the first blade and the outer surface of the second blade are formed with different shapes so as to reduce noise in a specific area. The first area portion of the first blade is connected to an end of the first side portion and the second area portion is connected to the second side portion, and the first area portion of the second blade is connected to the second side portion and the second area portion is connected to the first side portion, so as to reduce noise in a specific area and reduce noise at high output.

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The blade includes a plurality of first blades and a second blade arranged between the first blades, and the length of the second blade is formed shorter than the length of the first blade, so that the outer surface of the first blade forms a first region portion, and the second blade forms a second region portion.

As described above, the impeller of the present invention forms a first region and a second region with different gap areas by forming different heights on the outer surface of the blade, thereby minimizing the flow resistance of the fluid while maintaining the blowing performance, thereby reducing noise.

In addition, the shape of the outer surface of one blade and the shape of the outer surface of another blade positioned adjacent to it can be made different from each other to reduce noise in a specific band.

FIG. 1 is a plan view of a fan housing and impeller according to a first embodiment of the present invention.
Figure 2 is a plan view of an impeller according to the first embodiment of the present invention.
Figure 3 is a plan view of an impeller according to the second embodiment of the present invention.
Figure 4 is a plan view of an impeller according to a third embodiment of the present invention.
Figure 5 is a plan view of an impeller according to the fourth embodiment of the present invention.
Figure 6 is a plan view of an impeller according to the fifth embodiment of the present invention.
Figure 7 is a plan view of an impeller according to the sixth embodiment of the present invention.
Figure 8 is a graph showing noise according to the band of the impeller according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the attached drawings. In this process, the sizes and shapes of components illustrated in the drawings may be exaggerated for clarity and convenience of explanation. In addition, terms specifically defined in consideration of the configuration and operation of the present invention may vary depending on the intention or custom of the user or operator. The definitions of these terms should be made based on the contents throughout this specification.

Referring to FIG. 1, the present invention may include a fan housing (10) in which a passageway (12) is formed to allow air to pass in an axial direction, and an impeller (20) disposed inside the passageway (12) of the fan housing (10) to cause gas to flow in an axial direction.

The impeller (20) may include a hub (22) connected to a motor and a plurality of blades (24) formed radially at regular intervals in the circumferential direction of the hub (22).

As shown in FIG. 2, the blade (24) may include a hub connection portion (32) connected to the hub (22), first and second side portions (34, 36) having a predetermined gap from adjacent blades, and an outer surface portion (40) arranged to have a gap portion (14) that is a gap from the inner surface of the passage portion (12) of the fan housing (10).

Such an impeller (20) has a problem in that when a specific band or air volume increases, the amount of air passing through the impeller (20) increases, and as a result, air flow resistance occurs, generating noise. The flow resistance may occur when air that cannot smoothly pass through the blade (24) in front of the blade increases or in a specific band collides with the blade, or when a vortex is generated in the air passing through the blade at the rear of the blade, and the air passing through the blade and the air in which the vortex is generated collide with each other.

Therefore, this embodiment aims to provide an impeller that can minimize noise and reduce blowing performance degradation by minimizing flow resistance by changing the shape of the outer surface (40) of the blade (24).

As shown in FIG. 2, the outer surface of the blade (20) according to the first embodiment of the present invention is formed with a first area (42) in which the gap with the inner surface of the fan housing (10) is formed small, and the area of the gap (14) is small, and the second area (44) in which the area of the gap (14) is relatively large compared to the first area (42) is formed in one blade (24), thereby allowing air that generates flow resistance to smoothly pass through the second area (44), and allowing the first area (42) to perform the blade's original role of generating blowing force, thereby minimizing a decrease in blowing force and at the same time minimizing the generation of noise due to flow resistance.

The first area portion (42) is connected to the end of the first side portion (34), and the second area portion (44) is connected to the end of the second side portion (36) of the blade, so that the first area portion (42) and the second area portion are formed with a structure in which steps of different heights are formed, and accordingly, the outer surface portion (40) of one blade can be divided into the first area portion (42) and the second area portion (44).

The first area (42) and the second area (44) are formed with the same radius of curvature and have different heights so that the area of the gap (14) is different.

At this time, it is preferable that the length of the first area portion (42) be formed smaller than the length of the second outer surface portion (44). That is, if the length (L2) of the first outer surface portion (42) is equal to or greater than the set value, it does not significantly affect the airflow performance, but as the length (L1) of the second outer surface portion (44) increases, the area of the gap portion (14) increases, and accordingly, the airflow can be made smooth, thereby improving the noise reduction performance.

Of course, the length of the first region (42) may be formed to be greater than that of the second region (44), or the length of the first region (42) and the length of the second region (44) may be formed to be the same.

In this way, according to the present invention, the first area portion (42) and the second area portion (44) are formed integrally on the outer surface portion (40) of one blade (24), so that the blowing performance is maintained by the first area portion (42) and the flow resistance is minimized by the second area portion (44), thereby minimizing noise generation.

According to the second embodiment of the present invention, the outer surface (50) of the blade has second regions (52, 54) formed on both edges of the blade outer surface (50), as shown in FIG. 3, and the first region (56) formed in the center of the blade outer surface (50). The second regions (52, 54) are located on both sides of the outer surface (50) that are connected to the first side (34) and the second side (36) of the blade (24), and the first region (56) is formed between the second regions (52, 54).

The impeller according to the second embodiment of the present invention may also be formed so that the sum of the lengths of the second regions (52, 54) formed on both sides of the blade outer surface is smaller than the length of the first region (56) formed in the center of the blade outer surface (50).

An impeller according to a second embodiment of the present invention minimizes flow resistance as air passes through the second area portions (52, 54) located on both sides of the outer surface of the blade, and generates blowing force by the first area portion (56) located at the center of the outer surface portion (50) of the blade.

According to the third embodiment of the present invention, as shown in FIG. 4, the outer surface (60) of the blade has a second region (62) formed in the center of the outer surface (60) of the blade, and first region (64, 66) formed on both edges of the outer surface (60) of the blade. The first region (64, 66) is positioned on both sides of the outer surface (60) connected to the first side (34) and the second side (36) of the blade, and the second region (62) can be formed between the first region (64, 66).

According to the fourth embodiment of the present invention, a plurality of blades, as illustrated in FIG. 5, include a first blade (70) and a second blade (72) adjacent thereto, and the outer surface (80) of the first blade (70) and the outer surface (90) of the second blade (72) are formed with different shapes. That is, the shapes of the outer surface (80) of the first blade (70) and the outer surface (90) of the second blade (72) are not identical to each other.

The outer surface (80) of the first blade (70) and the outer surface (90) of the second blade (72) can be formed in different shapes to simultaneously minimize noise at high output or in a specific band. That is, by forming the outer surface (80) of the first blade (70) and the outer surface (90) of the second blade (72) in different shapes, the air flow in a specific band can be made smooth, thereby minimizing noise generation in a specific band and also minimizing noise generation at high output.

The outer surface (80) of the first blade (70) may include a first area portion (84) connected to the second side portion (36) and a second area portion (82) connected to the first side portion (34), and the outer surface (90) of the second blade (72) may include a first area portion (94) connected to the first side portion (34) and a second area portion (92) connected to the second side portion (36). That is, the first area portion (84) and the second area portion (82) of the first blade (70) are formed in opposite shapes to the first area portion (94) and the second area portion (92) of the second blade (72).

For example, when the number of blades is six, three blades are formed in the shape of the outer surface (80) of the first blade (70), and the remaining three blades are formed in the shape of the outer surface (90) of the second blade (72) and are respectively placed between the first blades (70).

According to the fifth embodiment of the present invention, as shown in FIG. 6, the blade includes a first blade (110) and a second blade (120) adjacent thereto, and the outer surface (130) of the first blade (110) includes a first region (134, 136) formed at both edges by being connected to the first side (34) and the second side (36) of the first blade (110), respectively, and a second region (132) positioned in the center between the first region (134, 136), and the outer surface (140) of the second blade (120) includes a second region (142, 144) formed at both edges by being connected to the first side (34) and the second side (36) of the second blade (120), respectively, and a second region (142, 144) positioned in the center between the second region (142, 144). Includes the first area (146).

According to the fifth embodiment, a plurality of blades are formed with the same number of first blades and second blades, and the first blades and second blades are arranged alternately.

According to the sixth embodiment of the present invention, a blade includes a plurality of second blades (210) arranged between a plurality of first blades (200), as illustrated in FIG. 7, and the length (H1) of the first blades (200) is formed as long as possible, and the length (H2) of the second blades (210) is formed shorter than the length (H1) of the first blades (200) so that the outer surface of the first blades (200) and the outer surface of the second blades (210) are not the same.

That is, a first region is formed on the outer surface of the first blade (200), and a second region is formed on the outer surface of the second blade (210), so that air that generates flow resistance can smoothly pass through the second region formed between the outer surface of the second blade (210) and the fan housing, thereby performing the original role of the blade, thereby minimizing reduction in blowing power and minimizing noise generation due to flow resistance.

Figure 8 is a graph showing noise by band of the impeller according to the first to sixth embodiments of the present invention, and it can be confirmed that noise is reduced in a specific (700 Hz) band (H).

Although the present invention has been described and illustrated with specific preferred embodiments as examples, the present invention is not limited to the above embodiments, and various changes and modifications may be made by those skilled in the art without departing from the spirit of the present invention.

10: Fan housing 12: Passageway
20: Impeller 22: Hub
24: Blade 32: Hub connector
34: First side 36: Second side
40: Outer surface 42: First area
44; 2nd area department

Claims (10)

It is arranged in the air passage of the fan housing and includes a hub and a plurality of blades formed radially on the outer surface of the hub,
Each of the plurality of blades includes a hub connection portion connected to the hub, a first side portion and a second side portion formed on both sides of the hub connection portion, and an outer surface portion connected to the ends of the first side portion and the second side portion and arranged to form a gap portion that is a gap with the inner surface of the passage portion of the fan housing.
Each outer surface of the plurality of blades includes a first region having a smaller area of the gap portion and a second region having a larger area of the gap portion than the first region,
The above plurality of blades include a first blade and a second blade arranged adjacent to the first blade, and the outer surface of the first blade and the outer surface of the second blade have different shapes,
A noise-reducing impeller, wherein the first region of the first blade is connected to the second side portion, the second region is connected to the first side portion, and the first region of the second blade is connected to the first side portion and the second region is connected to the second side portion. delete In the first paragraph,
A noise-reducing impeller having the first and second regions having the same radius of curvature. delete delete delete delete delete It is arranged in the air passage of the fan housing and includes a hub and a plurality of blades formed radially on the outer surface of the hub,
Each of the plurality of blades includes a hub connection portion connected to the hub, a first side portion and a second side portion formed on both sides of the hub connection portion, and an outer surface portion connected to the ends of the first side portion and the second side portion and arranged to form a gap portion that is a gap with the inner surface of the passage portion of the fan housing.
Each outer surface of the plurality of blades includes a first region having a smaller area of the gap portion and a second region having a larger area of the gap portion than the first region,
The above plurality of blades include a first blade and a second blade arranged adjacent to the first blade, and the outer surface of the first blade and the outer surface of the second blade have different shapes,
The first region of the first blade is formed on both edges of the outer surface, and the second region is formed in the center of the outer surface.
A noise-reducing impeller, wherein the first region of the second blade is formed in the center of the outer surface, and the second region is formed at both edges of the outer surface. delete

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