JP4660511B2 - Noise reduction device and vacuum cleaner - Google Patents

Description

  The present invention relates to a device for reducing fluid noise transmitted through air by allowing air to pass through a main body, and a vacuum cleaner in which the device is disposed at an exhaust port.

Conventionally, as a technique for reducing the exhaust noise of a vacuum cleaner, “a recess 7 is formed at the rear end of the rear cover 6 and an exhaust hole 8 is provided on the bottom surface of the recess 7. A soundproof plate 9 is disposed so as to face the exhaust hole 8 and to be substantially perpendicular to the exhaust flow passing through the exhaust hole 8, and a plurality of small holes 11 are provided in the inner wall 10 of the soundproof plate 9, Furthermore, by arranging the sound absorbing material 13 between the inner wall 10 and the outer wall 12, the generation of wind noise is reduced, and the exhaust energy is diffused and absorbed by the small holes 11 and the sound absorbing material 13 to promote noise reduction. . Is proposed (Patent Document 1).
JP-A-10-248766 (Summary)

Noise (fluid noise) contained in the fluid generated by the motor of the vacuum cleaner is radiated directly to the outside of the housing from an exhaust port provided at the rear of the housing, etc., and consumers and vacuum cleaner users By directly listening to the sound (noise) radiated from the station, it was directly exposed to noise damage.
Therefore, for example, as in the above-described conventional technology, there is an exhaust passage provided with a combination of a perforated plate and a sound absorbing material at the exhaust port to try to reduce fluid noise, but the fast flow rate cannot be sufficiently attenuated, Since the perforated plate hinders the flow of the fluid and the sound leaks from the surrounding opening, there is a problem that the fluid noise cannot be sufficiently reduced.
The present invention has been made to solve the above-described problems, and an object of the present invention is to obtain a device that can surely attenuate fluid noise transmitted by air.

The noise reduction device according to the present invention is
A device for reducing fluid noise transmitted by air through the body,
An air inlet is provided in the housing of the device body,
In the housing, a first attenuation plate is provided in a direction intersecting with the traveling direction of the fluid noise that has entered the main body from the suction port,
A guide portion is provided by folding the end portion of the first attenuation plate in a direction reverse to the fluid noise traveling direction, and after the fluid noise passes along the guide portion, along the inner wall of the housing Form a passage to progress,
At the end of the main body housing on the outlet side, a second attenuation plate is provided in a direction intersecting with the traveling direction of the fluid noise,
One or more openings are formed in the second damping plate, and fluid noise that has entered the main body is radiated from the openings ,
Providing a second expansion space between the first attenuation plate and the second attenuation plate;
In the second expansion space portion, a plurality of first walls projecting in a bowl shape from the inner wall of the main body housing are provided, and a step path through which fluid noise passes is formed.
Drilling one or more sound channel openings in the first damping plate;
The first wall is
It is characterized in that it is formed so as to obstruct the passage of fluid noise comprising the sound channel port and the opening .

  According to the noise reduction device of the present invention, a sufficient noise reduction effect can be obtained even with fluid noise having a high flow velocity by the first and second attenuation plates and the flow path formed by these. .

Embodiment 1 FIG.
1 is a side sectional view of a noise reduction device according to Embodiment 1 of the present invention.
The noise reduction device of FIG. 1 has a suction port 1, a first attenuation plate 2, and a second attenuation plate 4.
The suction port 1 is a port that is perforated in the housing of the device and sucks air that propagates fluid noise into the main body of the noise reduction device.
The first attenuation plate 2 is provided in the housing of the apparatus in a direction that intersects the traveling direction of the fluid noise that has entered the main body through the suction port 1.
The second damping plate 4 is provided at the end of the main body casing on the outlet side (opposite side of the suction port 1) in a direction crossing the traveling direction of the fluid noise.
The second damping plate 4 has one or more openings 5 formed therein.

The fluid noise that has entered the noise reduction apparatus of FIG. 1 is radiated out of the apparatus along the following path.
First, the fluid noise enters the body of the noise reduction device along the air flow.
Next, after the fluid noise collides with the first attenuation plate 2, the fluid noise travels along the first attenuation plate 2 and is radiated out of the apparatus through the opening 5 formed in the second attenuation plate 4. The
It is an object of the noise reduction apparatus according to the first embodiment to attenuate the fluid noise in these processes and to reduce the noise at the stage where the fluid noise is emitted outside the apparatus.

  Next, the detailed configuration of FIG. 1 and the effects based on the configuration will be described.

(1) Guide part 3
The first damping plate 2 has a guide portion 3 formed by folding back an end portion thereof in a direction reverse to the traveling direction of fluid noise.
The fluid noise that has collided with the first damping plate 2 travels along the first damping plate 2 and is guided by the guide portion 3 in a direction opposite to the direction of incidence in the device body, It proceeds along the inner wall and proceeds toward the second attenuation plate 4.
By doing so, the acoustic energy is attenuated by colliding with the first attenuation plate 2, and the fluid noise is once reversed by the guide portion 3 so that the traveling path of the fluid noise can be taken longer. The sound energy is further attenuated, and the noise attenuation effect is increased.

(2) First convex portion 6
A first convex portion 6 formed in a mountain shape is provided at the center of the first attenuation plate 2.
The fluid noise incident from the suction port 1 collides with the first convex portion 6 and consumes acoustic energy, so that a noise attenuation effect can be exhibited.
Moreover, since the flow of fluid noise in the vicinity of the first convex portion 6 is complicated by providing the first convex portion 6, it is possible to exhibit the effect of consumption of acoustic energy.
Note that the position where the first convex portion 6 is provided is not necessarily the central portion of the first attenuation plate 2 and may be a position where fluid noise incident from the suction port 1 collides. Moreover, the shape of the 1st convex part 6 does not necessarily need to be a mountain shape, For example, the same effect can be show | played as shapes, such as a column shape and a truncated cone shape.

(3) 2nd convex part 7
A second convex portion 7 formed in a mountain shape is provided on the inner peripheral edge of the suction port 1.
The first convex portion 6, the second convex portion 7, and the guide portion 3 form an S-shaped fluid noise passage, and the fluid noise travels along the S-shaped passage.
Compared to the case where the S-shaped fluid noise passage is not formed, the path in which the fluid noise bypasses the second damping plate 4 without colliding with the second damping plate 2 as compared with the case where the S-shaped fluid noise passage is not formed. Therefore, it is possible to take a longer path for fluid noise and increase the noise attenuation effect.
Thus, by making the traveling direction of the fluid noise S-shaped, a sufficiently long passage can be formed in the main body even when the width of the main body of the noise reducing device is thin, and the noise reducing device itself Contributes to downsizing
In addition, the shape of the 2nd convex part 7 does not necessarily need to be a mountain shape, For example, the same effect can be show | played, even if it is a shape which surrounds the internal periphery of the suction inlet 1 in frame shape. .

(4) First expansion space 8
A first expansion space portion 8 is provided on the back side of the guide portion 3 (inside the apparatus).
Further, the passage of fluid noise sandwiched between the end portion of the guide portion 3 and the inner wall of the main body is formed to be narrower than the first expansion space portion 8.
The fluid noise travels while being guided by the guide portion 3, and passes through a passage sandwiched between the end portion of the guide portion 3 and the inner wall of the apparatus main body when it exits the end portion of the guide portion 3. Since the cross-sectional area of the passage is formed to be narrower than that of the first expansion space portion 8, the air that propagates the fluid noise contracts in the passage and then expands when it exits the passage.
The acoustic energy is attenuated by this contraction-expansion process, so that noise can be reduced.

(5) Second expansion space 9 and sound absorbing material 10
A second expansion space 9 is provided between the first attenuation plate 2 and the second attenuation plate 4.
The fluid noise that has exited the first expansion space portion 8 reaches the second expansion space portion 9 having a larger cross-sectional area, and further expands to attenuate the acoustic energy.
Further, a sound absorbing material 10 is disposed in the second expansion space portion 9. The acoustic energy is converted into heat energy or the like by the sound absorbing effect of the sound absorbing material 10, so that the acoustic energy is attenuated as a whole.

(6) Opening 5
The fluid noise that has escaped from the second expansion space 9 is radiated out of the apparatus through the opening 5 formed in the second attenuation plate 4.
Here, the opening 5 is formed in a horn shape, and is formed with a larger opening diameter (ΦA in FIG. 1) on the outer side than the opening diameter on the inner side of the main body (ΦB in FIG. 1). Thereby, since the process of contraction-expansion can be given to the air which propagates fluid noise, the effect which attenuates acoustic energy in the process can be exhibited.

低減目標周波数ｆ０は、開口部５を流体騒音が通過することにより、周波数ｆ０の音成分を低減させることを意味する。
開口率Ｐは、第２の減衰板４の面積と、開口部５の開口面積との比率である。
板厚ｔは、第２の減衰板４の厚さである。
空気層幅Ｄは、第２の減衰板４の上流側に存在する空気層の厚みであり、図１においては、第１の減衰板２と第２の減衰板４の距離に相当する。
上記ｆ０を、例えば本装置を適用する機材のモータ回転成分に伴う高周波数帯域でのピーク周波数成分に合致するようにして開口部５を穿設すれば、従来技術で十分に減衰させることができなかった当該高周波成分を確実に減衰させることができる。 The opening 5 is formed so as to satisfy the following equation (1) of the Helmholtz resonator.

The reduction target frequency f0 means that the sound component of the frequency f0 is reduced when fluid noise passes through the opening 5.
The aperture ratio P is a ratio between the area of the second attenuation plate 4 and the aperture area of the opening 5.
The plate thickness t is the thickness of the second attenuation plate 4.
The air layer width D is the thickness of the air layer existing on the upstream side of the second attenuation plate 4, and corresponds to the distance between the first attenuation plate 2 and the second attenuation plate 4 in FIG. 1.
For example, if the opening 5 is formed so as to match the peak frequency component in the high frequency band accompanying the motor rotation component of the equipment to which the present apparatus is applied, f0 can be sufficiently attenuated by the conventional technology. The high-frequency component that has not been present can be attenuated reliably.

  Although there is no particular restriction on the drilling position of the opening 5, if the drilling is performed at a position closer to the center than the end of the back surface of the first attenuation plate 2, the opening 5 is formed in front of the first expansion space 8. Compared to the case of drilling, the fluid noise path can be made longer, which is advantageous in terms of noise attenuation effect. The same applies to the embodiments described later.

As described above, according to the first embodiment,
A device for reducing fluid noise transmitted by air through the body,
An air inlet 1 is provided in the housing of the apparatus body,
In the housing, a first attenuation plate 2 is provided in a direction intersecting with the traveling direction of the fluid noise that has entered the main body through the suction port 1.
A guide portion 3 is provided by folding the end portion of the first damping plate 2 in a direction reverse to the direction in which the fluid noise travels, and after the fluid noise has passed along the guide portion 3, along the inner wall of the housing Form a passage to progress,
At the end of the main body housing on the outlet side, a second damping plate 4 is provided in a direction crossing the direction of fluid noise,
Since one or more openings 5 are formed in the second attenuation plate 4 so that the fluid noise incident on the main body is radiated from the openings 5,
The energy consumption due to the collision with the first damping plate 2 and the long flow path of the fluid noise make it possible to obtain a sufficient noise reduction effect even with fluid noise having a high flow velocity.

Moreover, since the 1st convex part 6 which opposes the advancing direction of a fluid noise was provided in the center part of the 1st damping plate 2,
Since the fluid noise incident from the suction port 1 collides with the first convex portion 6 and consumes acoustic energy, a noise attenuation effect can be exhibited.
Moreover, since the flow of fluid noise in the vicinity of the first convex portion 6 is complicated by providing the first convex portion 6, it is possible to exhibit the effect of consumption of acoustic energy.

Moreover, the 2nd convex part 7 is provided in the inner peripheral edge of the suction inlet 1,
Since the S-shaped fluid noise passage is formed by the second convex portion 7, the first convex portion 6, and the guide portion 3,
Compared to the case where the S-shaped fluid noise passage is not formed, the fluid noise does not go straight to the second attenuation plate 4 after colliding with the first attenuation plate 2 and reliably takes a detour path. Therefore, the traveling path of the fluid noise can be made longer, and the noise attenuation effect is increased.
Further, by making the traveling direction of the fluid noise S-shaped, a sufficiently long passage can be formed in the main body even when the width of the main body of the noise reducing device is thin, and the noise reducing device itself is small. Contributes to the transformation.

Further, a first expansion space portion 8 is provided on the back side of the end portion of the guide portion 3,
Since the fluid noise passage formed between the end portion of the guide portion 3 and the inner wall of the main body is formed to be narrower than the first expansion space portion 8,
Air that propagates fluid noise contracts in the passage and then expands when it exits the passage. This contraction-expansion process attenuates acoustic energy, so that noise can be reduced.

The opening 5 formed in the second damping plate 4 is
Since the outer opening diameter ΦA is larger than the inner opening diameter ΦB,
A process of contraction to expansion can be given to air that propagates fluid noise, and an effect of attenuating acoustic energy can be exhibited in the process.

Further, a second expansion space portion 9 is provided between the first attenuation plate 2 and the second attenuation plate 4, and the second expansion space portion 9 is opened from a passage formed by the guide portion 3. Since the sound-absorbing material 10 is disposed in the part leading to the part 5,
Due to the sound absorbing effect of the sound absorbing material 10, the acoustic energy is converted into thermal energy or the like, and the acoustic energy is attenuated as a whole.

Further, the opening 5 drilled in the second attenuation plate 4 is formed in a horn shape and satisfies the formula (1).
For example, if the opening 5 is formed so as to match the peak frequency component in the high frequency band accompanying the motor rotation component of the equipment to which the present apparatus is applied, f0 can be sufficiently attenuated by the conventional technology. The high-frequency component that has not been present can be attenuated reliably.

Embodiment 2. FIG.
FIG. 2 is a top sectional view of the noise reduction apparatus according to Embodiment 2 of the present invention.
In the noise reduction device of FIG. 2, the configuration of the suction port 1 to the second expansion space portion 9 is the same as that of the first embodiment, and hence the description thereof is omitted (the reference numerals attached to FIG. 2 are also partially omitted). A new configuration will be described.
The noise reduction apparatus of FIG. 2 is provided with a first wall 11 and a second wall 12 in the second expansion space 9. Hereinafter, these configurations will be described.

(1) First wall 11
A plurality of first walls 11 project in a bowl shape from the inner wall of the apparatus housing toward the center of the apparatus in the second expansion space 9. Further, since the first wall 11 is disposed so as to prevent the passage of fluid noise from the guide portion 3 to the opening 5, the passage of fluid noise is formed in a stepped state.
Thereby, the fluid noise that has escaped from the guide portion 3 consumes energy by colliding with the first wall 11 and can take a long passage for the fluid noise, so that an acoustic energy attenuation effect can be exhibited. it can.

(2) Second wall 12
The second wall 12 has a bowl shape from the inner wall of the apparatus housing toward the center of the apparatus at a position between the first wall 11 and the second attenuation plate 4 in the second expansion space 9. Multiple overhangs. Further, since the second wall 12 is disposed so as to prevent the passage of fluid noise from the first wall 11 to the opening 5, the passage of fluid noise is formed in a two-step state.
As a result, the fluid noise that has escaped from the first wall 11 consumes energy by colliding with the second wall 12, and the fluid noise passage can be made longer, thereby increasing the acoustic energy attenuation effect. be able to.

(3) First wall interval 13 and second wall interval 14
The first wall 11 is provided with a gap 13 therebetween, and the lateral width of the second wall 12 is longer than the gap 13.
Similarly, the second wall 12 is provided with a gap 14 therebetween, and the lateral width of the first wall 11 is longer than the gap 14.
By forming the width in this way, the passage of fluid noise reaching the guide part 3 to the opening part 5 can be reliably blocked without a gap, so that the effects described in the above (1) and (2) are surely exhibited. Can be made.

The plurality of first walls 11 and second walls 12 project in a bowl shape from the inner wall of the device casing toward the center of the device, but the three-dimensional shape is arbitrary. Can do.
For example, it may be formed so as to protrude from the inner wall of the apparatus housing in the shape of an ice column having a wider width, or may be formed integrally with the second attenuation plate 4 with a greater depth. The same applies to the following embodiments.

  In the second embodiment, the two step paths are formed by the first wall 11 and the second wall 12, but the number of steps is not necessarily limited to two, and the step paths are formed by an arbitrary number of steps. The same effect can be obtained.

As described above, according to the second embodiment,
While providing the second expansion space 9 between the first attenuation plate 2 and the second attenuation plate 4,
Since the second expansion space portion 9 is provided with a plurality of first walls 11 projecting in a bowl shape from the inner wall of the main body casing, and a step path through which fluid noise passes is formed.
The passage of fluid noise can be made long, and an acoustic energy attenuation effect can be exhibited.

In addition, since a plurality of second walls 12 projecting in a bowl shape from the inner wall of the main body casing are provided between the first wall 11 and the second attenuation plate 4, two step paths are formed.
The passage of fluid noise can be made longer, and the acoustic energy attenuation effect can be increased.

In addition, the first wall 11 is formed so as to obstruct the passage of fluid noise including the guide portion 3 and the opening portion 5.
The fluid noise that has exited the guide portion 3 consumes energy by colliding with the second wall 12 and can exhibit a noise reduction effect due to acoustic energy attenuation.

In addition, the second wall 12 is formed so as to prevent a fluid noise passage formed by the gap between the first walls 11 and the opening 5.
The fluid noise that has escaped from the first wall 11 consumes energy by colliding with the second wall 12, and can exhibit a noise reduction effect due to acoustic energy attenuation.

Further, the lateral width of the first wall is formed longer than the gap between the second walls 12 (interval 14), and the lateral width of the second wall 12 is the gap between the first walls (interval 13). Since it was formed longer than
The passage of the fluid noise from the guide part 3 to the opening part 5 can be reliably blocked without a gap, and the above-described effects can be reliably exhibited.

Embodiment 3 FIG.
In the first and second embodiments, the configuration in which the first and second attenuation plates and the bowl-shaped first and second walls are provided in order to reduce the fluid noise has been described.
In the noise reduction device according to the third embodiment of the present invention, a configuration capable of ensuring a constant air volume while reducing fluid noise will be described.

FIG. 3 is a top cross-sectional view of a noise reduction device according to Embodiment 3 of the present invention.
In the noise reduction apparatus of FIG. 3, since the structure of the suction inlet 1-the 2nd wall 12 is the same as that of Embodiment 2, description is abbreviate | omitted (a part of code | symbol attached to FIG. 3 is also abbreviate | omitted similarly), and new A detailed configuration will be described.

As described in the first and second embodiments, a fluid noise passage having a complicated shape is formed by the first and second damping plates and the first and second walls having a bowl shape, or air contraction By giving the process of expansion, the attenuation effect of acoustic energy can be exhibited.
However, if such a configuration is frequently used, the air flow becomes worse and the flow rate is lowered. Therefore, depending on the property of the target to which the noise reduction device according to the present invention is applied, an undesirable situation arises.
For example, assuming a case where the noise reduction device according to the present invention is applied for the purpose of reducing the exhaust noise of a vacuum cleaner, the suction work rate of the vacuum cleaner is reduced by reducing the air flow rate, and the vacuum cleaner body The performance will be reduced.
Therefore, in the third embodiment, one or a plurality of sound passage openings 15 are provided in the first attenuation plate 2 so as to ensure a flow rate of air above a certain level. The number and size of the sound channel ports 15 may be set as appropriate according to the required air flow rate.

However, in order to maintain the noise reduction effect after providing the sound channel port 15, the first wall 11 is formed so as to obstruct the passage of fluid noise including the sound channel port 15 and the opening 5.
By doing so, a flow rate of air above a certain level can be secured, the fluid noise collides with the first wall 11 to consume energy, and further, the path of the fluid noise can be taken longer by the step path. Therefore, the noise attenuation effect can also be maintained.

As described above, according to the third embodiment,
1 to a plurality of sound passage openings 15 are formed in the first damping plate 2;
The first wall 11 is
Since it was formed so as to block the passage of fluid noise consisting of the sound channel port 15 and the opening 5,
The air flow rate can be secured above a certain level, the fluid noise collides with the first wall 11 to consume energy, and the fluid noise path can be made longer by the step path, so that the noise attenuation effect is also maintained. can do.

Embodiment 4 FIG.
FIG. 4 is a top sectional view of a noise reduction device according to Embodiment 4 of the present invention.
In the noise reduction apparatus of FIG. 4, the configuration of the suction port 1, the guide unit 3, and the second wall 12 is the same as that of the second embodiment, and thus the description thereof is omitted (the reference numerals in FIG. 4 are also partly the same). (Omitted), a new configuration will be described.

(1) Recess 16
A recess 16 is provided on the surface of the first protrusion 6.
The fluid noise incident from the suction port 1 collides with the first convex portion 6 and consumes acoustic energy. However, the flow of the fluid noise in the vicinity of the concave portion 16 is further reduced by providing the concave portion 16. This is more complicated than the case where only 6 is provided, so that the fluid noise consumes energy, and the effect of exhausting acoustic energy can be exhibited.
Moreover, since the flow path is elongated by the recess 16, the acoustic energy attenuation effect due to this can be exhibited.
In addition, although the position and magnitude | size which provide the recessed part 16 can be made into the arbitrary positions and arbitrary magnitude | sizes of the surface of the 1st convex part 6, it forms with a very fine hollow compared with the flow volume and flow velocity of air. Then, since the flow of fluid noise cannot be complicated, a corresponding size is necessary.
(2) Granular convex part A plurality of granular convex parts (not shown) are provided on the surface of the first damping plate 2 or the second convex part 7 or both.
By doing so, the flow of fluid noise can be further complicated, so that the attenuation effect of acoustic energy is further increased.

As described above, according to the fourth embodiment,
Since one or more concave portions 16 are provided on the surface of the first convex portion 6,
The flow of fluid noise in the vicinity of the concave portion 16 is further complicated as compared with the case where only the first convex portion 6 is provided, and the effect of exhausting acoustic energy can be exhibited.
Moreover, since the flow path is elongated by the recess 16, the acoustic energy attenuation effect due to this can be exhibited.

In addition, since the plurality of granular convex portions are provided on the surface of the first attenuation plate 2 or the second convex portion 7 or both,
The flow of fluid noise can be further complicated, and the attenuation effect of acoustic energy is further increased. Moreover, the energy consumption effect in a granular convex part is also expectable.

Embodiment 5. FIG.
In Embodiment 1, although the noise attenuation effect by the opening part 5 formed in the horn shape was demonstrated, the case where the shape of the opening part 5 differs in the noise reduction apparatus which concerns on Embodiment 5 of this invention is demonstrated.

FIG. 5 is a top sectional view of a noise reduction device according to Embodiment 5 of the present invention.
In the fifth embodiment, the configuration other than the shape of the opening 5 can use any of the configurations of the first to fourth embodiments. In FIG. 5, the same configuration as that of the second embodiment is used. (Part of the reference numerals are omitted).

(1) Compression space 5A and expansion space 5B
The opening 5 in FIG. 5 is configured in a two-stage columnar shape, and a compression space 5A is formed by a column inside the apparatus main body and an expansion space 5B is formed by a column outside.
Here, the opening diameter d0 of the compression space 5A is formed smaller than the opening diameter L0 of the expansion space 5B. Thereby, since the process of contraction-expansion can be given to the air which propagates fluid noise, the effect which attenuates acoustic energy in the process can be exhibited.

低減目標周波数ｆ０は、開口部５を流体騒音が通過することにより、周波数ｆ０の音成分を低減させることを意味する。
開口率Ｐは、第２の減衰板４の面積と、開口部５の開口面積との比率である。
板厚ｔ０は、第２の減衰板４の厚さである。
上記ｆ０を、例えば本装置を適用する機材のモータ回転成分に伴う高周波数帯域でのピーク周波数成分に合致するようにして開口部５を穿設すれば、従来技術で十分に減衰させることができなかった当該高周波成分を確実に減衰させることができる。
（２）吸音材１０
圧縮空間５Ａに近接する空間に、吸音材１０を配設し、音響減衰効果を高める。吸音材１０は必ずしも設けなくともよい。 The compression space 5A and the expansion space 5B are formed so as to satisfy the following equation (2) of the Helmholtz resonator.

The reduction target frequency f0 means that the sound component of the frequency f0 is reduced when fluid noise passes through the opening 5.
The aperture ratio P is a ratio between the area of the second attenuation plate 4 and the aperture area of the opening 5.
The plate thickness t0 is the thickness of the second attenuation plate 4.
For example, if the opening 5 is formed so as to match the peak frequency component in the high frequency band accompanying the motor rotation component of the equipment to which the present apparatus is applied, f0 can be sufficiently attenuated by the conventional technology. The high-frequency component that has not been present can be attenuated reliably.
(2) Sound absorbing material 10
The sound absorbing material 10 is disposed in a space close to the compression space 5A to enhance the sound attenuation effect. The sound absorbing material 10 is not necessarily provided.

As described above, according to the fifth embodiment,
Since the opening 5 drilled in the second damping plate 4 is formed in a two-stage columnar shape including a compression space 5A and an expansion space 5B, and satisfies the formula (2),
A process of contraction to expansion can be given to air that propagates fluid noise, and an effect of attenuating acoustic energy can be exhibited in the process.
Further, if the opening 5 is formed so as to match the peak frequency component in the high frequency band accompanying the motor rotation component of the equipment to which the present apparatus is applied, for example, the above-described f0 can be sufficiently attenuated by the conventional technique. The high-frequency component that cannot be attenuated can be reliably attenuated.

Embodiment 6 FIG.
In the third embodiment, the configuration in which the sound passage port 15 is formed in the first attenuation plate 2 in order to ensure a constant air flow rate has been described.
In the noise reduction device according to Embodiment 6 of the present invention, a configuration for securing a larger air flow rate will be described.

FIG. 6 is a side sectional view of the noise reduction apparatus according to the sixth embodiment.
The noise reduction device of FIG. 6 has a suction port 1, a first attenuation plate 2, a second attenuation plate 4, and a second convex portion 7, and the first convex portion 6 is provided on the first attenuation plate. The second attenuation plate 4 is common to the first embodiment in that an opening 5 is provided.
Hereinafter, a configuration different from that of the first embodiment will be described.

(1) Upper end portion of first attenuation plate 2 In the sixth embodiment, the upper end portion of the first attenuation plate 2 is folded back in a direction reverse to the traveling direction of fluid noise. Form.
By doing so, the fluid noise that travels along the upper side of the first attenuation plate 2 is shaped like an S-shape formed by the first convex portion 6, the second convex portion 7, and the guide portion 3. Since it proceeds along the fluid noise passage, the same acoustic energy attenuation effect as in the first embodiment is exhibited.

(2) Lower end portion of the first attenuation plate 2 Unlike the upper end portion, the lower end portion of the first attenuation plate 2 has a flat plate shape without being folded back.
Thus, the fluid noise passage formed by the lower end portion of the first attenuation plate 2 and the inner wall of the main body housing is formed wider than the passage formed by the guide portion 3.
By doing in this way, the flow volume of the air which progresses along the lower side of the 1st attenuation board 2 is securable.

(3) First wall 11 and second wall 12
If the passage formed by the lower end portion of the first attenuation plate 2 is formed wide as in (2) above, air can be easily discharged directly from the opening 5, so that a sufficient acoustic attenuation effect cannot be expected.
Therefore, in the space from the passage to the opening 5, the first wall 11 and the second wall 12 similar to those in the second embodiment are provided. By doing in this way, while being able to ensure the air flow rate below the 1st attenuation board 2, the noise reduction effect can also be maintained.

(4) Sound absorbing material 10
A sound absorbing material 10 is disposed in a path from the guide part 3 to the opening part 5 in the second expansion space part 9. Thereby, the noise of the fluid noise that travels along the upper side of the first attenuation plate 2 can be reduced.

In the sixth embodiment, the guide portion 3 is provided at the upper end portion of the first damping plate and the lower end portion forms a wide passage. However, it should be noted that the same effect can be obtained.
Furthermore, it is not always necessary to set the upper and lower sides strictly, and the same effect can be obtained even when the position is shifted to the extent that it does not contradict the purpose of the sixth embodiment.
Further, the shape of the opening 5 may be the horn shape described in the first embodiment or the two-stage columnar shape described in the fifth embodiment.

As described above, according to the sixth embodiment,
The guide portion 3 is formed by folding the upper end portion of the first damping plate 2 in a direction reverse to the traveling direction of the fluid noise,
The passage of fluid noise consisting of the lower end and the inner wall of the body housing is
A first wall 11 and a second wall 12 are provided in a portion of the second expansion space portion 9 that extends from the passage to the opening 5 and is wider than the passage formed by the guide portion 3. Because
The air flow rate below the first attenuation plate 2 can be secured, and the noise reduction effect can be maintained.

In addition, since the sound absorbing material 10 is disposed in the portion from the passage formed by the guide portion 3 to the opening portion 5 in the second expansion space portion 9,
The noise of fluid noise that travels along the upper side of the first damping plate 2 can be reduced.

Embodiment 7 FIG.
FIG. 7 is a side view of a vacuum cleaner according to Embodiment 7 of the present invention.
In the seventh embodiment, the noise reduction device of the first to sixth embodiments is arranged at the exhaust port of a vacuum cleaner.
In general, noise generated from a vacuum cleaner is radiated out of the main body of the vacuum cleaner together with exhaust gas, using a motor as a generation source. Therefore, this can be reduced by disposing the noise reduction device according to the first to sixth embodiments at the exhaust port of the vacuum cleaner.

FIG. 8 is a graph showing measurement results of noise characteristics before and after mounting a noise reduction device which is a noise countermeasure member in the present invention.
The vertical axis in FIG. 8 represents the sound pressure level (dB) of noise.
The horizontal axis in FIG. 8 represents the noise frequency (Hz).

The graph represented by the solid line in FIG. 8 shows the noise characteristics before the noise countermeasure member is mounted. As shown in the graph, the noise before mounting the noise countermeasure member has a peak in the fan rotation component (NZ component) due to the higher-order divided vibration component.
The graph represented by the dotted line in FIG. 8 shows the noise characteristics after mounting the noise countermeasure member. As shown in the graph, it can be seen that the peak noise of the NZ component is reliably attenuated and the noise level is lowered over almost all the frequency ranges of the noise after mounting the noise countermeasure member.

Here, it is assumed that the reduction target frequency f0 in the equations (1) and (2) is configured to match the peak frequency of the NZ component in FIG.
Further, it should be noted that the same effect as that of the graph represented by the dotted line in FIG. 8 can be obtained when any of the configurations of the first to sixth embodiments is used.

  In the seventh embodiment, the example in which the noise reduction device is disposed at the exhaust port of the vacuum cleaner has been described. However, the application target of the noise reduction device according to the present invention is not limited to this, for example, a fan The present invention can be applied to various equipment that generates fluid noise transmitted by air.

As described above, according to the seventh embodiment, since the noise reduction device according to any one of the first to sixth embodiments is arranged at the exhaust port of the vacuum cleaner,
Noise radiated with the exhaust of the vacuum cleaner can be reduced.

Embodiment 8 FIG.
FIG. 9 is a side sectional view of a noise reduction apparatus according to Embodiment 8 of the present invention.
In FIG. 9, the fluid noise that has flowed into the noise reduction device from the suction port 1 collides with the stepped path portion formed by the first wall 11 and the second wall 12. The configuration of the step path is the same as that described in the second embodiment.
The fluid noise passes through the stepped path portion while propagating in a zigzag manner in the space between the first wall 11 and the second wall 12. This space is called a first sound field space.

Behind the first sound field space is a fibrous sound-absorbing material 10 that is molded (woven) so that the cross-section is corrugated so as to have both functions of wind flow and acoustic attenuation. It is filled with an arbitrary amount.
The fibers constituting the sound-absorbing material 10 are formed of a PET material, a nonwoven fabric, or the like, and are mixed with an arbitrary amount of a shape-retaining material called a binder material, which is called a binder material, in order to maintain a sound propagation space. . The holding force of the sound propagation space by the shape maintaining material is maintained, and the space necessary for propagation is always maintained. This space behind the stepped portion is called a second sound field space.
When the sound passes through the second sound field space, the sound pressure level is attenuated over the entire frequency band of the sound according to the distance of the sound propagation space by vibrating the fiber surface formed in a waveform. It is done.

  That is, while maintaining the space where air propagates, acoustic energy is reduced by vibrating the corrugated fiber surface during the passage of fluid noise, so the suction work rate and noise reduction effect can be combined. .

An acoustic filter space composed of the second attenuation plate 4 is formed behind the second.
The second attenuation plate 4 is provided with the opening 5 having the compression space 5A and the expansion space 5B as described in the fifth embodiment.
By designing the compression space and the expansion space based on the above-described equation (2), fluid noise having an arbitrary frequency can be reduced as described in the fifth embodiment.

  As described above, according to the eighth embodiment, by providing the sound absorbing material 10 that allows fluid to pass through and attenuates the acoustic energy component contained in the fluid, both high suction work rate and low noise can be achieved. can do.

Embodiment 9 FIG.
FIG. 10 is a side sectional view of a noise reduction apparatus according to Embodiment 9 of the present invention.
In FIG. 10, the shape of the opening 5 is formed in the same horn shape as that described in the first embodiment. Other configurations are the same as those in the eighth embodiment.
In the configuration of FIG. 10 as well, as in the eighth embodiment, the fluid noise can be reduced by designing the shape of the opening 5 based on the equation (1) described above.

Embodiment 10 FIG.
FIG. 11 is a side sectional view of a noise reduction device according to Embodiment 10 of the present invention.
In the eighth embodiment, the opening portion 5 in which the compression space and the expansion space are formed with an arbitrary opening size is formed in the second attenuation plate 4 to form the “acoustic filter space”. In the tenth embodiment, a plurality of opening portions 5 having different opening areas are provided. Through this opening 5, fluid noise is radiated to the outside of the housing.
The opening 5 has a circular, oval, square, or substantially quadrangular cross section. Further, the openings 5 having different opening areas are formed so as to be arranged in a staggered manner.

Embodiment 11 FIG.
FIG. 12 is a side sectional view of a noise reduction apparatus according to Embodiment 11 of the present invention.
In FIG. 12, the configurations of the second sound field space and the acoustic filter space are the same as those in the tenth embodiment, and thus the description thereof is omitted.

In the first sound field space, a plurality of acoustic air passages having two or more types of arbitrary aperture areas with different distances are formed so that sound from the outside of the noise reduction device enters the acoustic air passage. . Here, two types of the first acoustic wind path 21 and the second acoustic wind path 22 are provided, and the second acoustic wind path is formed to be shorter.
The cross sections of the first acoustic air passage 21 and the second acoustic air passage 22 are formed in a circular shape, an oval shape, a square shape, or a substantially square shape.

  The first acoustic air passage 21 and the second acoustic air passage 22 are alternately arranged in a staggered manner. With this arrangement, the positions of the sound inlets of the first acoustic air passage 21 and the second acoustic air passage 22 are alternately different in the traveling direction of the fluid noise on the inside of the housing of the noise reduction device. Similarly, there is a difference in distance at the sound outlet.

The first acoustic air passage 21 and the second acoustic air passage 22 are reversed in sound phase when fluid noise exits the acoustic tube due to the acoustic air passage (acoustic tube) having a distance difference as described above. Are arranged as follows. As a result, the sounds emitted from the acoustic tubes are reversed in phase and perform an operation to cancel each other.
With this configuration, fluid noise can be effectively reduced.

FIG. 13 shows detailed operations of the first acoustic air passage 21 and the second acoustic air passage 22.
The first acoustic air passage 21 has an arbitrary distance L1, and the second acoustic air passage 22 has an arbitrary distance L2 (L1 ≠ L2).
The sound inlet of the first acoustic air passage 21 and the sound inlet of the second acoustic air passage 22 have a step at a distance L3.
Further, there is a step at a distance L4 between the sound outlet of the first acoustic air passage 21 and the sound outlet of the second acoustic air passage 22.

Inside each acoustic wind path (acoustic tube), fluid noise is one-dimensionally propagated, and sound propagates through the acoustic tube in a primary mode determined by the lengths of L1 and L2.
For example, the length L1 of the first acoustic air passage 21 is set to a length that allows the sound of two wavelengths and ½ wavelength to propagate, and the length L2 of the second acoustic air passage 22 is the sound of one wavelength. Set to the length of propagation.
In this state, by forming the distance steps L3 and L4 as shown in FIG. 13, it is possible to form a phase difference at the phase signal level of the sound emitted from the acoustic tube.
Thereby, when the fluid noise comes out from the sound outlets of the first acoustic air passage 21 and the second acoustic air passage 22, the phases of the sound are opposite to each other, and the sound is canceled at the sound outlet.

  As described above, according to the eleventh embodiment, the first acoustic air passage 21 and the second acoustic air passage 22 having different lengths are formed in the suction port, and the sound phase is opposite to the opposite phase at the sound output port. Since the lengths L1 to L4 are set as described above, the sound is canceled at the sound output port, and the fluid noise can be effectively reduced.

  Moreover, since the sound canceled by the sound outlet is further reduced by the sound absorbing material 10, the noise reduction effect can be further improved.

Embodiment 12 FIG.
In the eleventh embodiment, the configuration in which the first acoustic wind path 21 and the second acoustic wind path 22 are formed in the first sound field space has been described. In the twelfth embodiment of the present invention, a configuration in which the first acoustic air passage 21 and the second acoustic air passage 22 are formed on the outlet side of the noise reduction device will be described.

FIG. 14 is a side sectional view of the noise reduction apparatus according to the twelfth embodiment.
In FIG. 14, the configurations of the first sound field space and the second sound field space are the same as those in the eighth to tenth embodiments.
On the exit side of the noise reduction device, the first acoustic air passage 21 and the second acoustic air passage 22 are formed instead of or in combination with the opening 5. The configuration of these acoustic wind paths is the same as that described in the eleventh embodiment.
The fluid noise that has passed through the sound absorbing material 10 flows into the sound inlets of the first acoustic air passage 21 and the second acoustic air passage 22, and flows out of the main body through the sound outlet.

  The first acoustic air passage 21 and the second acoustic air passage 22 are alternately arranged in a staggered manner on the exit side of the noise reduction device. With this arrangement, the positions of the sound inlets of the first acoustic air passage 21 and the second acoustic air passage 22 are alternately different in the traveling direction of the fluid noise on the inside of the housing of the noise reduction device. Similarly, there is a difference in distance at the sound outlet.

The first acoustic air passage 21 and the second acoustic air passage 22 are arranged so that the phase of the sound is reversed when the fluid noise leaves the acoustic tube, as in the eleventh embodiment. As a result, the sounds emitted from the acoustic tubes are reversed in phase and perform an operation to cancel each other.
With this configuration, fluid noise can be effectively reduced.

  Moreover, the noise reduction effect can be further improved by using the stepped path composed of the first wall 11 and the second wall 12 and the sound absorbing material 10 in combination.

Embodiment 13 FIG.
FIG. 15 is a sectional side view showing a configuration example (A) and (B) of a noise reduction device according to Embodiment 13 of the present invention.
Due to clogging of the noise reduction device due to secular change or the like, the temperature of the fluid noise caused by the motor increases. Therefore, in order to detect such aged deterioration, in the configuration described in the first to twelfth embodiments, a sensor for measuring temperature and air volume is provided on the outlet side of the noise reduction device, and the detected value is presented to the user. And

In the example of FIG. 15A, the temperature sensor 800 is provided at an arbitrary position on the sound absorbing material 10 side of the second attenuation plate 4 after passing through the sound absorbing material 10.
In the example of FIG. 15B, the temperature sensor 800 is provided at an arbitrary position on the surface of the first acoustic air passage 21 or the second acoustic air passage 22 that is the outside of the housing.
In addition to the temperature sensor, an air volume sensor for detecting clogging may be provided, a sensor for detecting deterioration of other characteristics may be provided, and these may be used in combination.

  With the configuration as described above, it is possible to prevent in advance the ignition of the motor caused by the motor overload due to the clogging of the noise reduction device or the like. It is also possible to detect the product life.

  The output means for presenting the aging deterioration to the user can be configured as shown in the following (1) to (3) as an example.

(1) When the detected value reaches a predetermined threshold value, the user is notified of the aging deterioration by display means such as an LED (Light Emitting Diode) or an LCD (Liquid Crystal Display).
(2) When the detected value reaches a predetermined threshold value, a warning sound is emitted to notify the user.
(3) When the detection value reaches a predetermined threshold value, a wired / wireless interface is provided for outputting data to that effect. The interface is monitored by a monitoring device or the like provided outside the noise reduction device, and when data is received, the user is notified accordingly.

Embodiment 14 FIG.
The noise reduction devices described in the above eighth to thirteenth embodiments can be arranged at the exhaust port of a vacuum cleaner as in the seventh embodiment, and can reduce noise emitted from a motor or the like of the vacuum cleaner.

  It should be noted that the configurations of the embodiments described above can be combined as appropriate.

1 is a side cross-sectional view of a noise reduction device according to Embodiment 1. FIG. 6 is a top sectional view of a noise reduction device according to Embodiment 2. FIG. FIG. 6 is a top sectional view of a noise reduction device according to Embodiment 3. 6 is a top sectional view of a noise reduction device according to Embodiment 4. FIG. FIG. 7 is a top sectional view of a noise reduction device according to a fifth embodiment. FIG. 10 is a side cross-sectional view of a noise reduction device according to a sixth embodiment. It is a side view of the electric vacuum cleaner concerning Embodiment 7. It is a graph which shows the measurement result of the noise characteristic before and behind mounting | wearing with a noise reduction apparatus. FIG. 10 is a side sectional view of a noise reduction device according to an eighth embodiment. FIG. 10 is a side cross-sectional view of a noise reduction device according to a ninth embodiment. FIG. 10 is a side sectional view of a noise reduction device according to a tenth embodiment. FIG. 20 is a side sectional view of a noise reduction device according to Embodiment 11. Detailed operations of the first acoustic air passage 21 and the second acoustic air passage 22 are shown. FIG. 20 is a side sectional view of a noise reduction device according to Embodiment 12. It is a sectional side view which shows the structural example (A) (B) of the noise reduction apparatus which concerns on Embodiment 13.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 Suction port, 2 1st damping plate, 3 guide part, 4 2nd damping plate, 5 opening part, 6 1st convex part, 7 2nd convex part, 8 1st expansion space part, 9 1st 2 expansion spaces, 10 sound absorbing material, 11 first wall, 12 second wall, 13 first wall interval, 14 second wall interval, 15 sound channel port, 15 ′ sound channel port, 16 Recessed part, 5A Compression space of the opening 5, 5B Expansion space of the opening 5, 700 Vacuum cleaner, 710 Noise reduction device, 711 Motor, 712 Dust collection chamber, 21 First acoustic wind path, 22 Second acoustic wind path.

Claims (23)

A device for reducing fluid noise transmitted by air through the body,
An air inlet is provided in the housing of the device body,
In the housing, a first attenuation plate is provided in a direction intersecting with the traveling direction of the fluid noise that has entered the main body from the suction port,
A guide portion is provided by folding the end portion of the first attenuation plate in a direction reverse to the fluid noise traveling direction, and after the fluid noise passes along the guide portion, along the inner wall of the housing Form a passage to progress,
At the end of the main body housing on the outlet side, a second attenuation plate is provided in a direction intersecting with the traveling direction of the fluid noise,
One or more openings are formed in the second damping plate, and fluid noise that has entered the main body is radiated from the openings,
Providing a second expansion space between the first attenuation plate and the second attenuation plate;
In the second expansion space portion, a plurality of first walls projecting in a bowl shape from the inner wall of the main body housing are provided, and a step path through which fluid noise passes is formed.
Drilling one or more sound channel openings in the first damping plate;
The first wall is
Noise reduction device you characterized in that it is formed so as to prevent passage of fluid noise consisting of the opening and the sound passage openings.   2. The noise reduction device according to claim 1, wherein a first convex portion is provided at a central portion of the first attenuation plate so as to be opposed to a traveling direction of fluid noise. A second protrusion is provided on the inner peripheral edge of the suction port,
The noise reduction device according to claim 2, wherein an S-shaped fluid noise passage is formed by the second convex portion, the first convex portion, and the guide portion. A first expansion space is provided on the back side of the end of the guide,
4. The fluid noise passage formed between the end portion of the guide portion and the inner wall of the main body is formed to be narrower than the first expansion space portion. The noise reduction apparatus in any one. The opening formed in the second damping plate is
The noise reduction device according to any one of claims 1 to 4, wherein an opening diameter on the outer side is larger than an opening diameter on the inner side of the main body. Between the first wall and the second attenuation plate, a plurality of second walls projecting in a bowl shape from the inner wall of the main body housing are provided,
Noise reduction device according to any of claims 1 to 5, characterized in that the formation of the stepped path 2 step path. The first wall is
The noise reduction device according to any one of claims 1 to 6, wherein the noise reduction device is formed so as to obstruct a passage of fluid noise including the guide portion and the opening portion. The second wall is
Wherein a gap between the first wall between the noise reducing device according to claim 6 or claim 7, characterized in that it has formed to prevent the passage of fluid noise consisting of the opening. The noise reduction device according to claim 8 , wherein a width of the first wall is longer than a gap between the second walls. The lateral width of the second wall, the noise reduction device according to claim 8 or claim 9, characterized in that formed longer than the gap between the first wall. Noise reduction device according to any of claims 1 to 1 0, characterized in that were provided with sound absorbing material on said second expansion space. The noise reduction device according to any one of claims 2 to 11, wherein one or more concave portions are provided on the surface of the first convex portion. Wherein the surface of the first damping plate, noise reduction device according to any of claims 1 to 1 2, characterized in that a plurality of granular protrusions. Wherein the surface of the second protrusions, noise reduction device according to any of claims 3 to 1 3, characterized in that a plurality of granular protrusions. A device for reducing fluid noise transmitted by air through the body,
An air inlet is provided in the housing of the device body,
In the housing, a first attenuation plate is provided in a direction intersecting with the traveling direction of the fluid noise that has entered the main body from the suction port,
A guide portion is provided by folding the end portion of the first attenuation plate in a direction reverse to the fluid noise traveling direction, and after the fluid noise passes along the guide portion, along the inner wall of the housing Form a passage to progress,
At the end of the main body housing on the outlet side, a second attenuation plate is provided in a direction intersecting with the traveling direction of the fluid noise,
One or more openings are formed in the second damping plate, and fluid noise that has entered the main body is radiated from the openings,
Providing a second expansion space between the first attenuation plate and the second attenuation plate;
In the second expansion space portion, a plurality of first walls projecting in a bowl shape from the inner wall of the main body housing are provided, and a step path through which fluid noise passes is formed.
Between the first wall and the second attenuation plate, a plurality of second walls projecting in a bowl shape from the inner wall of the main body housing are provided,
Forming the step road into two step paths;
The guide portion is formed by folding back one of the upper and lower ends of the first damping plate in a direction reverse to the traveling direction of fluid noise,
The passage of fluid noise consisting of the other end and the inner wall of the body housing is
The passage is formed wider than the passage formed by the guide portion, and the fluid noise passage formed by the other end portion of the second expansion space portion and the inner wall of the main body housing is connected to the opening portion. the portion extending said first wall and noise reduction device you characterized in that a second wall. The noise reduction device according to claim 15 , wherein a sound absorbing material is disposed in a portion from the passage formed by the guide portion to the opening portion in the second expansion space portion. The noise reduction device according to any one of claims 5 to 16 , wherein the opening formed in the second attenuation plate is formed in a horn shape and satisfies the following expression (1). .

The noise according to any one of claims 5 to 17 , wherein the opening formed in the second damping plate is formed in a two-stage cylindrical shape and satisfies the following expression (2). Reduction device.

Vacuum cleaner being characterized in that disposed in the main body exhaust port noise reduction device according to any of claims 1 to 18. A temperature sensor or an air volume sensor is installed at either exhaust port on the outlet side of the main body housing
The noise reduction device according to any one of claims 1 to 18 , further comprising output means for outputting the detected value. The sound absorbing material is
The noise reduction device according to claim 11 or 16, wherein the noise reduction device is molded using a PET material or a non-woven fabric so as to have a corrugated cross section. The sound absorbing material is
The noise reduction device according to claim 21 , wherein a shape retaining material molded with resin yarn is mixed to form a space through which air passes. Vacuum cleaner, characterized in that arranged the noise reduction device according to the body outlet to claim 2 0 to claim 22.

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