JP2019019805A - Fan and fan unit - Google Patents

Abstract

To provide a fan that can sufficiently reduce aerodynamic noise that is generated corresponding to rotation of a fan blade.SOLUTION: A fan 10 includes: a fan blade 11; a fan casing 12 for storing the fan blade 11; and a silencer 13 formed integrally with the fan casing 12 downstream of the fan blade 11. A length Lof each hollow tube 13a of the silencer 13 is set to a length capable of decaying a peak frequency component fn of fan noise that is generated at a rotation number N of the fan blade 11.SELECTED DRAWING: Figure 1B

Description

  The present invention relates to a fan and a fan unit including a fan case that covers the fan.

  Centrifugal fans and axial fans (hereinafter simply referred to as “fans”) usually include a casing that covers fan blades that are rotating blades. When the fan blades rotate, pressure fluctuation occurs inside the casing, and aerodynamic noise (hereinafter referred to as “fan noise”) due to the pressure fluctuation is generated. The fan noise generally has a peak frequency component fn corresponding to the rotational speed N of the fan blade. Incidentally, the ink jet recording apparatus 80 as shown in FIG. 8 includes a fan 83 for sucking the paper 81 to the platen 82, and the fan 83 is provided with a plurality of suction ports 85 that open to the platen 82 through the duct 84. Aspirate. In the ink jet recording apparatus 80, a plurality of expansion chamber silencers 86 and 87 having different sizes are formed inside the duct 84 in order to reduce the fan noise described above (see, for example, Patent Document 1). . The length along the air flow of each expansion chamber type silencer 86, 87 is set to a length capable of attenuating the peak frequency component fn of the fan noise. Thereby, in each expansion chamber type silencer 86, 87, the peak frequency component fn of the fan noise is attenuated by the interference of the sound wave, and the fan noise is reduced.

  In some cases, an exhaust duct is disposed downstream of the exhaust port of the casing of the fan unit, and the air is exhausted to the outside through the exhaust duct. In this case, the exhaust flow becomes turbulent inside the exhaust duct and collides with the inner wall surface of the exhaust duct to generate noise (hereinafter referred to as “impact noise”). In order to reduce such collision noise, for example, as shown in FIG. 9, the exhaust duct 92 disposed on the downstream side of the exhaust port 91 of the casing 90 is arranged in the rotation direction D of the fan blades 93 at each corner. It has the curved inner wall surfaces 94 and 95 which follow (for example, refer patent document 2). Thereby, in the exhaust duct 92, it is possible to smoothly flow the exhaust flow to reduce the generation of turbulent flow and to suppress the occurrence of collision noise.

JP 2009-67015 A Japanese Patent No. 5293272

  However, in the technique of Patent Document 1, since the duct 84 is provided inside the inkjet recording apparatus 80, the size of the duct 84 is limited. As a result, it is difficult to set the length along the air flow of each expansion chamber type silencer 86, 87 to a length that can attenuate the peak frequency component fn of the fan noise, and the fan noise may not be sufficiently reduced. is there. Moreover, the technique of patent document 2 only reduces collision noise, and does not consider attenuating the peak frequency component fn of fan noise.

  The objective of this invention is providing the fan and fan unit which can fully reduce the aerodynamic noise which arises according to rotation of a fan blade | wing.

  In order to achieve the above object, a fan according to the present invention includes a fan blade, a casing that covers the fan blade, and a silencer, and the silencer is at least one of an upstream side and a downstream side of the fan blade. It is provided integrally with the casing.

  According to the present invention, it is possible to sufficiently reduce the aerodynamic noise generated according to the rotation of the fan blades.

1 is a perspective view schematically showing a configuration of a fan according to a first embodiment of the present invention. 1B is a partially exploded perspective view schematically showing an internal configuration of the fan of FIG. 1A. FIG. It is a perspective view which shows schematically the structure of the fan which concerns on the 2nd Embodiment of this invention. It is a perspective view which shows roughly the structure of the fan which concerns on the 3rd Embodiment of this invention. It is a perspective view which shows roughly the structure of the fan which concerns on the 4th Embodiment of this invention. 4B is a partially exploded perspective view schematically showing an internal configuration of the fan of FIG. 4A. FIG. FIG. 4B is a horizontal sectional view schematically showing the internal configuration of the fan of FIG. 4A. It is a perspective view which shows roughly the structure of the fan unit which concerns on the 5th Embodiment of this invention. FIG. 5B is a partially exploded perspective view schematically showing the internal configuration of the fan unit of FIG. 5A. FIG. 5B is another partially exploded perspective view schematically showing the internal configuration of the fan unit of FIG. 5A. It is a perspective view which shows roughly the structure of the fan unit which concerns on the 6th Embodiment of this invention. FIG. 6B is a partially exploded perspective view schematically showing the internal configuration of the fan unit of FIG. 6A. FIG. 6B is a horizontal sectional view schematically showing the internal configuration of the fan unit of FIG. 6A. It is a graph which shows the influence with respect to the overall value of the fan noise of the presence or absence of a silencer in a fan unit. It is a graph which shows the influence with respect to the overall value of the fan noise of the presence or absence of a silencer and a chamber in a fan unit. It is a figure which shows schematically the internal structure of an inkjet recording device provided with a fan. It is a figure which shows schematically the internal structure of a fan unit provided with an exhaust duct.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. However, the configuration described in each embodiment below is merely an example, and the scope of the present invention is not limited by the configuration described in each embodiment. First, a first embodiment of the present invention will be described.

  FIG. 1A is a perspective view schematically showing a configuration of a fan according to a first embodiment of the present invention. 1B is a partially exploded perspective view schematically showing the internal configuration of the fan of FIG. 1A. 1A and 1B, the fan 10 includes a fan blade 11 and a fan casing 12 that houses the fan blade 11. The fan blade 11 has a plurality of blades protruding from the rotation axis CL in a direction perpendicular to the rotation axis CL. When the rotation axis CL is viewed from the side, each blade has a predetermined inclination angle with respect to the rotation axis CL. Make. When the fan blade 11 rotates about the rotation axis CL, the fan blade 11 sucks air along the rotation axis CL and sends out air in a direction perpendicular to the rotation axis CL. Hereinafter, the air suction side of the fan blade 11 is referred to as “upstream side”, and the air supply side of the fan blade 11 is referred to as “downstream side”. The fan casing 12 communicates with the cylindrical flow generator 12a in which the fan blades 11 are offset from the center, and communicates with the rotary flow generator 12a, and extends in the tangential direction of the rotary flow generator 12a. And a rectifying unit 12b. The fan casing 12 has an opening 12 c that opens on the upstream side of the fan blade 11. When the fan blades 11 rotate, the air flow (airflow) sucked from the opening 12c and sent from the fan blades 11 in the direction perpendicular to the rotation axis CL flows along the inner wall of the rotation flow generator 12a. A rotating flow around CL is formed. The rotating flow is introduced along the arrow A to the rectifying unit 12b.

  A silencer 13 formed integrally with the fan casing 12 is connected to the rectifying unit 12b. The silencer 13 is composed of a plurality of hollow tubes 13a arranged in parallel to each other, and each hollow tube 13a has a rectangular or square cross section and forms an air passage extending linearly. One end of the silencer 13 communicates with the rectifying unit 12b, and an exhaust port 14 opens at the other end of the silencer 13. The airflow introduced into the rectifying unit 12b is introduced into the silencer 13 and sent out from the exhaust port 14 to the outside.

  Inside the fan casing 12, when the airflow passes through the tongue 12d, which is the connection between the rotary flow generator 12a and the rectifier 12b, pressure fluctuation occurs and fan noise is generated. This fan noise has a peak frequency component fn corresponding to the rotational speed N of the fan blade 11. Thereafter, the airflow is introduced into the silencer 13 with the fan noise having the peak frequency component fn. If the airflow introduced into the silencer 13 is sent out from the exhaust port 14 as it is, there is a risk of fan noise being emitted to the outside of the fan 10. In response to this, in the present embodiment, the silencer 13 is caused to function as an interference silencer in order to reduce fan noise.

Here, with respect to the sound wave (traveling wave) of the fan noise accompanied by the airflow flowing through each hollow tube 13a of the silencer 13, the exhaust port 14 acts as a reflecting wall due to the cross-sectional change, and generates a reflected wave. At this time, the amplitude of the sound wave of the fan noise is reduced by adjusting the phase difference of the reflected wave with respect to the traveling wave to cause the traveling wave and the reflected wave to interfere with each other. As a result, acoustic energy is reduced. In the fan 10, the length of each hollow tube 13a is adjusted to a predetermined value in order to cause the traveling wave and the reflected wave of the fan noise to interfere with each other. When the silencer 13 functions as an interference silencer, the frequency of the sound wave to be attenuated (hereinafter referred to as “attenuation frequency”) is F (Hz), and the length of each hollow tube 13a is L ₁ (m). Then, the following formula (1) is established.
F = (n · c) / (4 · L ₁ ) (1)
Here, n is an odd number (1, 3, 5,...), And c is the speed of sound (m / sec).

In this embodiment, the attenuation frequency F is to match the peak frequency components fn of fan noise, the length L ₁ of each hollow tube 13a is set. Thereby, the fan noise of the peak frequency component fn which the airflow which passes through the silencer 13 has is reduced.

According to the fan 10, the silencer 13 is formed integrally with the fan casing 12 on the downstream side of the fan blade 11, so that the layout of the silencer 13 can be given a margin. This increases the degree of freedom in setting the length L ₁ of each hollow tube 13a of the silencer 13, the length L ₁ of each hollow tube 13a, the peak of the fan noise produced in the rotational speed N of the fan blades 11 The frequency component fn can be reliably set to a length that can be attenuated. As a result, fan noise can be sufficiently reduced. Further, in the fan 10, the silencer 13 is integrally formed with the fan casing 12 on the downstream side of the fan blade 11, so that the fan noise can be reduced only by the fan 10. Thereby, in the device in which the fan 10 is arranged, it is possible to eliminate the necessity of reducing fan noise by the configuration on the downstream side of the fan 10. For example, the fan 10 has a silencer duct and a size necessary for noise reduction downstream of the fan 10. The need to arrange an expansion chamber can be eliminated. As a result, in the design of the apparatus, it is only necessary to pay attention to the smooth flow of the airflow on the downstream side of the fan 10, and the burden on the designer can be reduced.

  In the fan 10 described above, the silencer 13 is constituted by a plurality of hollow tubes 13a. However, the silencer 13 is constituted by a single hollow tube having the same cross-sectional area as the total sectional area of the plurality of hollow tubes 13a. Also good. Moreover, although the cross section of each hollow tube 13a exhibits a rectangle or a square, the shape of the said cross section is not restricted to these, For example, a polygon other than a rectangle, a perfect circle, and an ellipse may be sufficient. Further, in the fan 10 described above, each hollow tube 13a of the silencer 13 extends linearly. However, each hollow tube 13a may be bent within a range in which the size of the fan 10 is not expanded unnecessarily. Furthermore, the silencer 13 may be configured to be detachable from the fan casing 12 as long as it can be handled integrally with the fan casing 12.

  Next, a second embodiment of the present invention will be described. Since the configuration and operation of the second embodiment are basically the same as those of the first embodiment described above, the description of the overlapping configuration and operation will be omitted, and different configurations and operations will be described below. Give an explanation. The second embodiment differs from the first embodiment in that a silencer is provided on the upstream side of the fan blade.

  FIG. 2 is a perspective view schematically showing a configuration of a fan according to the second embodiment of the present invention. In FIG. 2, the fan 20 includes a fan casing 21 that houses the fan blades 11. The fan casing 21 includes a cylindrical rotary flow generation unit 21a in which the fan blades 11 are arranged offset from the center, and an exhaust port 21b that opens toward the tangential direction of the rotary flow generation unit 21a. The fan casing 21 has an opening (not shown) that opens on the upstream side of the fan blade 11. Note that the opening of the fan casing 21 is provided at substantially the same position as the opening 12 c of the fan casing 12. A silencer 22 formed integrally with the fan casing 21 is connected to the opening. The silencer 22 is erected in parallel with the rotation axis CL of the fan blade 11. The silencer 22 includes a plurality of hollow tubes 22a arranged in parallel to each other, and each hollow tube 22a has a rectangular or square cross section, and forms an air passage that extends linearly. One end of the silencer 22 communicates with the opening, and the intake port 23 opens at the other end of the silencer 22.

When the fan blade 11 rotates, air is sucked from the air inlet 23 and flows through the hollow tube 22 a of the silencer 22 and reaches the fan blade 11 through the opening of the fan casing 21. Thereafter, the air flow (airflow) sent from the fan blade 11 in the direction perpendicular to the rotation axis CL forms a rotation flow around the rotation axis CL along the inner wall of the rotation flow generation unit 21a. The rotational flow is sent out from the exhaust port 21b along the tangential direction of the rotational flow generation unit 21a. Also in the fan 20, when a rotational flow around the rotation axis CL is formed inside the fan casing 21, pressure fluctuation occurs and fan noise is generated. The fan noise has a peak frequency component fn corresponding to the rotational speed N of the fan blade 11, but may be propagated from the inside of the fan casing 21 to the silencer 22 and released from the intake port 23. Correspondingly, in this embodiment, in order to reduce fan noise, the silencer 22 is caused to function as an interference-type silencer as in the first embodiment. Specifically, as in the first embodiment, the attenuation frequency F of the silencer 22 is to match the peak frequency components fn of fan noise, the length L ₂ of the hollow tube 22a is set. Thereby, the fan noise of the peak frequency component fn propagated to the silencer 22 is reduced.

According to the fan 20, since the silencer 22 is formed integrally with the fan casing 21 on the upstream side of the fan blade 11, it is possible to give a margin to the layout of the silencer 22. This increases the degree of freedom in setting the length L ₂ of the hollow tube 22a of the silencer 22, the length L ₂ of the hollow tube 22a, the peak of the fan noise produced in the rotational speed N of the fan blades 11 The frequency component fn can be reliably set to a length that can be attenuated. As a result, fan noise can be sufficiently reduced. Further, in the fan 20, the silencer 22 is integrally formed with the fan casing 21 on the upstream side of the fan blade 11, so that fan noise can be reduced only by the fan 20. Thereby, in the apparatus in which the fan 20 is arranged, it is possible to eliminate the necessity of reducing fan noise by the configuration on the upstream side of the fan 20. For example, the fan 20 has a silencer duct and a size necessary for noise reduction upstream of the fan 20. The need to arrange an expansion chamber can be eliminated. As a result, in the design of the apparatus, it is only necessary to pay attention to the smooth flow of the airflow on the upstream side of the fan 20, and the burden on the designer can be reduced.

  In the fan 20 described above, the silencer 22 is configured by a plurality of hollow tubes 22a, but the silencer 22 is configured by a single hollow tube having the same cross-sectional area as the total cross-sectional area of the plurality of hollow tubes 22a. Also good. Moreover, although the cross section of each hollow tube 22a exhibits a rectangle or a square, the shape of the said cross section is not restricted to these, For example, a polygon other than a rectangle, a perfect circle, and an ellipse may be sufficient. Further, in the fan 20 described above, each hollow tube 22a of the silencer 22 extends linearly, but each hollow tube 22a may be bent within a range in which the size of the fan 20 is not expanded unnecessarily. Furthermore, the silencer 22 may be configured to be detachable from the fan casing 21 as long as it can be handled integrally with the fan casing 21.

  Next, a third embodiment of the present invention will be described. Since the configuration and operation of the third embodiment are basically the same as those of the first embodiment described above, the description of the overlapping configuration and operation will be omitted, and different configurations and operations will be described below. Give an explanation. The third embodiment differs from the first embodiment in that a silencer is provided not only on the downstream side of the fan blade but also on the upstream side.

  FIG. 3 is a perspective view schematically showing a configuration of a fan according to the third embodiment of the present invention. In FIG. 3, the fan 30 includes a fan casing 12 that accommodates the fan blades 11, similar to the fan 10, and a silencer 13 that is integrally formed with the fan casing 12 is connected to the rectifying unit 12 b of the fan casing 12. Is done. The fan casing 12 has an opening 12c that opens on the upstream side of the fan blade 11. The silencer 22 that is formed integrally with the fan casing 12 is connected to the opening 12c in the same manner as the fan 20. The

When the fan blade 11 rotates, air is sucked from the air inlet 23 and flows through the hollow tube 22 a of the silencer 22, and reaches the fan blade 11 through the opening of the fan casing 12. Thereafter, the air flow (airflow) sent from the fan blade 11 in the direction perpendicular to the rotation axis CL forms a rotation flow around the rotation axis CL along the inner wall of the rotation flow generation unit 12a. This rotating flow is introduced into the rectifying unit 12b, and further introduced into the silencer 13 and sent out from the exhaust port 14 to the outside. Also in the present embodiment, when a rotating flow around the rotation axis CL is formed inside the fan casing 12, pressure fluctuation occurs and fan noise is generated. The fan noise has a peak frequency component fn corresponding to the rotational speed N of the fan blade 11, but may be propagated from the inside of the fan casing 12 to the silencers 13 and 22 and released from the intake port 23 and the exhaust port 14. is there. Correspondingly, in the present embodiment, in order to reduce fan noise, the silencers 13 and 22 are caused to function as an interference type silencer as in the first and second embodiments. Specifically, as in the first and second embodiments, each of the hollow tubes 13a is set so that the attenuation frequency F of the silencers 13 and 22 matches the peak frequency component fn of the fan noise. the length of the length _{L 1} and the hollow tube 22a _{L 2} is set. Thereby, the fan noise of the peak frequency component fn propagated to the silencers 13 and 22 is reduced.

  According to the fan 30, the silencer 13 is formed integrally with the fan casing 12 on the downstream side of the fan blade 11, and the silencer 22 is formed integrally with the fan casing 12 on the upstream side of the fan blade 11. Therefore, both of the effect produced by the fan 10 and the effect produced by the fan 20 can be produced. In the fan 30, each of the silencer 13 and the silencer 22 may be configured by a single hollow tube, and the cross-sectional shape of each hollow tube 13 a or each hollow tube 22 a is, for example, a polygon other than a square. It may be a perfect circle or an ellipse. Each hollow tube 13a and each hollow tube 22a may be bent, and the silencer 13 and the silencer 22 may be configured to be detachable from the fan casing 12 as long as they can be handled integrally with the fan casing 12. Good.

  Next, a fourth embodiment of the present invention will be described. Since the configuration and operation of the fourth embodiment are basically the same as those of the first embodiment described above, the description of the overlapping configuration and operation will be omitted, and different configurations and operations will be described below. Give an explanation. The fourth embodiment differs from the first embodiment in that a chamber is provided between the fan casing and the silencer.

  FIG. 4A is a perspective view schematically showing a configuration of a fan according to a fourth embodiment of the present invention. FIG. 4B is a partially exploded perspective view schematically showing an internal configuration of the fan of FIG. 4A. FIG. 4C is a horizontal sectional view schematically showing the internal configuration of the fan of FIG. 4A. 4A to 4C, the fan 40 includes a fan blade 11 and a fan casing 41 that accommodates the fan blade 11. The fan casing 41 includes a cylindrical rotary flow generation unit 41a in which the fan blades 11 are offset from the center, and a communication port 41b that opens toward the tangential direction of the rotary flow generation unit 41a. The fan casing 41 has an opening 41 c that opens on the upstream side of the fan blade 11. When the fan blades 11 rotate, the air flow (airflow) sucked from the opening 41c and sent from the fan blades 11 in the direction perpendicular to the rotation axis CL flows along the inner wall of the rotation flow generation unit 41a. A rotating flow around CL is formed. The rotational flow is sent out from the communication port 41b along the tangential direction of the rotational flow generation unit 41a. A chamber 42 formed integrally with the fan casing 41 is connected to the communication port 41b. The chamber 42 is formed of a rectangular parallelepiped housing, and a communication port 41b is opened on one side surface in the vicinity of one end. The airflow sent from the communication port 41b collides with the inner wall of the chamber 42 and then flows along the longitudinal direction of the chamber 42 (see arrow B).

Also in the fan 40, when a rotating flow around the rotation axis CL is formed inside the fan casing 41, pressure fluctuation occurs and fan noise is generated. The fan noise has a peak frequency component fn corresponding to the rotational speed N of the fan blade 11, but is propagated from the inside of the fan casing 41 to the chamber 42. In the present embodiment, in order to reduce the fan noise, the chamber 42 is caused to function as an expansion chamber type silencer. Specifically, a sound wave (incident wave) of fan noise propagated to the chamber 42 is reflected on the inner wall of the chamber 42 to generate a reflected wave. At this time, the phase difference of the reflected wave with respect to the incident wave is adjusted, and the phase of the reflected wave is shifted by ½ wavelength from the phase of the incident wave, thereby causing the incident wave and the reflected wave to interfere with each other to cancel the incident wave. Thereby, the acoustic energy of the sound wave of fan noise is reduced. In the fan 40, the indoor length of the chamber 42 is adjusted to a predetermined value in order to cause the incident wave and the reflected wave of fan noise to interfere with each other in the chamber 42. By the way, when the chamber 42 is caused to function as an expansion chamber type silencer, the following equation (2) is established when the attenuation frequency is F ′ (Hz) and the chamber length of the chamber 42 is L ₃ (m).
F ′ = (n · c) / (4 · L ₃ ) (2)
Here, n is an odd number (1, 3, 5,...), And c is the speed of sound (m / sec).

In this embodiment, the attenuation frequency F 'is to match the peak frequency components fn of fan noise, it is set interior length L ₃ of the chamber 42. Thereby, the fan noise of the peak frequency component fn propagated to the chamber 42 is reduced. In the expansion chamber type silencer, the greater the expansion ratio, the higher the noise reduction effect. In the chamber 42, the ratio of the cross-sectional area _{S 2} of the chamber 42 with respect to the opening area _{S 1} of the communication port 41b corresponds to the expansion ratio. Thus, as the cross-sectional area S ₂ of the chamber 42 is as large as possible, it is preferable to configure the chamber 42, for example, the expansion ratio of the chamber 42 is preferably 5 or more. Here, the sectional area S ₂ of the chamber 42, the cross-sectional area of the vertical chamber 42 with respect to the air flow immediately below the communication opening 41b corresponds.

A silencer 43 formed integrally with the fan casing 41 is connected to the vicinity of the other end of the chamber 42. The silencer 43 is erected from the vicinity of the other end of the chamber 42 in parallel with the rotation axis CL. The silencer 43 is composed of a plurality of hollow tubes 43a arranged in parallel to each other, and each hollow tube 43a has a rectangular or square cross section and forms an air passage extending linearly. One end of the silencer 43 projects to the inside of the chamber 42 (fan casing 41). At this time, since all the silencer 43 is not accommodated inside the chamber 42, the other end of the silencer 43 protrudes to the outside of the chamber 42 (fan casing 41). One end of the silencer 43 opens in the chamber 42, and the silencer 43 and the chamber 42 communicate with each other. Further, an exhaust port 44 opens at the other end of the silencer 43. The airflow introduced into the chamber 42 is introduced into the silencer 43 and sent out from the exhaust port 44. If the fan noise is not sufficiently reduced in the chamber 42, the fan noise is transmitted to the silencer 43 and may be emitted from the outside of the fan 40. Correspondingly, in this embodiment, in order to reduce fan noise, the silencer 43 is caused to function as an interference silencer, as in the first embodiment. Specifically, as in the first embodiment, the attenuation frequency F of the silencer 43 is to match the peak frequency components fn of fan noise, the length L ₄ of the hollow tube 43a is set. Thereby, the fan noise of the peak frequency component fn propagated to the silencer 43 is reduced. The total cross-sectional area S ₃ of the hollow tube 43a of the silencer 43 is preferably set to equal to or less than the opening area S ₁ of the communication port 41b, thereby, it is released from the exhaust port 44 of the silencer 43 Fan noise can be further reduced. In this case, the reduced margin for the opening area S ₁ of the total cross-sectional area S ₃ of the hollow tube 43a is preferably kept to an extent that conductance of the silencer 43 is not deteriorated significantly.

According to the fan 40, since the silencer 43 and the chamber 42 are formed integrally with the fan casing 41 on the downstream side of the fan blade 11, fan noise can be reduced only by the fan 40. Thereby, in the apparatus in which the fan 40 is arranged, it is possible to eliminate the need to reduce fan noise by the configuration on the downstream side of the fan 40, and for example, it is possible to eliminate the need to arrange a silencer duct downstream of the fan 40. . Further, since the fan 40 can reduce fan noise in both the silencer 43 and the chamber 42, the fan noise can be more reliably reduced as compared to the fan 10 including only the silencer 13, for example. Moreover, in the fan 40, since the end of the silencer 43 protrudes inside the chamber 42, the protrusion amount of the silencer 43 protruding outside the chamber 42 can be reduced, whereby the arrangement of the fan 40 in the apparatus can be reduced. The degree of freedom can be improved. Incidentally, when the attenuation frequency F is the length L ₄ is less of each hollow tube 43a when matching the peak frequency components fn fan noise, all of the silencer 43 may protrude toward the inside of the chamber 42. Further, if there is a sufficient space volume in the apparatus, all of the silencer 43 may be protruded to the outside of the chamber 42.

  In the fan 40, both the silencer 43 and the chamber 42 are disposed on the downstream side of the fan blade 11. However, both the silencer 43 and the chamber 42 may be disposed on the upstream side of the fan blade 11. Alternatively, one of the silencer 43 and the chamber 42 may be disposed on the downstream side of the fan blade 11, and the other of the silencer 43 and the chamber 42 may be disposed on the upstream side of the fan blade 11.

  Next, a fifth embodiment of the present invention will be described. Since the fifth embodiment is basically the same in configuration and operation as the first embodiment described above, the description of the duplicated configuration and operation is omitted, and the different configuration and operation are described below. Give an explanation. The fifth embodiment is different from the first embodiment in that a fan case that covers the fan itself is provided.

FIG. 5A is a perspective view schematically showing a configuration of a fan unit according to the fifth embodiment of the present invention. FIG. 5B is a partially exploded perspective view schematically showing the internal configuration of the fan unit of FIG. 5A. FIG. 5C is another partially exploded perspective view schematically showing the internal configuration of the fan unit of FIG. 5A. 5A to 5C, the fan unit 50 includes a fan 51 and a fan case 52 that accommodates the fan 51. The fan 51 includes a fan blade 11 and a fan casing 53 that accommodates the fan blade 11. The fan casing 53 includes a cylindrical rotary flow generation unit 53a in which the fan blades 11 are offset from the center, and a communication port 53b that opens toward the tangential direction of the rotary flow generation unit 53a. The fan casing 53 has an opening 53 c that opens on the upstream side of the fan blade 11. The fan case 52 includes a housing-like case body 52a in which the fan 51 is disposed, and a flat case cover 52b that functions as a lid of the case body 52a. A communication port 52 c is opened on one side wall of the case body 52 a so as to face the communication port 53 b of the fan 51. Further, the case cover 52b has an opening 52d so as to face the opening 53c of the fan 51. When the fan blade 11 rotates, the air flow (airflow) sucked through the opening 52d and the opening 53c and sent out from the fan blade 11 in the direction perpendicular to the rotation axis CL is generated by the rotating flow generator 53a. A rotational flow around the rotation axis CL is formed along the inner wall. The rotary flow is sent out from the communication port 53b and further from the communication port 52c along the tangential direction of the rotary flow generation unit 53a. A silencer 54 formed integrally with the fan case 52 is connected to the communication port 52c. The silencer 54 has a plurality of hollow tubes 54a arranged in parallel to each other and a buffer 54b which is a hollow chamber. Each hollow tube 54a has a rectangular or square cross section, and has a ventilation path extending linearly. Form. The buffer 54b communicates with the communication port 52c, one end of each hollow tube 54a communicates with the buffer 54b, and the exhaust port 55 opens at the other end of each hollow tube 54a. The airflow introduced into the buffer 54b from the communication port 52c is introduced into each hollow tube 54a and sent out from the exhaust port 55 to the outside. In the fan unit 50 as well, when a rotational flow around the rotation axis CL is formed inside the fan casing 53, pressure fluctuation occurs and fan noise is generated. The fan noise has a peak frequency component fn corresponding to the rotational speed N of the fan blade 11, but may be propagated from the inside of the fan casing 53 to the silencer 54 and emitted from the exhaust port 55. Correspondingly, in this embodiment, in order to reduce fan noise, the silencer 54 is caused to function as an interference-type silencer as in the first embodiment. Specifically, as in the first embodiment, the attenuation frequency F of the silencer 54 is to match the peak frequency components fn of fan noise, the length L ₅ of the hollow tube 54a is set. Thereby, the fan noise of the peak frequency component fn propagated to the silencer 54 is reduced.

  In the fan unit 50, a plurality of vibration isolating materials 56 are disposed between the fan 51 and the fan case 52. The anti-vibration members 56 are disposed on the side surface, bottom surface, and top surface of the fan casing 53 and are interposed between the fan casing 53 and the fan case 52 to prevent the fan casing 53 from contacting the fan case 52. Thereby, it is possible to suppress the vibration of the peak frequency component fn caused by the rotation of the fan 51 from propagating to the fan case 52, and to prevent the vibration noise of the peak frequency component fn from being emitted from the fan case 52. Can do. As a material of the vibration isolator 56, for example, an EPDM rubber foam can be used. Further, the shape of the vibration isolator 56 is not limited to the rectangle shown in the figure (for example, a square having a side of 15 mm and a thickness of 3 mm), and is appropriate depending on factors such as the vibration isolating performance and cost. Shape is adopted.

  According to the fan unit 50, since the silencer 54 is formed integrally with the fan case 52 on the downstream side of the fan blade 11, the fan noise can be reduced only by the fan unit 50. Thereby, in the apparatus in which the fan unit 50 is arranged, it is possible to eliminate the need to reduce fan noise by the downstream configuration of the fan unit 50. Further, since the fan 51 is covered by the fan case 52, it is possible to prevent vibration noise caused by the vibration of the fan casing 53 of the fan 51 from being radiated. Furthermore, in the fan unit 50, since the silencer 54 is formed in the fan case 52 that covers the fan 51, it is not necessary to construct a configuration for reducing fan noise in the fan 51 itself. Therefore, a commercially available fan can be used as the fan 51.

  In the fan unit 50, the silencer 54 is disposed on the downstream side of the fan blade 11, but the silencer 54 may be disposed on the upstream side of the fan blade 11. Further, two silencers 54 may be provided and arranged on the downstream side and the upstream side of the fan blade 11, respectively. Moreover, the silencer 54 may be configured by a single hollow tube, and the cross-sectional shape of each hollow tube 54a may be, for example, a polygon other than a square, a perfect circle, or an ellipse. Each hollow tube 54 a may be bent, and the silencer 54 may be configured to be detachable from the fan case 52 as long as it can be handled integrally with the fan case 52.

  Next, a sixth embodiment of the present invention will be described. Since the configuration and operation of the sixth embodiment are basically the same as those of the fifth embodiment described above, the description of the overlapping configuration and operation will be omitted, and the different configuration and operation will be described below. Give an explanation. The sixth embodiment is different from the fifth embodiment in that a chamber is provided between the fan and the silencer.

  FIG. 6A is a perspective view schematically showing a configuration of a fan unit according to the sixth embodiment of the present invention. 6B is a partially exploded perspective view schematically showing an internal configuration of the fan unit of FIG. 6A. FIG. 6C is a horizontal sectional view schematically showing the internal configuration of the fan unit of FIG. 6A. 6A to 6C, the fan unit 60 includes a fan 51 and a fan case 61 that accommodates the fan 51. The fan case 61 includes a housing-like case body 61a in which the fan 51 is disposed, and a flat case cover 61b that functions as a lid of the case body 61a. A communication port 61 c is opened on one side wall of the case body 61 a so as to face the communication port 53 b of the fan 51. Further, an opening 61d is opened in the case cover 61b so as to face the opening 53c of the fan 51. When the fan blade 11 rotates, the air flow (air flow) sucked through the opening 61d and the opening 53c and sent from the fan blade 11 in the direction perpendicular to the rotation axis CL is the flow of the rotating flow generator 53a. A rotational flow around the rotation axis CL is formed along the inner wall. The rotary flow is sent out from the communication port 53b and further from the communication port 61c along the tangential direction of the rotary flow generation unit 53a. A chamber 62 formed integrally with the fan case 61 is connected to the communication port 61c. The chamber 62 is formed of a rectangular parallelepiped housing, and a communication port 61c is opened on one side surface in the vicinity of one end. The airflow sent from the communication port 61c collides with the inner wall of the chamber 62 and then flows along the longitudinal direction of the chamber 62 (see arrow C).

Also in the fan unit 60, when a rotational flow around the rotation axis CL is formed inside the fan casing 53, pressure fluctuation occurs and fan noise is generated. This fan noise has a peak frequency component fn corresponding to the rotational speed N of the fan blades 11, but is propagated from the inside of the fan casing 53 to the chamber 62 through the communication port 53b and further through the communication port 61c. In the present embodiment, in order to reduce the fan noise, the chamber 62 is caused to function as an expansion chamber type silencer. Specifically, as in the fourth embodiment, as the attenuation frequency F of the chamber 62 'coincides with the peak frequency components fn of fan noise, interior length L ₆ of the chamber 62 is set. Thereby, the fan noise of the peak frequency component fn propagated to the chamber 62 is reduced. Further, the chamber 62, the ratio of the cross-sectional area _{S 5} of chamber 62 relative to the opening area _{S 4} of the communication port 61c corresponds to the expansion ratio. Thus, as the cross-sectional area S ₅ of the chamber 62 as large as possible, it is preferable to configure the chamber 62, for example, the expansion ratio of the chamber 62 is preferably 5 or more. Here, the cross-sectional area S ₅ of the chamber 62, the cross-sectional area of the vertical chamber 62 with respect to the air flow immediately below the communication port 61c corresponds.

A silencer 63 formed integrally with the fan case 61 is connected to the vicinity of the other end of the chamber 62. The silencer 63 is erected in parallel with the rotation axis CL from the vicinity of the other end of the chamber 62. The silencer 63 is composed of a plurality of hollow tubes 63a arranged in parallel to each other, and each hollow tube 63a has a rectangular or square cross section and forms an air passage extending linearly. One end of the silencer 63 protrudes to the inside of the chamber 62 (fan case 61). At this time, since all the silencers 63 are not accommodated inside the chamber 62, the other end of the silencer 63 protrudes to the outside of the chamber 62 (fan case 61). One end of the silencer 63 opens in the chamber 62, and the silencer 63 and the chamber 62 communicate with each other. Further, an exhaust port 64 opens at the other end of the silencer 63. The airflow introduced into the chamber 62 is introduced into the silencer 63 and sent out from the exhaust port 64. If the fan noise is not sufficiently reduced in the chamber 62, the fan noise is propagated to the silencer 63, and the fan noise may be emitted to the outside of the fan unit 60. Correspondingly, in this embodiment, in order to reduce fan noise, the silencer 63 is caused to function as an interference silencer, as in the first embodiment. Specifically, as in the first embodiment, the attenuation frequency F of the silencer 63 is to match the peak frequency components fn of fan noise, the length L ₇ of the hollow tube 63a is set. Thereby, the fan noise of the peak frequency component fn propagated to the silencer 63 is reduced. The total cross-sectional area S ₆ of the hollow tube 63a of the silencer 63 is preferably set to equal to or less than the opening area S ₄ of the communication port 61c, thereby, be released from the exhaust port 64 of the silencer 63 Fan noise can be further reduced. In this case, the reduced margin for the opening area S ₄ of the total cross-sectional area S ₆ of the hollow tube 63a is preferably kept to an extent that conductance of the silencer 63 is not deteriorated significantly. Further, in the fan unit 60, similarly to the fan unit 50, a plurality of vibration isolation materials 56 are disposed between the fan 51 and the fan case 61.

According to the fan unit 60, the silencer 63 and the chamber 62 are integrally formed with the fan case 61 on the downstream side of the fan blade 11, so that fan noise can be reduced only by the fan unit 60. Thereby, in the apparatus in which the fan unit 60 is arranged, it is possible to eliminate the need to reduce fan noise by the configuration on the downstream side of the fan unit 60. Moreover, in the fan unit 60, since fan noise can be reduced in both the silencer 63 and the chamber 62, for example, the fan noise can be reduced more reliably than in the fan unit 50 including only the silencer 43. Moreover, in the fan unit 60, since the end of the silencer 63 is protruded inside the chamber 62, the protrusion amount of the silencer 63 protruding outside the chamber 62 can be reduced. Thereby, the freedom degree of arrangement | positioning of the fan unit 60 in an apparatus can be improved. Incidentally, when the attenuation frequency F is a length L ₆ is smaller in each hollow tube 63a when matching the peak frequency components fn of fan noise, all of the silencer 63 may protrude toward the inside of the chamber 62. Further, when there is a sufficient space volume in the apparatus, all of the silencer 63 may be protruded to the outside of the chamber 62.

  Further, in the fan unit 60, similarly to the fan unit 50, the fan 51 is covered with the fan case 61, so that it is possible to prevent the vibration noise generated due to the vibration of the fan casing 53 of the fan 51 from being radiated. it can. Furthermore, in the fan unit 60, since the silencer 63 is formed in the fan case 61 that covers the fan 51, it is not necessary to construct a configuration for reducing fan noise in the fan 51 itself.

  Further, in the fan unit 60, both the silencer 63 and the chamber 62 are disposed on the downstream side of the fan blade 11, but both the silencer 63 and the chamber 62 may be disposed on the upstream side of the fan blade 11. Alternatively, one of the silencer 63 and the chamber 62 may be disposed on the downstream side of the fan blade 11, and the other of the silencer 63 and the chamber 62 may be disposed on the upstream side of the fan blade 11. Moreover, the silencer 63 may be configured by one hollow tube, and the cross-sectional shape of each hollow tube 63a may be, for example, a polygon other than a square, a perfect circle, or an ellipse. Each hollow tube 63a may be bent, and the silencer 63 may be configured to be detachable from the fan case 61 as long as it can be handled integrally with the fan case 61.

  The preferred embodiments of the present invention have been described above. However, the present invention is not limited to the above-described embodiments, and various modifications and changes can be made within the scope of the gist.

  Next, examples of the present invention will be described.

  First, the fan unit 50 (Example 1) is compared with the fan unit (Comparative Example 1) in which the silencer 54 is removed from the fan unit 50. The overall (OA) value of the fan noise of Example 1 was measured, and the OA value of the fan noise of Comparative Example 1 was further measured. As shown in FIG. 7A, it was confirmed that the OA value of Example 1 was smaller by about 1.5 [dBA] than the OA value of Comparative Example 1. As a result, it was found that the silencer 54 can provide a silencing effect.

  Next, the fan unit 60 (Example 2) and the fan unit (Comparative Example 2) in which the chamber 62 and the silencer 63 are removed from the fan unit 60 are compared. The OA value of the fan noise of Example 2 was measured, and the OA value of the fan noise of Comparative Example 2 was further measured. As shown in FIG. 7B, it was confirmed that the OA value of Example 2 was about 3 [dBA] smaller than the OA value of Comparative Example 2. As a result, it has been found that a large silencing effect can be obtained by the chamber 62 and the silencer 63.

10, 20, 30, 40, 51 Fan 11 Fan blades 12, 21, 41, 53 Fan casing 13, 22, 43, 54, 63 Silencer 42, 62 Chamber 50, 60 Fan unit 52 Fan case 56 Vibration isolator

Claims (13)

A fan blade, a casing covering the fan blade, and a silencer,
The fan, wherein the silencer is provided integrally with the casing on at least one of an upstream side and a downstream side of the fan blade.   The fan according to claim 1, wherein the silencer includes a hollow tube projecting to at least one of an inner side and an outer side of the casing.   The fan according to claim 2, wherein the silencer further includes an expansion chamber communicating with the hollow tube.   The fan according to claim 3, wherein the hollow tube protrudes to at least one of an inner side and an outer side of the expansion chamber.   5. The length of the hollow tube is set to a length that reduces noise having a frequency component determined according to the number of rotations of the fan blade. 6. Fans.   The expansion chamber has an expansion ratio of 5 or more, and the length of the expansion chamber is set to a length that reduces noise having a frequency component determined according to the rotational speed of the fan blade. Item 5. The fan according to Item 3 or 4. A fan having a fan blade and a casing covering the fan blade, a fan case covering the fan, and a silencer,
The fan unit, wherein the silencer is provided integrally with the fan case on at least one of an upstream side and a downstream side of the fan blade.   The fan unit according to claim 7, wherein the silencer includes a hollow tube projecting to at least one of an inner side and an outer side of the fan case.   The fan unit according to claim 8, wherein the fan case includes an expansion chamber communicating with the hollow tube.   The fan unit according to claim 9, wherein the hollow tube protrudes to at least one of an inner side and an outer side of the expansion chamber.   11. The length of the hollow tube is set to a length that reduces noise having a frequency component determined according to the rotational speed of the fan blade. 11. Fan unit.   The expansion chamber has an expansion ratio of 5 or more, and the length of the expansion chamber is set to a length that reduces noise having a frequency component determined according to the rotational speed of the fan blade. Item 11. The fan unit according to Item 9 or 10.   The fan unit according to any one of claims 7 to 12, wherein a vibration isolating material is interposed between the fan and the fan case.