JP6589131B2 - Blower - Google Patents

Description

  The present invention relates to an air blower with reduced noise.

  Hereinafter, background art will be described for a range hood as an example of a blower.

  In recent years, with the diversification of the layout of a residence, cases where a kitchen and a living room are provided in the same space are increasing. Accordingly, in order to prevent noise from entering the living room and maintain quietness, the range hood installed in the kitchen is more demanded to reduce noise generated during operation. Moreover, since the frequency characteristics of the noise of the range hood tend to be distributed over a wide area, it is necessary to obtain a silencing effect in a wide frequency range.

  As one means for solving such a problem, it is known to mount an active silencer unit constituted by a plurality of small-diameter air passages in a range hood. (For example, refer to Patent Document 1).

  Hereinafter, the range hood will be described with reference to FIG.

  As shown in FIG. 15, the conventional range hood includes a blower 102 in the upper portion of the range hood 101, an active silencer unit 103 in the middle position, and a hood 104 in the lower portion. In such a range hood 101, a plurality of small-diameter air passages 107 (shown in FIG. 15 as small-diameter air passages 107a and 107b) are formed between the suction port 105 of the blower 102 and the opening 106 of the hood 104. Each of the small-diameter air passages 107 is provided with an active silencer 108.

  In the active silencer 108 of the small-diameter air passage 107a, the downstream microphone 109a, the speaker 110a, and the upstream microphone 111a are arranged in this order from the side near the suction port 105 of the blower 102. Similarly, in the active silencer 108 of the small-diameter air passage 107b, the downstream microphone 109b, the speaker 110b, and the upstream microphone 111b are arranged in this order from the side close to the suction port 105 of the blower 102.

  Then, the noise generated by the operation of the blower 102 is detected by the downstream microphone 109 (showing the downstream microphone 109a and the downstream microphone 109b), and the phase of the detected noise from the speaker 110 (showing the speaker 110a and the speaker 110b) is reversed. A noise was emitted to cancel each noise in the small-diameter air passage 107 to reduce the noise.

  In general, a duct-shaped active silencer can control up to a frequency band in which a plane wave is formed, and it is known that the frequency F varies depending on the duct diameter D. Specifically, the sound speed is used to determine from F = 0.5 × sound speed / D. That is, it is possible to mute over a wide band by reducing the duct diameter.

  Furthermore, by constructing the active silencer unit 103 from the plurality of small-diameter air passages 107, it is possible to secure an air volume for exhausting the oily smoke generated during cooking sufficiently.

JP 2014-163570 A

  However, in the range hood described in Patent Document 1, a phenomenon (hereinafter referred to as crosstalk) in which mutual control sounds come and go between a plurality of small-diameter air passages 107 occurs. That is, the control sound transmitted from the speaker 110a of the arbitrary small-diameter air passage 107a is radiated from the opening on the blower 102 side of the small-diameter air passage 107a. The radiated control sound is reflected, for example, on the side surface of the blower 102 and transmitted to the adjacent small-diameter air passage 107b, and is detected by the microphone 108b of the small-diameter air passage 107b. As a result, it has been found that the microphone 108b cannot detect only the noise of the small-diameter air passage 107b to be muffled, the muffling control becomes unstable, and the muffling effect is reduced.

That is, there is a problem that the silencing effect is reduced due to the influence of crosstalk caused by the configuration of the plurality of small-diameter air paths 107.
Therefore, the present invention solves the above-described problems, and an object thereof is to provide a blower device that improves the silencing effect of the active silencing device.

  In order to achieve the above object, the air blower according to the present invention includes a suction port for sucking air on the upstream side in the air flow direction, and a discharge port for discharging air sucked from the suction port. A blower passage communicating the suction port and the discharge port, a blower unit provided inside the blower passage for guiding air from the suction port to the discharge port, and a partition on the upstream side of the blower unit A divided air passage that divides the air passage into two or more through a wall, a suction space formed between the air blowing portion and the divided air passage, and the divided air passage arranged with respect to the divided air passage An active silencer for silencing the inside, and a dividing wall arranged in the suction space to prevent the sound from passing between the adjacent divided air passages, thereby achieving the intended purpose. To achieve.

  ADVANTAGE OF THE INVENTION According to this invention, the air blower which reduced the influence of the crosstalk which arises between several division | segmentation air paths can be provided.

The figure which shows the installation state of the range hood which concerns on Embodiment 1 of this invention. The figure which shows schematic structure of the range hood which concerns on Embodiment 1 of this invention. Side sectional view of the vicinity of the divided air passage according to the first embodiment of the present invention. Side sectional view of the range hood according to Embodiment 1 of the present invention. Side sectional view which shows the relationship between the active sound deadening part and the casing when the dividing hood according to Embodiment 1 of the present invention is not provided with a dividing wall The perspective view which shows the casing periphery of the range hood which concerns on Embodiment 1 of this invention. Sectional drawing of the exhaust part of the range hood which concerns on Embodiment 1 of this invention. The perspective view which shows the casing periphery of the range hood which concerns on Embodiment 2 of this invention. Sectional drawing of the exhaust part of the range hood which concerns on Embodiment 2 of this invention. The perspective view which shows the casing periphery in the case of being short in the perpendicular direction with the range hood which concerns on Embodiment 2 of this invention. The perspective view which shows the casing periphery of the range hood which concerns on Embodiment 3 of this invention. Sectional drawing of the exhaust part of the range hood which concerns on Embodiment 3 of this invention. Sectional drawing of the exhaust part of the range hood which concerns on Embodiment 4 of this invention. Sectional drawing of the exhaust part of the range hood which concerns on Embodiment 5 of this invention. Side view of a conventional range hood

  The blower according to claim 1 of the present invention includes a suction port that sucks air on the upstream side in the air flow direction, a discharge port that discharges air sucked from the suction port, the suction port, and the discharge port. An air passage that communicates with the air passage, an air passage that is provided inside the air passage, guides air from the suction port to the exhaust port, and a partition wall on the upstream side of the air blowing portion. A divided air passage that is divided into two or more, a suction space formed between the blower and the divided air passage, and an active silencer that is arranged with respect to the divided air passage and silences the divided air passage. And a dividing wall that is arranged in the suction space and prevents sound from passing between the adjacent divided air passages.

  Thereby, it is possible to prevent control sounds generated from the speakers from passing between adjacent divided air paths. That is, occurrence of crosstalk is prevented, and noise can be accurately detected without detecting control sound generated by a speaker in a divided air path adjacent to the microphone. As a result, the silencing effect of the active silencing device can be improved.

  In the blower according to claim 2 of the present invention, the dividing wall is a shielding plate that shields a sound wave from the divided air passage.

  Thereby, the control sound generated from the speaker of the divided air passage and radiated to the suction space is shielded by the shielding plate that is the dividing wall. That is, the control sound radiated from the blower side opening of the divided air passage can be prevented from propagating through the suction space and entering the adjacent divided air passage. Thereby, generation | occurrence | production of crosstalk can be prevented and the silencing effect of an active silencer can be improved.

  Moreover, the air blower which concerns on Claim 3 of this invention is a shielding board with which the said division wall was extended in the said suction space of the downstream of the said division | segmentation air path from the end surface of the said partition wall.

  As a result, the partition wall is interposed between the end face of one of the divided air paths and the end face of the other divided air path, so that the suction space is generated from the speaker of the divided air path and from the blower side opening of the divided air path. The control sound radiated to reaches the other divided air path by bypassing the shielding plate. That is, since the distance to the other divided air passage becomes longer, the control sound is hardly transmitted. That is, the control sound radiated from the blower side opening can be prevented from propagating through the suction space and entering the adjacent divided air passage. Thereby, generation | occurrence | production of crosstalk can be prevented and the silencing effect of an active silencer can be improved.

  Moreover, the air blower which concerns on Claim 4 of this invention WHEREIN: The said division wall reflects the sound wave from the said division | segmentation air path in the inner wall direction from the center of the said air flow path in the upstream edge part of the said air blowing part. It is a reflector.

  Thereby, the control sound generated from the speaker of the divided air passage and radiated from the blower side opening of the divided air passage to the suction space reaches the reflecting plate provided at the upstream end of the air blowing portion and is reflected. Then, the traveling direction is changed toward the inner wall of the range hood. In other words, the light is reflected in a direction away from the center of the air passage, and proceeds in a direction away from the adjacent divided air passage. As a result, it is possible to prevent the control sound radiated from the blower side opening from propagating through the suction space and entering the adjacent divided air passage. Thereby, generation | occurrence | production of crosstalk can be prevented and the silencing effect of an active silencer can be improved.

  Further, in the blower device according to claim 5 of the present invention, the blower unit includes a fan, a motor that drives the fan, and a cylindrical casing that includes the fan and includes an inlet that sucks in air. The inflow port is provided in parallel to the air flow direction at the suction port, and the reflecting plate has two contact surfaces in contact with the side surface of the casing intersecting between the divided air passage and the air blowing unit. Thus, the bent portion is configured.

  Thereby, the control sound generated from the speaker of the divided air passage and radiated from the blower side opening of the divided air passage to the suction space reaches the reflecting plate provided at the upstream end of the air blowing portion and is reflected. Then, change the direction of travel toward the inner wall of the range hood. Thereby, generation | occurrence | production of crosstalk can be prevented and the silencing effect of an active silencer can be improved.

Moreover, the air blower which concerns on Claim 6 of this invention WHEREIN: The said air blower is provided with an inflow port in parallel with the flow direction of the air in the said suction inlet, The said division wall is the said division | segmentation air path, an air blower, and Are connected.
As a result, the suction space can be divided between the adjacent divided air passages in a cross-sectional view, so that the control sound generated from each speaker is transmitted and received through the gap between the divided wall and the divided air passage or the air blowing section. Can be prevented. Therefore, the occurrence of crosstalk can be prevented more efficiently. In addition, it is possible to suppress the vortex and turbulence of the airflow generated when the airflow branches or collides in the gap between the dividing wall and the divided air passage or the air blowing section, and it is possible to prevent the generation of noise due to the vortex and turbulence of the airflow. Thereby, the microphone can detect only the noise of the corresponding divided air passage. As a result, the silencing effect of the active silencing device can be improved.

  Moreover, the air blower which concerns on Claim 7 of this invention WHEREIN: The said division wall reflects the wave of the sound from the said division | segmentation air path in the inner wall direction from the center of the said air flow path in the upstream edge part of the said air blowing part. The reflecting plate and the shielding plate that shields the sound wave from the divided air path are configured.

  As a result, the suction space can be divided between the adjacent divided air passages in a cross-sectional view, so that the control sound generated from each speaker is transmitted and received through the gap between the divided wall and the divided air passage or the air blowing section. Can be prevented. Therefore, the occurrence of crosstalk can be prevented more efficiently. Moreover, it can suppress that the airflow which flows out out of several division | segmentation air path branches or collides in the clearance gap between a division | segmentation air path or a ventilation part. Furthermore, since the reflecting plate has an inclination, the traveling direction of the airflow smoothly changes along the reflecting plate, and the collision with the casing can be suppressed. Thereby, generation | occurrence | production of the noise by the vortex or disturbance which arises by the collision of an airflow can be prevented, and a microphone can detect only the noise of a corresponding division | segmentation wind path. As a result, the silencing effect of the active silencing device can be improved.

  Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings for understanding of the present invention. In addition, the following embodiment is an example which actualized this invention, Comprising: The thing of the character which limits the technical scope of this invention is not. Moreover, in order to avoid duplication, the same number is attached | subjected about the same site | part through all drawings, and the description after the 2nd is abbreviate | omitted. Furthermore, in each drawing, the description of the details of each part not directly related to the present invention is omitted.

(Embodiment 1)
First, the installation state of the range hood which concerns on this Embodiment is demonstrated using FIG. In addition, FIG. 1 is a figure which shows the installation state of the range hood which concerns on Embodiment 1 of this invention.

  As shown in FIG. 1, the range hood 1 attached to the kitchen is attached above the cooking device 2. The range hood 1 includes a hood portion 3 arranged so as to cover the upper surface of the cooking device 2 and an exhaust portion 4 formed so as to protrude toward the center upper surface side of the hood portion 3. In addition, a duct 9 is connected above the exhaust unit 4 (exhaust direction), and constitutes an air path for exhausting the exhaust from the exhaust unit 4 to the outside of the room, for example. In addition, the front surface of the range hood 1 when it sees from the arrow X direction in FIG. 1, ie, the surface of the range hood which a chef faces at the time of cooking, is defined as a range hood front surface. In addition, an operation unit 5 that operates a later-described air blowing unit of the range hood is disposed on the front surface of the range hood of the hood unit 3.

  Then, the structure of the range hood 1 which concerns on this Embodiment using FIG. 2 is demonstrated. In addition, FIG. 2 is a figure which shows schematic structure of the range hood which concerns on Embodiment 1 of this invention. Moreover, in FIG. 2, the state which removed the panel of the range hood front side of the exhaust part 4 is shown in order to use for an understanding, and the baffle plate 46 with which the collection port of the hood part 3 was equipped is represented by the dotted line. .

  As shown in FIG. 2, the range hood 1 includes a rectangular parallelepiped exhaust portion 4 and a hood portion 3 below the exhaust portion 4 (downward in the drawing and upstream as described later).

  The exhaust part 4 has a vertically long rectangular parallelepiped shape having a discharge port 7 opened on the top surface 6 (upward direction in the drawing and downstream direction described later) and a suction port 8 opened in the lower part. By connecting the duct 9 to the discharge port 7, the discharge port 7 of the range hood 1 can be communicated outdoors. The duct 9 is not included in the range hood 1. Further, the suction port 8 communicates with the downstream opening 28 of the hood portion 3.

  Inside the exhaust part 4, an air passage 40 is formed to communicate the suction port 8 and the discharge port 7. The inside of the air passage 40 is divided air that divides the air passage 40 into two or more with a blower 10 that guides air from the suction port 8 to the discharge port 7 and a partition wall 44 on the upstream side of the air blower 10. A passage 11 and a suction space 45 formed between the blower 10 and the divided air passage 11 are provided. The divided air passage 11 is connected to the suction port 8 on the upstream side. Further, the exhaust unit 4 includes an active silencer 26 that is arranged with respect to the divided air passage 11 and silences the divided air passage 11.

  The air blower 10 is connected to the discharge port 7 on the downstream side of the air passage 40. The blower unit 10 includes a fan 12, a motor (not shown) that drives the fan 12, and a casing 13 that includes the fan 12 and includes an inlet 15 that sucks air. That is, the air blowing unit 10 is located above the exhaust unit 4 and exhausts air in the air passage 40 connecting the suction port 8 and the discharge port 7.

  As shown in FIG. 2, the casing 13 is composed of a scroll plate 55 that expands the air path in the centrifugal direction on the outer periphery of the fan 12 and a plate body that is disposed so as to sandwich the end face of the scroll plate 55. The casing 13 includes a substantially cylindrical side surface formed by a scroll plate 55, and a top plate 56 and a bottom plate 57 arranged as the plate on both sides of the side surface (in FIG. 2, the bottom plate 57 is a top plate). It is not shown because it is arranged on the back side with respect to the plate 56). The substantially cylindrical shape does not indicate an exact cylindrical shape. That is, the top plate 56 and the bottom plate 57 in the casing 13 do not have to be perfect circles, but are adapted to the scroll plate 55 that expands the air path. Hereinafter, in the description, the distance between the top plate 56 and the bottom plate 57 in the outer shape of the casing 13 is referred to as the height of the casing 13.

  The casing 13 includes a discharge port 14 connected to the discharge port 7 and an inflow port 15 that opens to the air passage 40 side. Here, the opening surface of the inflow port 15 is provided on each of the top plate 56 and the bottom plate 57 of the casing 13. As described above, the double-sided suction type casing 13 is used in the present embodiment, but the single-sided suction type casing 13 may be used. The double-sided suction type is a shape having an inlet on each of the cylindrical top plate 56 and the bottom plate 57, and the single-sided suction type is a shape having an inlet 15 on only one of the top plate 56 and the bottom plate 57. . In the present embodiment, inside the exhaust section 4, one opening surface of the inlet 15 faces the front surface of the range hood 1, and the other opening surface faces the back surface of the range hood 1.

  In FIG. 3, the two divided air passages 11 are arranged below the air blowing unit 10 (upstream side to be described later). In the front view of the ren hood, they are arranged in parallel on the left and right with the partition wall 44 interposed therebetween. Furthermore, the depth of the two divided air paths 11 is shorter than or equal to the height of the casing 13.

  As described above, the suction space 45 is a space formed between the blower unit 10 and the divided air passage 11, and in the present embodiment, the divided air passage 11 is connected to the suction port 8 on the upstream side to blow air. The unit 10 connects the discharge port 14 to the discharge port 7, and provides a ventilation intermediate space 17 between the blowing unit side opening 16 of the divided air passage 11 and the lower end of the casing 13 of the blowing unit 10 (for details). Will be described later). The ventilation intermediate space 17 is also a part of the suction space 45.

  As shown in FIG. 2, the hood 3 includes a top plate 27, a downstream opening 28 provided at the center of the top plate 27, a side wall 29 surrounding the outer periphery of the top plate 27, and a downstream opening 28. A rectifying plate 46 (indicated by a broken line in FIG. 2) is provided below (downward in the drawing and upstream direction described later).

  The top plate 27 constitutes one surface above the hood portion 3 (upward in the drawing and downstream direction described later).

  The downstream opening 28 is an opening having a substantially square cross section and communicates with the suction port 8 of the exhaust part 4 provided on the upper surface side of the top plate 27. At the edge of the top plate 27, a side wall 29 protrudes downward (downward in the drawing, upstream direction described later), and the side wall 29 and the top plate 27 open the collection downward. A mouth 30 is formed.

  The rectifying plate 46 is a plate disposed below the downstream opening 28. As a result, the collection port 30 serving as an intake port for air into the hood portion 3 is formed by the inner periphery of the side wall 29 and the outer periphery of the rectifying plate 46. The rectifying plate 46 is provided in order to ensure the flow velocity of the airflow at the collection port 30, and is configured to cover the downstream opening 28 provided at the center of the top plate 27 from below.

  Then, the structure of the upstream of the ventilation path 40 of the range hood 1 which concerns on this Embodiment is demonstrated in detail using FIG. FIG. 3 is a side sectional view of the vicinity of the divided air passage according to the first embodiment of the present invention.

  As shown in FIG. 3, the ventilation intermediate space 17 is provided with a distance of about ¼ of the opening diameter of the inflow port 15 between the blower side opening 16 and the lower end of the casing 13. . The ventilation intermediate space 17 is effective for guiding the airflow flowing out from the blower side opening 16 of the divided air passage 11 to the inlet 15 of the casing 13 without stagnation. That is, the divided air passage 11 allows the suction port 8 and the ventilation intermediate space 17 to communicate with each other, and the blower side opening 16 of the divided air passage 11 is opened facing the side surface 42 of the cylindrical shape of the casing 13. . The blower-side opening 16 is provided on the blower-side opening end face 18 that is the downstream end of the divided air passage 11. In the ventilation intermediate space 17, a shielding plate 19 is provided as a dividing wall 54 that connects a side surface 42 of the casing 13 and a partition wall end surface 47 that is an end surface on the downstream side of the partition wall 44.

  The divided air passage 11 is surrounded by a partition wall 44 and an inner wall 20, and the inner wall 21, which is the inner side of the side plate 43 of the exhaust part 4, is located on the outer side of the inner wall 20. It has a structure that suppresses release.

  The divided air passage 11 provided in the exhaust unit 4 below the casing 13, that is, on the upstream side of the air blowing unit 10, includes a downstream microphone 22, a speaker 23, an upstream microphone 24, and an arithmetic controller 25. An active silencer 26 is provided.

  Next, the configuration of the active silencer 26 will be described in detail. As shown in FIG. 3, the active silencer 26 includes an upstream microphone 24, a speaker 23, and a downstream microphone 22 in order from the suction port 8 side on the inner wall 20 of each of the plurality of divided air paths 11. In addition, an arithmetic controller 25 is provided that generates an audio signal whose phase and amplitude are adjusted from the signals of the downstream microphone 22 and the upstream microphone 24 and oscillates from the speaker 23.

  The upstream microphone 24 and the speaker 23 are brought closer to the suction port 8 side from the central part in the height direction of the divided air passage 11, and the downstream microphone 22 is also brought closer to the air blowing part 10 side which is a noise source from the central part. It is installed. As a result, the upstream microphone 24 and the speaker 23 are disposed farther from the air blowing unit 10 than the downstream microphone 22.

  The arithmetic controller 25 is connected to the upstream microphone 24, the speaker 23, and the downstream microphone 22, and is disposed in the space between the divided air path 11 and the inner wall 21 of the exhaust unit 4. This space has a rectangular tube shape that goes around the inner wall 21 of the exhaust portion 4, an upstream plate extending from the upstream end of the divided air passage 11 toward the inner wall 21 of the exhaust portion 4, and the divided air passage 11. A blower-side opening end surface 18 extending in the direction of the inner wall 21 of the exhaust part 4 from the downstream end of the exhaust part 4 constitutes a space independent of the air passage 40. Thus, by providing the calculation controller 25 in a space independent of the air blowing path 40, it is isolated from smoke, oily smoke, steam, or the like.

  Then, operation | movement of the range hood 1 is demonstrated using FIG. FIG. 4 is a side sectional view of the range hood according to Embodiment 1 of the present invention. In FIG. 4, for the sake of understanding, the rectifying plate 46 provided in the collection port of the hood portion 3 is indicated by a broken line.

  In the above configuration, when the range hood 1 is operated, air is collected by the collection port 30 as shown by a broken line in FIG. 4 due to the operation of the air blowing unit 10, and an air flow flowing from the suction port 8 toward the duct 9 is generated. In addition, air containing smoke and water vapor rising from below (upstream direction) during cooking is collected.

  The air sucked from the suction port 8 passes through the air passage 40 in the order of the divided air passage 11, the ventilation intermediate space 17, the inflow port 15, and the air blowing unit 10, and then passes through the duct 9 from the discharge port 14 to the outside of the exhaust unit 4. Is exhausted. Since the active air silencer 26 is provided in the divided air passage 11, the noise radiated from the divided air passage 11 is detected by the downstream microphone 22, and the reverse phase sound controlled by the arithmetic controller 25 is output from the speaker 23. As a result, the noise of the air blowing unit 10 accompanying the air blowing is reduced. And the reduced noise is radiated | emitted from the collection port 30. FIG.

  The above is the basic operation of the range hood 1 of the present embodiment.

  Next, the crosstalk phenomenon solved by the range hood 1 of the present embodiment will be described with reference to FIG. FIG. 5 is a side sectional view showing the relationship between the active silencer 26 and the casing 13 when the shielding plate 19 as a dividing wall is not provided. In FIG. 5, the divided air passage 11, the downstream microphone 22, the speaker 23, and the upstream microphone 24 described above are distinguished from each other by adding alphabets “a” and “b” to the respective codes. That is, the divided air passage 11 is displayed as a divided air passage 11a and a divided air passage 11b, and the divided air passage 11a includes a downstream microphone 22a, a speaker 23a, and an upstream microphone 24a. Similarly, the divided air passage 11b adjacent to the divided air passage 11a includes a downstream microphone 22b, a speaker 23b, and an upstream microphone 24b.

  As described above, the speaker 23a radiates the control sound having the opposite phase into the divided air path 11a with respect to the noise detected by the downstream microphone 22a. This control sound acts on the noise transmitted through the divided air passage 11a, and a reduced sound is emitted from the collection port 30 described in FIG. However, at this time, a part of the control sound generated by the speaker 23a of the divided air passage 11a is transmitted through the divided air passage 11a as shown by the dotted line in FIG. 5, and is sucked from the blower side opening 16 of the divided air passage 11a. Radiated to the ventilation intermediate space 17 which is a part of the space 45. The control sound radiated to the ventilation intermediate space 17 is transmitted through the ventilation intermediate space 17 or is reflected by the side surface 42 of the casing 13 and enters the adjacent divided air passage 11b. A phenomenon occurs in which the downstream microphone 22b and the upstream microphone 24b in the adjacent divided air passage 11b detect this control signal. This phenomenon is called crosstalk, and the two microphones (downstream microphone 22b and upstream microphone 24b) in the adjacent divided air passage 11b cannot detect noise correctly in the corresponding divided air passage 11 due to the crosstalk. As a result, the control of the active silencer 26 becomes unstable and the silencing effect is reduced. This also occurs in the divided air passage 11a in the same manner as the crosstalk affected by the speaker 23b. That is, a sound traffic occurs between the divided air paths 11, and neither of the divided air paths 11 can detect noise correctly.

  Next, the dividing wall 54 that prevents the sound from passing between the divided air paths 11 will be described with reference to FIGS. 6 and 7. FIG. 6 is a perspective view showing the vicinity of the casing 13 of the range hood according to the first embodiment of the present invention (including the blower side opening 16 of the divided air passage 11). FIG. 7 is a cross-sectional view of the exhaust section 4 of the range hood according to Embodiment 1 of the present invention.

  As shown in FIG. 6, the shielding plate 19 connects the lower end portion of the side surface 42 of the casing 13 and a partition wall end surface 47 that is an end surface of the partition wall 44. In addition, when the end surface of the partition wall 44 is also viewed as the blower side opening end surface 18, the side surface of the casing 13 and the blower side opening end surface 18 of the divided air passage 11 are connected in the ventilation intermediate space 17.

  In other words, the dividing wall in the present embodiment is a shielding member 19 of a plate member that is installed in the vertical vertical direction so as to divide between the blower side openings 16 of the two divided air passages 11 when the range hood is viewed from the front. That is, the shielding plate 19 spatially separates the two divided air passages 11 in the ventilation intermediate space 17. Accordingly, as shown in FIG. 7, the control sound released from the blower side opening 16 of the one divided air passage 11 to the ventilation intermediate space 17 is shielded by the shielding plate 19, and therefore the other divided air passage. 11 can be prevented from entering. As a result, no crosstalk occurs and the effect of the active silencer 26 can be improved. In the present embodiment, the shielding plate 19 connects the lower portion of the side surface 42 and the partition wall end surface 47 (the blower side opening end surface 18) without any gap. For example, the upstream end of the shielding plate 19 is connected to the partition wall. It is good also as a structure which connects to the end surface 47 (blower part opening end surface 18), and a downstream end part is not connected to the side surface 42. FIG. Alternatively, the downstream end portion of the shielding plate 19 may be connected to the side surface 42, and the upstream end portion may not be connected to the partition wall end surface 47 (blower portion opening end surface 18). Even with this configuration, it is possible to prevent sound from passing between the divided air paths 11 to some extent.

  As described above, by providing the shielding plate 19 so as to connect the side surface of the casing 13 and the partition wall end surface 47 that is the end surface of the partition wall 44 in the ventilation intermediate space 17, the range hood 1 that ensures high noise reduction performance. Can be realized.

(Embodiment 2)
Then, the range hood which concerns on this Embodiment 2 is demonstrated using FIG. 8 and FIG. FIG. 8 is a cross-sectional view around the casing of the range hood according to the second embodiment of the present invention, and FIG. 9 is a cross-sectional view of the exhaust part of the range hood according to the second embodiment of the present invention.

  As shown in FIG. 8, the range hood of the second embodiment includes a divided air passage 48 having a larger air passage cross-sectional area instead of the divided air passage 11 of the first embodiment in order to increase the ventilation air volume. It is a thing. In order to increase the cross-sectional area of the air passage, the depth of the divided air passage 48 is made larger than the height of the casing 13 of the blower 10 (the distance between the top plate 56 and the bottom plate 57), and the height of the casing 13 in plan view. Is arranged so as to be included within the depth of the two divided air paths 48.

  The shielding plate 49 which is the dividing wall 54 of the present embodiment extends from the end face of the partition wall 44 into the suction space 45 on the downstream side of the dividing air passage 48.

  As an example, as shown in FIG. 9, the shielding plate 49 includes a vertical plate 50 extending from the partition wall end surface 47 to the lower end of the side surface 42 of the casing 13, and an end surface positioned at the top of the vertical plate 50. It is comprised from the horizontal plate 51 extended. The horizontal plate 51 is also a member arranged on the outer peripheral side of the inlet 15 and perpendicular to the top surface or bottom surface of the casing 13. That is, in the cross-sectional shape seen from the front side, the shape of the shielding plate 49 is a substantially “T” shape extending in the vertical direction from the end face of the partition wall 44 and extending in the horizontal direction at the tip.

  The shield plate 49 is surrounded on the inner wall 21 side of each of the two divided air passages 48 on the inner wall 21 side, on the downstream side of the blower side opening end face 18 and on the outer peripheral side of the inlet 15 when viewed in front of the range hood. It arrange | positions so that the division | segmentation suction space 52 may be passed. In other words, the shielding plate 49 extends from the end surface of the partition wall 44 to the lower end portion of the side surface 42 of the casing 13, and is configured to be away from each other and away from the adjacent divided air passage 48.

  In the above configuration, the shielding plate 49 has a region partially overlapping the cross section of the divided air passage 48 when viewed in the direction of viewing the blower side opening 16 from the suction port 8. By this shielding plate 49, the shortest distance between the two divided air paths 48 in the suction space 45 can be increased. The sound wave attenuates as the traveling distance becomes longer. That is, as shown in FIG. 9, the control sound released from the blower side opening 16 of the one divided air passage 48 to the suction space 45 is sufficient to reach the other divided air passage 48 by the shielding plate 49. It will be attenuated. As a result, crosstalk hardly occurs and the effect of the active silencer can be improved. In addition, as a dividing wall, a shielding plate 49 extends from the partition wall end surface 47 to the lower end of the side surface 42 of the casing 13, and a horizontal plate 51 extends substantially horizontally at an end surface located at the top of the vertical plate 50. In order to increase the cross-sectional area of the air passage, the horizontal plate 51 can shorten the distance between the divided air passages 48 even when the depth of the divided air passage 48 is larger than the height of the casing 13 of the blower unit 10. The distance can be increased. And it becomes difficult to generate | occur | produce crosstalk, and the effect of an active silencer can be improved.

  In the present embodiment, the shielding plate 49 has a substantially “T” shape extending in the vertical direction from the partition wall end surface 47 and extending in the substantially horizontal direction at the tip, but has a predetermined angle from the tip rather than in the horizontal direction. An approximately “Y” shape configuration extending upward or an approximately “V” shape configuration extending in two directions at a predetermined angle directly from the partition wall end face 47 may be employed. Similar effects can be obtained with these configurations.

  Further, in response to the demand for lowering the height of the exhaust part 4, when the vertical longitudinal distance of the ventilation intermediate space 17 included in the suction space 45 is formed short, as shown in FIG. The horizontal plate 51 is arranged so as to be in contact with the outer periphery of the inflow port 15 and the shortest distance between the two divided air paths 48 can be increased. In this case, the vertical plate 50 is provided with a notch 53, and a part of the casing 13 enters the notch 53.

  As described above, by providing the shielding plate 49 composed of the member passing through the partition wall end surface 47 and the lower end portion of the side surface 42 of the casing 13 and the member extending away from the front end thereof, high noise reduction performance is ensured. The cooked range hood 1 can be realized.

(Embodiment 3)
Next, the range hood according to the third embodiment will be described with reference to FIGS. 11 and 12. FIG. 11 is a cross-sectional view around the casing of the range hood according to Embodiment 3 of the present invention, and FIG. 12 is a cross-sectional view of the exhaust part of the range hood according to Embodiment 3 of the present invention.

  As shown in FIG. 11, in the range hood according to the third embodiment, a reflector 32 having a bent portion 31 is provided in the ventilation intermediate space 17. That is, the reflecting plate 32 functions as the dividing wall 54. In the reflection plate 32, two contact surfaces sandwiching the bent portion 31 are in contact with the side surface 42 of the casing 13, and the bent portion 31 is between the lower end portion of the casing 13 and the blower side opening end surface 18 of the divided air passage 11. That is, it is arranged in the ventilation intermediate space 17. That is, as shown in FIG. 12, the reflector 32 has a substantially “<” shape when viewed from the front of the range hood, and is inclined so as to spread toward the downstream side. Further, the bent portion 31 is disposed at the center of the cross section of the two divided air paths 11 on the extension of the divided air paths 11. With this arrangement, the contact surface is directed in a direction in which noise toward the blowing direction is reflected to the inner wall 21 side.

  As a result, the control sound released from the blower-side opening 16 of the one divided air passage 11 to the ventilation intermediate space 17 reaches the reflector 32 provided at the upstream end of the blower 10 and is reflected. The traveling direction is changed toward the inner wall 21 of the range hood 1. In other words, the light is reflected in a direction away from the center of the air passage and travels in a direction away from the adjacent divided air passage 11. As a result, it is possible to prevent the control sound radiated from the blower side opening 16 from propagating through the ventilation intermediate space 17 and entering the adjacent divided air passage 11. As a result, occurrence of crosstalk is prevented, and it becomes possible to accurately detect only the noise of the corresponding divided air passage 11 without detecting the control sound of the adjacent divided air passage 11 by the microphone, and active silencing. The silencing effect of the device can be improved.

  As described above, by providing the reflector 32 having the bent portion 31 in the ventilation intermediate space 17 as the dividing wall 54, the range hood 1 that ensures high noise reduction performance can be realized.

(Embodiment 4)
Next, the range hood according to the fourth embodiment will be described with reference to FIG. In addition, FIG. 13 is sectional drawing of the exhaust part of the range hood which concerns on Embodiment 4 of this invention.

  As shown in FIG. 13, in the range hood according to the fourth embodiment, the dividing wall 54 is configured by the reflecting plate 32 having the bent portion 31 in the ventilation intermediate space 17 and the shielding plate 19 provided on the downstream side of the reflecting plate 32. is doing. The two contact surfaces of the reflector 32 sandwiching the bent portion 31 are in contact with the side surface of the casing 13, and the bent portion 31 is disposed between the lower end portion of the casing 13 and the blower side opening end surface 18 of the divided air passage 11. ing. Further, a shielding plate 19 is provided so as to connect the bent portion 31 which is the lowermost end portion of the reflecting plate 32 and the blower side opening end surface 18 of the divided air passage 11.

  As a result, the control sound released from the blower-side opening 16 of the one divided air passage 11 to the ventilation intermediate space 17 reaches the reflector 32 provided at the upstream end of the blower 10 and is reflected. The traveling direction is changed toward the inner wall 21 of the range hood 1. In other words, the light is reflected in a direction away from the center of the air passage and travels in a direction away from the adjacent divided air passage 11. Moreover, since the clearance gap between the reflection plate 32 and the ventilation part side opening end surface 18 of the division | segmentation air path 11 is shielded by the shielding board 19, it suppresses that a sound advances to the division | segmentation air path 11 side which adjoins through a clearance gap. be able to. As a result, it is possible to prevent the control sound radiated from the blower side opening 16 from propagating through the ventilation intermediate space 17 and entering the adjacent divided air passage 11.

  Further, by connecting the casing 13 from the blower-side opening end face 18 of the divided air passage 11 by a dividing wall 54 constituted by the shielding plate 19 and the reflecting plate 32, the blower-side openings of two adjacent divided air passages 11 are opened. The airflow flowing out from the portion 16 can be prevented from colliding in the ventilation intermediate space 17. Furthermore, since the reflecting plate has an inclination so as to spread toward the downstream side, the airflow smoothly changes its traveling direction along the reflecting plate, and can be prevented from colliding with the casing. Thereby, the eddy and disturbance of the airflow caused by the collision of the airflow can be suppressed. As a result, it is possible to prevent the generation of noise due to the vortex or turbulence of the air current, and the microphone can accurately detect only the noise.

  As described above, the ventilation intermediate space 17 includes the reflecting plate 32 having the bent portion 31 in the ventilation intermediate space 17 as the dividing wall 54 and the shielding plate 19 that connects the bent portion 31 and the blower side opening end surface 18. Thus, it is possible to realize the range hood 1 that secures high noise reduction performance.

(Embodiment 5)
Next, the range hood according to the fifth embodiment will be described with reference to FIG. In addition, FIG. 14 is sectional drawing of the exhaust part of the range hood which concerns on Embodiment 5 of this invention.

  As shown in FIG. 14, in the range hood according to the fifth embodiment, the inlet 15 of the blower 10 is provided vertically when viewed from the suction port 8 side. The ventilation intermediate space 17 is provided with a shielding plate 19 as a dividing wall 54 in the vertical vertical direction from the blower side opening end face 18 of the divided air passage 11 toward the inlet 15 of the blower 10. The shielding plate 19 is a plate member connected to the blower side opening end face 18 in the center of the blower side opening 16 of the adjacent divided air passage 11.

  As shown in FIG. 14, since the control sound emitted from the blower side opening 16 of the one divided air passage 11 to the ventilation intermediate space 17 is shielded by the shielding plate 19, it is diffracted at the end of the shielding plate 19. Then, the air travels to the blower side opening 16 of the other divided air passage 11. That is, the distance that the control sound reaches from the blower side opening of one divided air passage 11 to the other divided air passage 11 becomes longer. Also, the sound attenuates as it progresses. That is, the control sound released from the blower side opening 16 of the one divided air passage 11 to the ventilation intermediate space 17 is sufficiently attenuated before reaching the air blower side opening of the other divided air passage. It will be. As a result, the effect of the active silencer can be improved without detecting a control sound from the divided air path 11 adjacent to each other.

  Further, by connecting the blower-side opening end face 18 of the divided air passage 11 and the shielding plate 19, the airflow flowing out from the blower-side opening 16 of the two adjacent divided air passages 11 collides with the ventilation intermediate space 17. Can be suppressed. Thereby, the eddy and disturbance of the airflow caused by the collision of the airflow can be suppressed. As a result, it is possible to prevent the generation of noise due to the vortex or turbulence of the air current, and the microphone can accurately detect only the noise.

  As described above, by providing the shielding plate 19 as the dividing wall 54 in the ventilation intermediate space 17, the range hood 1 that ensures high noise reduction performance can be realized.

(Modification)
As described above, the silencer technology of the range hood has been described as an example in which the silencer is particularly required in the blower. However, the present invention is not limited to the range hood, and can be applied to any air blower that generates noise by air blowing, such as an air purifier, a dehumidifier, or a ventilation fan.

  In the embodiment described above, the two divided air passages 11 are configured. However, the number of the divided air passages 11 may be increased according to the frequency band to be silenced.

  INDUSTRIAL APPLICATION This invention is useful as a technique applicable to the air blower which generate | occur | produces noise by ventilation, such as a range hood, an air cleaner, a dehumidifier, and a ventilation fan.

DESCRIPTION OF SYMBOLS 1 Range hood 2 Heating cooking equipment 3 Hood part 4 Exhaust part 5 Operation part 6 Top surface 7 Outlet 8 Suction port 9 Duct 10 Blower part 11, 11a, 11b Split air path 12 Fan 13 Casing 14 Outlet 15 Inlet 16 Inlet Part-side opening 17 Ventilation intermediate space 18 Blower-side opening end face 19 Shield plate 20 Inner wall 21 Inner side walls 22, 22a, 22b Downstream microphones 23, 23a, 23b Speakers 24, 24b Upstream microphone 25 Arithmetic controller 26 Active silencer 27 Face plate 28 Downstream opening 29 Side wall 30 Collection port 31 Bending portion 32 Reflector plate 40 Air passage 42 Side surface 43 Side plate 44 Partition wall 45 Suction space 46 Rectifier plate 47 Partition wall end surface 49 Shield plate 50 Vertical plate 51 Horizontal plate 52 Division Suction space 53 Notch 54 Dividing wall 55 Scroll plate 56 Top plate 57 Bottom plate

Claims (6)

And a suction port for sucking the air on the upstream side in the air flow direction,
And a discharge port for discharging the air sucked from the previous Symbol suction port,
And air passage for communicating the front SL inlet and said outlet,
Provided inside of the front Symbol air passage, and a blower for directing air from said inlet to said outlet,
A dividing air duct for dividing the airflow path into two or more by interposing a partition wall on the upstream side of the front Symbol blower,
A suction space formed between front Symbol blower between the divided air path,
And active noise reduction unit disposed to the front Symbol split air passage performing silencing of the divided air passage,
A dividing wall to prevent traffic of sound between the divided air passage adjacent placed before Symbol suction space,
With
The dividing wall has a reflecting plate configured to reflect a sound wave from the divided air passage at an upstream end portion of the air blowing portion from the center of the air blowing passage toward the inner wall. blower to. Before Symbol dividing wall, blower according to claim 1, characterized in that it is configured with a shielding plate for shielding the sound waves from the divided air passage further. Before SL shielding plate, blower according to claim 2, characterized in that it is extended from the end surface of the partition wall to the divided air passage downstream of the suction space of. Before SL blowing unit includes a fan, a motor for driving the fan, a casing of cylindrical shape with an inlet to suck air containing the fan,
Before SL inlet is provided in parallel to the flow direction of air at the suction port,
Before SL reflector, blower according to any one of claims 1 to 3, two contact surfaces in contact with the side surfaces of the casing and wherein the configuring the cross at the suction space bent portion. Before SL blower is parallel to the inlet is provided for direction of air flow in the suction port,
Before Symbol dividing wall, blower according to claim 3, characterized in that the connection between the divided air path between the blower. A suction port for sucking air upstream in the air flow direction;
A discharge port for discharging air sucked from the suction port;
An air passage communicating the suction port and the discharge port;
A blower section that is provided inside the blower path and guides air from the suction port to the discharge port;
A divided air passage that divides the air passage into two or more through a partition wall upstream of the air blowing portion;
A suction space formed between the blowing section and the divided air passage;
An active silencer that is arranged with respect to the divided air passage to mute the divided air passage;
A dividing wall disposed in the suction space to prevent the sound from passing between the adjacent divided air passages;
With
Wave front Symbol dividing wall, the sound of the sound waves from the divided air path from the air flow passage the split air duct a reflector for reflecting the inner sidewall direction from the center of at the upstream end of the blower blower, characterized in that constituted by the shielding plate for shielding.

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