ES2604201T3 - Tangential fan - Google Patents

Abstract

A tangential fan comprising: - an impeller (12); and - a tongue (18) provided along a portion of the outer circumference of the impeller (12), in which the tongue is provided with a plurality of openings (21) such that a cross-section of the tongue ( 18) on a surface perpendicular to the circumferential direction of the impeller (12) is shaped in a comb shape, and in which at least one opening (21) of the plurality of openings (21) is shaped in a different way, characterized in that the at least one opening (21) has a rib (25) in which the at least one opening (21) is at least partially hidden.

Description

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DESCRIPTION

Tangential fan Background of the invention

1. Technical field

The present invention relates to a tangential fan used in an air conditioner or similar equipment.

2. Related technique

In a tangential fan that is used in an air conditioner, in an air curtain or in similar equipment, a distance between a fan rotor (impeller) and a tongue is preferably shortened to improve its efficiency, with the tongue at a predetermined height along the outside diameter of the fan rotor. However, in this case, when a fan rotor blade moves from a tongue region to an air suction region, the air flow around the blade varies rapidly, thereby increasing the noise in a termination region. from the tongue region.

Therefore, in the conventional tangential fan, in order to prevent the flow around the blade from flowing rapidly when the fan rotor blade moves from the tongue region to the air suction region, a portion of Comb-shaped groove at the upper end of the tongue. As the comb-shaped groove portion approaches the air suction region from the tongue region, the width of the tongue enlarges, and its depth between the right and left rotor rotors is changed of the fan (for example, refer to Japanese Patent No. 3 248 466 (pages 2 and 3, and Figure 3)). JP 4-080 533 A discloses an exemplary tangential fan comprising a stabilizer having recess and projection parts to disperse the frequency of the sound of the blade generated by the tangential fan.

Summary

However, in a tangential fan as such, since the length of the tongue is shortened in one direction along the outside diameter of the fan rotor (impeller), the leakage rate flowing from a discharge side is increased to the side of suction. Therefore, the pressure difference between the suction side and the discharge side is made smaller, and an unstable circular vortex is produced in the tangential fan. Consequently, when the flow rate is low or dust accumulates in the filter, it is very possible that an inverse flow to the original output flow will occur. Consequently, efficiency is degraded and noise increases.

According to one aspect of the invention, a tangential fan is provided in which the efficiency is high while reducing the noise.

The present invention provides a tangential fan according to independent claim 1. Additional embodiments of the invention may be carried out according to the dependent claims.

According to the aforementioned aspects, it is possible to provide a tangential fan in which the efficiency is high while reducing the noise.

Brief description of the drawings

Figure 1 is a sectional view of an air conditioner using a tangential fan according to a first example not claimed.

Figures 2A and 2B are sectional views of a front part of the tangential fan according to the first example not claimed.

Figure 3 is a perspective view of the front part of the tangential fan according to the first example not claimed.

Figures 4A and 4B are sectional views of the front part of the tangential fan according to the first example not claimed.

Figure 5 is a sectional view of the front part of a tangential fan according to a second unclaimed example.

Figure 6 is a perspective view of the front part of the tangential fan according to the second example not claimed.

Figure 7 is a perspective view of the front part of the tangential fan according to the second example not claimed.

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Figure 8 is a perspective view of the front part of a tangential fan according to a third example not claimed.

Figure 9 is a perspective view of the front part of a tangential fan according to a fourth example not claimed.

Figure 10 is a sectional view of the front part of the tangential fan according to the invention.

Figure 11 is a perspective view of the front part of the tangential fan according to the invention.

Figures 12A, 12B are sectional views of the front part of the tangential fan according to the invention.

Figures 13A, 13B are sectional views of the front part of the tangential fan according to the invention.

Description of the embodiments First example

Figure 1 illustrates a sectional view illustrating an air conditioner using a tangential fan according to a first example. In the accompanying drawings, the same reference number represents the same component or a corresponding component, which is common in the specification in general. The forms of the components represented in the general specification are only examples, and are not limited thereto.

A suction grille on the front side 2 is provided in Figure 1 on the front surface of a housing 1 of the air conditioner, and a suction grille on the upper side 3 is provided on the upper surface thereof. Inside the housing 1, a filter 4 is provided to remove dust contained in the air along the suction grill of the front side 2 and the suction grill of the upper side 3. A heat exchanger 5, which exchanges heat with the air sucked from the suction grill of the front side 2 and the suction grill of the upper side 3, is arranged along the filter 4. In a lower portion of the front surface of the housing 1, a front part 6 in order to be connected to the suction grille on the front side 2. On the inner rear surface of the housing 1, a rail 7 is installed, which introduces the air flow into the interior of the air conditioner.

Between the heat exchanger 5 and the rail 7, an impeller 12 is arranged which rotates around a rotating shaft 13 of the tangential fan. The impeller 12 is composed of the rotating shaft 13, a plurality of disc-shaped side plates 14 fixed to both ends and in the middle of the rotating shaft 13, and impeller blades 15 radially fixed to the outer circumferences of the side plates 14 The tangential fan is provided with the impeller 12, the crane 7 and the front part 6.

In the lower portion of the housing 1, an air outlet 8 is provided between the front part 6 and the rail 7, through which the air is blown out of the air conditioner. In the immediate vicinity of the air outlet 8, an air flow direction change plate is provided from left to right 9 connected to the front part 6, which changes the air flow in the direction of the rotating shaft 13 and, similarly, in the vicinity of the outlet 8, a top-down air flow direction change plate 10 is provided, which changes the air flow in the top-down direction. Also, within the rear surface of the housing 1, that is, on the side of the rear surface of the grille 7, a pipe 11 is arranged through which the coolant of the heat exchanger 5 circulates.

As the impeller 12 rotates in the direction of the arrow C of Figure 1, the air is sucked from the suction sides of the suction grille on the front side 2 and the suction grille on the upper side 3. The air Suction exchanges heat with the heat exchanger 5 through the filter 4, and then circulates through the blades of the impeller 15 or impeller 12. After the air circulates through the blades of the impeller 15 of the impeller 12, appropriately adapts the air flow direction thereof by means of the air flow direction change plate from left to right 9 and the air flow direction change plate from top to bottom 10. Then, it is driven the air out of the air outlet 8.

Figure 2 is a sectional view illustrating the front part of the tangential fan according to the first example, and Figure 3 is a perspective view of the front part of the tangential fan according to the first example. Specifically, Figure 2A is a sectional view of the front part on a surface perpendicular to the rotating axis of the tangential fan according to the first example, and Figure 2B is a sectional view of the front part on a surface (a surface that includes to the rotating shaft 13 of the impeller 12, that is, a cross-sectional surface taken along the line E-E of Figure 2A) perpendicular to a circumferential direction of the tangential fan impeller according to the first example.

As shown in Figures 2 and 3, the front part 6 is provided with an air passage constituting the portion 17 and a tongue 18. The air passage constituting the portion 17 constitutes a portion of an air passage in the inside the air conditioner and serves as a drain that receives water droplets that fall from the heat exchanger 5 in order to be discharged. The tab 18, provided along a portion of the outer circumference of the impeller 12 maintains a pressure difference between a suction side B and a side of

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discharge A, which is generated by the rotation of impeller 12, such that the tangential fan achieves high efficiency. On the tongue 18, a plurality of concave openings 21 are arranged in the direction of the rotating shaft 13 of the impeller 12 such that the tongue 18 is shaped in the form of a comb. In the form of a comb, the cross section of the tongue 18 on a surface (a surface that includes the rotating shaft 13 of the impeller 12, that is, a cross-sectional surface taken along the line E-E of the Figure 2A) perpendicular to a circumferential direction of the impeller 12 has a plurality of convex portions that are connected to a base and on the same side of the corresponding base. Some openings 21 between the plurality of openings 21 are shaped in a different way, and have a different depth H in a direction of the radius of the impeller 12 on the side of the discharge A. The remaining openings 21 are shaped to have the same shape and the same depth H in a direction of the radius of the impeller 12 on the side of the discharge A. The depths H of some openings 21 can be changed regularly or irregularly on the side of the discharge A.

In the tangential fan shown in the first example, not all openings 21 necessarily need to be shaped to have a different shape. However, at least some openings 21 between the plurality of openings 21 may be shaped to have a different shape and may have a different depth H in the direction of the radius of the impeller 12 on the side of the discharge A. In addition, all openings 21 may be shaped differently and the depths H thereof in the direction of the radius of the impeller 12 on the side of the discharge A may differ from each other. In all openings 21, respective lengths L in a circumferential direction of the impeller 12, widths D in the direction of the rotating shaft 13 and distances T between adjacent openings 21 are identical.

In the tangential fan shown in the first example, the tongue 18 is provided with a plurality of openings 21 in such a way that the cross-section of the tongue 18 on a surface perpendicular to the circumferential direction of the impeller 12 is shaped in the form of a comb. In addition, at least some openings 21 between the plurality of openings 21 have a different depth H in the direction of the impeller radius 12. Therefore, it is possible to change the pressure cup in each of the openings 21 and change the flow rate and the direction of the leakage rate from the discharge side (high pressure side) A to the suction side (low pressure side) B for each position of the openings 21. Therefore, given that an interference position between the leakage rate and the impeller blade 15 differs in each of the openings 21, an area correlated with pressure fluctuation (an area of a region having synchronism) can be reduced, and the noise of the tangential fan can be reduced while maintaining efficiency.

Because the leakage rate differs for each position of the openings 21, a suction flow and a leakage flow converge on each other, and the tension and position of the cutoff disturbances of the flow flowing in the impeller 12 differ in the circumferential direction of the impeller 12. Therefore, an area correlated with the pressure fluctuation (an area of a region that has synchronism) is reduced, which makes it possible to reduce the noise.

In the tangential fan, a flow rate is reduced in the vicinity of the side plates 14 provided at both ends in a direction of the rotating shaft 13 of the impeller 12 and in the middle thereof. When a leakage rate is large in the region of low flow rate, an inverse flow is easily produced, thereby decreasing efficiency. Therefore, the openings 21, in which the depths H on the side of the discharge A are small, are provided in the region of low flow flowing to the impeller 12, and the openings 21, in which the depths H On the discharge side A are large, they are provided in a high flow region. Therefore, it is possible to provide a tangential fan without a reduction in efficiency caused by an inverse flow and without increasing the noise in any position in the direction of the rotating shaft 13 of the impeller 12. That is, the depths H of the openings 21 on the side of the discharge A they can be decreased in the vicinity of the side plates 14 provided at both ends and in the middle of the rotating shaft 13 of the impeller 12, and the depths H of the openings 21 on the side of the download A in other regions.

Figure 4 is a sectional view of the front part on a surface perpendicular to the circumferential direction of the tangential fan impeller according to the first example.

In Fig. 2B, the openings 21 are illustrated, whose cross sections on a surface perpendicular to the circumferential direction of the impeller 12 are shaped rectangular. However, the cross sections of the openings 21 can be shaped in any way. That is, the cross-sectional surfaces of the openings 21 may be shaped in a triangle shape shown in Figure 4A or in a trapezoidal shape shown in Figure 4B. In addition, several types of shapes can be combined in cross section. Similarly, the cross section on a surface perpendicular to the direction of the impeller radius can be shaped in any way. That is, the cross section can be formed with a rectangular shape, a triangle shape, or a trapezoidal shape. In addition, several types of shapes can be combined in cross section. When several types of shapes are combined in cross section, the pressure cup of each opening 21 can be changed.

In the tangential fan shown in the first example, the lengths L in the circumferential direction of the impeller 12, the widths D in the direction of the rotating shaft 13 and the distances T between the adjacent openings 21 are set to be respectively identical in all openings 21. However, the lengths L in one direction

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circumferential of the impeller 12, the widths D in the direction of the rotating shaft 13 and the distances T between the adjacent openings 21 may differ from each other.

Second example

In the first example the air conditioner using the tangential fan is shown in which at least some openings between the plurality of openings have a different depth H in the direction of the impeller radius 12. In a second example a conditioner is shown of air using a tangential fan in which at least some openings between a plurality of openings have a different length L in a circumferential direction of the impeller 12.

Figure 5 is a sectional view of a front part on a surface perpendicular to the rotating axis of the tangential fan according to the second example and Figure 6 is a perspective view of the front part of the tangential fan according to the second example.

As shown in Figures 5 and 6, a tongue 18 has a plurality of openings 22 arranged in the direction of the rotating shaft 13 of the impeller 12 such that the cross section of the tongue 18 on a surface (which includes the rotating shaft 13 of the impeller 12) perpendicular to the circumferential direction of the impeller 12 is formed with a comb shape. Some openings 22 between the plurality of openings 22 are shaped in a different way and have a different length L in the circumferential direction of the impeller 12. The remaining openings 22 are shaped in the same way and have an identical length L in the circumferential direction of the impeller 12. With the exception above, the construction and functions of the air conditioner are the same as those of the air conditioner shown in the first example.

In the tangential fan shown in the second example, all openings 22 may have the same shape, but at least some of the openings 22 between the plurality of openings 22 may be shaped to have a different shape and a different length L in the circumferential direction of the impeller 12. In addition, all openings 22 may be shaped to have a different shape from each other, and the lengths L thereof in the circumferential direction of impeller 12 may differ from each other in all openings 22. More even, in all openings 22 the respective depths H in the direction of the radius of the impeller 12, the widths D in the direction of the rotating axis 13 and the distances T between the adjacent openings 22 are identical.

In the tangential fan shown in the second example, the tongue 18 is provided with a plurality of openings 22 such that the cross section thereof on a surface perpendicular to the circumferential direction of the impeller 12 is formed in a comb shape, and at least some openings 22 between the plurality of openings 22 have a different length L in the circumferential direction of the impeller 12. Therefore, by changing the length one can change the pressure cup in each of the openings 22, and the flow rate and the direction of the leakage flow from the discharge side (high pressure side) A to the suction side (low pressure side) B may be different for each position of the openings 22. Therefore, since an interference position between the leakage rate and the impeller blade 15 differs in each of the openings 22, an area correlated with pressure fluctuation can be reduced (an area of a region which has synchronism), and the noise of the tangential fan can be reduced while maintaining efficiency.

Because the leakage rate differs for each position of the openings 22, a suction flow and a leakage flow converge on each other, and the tension and position of the cutoff disturbances of the flow flowing in the impeller 12 differ in the circumferential direction of the impeller 12. Therefore, an area correlated with the pressure fluctuation (an area of a region that has synchronism) is reduced, which makes it possible to reduce the noise.

Figure 7 is a perspective view of the front of the tangential fan according to the second.

In the tangential fan shown in Figure 6, the lengths L of the openings 22 in the circumferential direction of the impeller 12, are irregularly changed in the direction of the rotating shaft 13. However, although the lengths L of the openings 22 in The circumferential direction of the impeller 12 is changed on a regular basis as shown in Figure 7, it is possible to obtain the same effect as with the lengths L irregularly changed.

In addition, the openings 22, in which the lengths L in the circumferential direction of the impeller 12 are small, are provided in a region of low flow flowing through the impeller 12, and the openings 22, in which the lengths L in The circumferential direction of the impeller 12 is large, provided in a high flow region, which makes it possible to provide a tangential fan without a reduction in efficiency caused by an inverse flow and without increasing the noise at any position in the direction of the axis. rotating 13 of the impeller 12. That is, the lengths L of the openings 22 in the vicinity of the side plates 14 provided at both ends and in the middle of the rotating shaft 13 of the impeller 12 can be decreased, and the lengths L can be increased of openings 22 in other regions.

In the tangential fan shown in the second example, the depths H in the direction of the radius of the impeller 12, the widths D in the direction of the rotating shaft 13 and the distances T between the adjacent openings 22 are set to be respectively identical in all openings 22. However, the depths H in the direction

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of the radius of the impeller 12, the widths D in the direction of the rotating shaft 13 and the distances T between the adjacent openings 22 may differ respectively.

Third Example

In the first example the air conditioner using the tangential fan is shown in which at least some openings between the plurality of openings have a different depth H in the direction of the impeller radius 12. In a third example, a air conditioner using a tangential fan in which at least some openings between a plurality of openings have a different width D in a direction of the rotating shaft 13 of the impeller 12.

Figure 8 is a perspective view illustrating a front part of a tangential fan according to the third example.

As shown in Figure 8, a tongue 18 has a plurality of openings 23 arranged in the direction of the rotating shaft 13 of the impeller 12 such that the cross-section of the tongue 18 on a surface (which includes the rotating shaft 13 of the impeller 12) perpendicular to the circumferential direction of impeller 12 conforms to a comb shape. Some openings 23 between the plurality of openings 23 are shaped to have a different shape and a different width D in the direction of the rotating shaft 13 of the impeller 12. The remaining openings 23 are shaped to have the same shape and a width D identical in the direction of the rotary axis 13 of the impeller 12. With the exception above, the construction and functions of the air conditioner are the same as those of the air conditioner shown in the first example.

In the tangential fan shown in the third example, all openings 23 may be shaped in the same way, but at least some of the openings 23 between the plurality of openings 23 may be shaped to have a different shape and may have a width D different in the direction of the rotating shaft 13 of the impeller 12. In addition, all openings 23 may be shaped to have a different shape from each other, and the widths D in the direction of the rotating shaft 13 of the impeller 12 may differ from each other. in all openings 23. In all openings 23 the depths H in the direction of the impeller radius 12, the lengths L in the circumferential direction thereof, and the distances T between the adjacent openings 23 are respectively identical.

In the tangential fan shown in the third example, the tongue 18 is provided with a plurality of openings 23 such that the cross section of the tongue 18 on a surface perpendicular to the circumferential direction of the impeller 12 is shaped in the form of a comb and at least some openings 23 between the plurality of openings 23 have a different width D in the direction of the rotary axis 13 of the impeller 12. Therefore, the pressure cup in each of the openings 23 can be changed, and the flow rate and the direction of the leakage flow from the discharge side (high pressure side) A to the suction side (low pressure side) B may be different for each position of the openings 23. Therefore, since an interference position between the leakage rate and the impeller blade 15 differs in each of the openings 23, an area correlated with pressure fluctuation can be reduced (an area of a region that has sync ronismo), and the noise of the tangential fan can be reduced while maintaining efficiency.

Because the leakage rate differs for each position of the openings 23, a suction flow and a leakage flow converge on each other, and the tension and position of the cutoff disturbances of the flow flowing in the impeller 12 differ in the circumferential direction of the impeller 12. Therefore, an area correlated with the pressure fluctuation (an area of a region that has synchronism) is reduced, which makes it possible to reduce the noise.

In the fan rotor shown in the third example, the thickness of a material of which the tongue 18 is composed is uniform, compared to the tangential fans shown in the first and second embodiments. Therefore, it is possible to easily mold the tangential fan.

In the third example, the widths D of the openings 23 in the direction of the rotating shaft 13 are irregularly changed, as shown in Figure 8. However, although the widths D of the openings 23 in the direction of the rotating shaft 13 are changed regularly in the direction of the rotating shaft 13, it is possible to obtain the same effect as with the widths that are changed irregularly.

The openings 23, in which the widths D in the direction of the rotating shaft 13 are small, are provided in a region of low flow that circulates through the impeller 12, and the openings 23, in which the widths D in the direction of the rotating shaft 13 are large, are provided in a high flow region. Therefore, it is possible to provide a tangential fan without a reduction in efficiency caused by an inverse flow and without increasing the noise in any position in the direction of the rotating shaft 13 of the impeller 12. That is, the widths D of the openings 23 they can be reduced in the vicinity of the side plates 14 provided at both ends and in the middle of the rotating shaft 13 of the impeller 12, and the widths D of the openings 23 in other regions can be increased.

In the tangential fan shown in the third example, the depths H in the direction of the radius of the impeller 12, the lengths L in the circumferential direction and the distances T between the adjacent openings 23 are set to

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be respectively identical in all openings 23. However, the depths H in the direction of the radius of the impeller 12, the lengths L in the circumferential direction and the distances T between the adjacent openings 23 may differ respectively.

First realization

In the first example the air conditioner using the tangential fan is shown in which some openings between the plurality of openings have a different depth H in the direction of the impeller radius 12. In a first embodiment of the invention, a air conditioner that uses a tangential fan in which some openings between a plurality of openings are provided with a rib.

Figure 9 is a perspective view of the front part of a tangential fan according to the first embodiment of the invention, and Figure 10 is a sectional view of the front part on a surface perpendicular to the rotating axis of the tangential fan according to the first realization of the invention.

As shown in Figures 9 and 10, a tongue has a plurality of openings 24 arranged in the direction of the rotating shaft 13 of the impeller 12 such that the cross section of the tongue 18 on a surface (which includes the rotating shaft 13 of the impeller 12) perpendicular to the circumferential direction of the impeller 12 is formed with a comb shape. The plurality of openings 24 is provided with ribs 25 that block the leakage rate in order to hide portions of the openings 24. In addition, some openings 24 between the plurality of openings 24 are shaped to have a different shape, and the positions of the ribs 25 differ in the circumferential direction of the impeller 12. The remaining openings 24 are shaped in the same way, and the positions of the ribs 25 are identical in the circumferential direction of the impeller 12. With the exception, the construction and functions of the Air conditioners are the same as those of the air conditioner shown in the first example.

In the tangential fan shown in the first embodiment, not all openings 24 necessarily need to be formed to have a different shape, but at least some openings 24 between the plurality of openings 24 may be formed to have a different shape and the positions of the ribs 25 may differ in the circumferential direction of the impeller 12. In addition, all openings 24 may be shaped to have a different shape and the positions of the ribs 25 in the circumferential direction of the impeller 12 may differ from each other in all the openings 24. In all openings 24, the depths H in the direction of the radius of the impeller 12, the lengths L in the circumferential direction thereof, the widths D in the direction of the rotating shaft 13 and distances T between the adjacent openings 24 They are respectively identical.

In the tangential fan of the first embodiment, the tongue 18 is provided with a plurality of openings 24 such that the cross section of the tongue 18 on a surface perpendicular to the circumferential direction of the impeller 12 is shaped in the form of a comb. In addition, the plurality of openings 24 have the ribs 25, and the positions of the ribs 25 of at least some openings 24 differ in the circumferential direction of the impeller 12. Therefore, the pressure cavity can be changed in each of the openings 24 and the flow rate and the direction of the leakage rate from the discharge side (high pressure side) A to the suction side (low pressure side) B may be different for each position of the openings 24. By therefore, since an interference position between the leakage rate and the impeller blade 15 differs in each of the openings 24, an area correlated with pressure fluctuation (an area of a region having synchronism) can be reduced, and the noise of the tangential fan can be reduced while maintaining efficiency.

Because the leakage rate differs in each position of the openings 24, a suction flow and a leakage flow converge into each other, and the tension and position of the cutoff disturbances of the flow flowing in the impeller 12 differ in the circumferential direction of the impeller 12. Therefore, an area correlated with the pressure fluctuation (an area of a region that has synchronism) is reduced, which makes it possible to reduce the noise.

In the air conditioner shown in the first embodiment, the water generated at the time the air conditioner is in operation can be collected by the rib 25 as well as by the surface tension of the opening 24, which makes it possible to reinforce the water retention force. Therefore, the accumulation of droplets is minimized.

Figure 11 is a perspective view of the front part of the tangential fan according to the first embodiment of the invention.

In the first embodiment, the positions of the ribs 25 in the circumferential direction of the impeller 12 are irregularly changed in the direction of the rotating shaft 13, as shown in Figure 9. However, although the positions of the ribs 25 in The circumferential direction of the impeller 12 is changed regularly in the direction of the rotating shaft 13 as shown in Figure 11, it is possible to produce the same effect as when the positions are changed irregularly.

Figure 12 is a sectional view of the front part on a surface perpendicular to the axis of rotation of the tangential fan according to the first embodiment of the invention.

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In the tangential fans shown in Figures 9 and 10, the positions of the ribs 25 in the plurality of openings 24 are changed, and the flow rate and direction of the leakage flow are changed. However, even though all the ribs 25 of the openings 24 are provided in the same position, the angles of the ribs 25 are changed and the flow rate and direction of the leakage flow are changed as shown in Figures 12A and 12B, it is It is possible to produce the same effect as that of the tangential fans shown in Figures 9 and 10.

Figure 13 is a sectional view of the front part of the tangential fan according to the first embodiment of the invention. Specifically, Figure 13A is a sectional view of the front part on a surface perpendicular to the axis of rotation of the tangential fan according to the first embodiment of the invention, and Figure 13B is a sectional view of the front part of the tangential fan on a surface (a surface that includes the rotating axis, that is, a cross-section taken along the line F-F of Figure 13A) perpendicular to the circumferential direction of the tangential fan impeller according to the first embodiment of the invention.

In Figure 13, all the ribs 25 of the openings 24 are positioned in the same position, similar to the ribs shown in Figure 12. In addition, the heights Hr of the ribs 25 are changed, and the flow and direction of the leakage flow Although the ribs 25 of the openings 24 are positioned in the same position and the heights Hr of the ribs are changed it is possible to produce the same effect as that of the tangential fans shown in Figures 9 and 10.

The ribs 25 do not need to be installed in all the openings 24, but they can be installed in only some of the openings 24. Also, when the ribs 25 are installed in only some openings 24, the respective positions, angles and heights of the ribs 25 in the circumferential direction of the impeller 12 they can be identical in the openings 24. Since only some openings 24 have the rib 25, the pressure cup can be changed by the presence or absence of the ribs 25, and the flow and direction of the leakage rate from the discharge side (high pressure side) A to the suction side (low pressure side) B may be different for each position of the openings 24. Therefore, since an interference position between the leakage rate and impeller blade 15 differs in each of the openings 24, an area correlated with pressure fluctuation (an area of a region having synchronism) can be reduced, and Tangential fan noise can be reduced while maintaining efficiency. Also, because the leakage rate differs for each position of the openings 24, a suction flow and a leakage flow converge on each other, and the tension and position of the cutoff disturbances of the flow flowing in the impeller they differ in the circumferential direction of the impeller 12. Therefore, an area correlated with the pressure fluctuation (an area of a region that has synchronism) is reduced, which makes it possible to reduce the noise. Therefore, in the tangential fan shown in the first embodiment, at least some openings 24 may have the rib 25.

In the tangential fan shown in the first embodiment, the depths H in the direction of the radius of the impeller 12, the lengths L in the circumferential direction, the widths D in the direction of the rotating shaft 13 and the distances T between adjacent openings 24 are set to be respectively identical in all openings 24. However, the depths H in the direction of the impeller radius 12, the lengths L in a circumferential direction, the widths D in the direction of the rotating axis 13 and the distances T between the Adjacent openings 24 may differ respectively.

Claims (4)

1. A tangential fan comprising: - an impeller (12); Y - a tongue (18) provided along a portion of the outer circumference of the impeller (12), in which the tongue is provided with a plurality of openings (21) such that a cross section of the tongue (18) on a surface perpendicular to the circumferential direction of the impeller (12) is shaped in a comb shape, and in which at least one opening (21) of the plurality of openings (21) is shaped in a different way , characterized by that 10 the at least one opening (21) has a rib (25) in which the at least one opening (21) is at least partially hidden. 2. The tangential fan according to claim 1, wherein, in the at least one opening (21), the position of the rib (25) is different in the circumferential direction of the impeller (12). 3. The tangential fan according to claim 1, wherein, in the at least one opening (21), the rib has a different height (Hr). 4. The tangential fan according to claim 1, wherein, in the at least one opening (21), the angle of the rib (25) is different.