JP2021110260A - Blower module - Google Patents

Abstract

To obtain a blower module which can be suppressed in enlargement, can suppress the lowering of blowing performance, and can reduce noise.SOLUTION: A blower module 1 comprises: a centrifugal blower 2 having an impeller 7 and a scroll casing 9; a box body 3 having an opening 3h and accommodating the centrifugal blower 2; and a silencer 4 having an acoustic structure attached to an end face 18 being a first face, and having an acoustic material 12 surrounding a space 14. The scroll casing 9 has a scroll part 15a, a diffuse part 15b and a tongue part 15c. A first angle θ0 which is formed between a first inner wall face 16 opposing the tongue part 15c of the diffuse part 15b and the end face 18 at the outside of the scroll casing 9 is smaller than 90 degrees. A second angle θ which is formed between a second inner wall face 17 adjoining the first inner wall face 16 facing the space 14 and across the opening 3h and a second face being an end face 19 at a side opposite to the box body 3 of the acoustic material 12 at the outside of the space 14 is smaller than 90 degrees.SELECTED DRAWING: Figure 3

Description

The present disclosure relates to a blower having a centrifugal blower.

As a blower for ventilating the room, a centrifugal blower that blows air into the room through a duct connecting the room and the outside may be used. The centrifugal blower generates an air flow by rotating an impeller housed in a scroll casing. The noise generated by the centrifugal blower may propagate indoors through the duct. A sound absorbing material may be provided around the scroll casing to reduce noise.

Patent Document 1 discloses a blower device in which a sound absorbing structure in which a sound absorbing material is combined is arranged between an outlet of a scroll casing and an opening through which an air flow flows out in a housing accommodating the scroll casing. .. The blower according to Patent Document 1 reduces noise by absorbing noise by the sound absorbing material when the air flow passes through the air passage in the sound absorbing structure.

Japanese Patent No. 5078864

In the case of the prior art according to Patent Document 1, in order to further reduce the noise, the sound absorbing material may be enlarged so that the passing distance of the noise in the sound absorbing material becomes long. Alternatively, the air passage may be narrowed so that the noise passing through the air passage without passing through the sound absorbing material is reduced. If it is decided to reduce noise by increasing the size of the sound absorbing material, the size of the blower device will be increased due to the large size of the sound absorbing structure. Further, when the noise is reduced by narrowing the air passage, the air resistance in the air passage increases, so that the blowing performance of the blower deteriorates. As described above, according to the above-mentioned prior art, the blower has a problem that it is difficult to reduce the noise while suppressing the increase in size of the blower and the deterioration of the blower performance.

The present disclosure has been made in view of the above, and an object of the present invention is to obtain a blower device capable of suppressing an increase in size of a blower device, suppressing a decrease in blower performance, and reducing noise.

In order to solve the above-mentioned problems and achieve the object, the blower device according to the present disclosure includes an impeller and a scroll casing accommodating the impeller, and discharges an air flow from the scroll casing by rotation of the impeller. It is attached to a casing that has an opening through which the air flow passes, and a housing that accommodates the centrifuge blower, and a first surface that is the outer surface of the portion of the housing that is provided with the opening, and allows the air flow to pass through. It has a sound absorbing structure having a sound absorbing material that surrounds the space. The scroll casing is a portion between the scroll portion that surrounds the outer circumference of the impeller, the diffuse portion through which the air flowing from the scroll portion to the opening passes, and the scroll portion and the diffuse portion, and protrudes into the scroll casing. It has a tongue and. The first angle, which is the angle formed by the first inner wall surface and the first surface of the diffuser portion facing the tongue portion outside the scroll casing, is less than 90 degrees. The second inner wall surface facing the space and adjacent to the first inner wall surface across the opening, and the second surface of the sound absorbing material, which is the end surface opposite to the housing, form outside the space. The second angle, which is an angle, is less than 90 degrees.

The blower device according to the present disclosure has the effect of suppressing the increase in size of the blower device, suppressing the deterioration of the blower performance, and reducing noise.

A perspective view showing the appearance of the blower device according to the first embodiment. The first figure which shows the internal structure of the blower device which concerns on Embodiment 1. The second figure which shows the internal structure of the blower device which concerns on Embodiment 1. The figure for demonstrating the noise reduction effect by the blower device which concerns on Embodiment 1. The figure for demonstrating the blowing performance by the blowing apparatus which concerns on Embodiment 1. The figure for demonstrating the relationship between the air resistance in the silencer of the blower of Embodiment 1 and the 2nd angle. The figure which shows the internal structure of the blower device which concerns on Embodiment 2. The figure which shows the internal structure of the blower device which concerns on Embodiment 3. Top view of the resonance type sound absorbing plate included in the blower according to the third embodiment.

The blower according to the embodiment will be described in detail below with reference to the drawings. The present disclosure is not limited to this embodiment.

Embodiment 1.
FIG. 1 is a perspective view showing the appearance of the blower device according to the first embodiment. FIG. 2 is a first diagram showing an internal configuration of the blower device according to the first embodiment. FIG. 3 is a second diagram showing the internal configuration of the blower device according to the first embodiment. The blower 1 according to the first embodiment is installed behind the ceiling of the building. The blower 1 is connected to a duct installed behind the ceiling. The blower 1 takes in outdoor air through a duct and sends the air into the room through the duct. The illustration of the duct is omitted.

The blower 1 includes a centrifugal blower 2, a housing 3 for accommodating the centrifugal blower 2, a silencer 4 having a sound absorbing structure, and duct connecting parts 5 and 6. The centrifugal blower 2 includes an impeller 7, a motor 8 that rotationally drives the impeller 7, and a scroll casing 9 that houses the impeller 7 and a part of the motor 8. The impeller 7 is a multi-blade impeller.

The housing 3 is a box body having a rectangular parallelepiped shape. The upper surface portion 3a is a plate-shaped portion of the housing 3 located vertically above the housing 3 in a state where the blower 1 is installed. The bottom surface portion 3b is a plate-shaped portion of the housing 3 located vertically below the housing 3 in a state where the blower 1 is installed. The outdoor end face portion 3c is a plate-shaped portion of the housing 3 located on the outdoor side when the blower 1 is installed. The indoor side end face portion 3d is a plate-shaped portion of the housing 3 located on the indoor side in a state where the blower 1 is installed. The outdoor side is the side where the duct connecting to the outdoor side is arranged when viewed from the housing 3. The indoor side is the side where the duct connecting to the room is arranged when viewed from the housing 3.

The front portion 3e is a plate-shaped portion of the housing 3 facing the motor 8. The back surface portion 3f is a plate-shaped portion of the housing 3 on the opposite side of the front surface portion 3e. In the following description, the direction in which the outer surface of the front portion 3e on the outside of the housing 3 is directed may be referred to as the front, and the direction opposite to the front may be referred to as the rear. The outdoor end face portion 3c is provided with an opening 3g through which air flowing into the housing 3 passes. The indoor end face portion 3d is provided with an opening 3h through which the air flowing out of the scroll casing 9 passes.

FIG. 2 shows a blower 1 in a state in which the upper surface portion 3a and the upper portion of the scroll casing 9 are removed. FIG. 2 shows a state in which the centrifugal blower 2 is arranged inside the housing 3 and a state in which the elements arranged inside the scroll casing 9 are viewed from above. Further, FIG. 2 shows a cross section of the silencer 4 and an upper surface of the duct connecting parts 5 and 6. The cross section of the silencer 4 shown in FIG. 2 includes the central axis N of the blower 1 and is parallel to the rotation axis of the impeller 7. The central axis N is an axis that passes through the opening center of the suction port 5a and the opening center of the air outlet 6a. The suction port 5a and the air outlet 6a will be described later. The illustration of the rotating shaft is omitted.

FIG. 3 shows a blower 1 in a state where the front portion 3e is removed. FIG. 3 shows a state in which the centrifugal blower 2 is arranged inside the housing 3 as viewed from the front. In FIG. 3, the motor 8 is not shown. Further, FIG. 3 shows a cross section of the silencer 4 and a front surface of the duct connecting parts 5 and 6. The cross section of the silencer 4 shown in FIG. 3 is a cross section including the central axis N and perpendicular to the rotation axis.

A circular suction port 10a is provided on the first side wall portion 9a, which is a wall portion on the front side of the scroll casing 9. A circular suction port 10b is provided on the second side wall portion 9b, which is a wall portion on the rear side of the scroll casing 9. The suction port 10a and the suction port 10b face each other with the impeller 7 interposed therebetween. The outlet 10c of the scroll casing 9 is connected to the opening 3h. The third side wall portion 9c is a wall portion of the scroll casing 9 that covers between the first side wall portion 9a and the second side wall portion 9b.

The scroll casing 9 has a scroll portion 15a that surrounds the outer circumference of the impeller 7, a diffuse portion 15b through which air flowing from the scroll portion 15a to the opening 3h passes, and a tongue portion 15c. The tongue portion 15c is a portion between the scroll portion 15a and the diffuse portion 15b and is a portion protruding inward of the scroll casing 9. The space between the scroll portion 15a and the outer circumference of the impeller 7 is a spiral air passage through which the air flow blown from the impeller 7 passes. The air passage in the scroll casing 9 is extended from the space between the scroll portion 15a and the outer circumference of the impeller 7 to the outlet 10c via the diffuse portion 15b.

The silencer 4 has a sound absorbing material 12 and a casing 13 surrounding the sound absorbing material 12. The silencer 4 is attached to an end surface 18 on the indoor side of the housing 3. The end surface 18 is the outer surface of the indoor side end surface portion 3d, which is a portion of the housing 3 provided with the opening 3h. The sound absorbing material 12 is a material used for the purpose of absorbing sound. In the first embodiment, the sound absorbing material 12 is a porous material.

The silencer 4 is provided with an integral sound absorbing material 12, or is provided with a plurality of sound absorbing materials 12 combined with each other. The sound absorbing material 12 surrounds the space 14 through which air passes. As the sound absorbing material 12, for example, a non-woven fabric made of heat-adhesive fibers is used. The sound absorbing material 12 is manufactured by preparing a thick non-woven fabric using heat-adhesive fibers, laminating and heat-bonding a plurality of non-woven fabrics. The sound absorbing material 12 may be a material other than the non-woven fabric made of heat-adhesive fibers.

The duct connecting component 5 is attached to the outdoor end face portion 3c. The duct connection component 5 has a suction port 5a through which air from the outside passes. The duct connecting component 5 is connected to a duct connected to the outside of the room. A duct connecting component 6 is attached to an end face portion of the silencer 4 opposite to the end face portion attached to the housing 3. The duct connection component 6 has an air outlet 6a through which air flowing into the room passes. The duct connection component 6 is connected to a duct connected to the room.

When the motor 8 rotationally drives the impeller 7, the air in the duct connected to the outside passes through the duct connecting component 5 from the suction port 5a, and is taken into the housing 3 from the opening 3g. The centrifugal blower 2 takes in the air in the housing 3 from the suction port 10a and the suction port 10b into the scroll casing 9. The air taken into the scroll casing 9 flows into the space 14 through the opening 3h. The air that has flowed through the space 14 passes through the duct connecting component 6, and flows from the air outlet 6a into the duct that connects to the room.

The silencer 4 uses the sound absorbing material 12 to absorb the noise generated when the motor 8 rotationally drives the impeller 7. By providing the silencer 4, the blower 1 suppresses the noise generated in the blower 1 from propagating into the room through the duct.

The first inner wall surface 16 shown in FIG. 3 is one of the surfaces constituting the inner wall of the scroll casing 9, and is a surface of the diffuse portion 15b facing the tongue portion 15c. The first angle θ ₀ is an angle formed by the first inner wall surface 16 and the end surface 18 which is the first surface outside the scroll casing 9. The first angle θ ₀ is less than 90 degrees. The end surface 18 is a surface perpendicular to the central axis N.

The second inner wall surface 17 is one of the surfaces forming the inner wall of the sound absorbing material 12. The second inner wall surface 17 faces the space 14 and is adjacent to the first inner wall surface 16 with the opening 3h interposed therebetween. The end face 19 is an end face of the sound absorbing material 12 on the opposite side of the housing 3. The second angle θ is an angle formed by the second inner wall surface 17 and the end surface 19 which is the second surface outside the space 14. The second angle θ is less than 90 degrees. The end surface 19 is a surface perpendicular to the central axis N.

Further, in the first embodiment, the second angle θ is the same as _{the first angle θ 0.} That is, the first inner wall surface 16 and the second inner wall surface 17 have the same inclination with respect to the plane perpendicular to the central axis N. As described above, inside the sound absorbing material 12, a second inner wall surface 17 having the same inclination as the first inner wall surface 16 with respect to the horizontal plane is formed so as to be continued to the first inner wall surface 16. ..

Next, the noise reducing action and the blowing performance of the blowing device 1 according to the first embodiment will be described. The sound absorbing effect of the sound absorbing material 12 can be quantitatively expressed by, for example, the following equation (1). Equation (1) is an equation for simply obtaining the sound absorption volume in the sound absorbing duct, and is derived from Bruel's attenuation theory. In the formula (1), L represents the sound absorption volume, C represents the speed of sound, X represents the space width in the duct, ω represents the angular velocity of the sound, and G represents the coefficient. The unit of L is dB / m, the unit of C is m / s, the unit of X is m, and the unit of ω is rad / s.

According to the above equation (1), the narrower the width of the space 14 in the sound absorbing material 12, the higher the sound absorbing effect in the silencer 4. As shown in FIG. 3, the width of the space 14 in the vertical direction in the cross section shown in FIG. 3 is provided by providing the second inner wall surface 17 inclined so that the second angle θ is less than 90 degrees. Narrows toward the downstream side of the air flow. Therefore, the silencer 4 can obtain a higher sound absorbing effect than the case where the width of the space 14 in the vertical direction is not narrowed and is constant. By providing the silencer 4, the blower 1 can obtain a high sound absorbing effect without increasing the size of the sound absorbing material 12.

FIG. 4 is a diagram for explaining the noise reduction effect of the blower according to the first embodiment. In FIG. 4, the relationship between the frequency of the noise generated from the blower 1 and the magnitude of the noise is represented by a graph. In FIG. 4, the solid line graph shows the relationship between the noise frequency and the noise level of the blower 1 according to the first embodiment. The dotted line graph shows the relationship between the noise frequency and the noise level of the blower device according to the comparative example of the first embodiment. It is assumed that the blower device according to the comparative example is provided with a silencer having a constant width of the space 14 in the vertical direction. According to FIG. 4, when the graph of the first embodiment and the graph of the comparative example are compared, it can be seen that the noise is further reduced in the case of the first embodiment.

FIG. 5 is a diagram for explaining the blowing performance of the blowing device according to the first embodiment. FIG. 5 shows an example of the flow velocity distribution of the air flow inside the scroll casing 9 and inside the duct 20 when the duct 20 having a space having a constant width inside is connected to the outlet 10c of the centrifugal blower 2. Shown. FIG. 5 shows the result of analyzing the flow velocity distribution in the cross section including the central axis N and perpendicular to the rotation axis. In FIG. 5, the denser the dots, the higher the flow velocity. Further, the region 22 which is the portion showing the hatching of the diagonal line is a region above the extension line 23 of the straight line representing the first inner wall surface 16 in the cross section shown in FIG.

Inside the duct 20, the flow velocity in the region 21 below the extension line 23 is higher than the flow velocity in the region 22 above the extension line 23. That is, in the space downstream of the outlet 10c, the range that mainly functions as an air passage is the range of the region 21. By arranging the sound absorbing material 12 in the region 22, even if the space downstream of the outlet 10c is narrowed, the influence on the blowing performance of the blowing device 1 is small. In the blower device 1 according to the first embodiment, the deterioration of the blower performance can be suppressed by providing the sound absorbing material 12 in the portion corresponding to the region 22.

FIG. 6 is a diagram for explaining the relationship between the air resistance in the silencer of the blower according to the first embodiment and the second angle. FIG. 6 is a graph showing an example of the relationship between the second angle θ and the resistance coefficient representing air resistance.

When “θ = θ ₀ ” and “θ = θ ₀ + 8 °”, the sound absorbing material 12 is arranged in the range corresponding to the region 22 shown in FIG. 5 of the silencer 4. The air resistance in this case is zero. When the sound absorbing material 12 is arranged in the range corresponding to the region 22, the blowing device 1 does not deteriorate the blowing performance due to the presence of the sound absorbing material 12. On the other hand, if "θ = θ ₀ -7 °", and if "θ = θ ₀ -19 °" is sound absorbing material beyond the range corresponding to the region 22 shown in out Figure 5 silencer 4 12 are arranged. In this case, the air resistance increases as θ decreases. As described above, the blower device 1 deteriorates the blowing performance because the second angle θ is the same as _{the first angle θ 0 or the second angle θ is larger than the first angle θ 0.} It can be suppressed.

According to the first embodiment, the blower device 1 does not make the sound absorbing structure large and does not increase the size of the sound absorbing structure because _{the first angle θ 0 is less than 90 degrees and the second angle θ is less than 90 degrees.} A high sound absorbing effect can be obtained by the sound absorbing material 12 without increasing the air resistance. As a result, the blower device 1 has the effect of suppressing the increase in size of the blower device 1 and suppressing the deterioration of the blower performance, and reducing noise.

Embodiment 2.
FIG. 7 is a diagram showing an internal configuration of the blower device according to the second embodiment. In the blower device 30 according to the second embodiment, the second inner wall surface 32 of the sound absorbing material 12 has a first region 33 and a second region 34. In the second embodiment, the same components as those in the first embodiment are designated by the same reference numerals, and the configurations different from those in the first embodiment will be mainly described.

The blower 30 has a silencer 31 having a sound absorbing structure. FIG. 7 shows a blower device 30 in a state where the front portion 3e is removed, as in FIG. FIG. 7 shows a state in which the centrifugal blower 2 is arranged inside the housing 3 as viewed from the front. In FIG. 7, the motor 8 is not shown. Further, FIG. 7 shows a cross section of the silencer 31 and a front surface of the duct connecting parts 5 and 6. The cross section of the silencer 31 shown in FIG. 7 is a cross section including the central axis N and perpendicular to the rotation axis.

The second inner wall surface 32 is one of the surfaces forming the inner wall of the sound absorbing material 12. The second inner wall surface 32 faces the space 14 and is adjacent to the first inner wall surface 16 with the opening 3h interposed therebetween. The second inner wall surface 32 is a first region 33 forming a second angle θ with respect to the end surface 19 and a region on the downstream side of the air flow from the first region 33, and is a space toward the downstream side. It has a second region 34 that extends the width of 14. The second region 34 is a region between the first region 33 and the end face 19. The second region 34 of the second inner wall surface 32 is a curved surface represented by an arc in the cross section shown in FIG. 7. In the range where the second region 34 of the sound absorbing material 12 is formed, the width of the space 14 in the vertical direction becomes wider toward the downstream side. The second region 34 of the second inner wall surface 32 is not limited to the curved surface indicated by the arc, and can be appropriately changed as long as it is a surface that expands the width of the space 14 toward the downstream side.

The flow velocity of the air flow at the outlet 10c of the scroll casing 9 is higher than the flow velocity of the air flow at the suction port 5a. The flow velocity decreases toward the downstream side in the space 14, and becomes stable at the same flow velocity as the flow velocity at the suction port 5a. In the blower 30 of the second embodiment, since the air passage is widened at a position in front of the upstream side of the duct connecting component 6, the air flow is diffused at that position and the flow velocity is reduced. The blower 30 can reduce the flow velocity even if the distance of the air passage in the silencer 31 is short.

The friction loss caused by the flow of air through the air passage is proportional to the square of the flow velocity. The blower 30 reduces the flow velocity before the air flow reaches the outlet 6a by expanding the air passage in the range where the second region 34 is formed. The blower 30 can reduce the friction loss by being able to reduce the flow velocity at an early point when the air flow goes downstream. As a result, the blower device 30 can improve the blower performance.

According to the second embodiment, the blower device 30 can improve the blower performance by having the second inner wall surface 32 having a second region 34 that expands the width of the space 14 toward the downstream side. As a result, the blower device 30 has the effect of improving the blower performance and reducing noise.

Embodiment 3.
FIG. 8 is a diagram showing an internal configuration of the blower device according to the third embodiment. In the blower 40 according to the third embodiment, the silencer 41 is provided with a resonance type sound absorbing plate 42 which is a sound absorbing material. In the third embodiment, the same components as those in the first or second embodiment are designated by the same reference numerals, and the configurations different from those in the first or second embodiment will be mainly described.

FIG. 9 is a plan view of the resonance type sound absorbing plate included in the blower according to the third embodiment. A plurality of holes 44 are formed in the resonance type sound absorbing plate 42. Inside the silencer 41, a plurality of resonance type sound absorbing plates 42 surrounding the space 14 are arranged. The resonance space 43 is a space between each resonance type sound absorbing plate 42 and the casing 13. The silencer 41 absorbs sound by consuming sound energy by utilizing the resonance phenomenon.

One of the plurality of resonance type sound absorbing plates 42 includes a second inner wall surface 17 adjacent to the first inner wall surface 16 with the opening 3h interposed therebetween. The end surface 19 is a surface of the casing 13 facing the resonance space 43 and is perpendicular to the central axis N. The second angle θ, which is the angle formed by the second inner wall surface 17 and the end surface 19, is less than 90 degrees. Further, the second angle theta, is either larger than the first angle theta ₀ the same as the first angle theta _0.

Since the resonance type sound absorbing plate 42 having the second inner wall surface 17 is provided, the width of the space 14 in the vertical direction in the cross section shown in FIG. 8 becomes narrower toward the downstream side of the air flow. Therefore, the silencer 41 can obtain a higher sound absorbing effect than the case where the width of the space 14 in the vertical direction is constant. By providing the silencer 41, the blower 40 can obtain a high sound absorbing effect without increasing the size of the resonance space 43. Further, the blower device 40 can suppress the deterioration of the blower performance by providing the resonance space 43 in the portion corresponding to the region 22 shown in FIG. Further, the blower device 40 suppresses the deterioration of the blowing performance because the second angle θ is the same as _{the first angle θ 0 or the second angle θ is larger than the first angle θ 0.} be able to.

According to the third embodiment, the blower 40 _{does not make the sound absorbing structure large because the first angle θ 0} is less than 90 degrees and the second angle θ is less than 90 degrees. A high sound absorption effect can be obtained by the resonance type sound absorbing plate 42 and the resonance space 43 without increasing the air resistance. As a result, the blower 40 has the effect of suppressing the increase in size of the blower 40 and suppressing the deterioration of the blower performance, and reducing noise.

The configuration shown in the above-described embodiment shows an example of the contents of the present disclosure. The configurations of each embodiment can be combined with other known techniques. The configurations of the respective embodiments may be combined as appropriate. It is possible to omit or change a part of the configuration of each embodiment without departing from the gist of the present disclosure.

1,30,40 Blower, 2 Centrifugal blower, 3 Casing, 3a Top surface, 3b Bottom surface, 3c Outdoor end surface, 3d Indoor end surface, 3e Front, 3f Back, 3g, 3h opening, 4 , 31,41 Silencer, 5,6 Duct connection parts, 5a, 10a, 10b Suction port, 6a outlet, 7 impeller, 8 motor, 9 scroll casing, 9a 1st side wall part, 9b 2nd side wall part, 9c first 3 side wall part, 10c outlet, 12 sound absorbing material, 13 casing, 14 space, 15a scroll part, 15b diffuse part, 15c tongue part, 16 first inner wall surface, 17, 32 second inner wall surface, 18, 19 end face , 20 ducts, 21 and 22 regions, 23 extension lines, 33 first region, 34 second region, 42 resonance type sound absorbing plate, 43 resonance space, 44 holes, N central axis.

Claims (4)

A centrifugal blower having an impeller and a scroll casing accommodating the impeller, and discharging an air flow from the scroll casing by rotation of the impeller.
A housing having an opening through which the air flow passes and accommodating the centrifugal blower,
It is provided with a sound absorbing structure which is attached to a first surface which is an outer surface of a portion of the housing provided with the opening and has a sound absorbing material which surrounds a space through which the air flow passes.
The scroll casing is a portion between a scroll portion that surrounds the outer circumference of the impeller, a diffuse portion through which air flowing from the scroll portion to the opening passes, and the scroll portion and the diffuse portion. It has a tongue that overhangs the inside of the casing,
The first angle of the diffuse portion, which is the angle formed by the first inner wall surface facing the tongue portion and the first surface outside the scroll casing, is less than 90 degrees.
A second inner wall surface facing the space and adjacent to the first inner wall surface across the opening, and a second surface of the sound absorbing material, which is an end surface opposite to the housing, are formed. A blower having a second angle of less than 90 degrees, which is an angle formed outside the space. The blower according to claim 1, wherein the second angle is the same as or larger than the first angle. The second inner wall surface is a first region forming the second angle with respect to the second surface and a region on the downstream side of the air flow from the first region, and is directed downstream. The blower according to claim 1 or 2, characterized in that it has a second region that expands the width of the space according to the above. The blower according to claim 1 or 2, wherein the sound absorbing material is a resonance type sound absorbing plate.

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