JP2005171987A - Small-sized mixed flow fan motor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a small-sized mixed flow fan motor with increase in the static pressure of the fan motor and by motor revolution at a lower noise level than the conventional case, without reducing the wind volume. <P>SOLUTION: The small-sized mixed flow fan motor is equipped with a casing 10, an impeller 14 revolved by a motor 11, and a hub 12 belonging to the motor 11. In this equipment, a flow channel 18 with an air suction port 19 and an air discharge port 20 is formed into an almost round shape by means of the hub 12 and air-guide covers 17 installed around the hub 12. The hub 12 has the shape of a circular cone that expands toward the air discharge port 20, with its sharply pointed tip removed, while the section of an air-guide cover 17 is roughly in a wing form. The motor 11 is supported by the casing 10 through a support piece 16, which extends toward the exterior in the radius direction, while the support piece 16 is placed at a position belonging to the air suction port 19 in the flow channel 18. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a small mixed flow fan motor including a casing, an impeller rotated by a motor, and a hub belonging to the motor.

  The mixed flow fan motor is configured to send air between, for example, a conical cup and a casing provided with an inclined surface corresponding to the cup on the inner peripheral side. Since it is difficult to distinguish from a motor, it is sometimes referred to as a “half-axis blower”.

FIG. 3 is an axial cross-sectional view illustrating a small mixed flow fan motor according to the prior art.
Similar to the axial fan motor, the mixed flow fan motor shown in FIG. 3 is generally constituted by a casing 100 and a motor 101 incorporated in the casing 100.

  The hub 102 belonging to the motor 101 forms an impeller 104 from the hub 102 and a plurality of blades 103 formed directly on the hub 102. The impeller 104 is rotatably supported by the motor 101 so as to be rotatable with respect to the rotation shaft 105. The motor 101 is supported on the casing 100 by a support piece 106 that extends outward in a substantially radial direction.

  In any case of the mixed flow fan motor and the axial flow fan motor, the motor 101, the electric rectification mechanism (only when provided in the motor), the impeller 104, and the casing 100 are integrated. The motor 101 is an outer rotor type motor in which a rotor rotates around a stator disposed on the inner side. With this configuration, a very small motor 101 can be obtained.

  This is because the impeller 104 can be directly fixed to the rotor arranged outside the stator. As the motor 101 itself, in the case of alternating current driving, a scraping motor or a condenser motor (however, the condenser motor is only in the case of high output) is usually used. A motor or a brushless DC motor is used.

  In the case of a mixed flow fan motor, air is sucked in the axial direction, while being exhausted obliquely to the shaft. Further, the hub 102 is formed in a substantially conical shape, and air can be exhausted in a range of 0 ° to 90 ° with respect to the rotating shaft by circulating air outside the casing 100 by a predetermined method. . In particular, the peripheral speed of the hub 102 required to generate the static pressure can be increased by expanding the outer diameter of the hub 102 in the direction of air flow.

  For this reason, when compared with the same external dimensions and the same rotation speed, the static flow fan motor can improve the static pressure higher than the axial flow fan motor. Accordingly, it is a mixed flow fan motor that attracts more users' interest, and this mixed flow fan motor is frequently used particularly in the field of telecommunications. The reason is that as the integration of related parts or components of telecommunications related products progresses, the air circulation resistance in the enclosure in which they are housed tends to increase.

  Accordingly, there is a demand for a small fan motor having higher performance. However, until now, it has been relatively rare to adopt a mixed flow system for a small fan motor. The reason is considered that the structure of the impeller is complicated in the case of the mixed flow type fan motor.

  As already described, the stator of the outer rotor type motor is usually fixed to the casing by a plurality of support pieces. In the case of an axial fan motor, it is known that these support pieces are arranged at the intake port or the exhaust port.

  In the axial fan motor, the arrangement of the support piece hardly affects the generated noise level due to the rotation of the impeller or the fan. The reason is that, in the case of an axial fan motor, unlike the case of a mixed flow fan motor, even if the support piece is arranged at the intake or exhaust port, there is no change in the cross-sectional shape of the air flow path. It is because it does not.

  By the way, most small axial fan motors have a structure in which the blown wind passes around the support piece for various reasons. And the conventional small mixed flow fan motor is also the structure where the wind sent out passes the circumference | surroundings of a support piece. That is, the support piece of the conventional small fan motor is provided on the exhaust port side.

  Also, in the mixed flow fan motor, the cross-sectional area (cross-sectional shape) of the air flow path from the intake port to the exhaust port is reduced toward the intake port direction. The area (cross-sectional shape) changes so as to be enlarged. Therefore, the conventional small mixed flow fan motor has a problem that high level noise is likely to occur due to the rotation of the impeller or the fan.

  The present invention has been made in order to solve the above-described problems, and is a small mixed flow fan motor having a lower noise level than that of the conventional small mixed flow fan motor with a high static pressure and a reduced air volume. The purpose is to provide.

  In order to solve the above-described problems, a small mixed flow fan motor of the present invention is a small mixed flow fan motor including a casing, an impeller rotated by the motor, and a hub belonging to the motor. The air guide cover that is disposed to surround the flow path constitutes a substantially annular flow path having an intake port and an exhaust port, and the hub has a conical shape that expands toward the exhaust port. The air guide cover has a shape in which the acute angle portion is removed, the cross section is formed in a substantially airfoil shape, and the motor is supported on the casing by a support piece extending outward in a substantially radial direction; A support piece is arrange | positioned in the position which belongs to the inlet in a flow path, It is characterized by the above-mentioned.

  In the small mixed flow fan motor of the present invention, since the support piece is disposed on the intake port side of the flow path and the impeller can be disposed on the exhaust port side of the flow path, compared with the conventional small mixed flow fan motor, Even with the same outer dimensions, the outer diameter of the impeller can be increased, and therefore the rotational speed can be reduced when obtaining the same air volume as in the prior art. Therefore, in the small mixed flow fan motor of the present invention, the static pressure of the conventional small mixed flow fan motor can be maintained high, and the noise level can be reduced without reducing the air volume.

  Embodiments of the present invention will be described below with reference to the drawings schematically showing the embodiments of the present invention.

FIG. 1 is an axial sectional view showing a small mixed flow fan motor according to an embodiment of the present invention, and FIG. 2 is a perspective view showing the small mixed flow fan motor of FIG.
The small mixed flow fan motor shown in FIG. 1 and FIG. 2 is generally composed of a casing 10 and a motor 11 incorporated in the casing 10. The hub 12 belonging to the motor 11 constitutes an impeller 14 from the hub 12 and a plurality of blades 13 formed directly on the hub 12. The impeller 14 is pivotally supported by the motor 11 so as to be rotatable by the rotation shaft 15. Further, the motor 11 is supported by the casing 10 by a support piece 16 that extends approximately outward in the radial direction.

  The casing 10 includes an air guide cover 17 formed corresponding to the outer diameter of the impeller 14. The hub 12 constitutes a boundary portion of the substantially circular flow path 18 by an air guide cover 17 disposed so as to surround the impeller 14. An intake port 19 and an exhaust port 20 are formed in the flow path 18. The air is sucked from the air inlet 19, passes through the fan motor in the direction of the air blowing direction 22, and is then exhausted from the air outlet 20.

  The hub 12 generally has a conical shape in which an acute angle portion at the tip is removed and expands toward the exhaust port 20. Similarly, the air guide cover 17 is roughly formed in a wing shape in cross section, and the inner diameter (diameter) dimension thereof increases toward the exhaust port 20. The air inlet 19 of the air guide cover 17 is formed with a shape rounded outward in the radial direction by the air guide curved surface portion 21 below the boundary of the air inlet 19 of the flow path 18. By forming this rounded shape on the air guide curved surface portion 21, turbulent air flow from the suction side can be avoided.

  The inclination angle of the air guide cover 17 in the direction of the exhaust port 20 with respect to the rotation shaft 15 is preferably larger than the inclination angle of the surface of the hub 12. By doing so, the outer diameter of the annular flow path 18, particularly corresponding to the impeller 14, can be enlarged toward the exhaust port 20.

  When viewed from the viewpoint of air flow by the inventor of the present invention, unlike the axial fan motor, in the small mixed flow fan motor, it is preferable that the support piece 16 that supports the motor 11 is disposed on the intake port 19 side. Something was found.

This will be described with reference to FIGS. FIG. 3 is an axial cross-sectional view showing a small mixed flow fan motor according to the prior art as described above.
In the case of this conventional fan motor, the support piece 106 is disposed on the exhaust port side. From this, the stationary part of the motor 101 is also arranged on the exhaust port side, while the impeller 104 and the hub 102 are arranged on the intake port side. In this case, the blade 103 is fixed to a small diameter portion of the hub 102 on the intake port side.

FIG. 1 is an axial sectional view showing a small mixed flow fan motor according to an embodiment of the present invention as described above.
In the case of the small mixed flow fan motor of the present embodiment, the support piece 16 is disposed on the intake port 19 side. Compared with the conventional small mixed flow fan motor shown in FIG. 3, both wall surfaces of the outer periphery of the hub 12 and the inner periphery of the air guide cover 17 are inclined. It can be seen that an impeller 14 having a larger outer diameter is obtained. This is because in the case of the present embodiment, the plurality of blades 13 belonging to the impeller 14 are fixed to the large-diameter portion on the exhaust port side of the hub 12. In the illustrated example, the outer diameter dimension of the impeller 14 shown in FIG. 1 is approximately 20% larger than the outer diameter dimension of the impeller 104 shown in FIG.

  When the outer diameter of the impeller 14 is increased by 20%, the performance (air volume, static pressure) of the small mixed flow fan motor is greatly affected.

The factors that determine the air volume of the fan motor, in other words, the volume of the blown air, are the rotational speed and outer diameter of the impeller 14. When the outer diameter dimension of the impeller 14 is expanded, the air volume is also increased by an amount corresponding to the fifth power of the coefficient of the expanded outer diameter dimension. For example, when the rotational speed is deferred and the outer diameter of the impeller 14 is increased by 10% (coefficient 1.10), since 1.10 ⁵ = 1.61, the air volume is 61%. It means that only the original air volume will be increased.

Another factor that affects airflow is the number of fan rotations. The air volume changes by an amount corresponding to the cube of the coefficient of the rotational speed. For example, according to the example described above, in the case of a fan motor in which the outer diameter of the impeller 14 is increased by 10%, the air volume is increased by 61%. Therefore, the outer diameter of the impeller 14 is increased by 10%. The number of rotations for obtaining the same air volume as that of the non-fan motor is (1 / 1.61) ^1/3 = 0.85. Since 0.85 is 0.85 = 1.0−0.15, it can be seen that the rotational speed may be reduced by 15% in order to obtain an air volume equivalent to the conventional one.

In the fan motor, the noise level can be reduced when only the number of revolutions is reduced while leaving other driving conditions unchanged. The following formula usually holds:
L _W = A log (N ₁ / N ₂ )
here,
L _W = noise level (dB)
A = 50 to 55 (constant calculated from experience)
N ₁ = rated speed N ₂ = reduced speed.

Considering the case where the number of revolutions is reduced by the above 15% using the above formula, it can be seen that the noise level of the fan motor can be reduced as in the following formula.
L _W = 50 (to 55) log (1.0 / 0.85)
= 3.5 dB (or 3.9 dB)

  The fact that the noise level can be reduced by 3.5 dB to 3.9 dB means that the noise level can be reduced to half or less of the initial level. Therefore, by using the small mixed flow fan motor of the present embodiment, the same air volume can be obtained even if the rotational speed of the fan is reduced. It is preferable for reducing the above.

  However, regarding the noise level, various other factors need to be considered. One of the factors is a noise level related to the outer diameter of the impeller 14 itself. However, in general, even if the outer diameter of the impeller 14 (for example, the radius D in FIG. 1) is increased, it is more effective in reducing the noise level to decrease the rotational speed of the fan. This can be explained using the fact that the tangential speed of the impeller 14 is linearly proportional to both its radius and rotational speed.

For example, in the case of the above example (the outer diameter of the impeller 14 is increased by 10% and the rotational speed is reduced by 15%), the outer diameter of the impeller is the original outer diameter and the rotational speed is also the initial rotation. Compared with the case of a number, the tangential speed of the impeller 14 is 6.5% slower as in the following equation.
1.10 x 0.85 = 0.935
= 1-0.065

  Briefly described above, the small mixed flow fan motor of the present embodiment shown in FIGS. 1 and 2 is shown in FIG. 3 having the same external dimensions and air volume (increase in air capacity and static pressure). Compared to the conventional small mixed flow fan motor, it can be driven at a lower rotational speed and a lower noise level.

  The small mixed flow fan motor of this embodiment is a mixed flow fan motor including a casing 10, an impeller 14 rotated by the motor 11, and a hub 12 belonging to the motor 11, and surrounds the hub 12 and the hub 12. The air guide cover 17 arranged in the above form a flow path 18 having an intake port 19 and an exhaust port 20 formed in a substantially annular shape, and the hub 12 has a conical shape that expands toward the exhaust port 20. The air guide cover 17 has a shape in which the acute angle portion of the tip is removed, and the cross section of the air guide cover 17 is formed in a substantially airfoil shape, and the motor 11 is extended to the outer side in the substantially radial direction. 16 is supported by the casing 10, and the support piece 16 is disposed at a position belonging to the air inlet 19 in the flow path 18.

  Further, in the small mixed flow fan motor of the present embodiment, the blade 13 of the impeller 14 may be fixed at a place where the outer diameter of the hub 12 is maximum, and the impeller 14 is connected to the exhaust port in the flow path 18. 20 may be arranged at a position belonging to 20, and the flow path 18 may be formed to extend at an acute angle radially outward in the cross section of the flow path 18 with respect to the rotation shaft 15 of the impeller 14. Good. Further, in the small mixed flow fan motor of the present embodiment, the flow path 18 may have its cross-sectional area reduced toward the intake port 19, and the air guide cover 17 may have an inner diameter (diameter) of the exhaust port. The air guide cover 17 may be enlarged, and the air inlet 19 of the air guide cover 17 may be provided with an air guide curved surface portion 21 having a shape rounded outward in the radial direction. Good. Furthermore, in the small mixed flow fan motor of this embodiment, the motor 11 is an outer rotor type motor, the stationary part of the motor 11 is supported by the casing 10, and the rotor belonging to the motor 11 includes the impeller 14. 12 may be comprised.

  A feature of the present embodiment is that a support piece 16 for fixing the motor 11 is disposed at the air inlet 19 of the casing 10. By doing so, the impeller 14 can be made larger without changing the external dimensions of the small mixed flow fan motor. When the impeller 14 becomes larger, the air volume also increases. Therefore, when obtaining the same air volume as that of the conventional small mixed flow fan motor, the rotational speed may be lower than that of the conventional small mixed flow fan motor. By reducing the rotational speed of the blade 13 (fan), it is possible to reduce the noise level, which is the object of the present invention.

  In this embodiment, by disposing the support piece 16 on the intake port 19 side, the blades 13 belonging to the impeller 14 can be fixed in the vicinity of the exhaust port 20, that is, at the place where the outer diameter of the hub 12 is the largest. . As a result, the outer diameter of the entire impeller 14 can be increased.

  In the mixed flow fan motor, the cross section of the air flow path 18 is extended at an acute angle outward in the radial direction with respect to the rotating shaft 15 of the impeller 14. As a result, the air flowing through the mixed flow fan motor is exhausted in an oblique direction with respect to the rotating shaft 15. One of the factors that cause an increase in static pressure, which is improved in the mixed flow fan motor as compared with the axial flow fan motor, is that the cross section of the air flow path 18 is enlarged toward the exhaust port 20. It is that you are.

  Further, in the small mixed flow fan motor of the present embodiment, the portion of the air guide cover 17 on the air inlet 19 side is rounded outward in the radial direction in order to further suppress the noise level of the impeller 14. The shape (air guide curved surface portion 21) is formed.

  In the small mixed flow fan motor of the present embodiment, the motor 11 is an outer rotor type motor, the stationary part belonging to the motor 11 is supported by the casing 10 by the support piece 16, and the rotor moves the impeller 14. The hub 12 is provided.

  As described above, in the small mixed flow fan motor of the present embodiment, the support piece is disposed on the intake port 19 side of the flow path 18 and the impeller 14 can be disposed on the exhaust port 20 side of the flow path 18. Compared with a flow fan motor, the outer diameter of the impeller 14 can be increased even with the same outer dimensions, and the rotational speed can be reduced when obtaining the same air volume as the conventional one. Therefore, in the small mixed flow fan motor of the present embodiment, the noise level can be reduced while maintaining the high static pressure characteristic and the air volume of the conventional small mixed flow fan motor. Further, in the small mixed flow fan motor of the present embodiment, the air guide curved surface portion 21 having a shape rounded toward the outside in the radial direction is provided on the air inlet 19 side of the air guide cover. The level can be lowered further.

It is an axial sectional view showing a small mixed flow fan motor of an embodiment of the present invention. It is a perspective view which shows the small mixed flow fan motor of FIG. It is an axial sectional view showing a conventional small mixed flow fan motor.

Explanation of symbols

10 casing,
11 Motor,
12 hubs,
13 feathers,
14 impeller,
15 rotation axis,
16 support pieces,
17 Air guide cover,
18 channels,
19 (air) inlet,
20 (air) exhaust,
21 air conduction curved surface,
22 Blowing direction,
100 casing,
101 motor,
102 hub,
103 feathers,
104 impeller,
105 rotation axis,
106 Support piece.

Claims (8)

A small mixed flow fan motor comprising a casing, an impeller rotated by a motor, and a hub belonging to the motor,
The hub and the air guide cover arranged to surround the hub constitute a flow path formed in a substantially annular shape with an intake port and an exhaust port, and
The hub has a conical shape that expands toward the exhaust port, and has a shape from which the acute angle portion of the tip is removed, and
The air guide cover has a substantially wing-shaped cross section, and
The motor is supported by the casing by a support piece extending outward in a substantially radial direction,
The support piece is disposed at a position belonging to the air inlet in the flow path. A small mixed flow fan motor. The small mixed flow fan motor according to claim 1, wherein the blades of the impeller are fixed at a place where the outer diameter of the hub is maximized. The small impeller fan motor according to claim 1 or 2, wherein the impeller is arranged at a position belonging to the exhaust port in the flow path. The said flow path is formed by extending | stretching at an acute angle toward the radial direction outer side in the cross section of the said flow path with respect to the rotating shaft of the said impeller. A small mixed flow fan motor described in 1. 5. The small mixed flow fan motor according to claim 1, wherein a cross-sectional area of the flow path is reduced toward the intake port. The small airflow fan motor according to any one of claims 1 to 5, wherein the air guide cover has a diameter that increases toward the exhaust port. The air guide curved surface part in which the shape rounded toward the outer side of a radial direction is formed in the said inlet side of the said air guide cover is provided. In any one of Claims 1-6 characterized by the above-mentioned. Small mixed flow fan motor as described. The motor is an outer rotor type motor,
The stationary part of the motor is supported by the casing,
The rotor which belongs to the said motor is comprised by the hub provided with the said impeller. The small mixed flow fan motor of any one of Claims 1-7 characterized by the above-mentioned.

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