KR102024833B1 - Sound absorbing damper and damper structure using same - Google Patents

Abstract

The present invention relates to a sound absorbing damper and a damper structure using the same. The objective of the present invention is to provide a sound absorbing damper, in which an area for absorbing noise is increased and a sound insulation structure is modified, thereby reducing noise leaking to the outside, and a damper structure using the same. According to the present invention, a damper comprises: a damper housing; a plurality of rotary shafts installed in the damper housing; and a plurality of blades installed on the rotary shafts. The blade comprises a blade body, when converted into a standing position for blocking an air flow path, forming a front side and a rear side, arranged at an inlet side and an outlet side of air, with perforated plates in a vertical position, forming an upper side and a lower side, facing the damper housing or a neighboring blade, with plate materials in an inclined position based on a flowing direction of the air, and thus forming a parallelogram cross section, wherein the upper side and the lower side are inclined in the identical direction and angle; and a sound absorbing material filled in the inside of the blade body. An upper side of the blade is made of a perforated plate. The upper side of the blade, made of the perforated plate is formed to be arranged on the outlet side of the air when the blade rotates for opening the air flowing path. A lower side and an upper side of neighboring two blades are spaced apart and face each other to form an empty space. Protrusion parts are formed on the lower side and the upper side of the two blades by being extended and closely attached to the neighboring blades to close the empty space and form a resonance chamber.

Description

Sound absorbing damper and damper structure using same

The present invention relates to a sound-absorbing damper, and more particularly, to a suction-type damper and a damper structure including the function of a silencer, in which a thick sound-absorbing layer is formed on each blade which rotates to control or block a flow rate of fluid. It is about.

In the general machine room, there are many systems in which the building grill is installed on the outer wall of the building for internal ventilation and the outside is ventilated. However, complaints are frequently generated because the noise transmitted to the outside through these architectural grills transmits the noise exceeding the standard level to the surrounding area.

On the other hand, the conventionally used damper is installed to have a structure in which at least one blade is rotatable inside the damper housing made of tubular shape, it is configured to adjust or block the flow rate of air while the blade rotates by the drive mechanism.

As such, the conventional damper is developed for the purpose of controlling or blocking the flow rate of air, and mainly constitutes a blade using a thin steel plate.

However, in the case of a blade made of thin steel plate, it is effective to control or block the flow of air, but not to block or attenuate the noise, so that the noise generated inside the building is transmitted to the outside along with the discharged air. A separate silencer is installed to prevent this.

On the other hand, Patent Document 1 discloses a damper housing made of a porous sound absorbing material and a metal fiber porous sound absorbing plate, and a damper blade comprising a porous sound absorbing material and a metal porous sound absorbing plate.

The noise reduction damper reduces noise through the sound absorbing effect of the sound absorbing material and the sound absorbing plate provided in the damper housing and the damper blade. Have

However, the blade of the noise damping damper disclosed in Patent Document 1 has a thinner thickness and absorbs noise as the porous suction member is installed inside the porous sound absorbing plate formed in a streamlined structure to minimize the flow resistance of air. There is a problem that less noise reduction effect.

In particular, the noise reduction damper as described above has a problem in that a sufficient noise reduction effect may not be realized in a place where low frequency noise is mainly generated, such as a substation or a power plant.

Patent Application Publication No. 10-0717683 (2007.05.11.Notification)

The present invention has been made in consideration of the above problems, and an object of the present invention is to provide a sound-absorbing damper and a damper structure using the same to reduce the noise flowing to the outside by increasing the area to absorb noise and improving the sound insulation structure. In providing.

The present invention to achieve the object as described above and to accomplish the problem for eliminating the conventional drawbacks is a damper housing consisting of an air flow path connecting the two opposite sides open and the two open sides formed inside; A plurality of rotating shafts installed in the damper housing to have parallel structures spaced apart from each other by a predetermined distance; And a plurality of blades installed on the rotation shaft to adjust or block a flow rate of air flowing through the air flow path while rotating together with the rotation shaft, wherein the blades stand to block the air flow path. When switched to the posture, the front and rear surfaces of the air inlet and outlet sides are vertically perforated plates, and the upper and lower surfaces facing the damper housing or neighboring blades are inclined relative to the air flow direction. A blade body formed of a plate member having a photographic posture and having a cross-section of a parallelogram, the blade body having an upper surface and a lower surface inclined at the same direction and angle; And a sound absorbing material filled in the blade body; wherein the upper surface of the blade is made of a perforated plate, and the upper surface of the blade made of the perforated plate is rotated to open an air flow path, on the discharge side of air. The lower and upper surfaces of the two neighboring blades are formed so as to be spaced apart from each other to form an empty space, and the lower and upper surfaces of the two blades are adjacent to the adjacent blades to form a resonance chamber while closing the empty space. Provided is a sound absorbing damper, characterized in that the protruding portion is extended and in close contact.

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Meanwhile, the sound absorbing damper may further include a shielding plate installed to connect the upper and lower surfaces of the blade to block the flow of air in the blade body.

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Comprising a plurality of sound-absorbing dampers, comprising a controller for integrally controlling a plurality of sound-absorbing dampers, the plurality of sound-absorbing dampers are in close contact with each other along the flow direction of the air and the blades of two adjacent sound-absorbing dampers Are installed to have a structure symmetric with each other, the controller is adjacent to form a structure in which a plurality of blades arranged along the flow direction of the air, or the unfolded structure when the blade rotation is required to control the flow rate of air It provides a damper structure using a sound-absorbing damper, characterized in that it comprises the function of rotating the two blades in different directions.

According to the present invention having the above characteristics, it is possible to reduce the noise more effectively by increasing the sound absorption area and thickness, in particular to effectively reduce the low-frequency noise generated in substations or power plants to prevent damage caused by low-frequency noise It can be effective.

In addition, when the attitude of the blade is switched to block the air flow path, a resonance chamber is formed between two neighboring blades, and noise is reduced by maximizing the transmission loss value through the combined action of the sound absorbing material and the resonance chamber configured in the blade. And the sound insulation effect can be improved.

1 is a perspective view of a sound absorbing damper according to a preferred embodiment of the present invention,
2 is a cross-sectional view of a sound absorbing damper according to a preferred embodiment of the present invention;
3 is a cross-sectional view showing an air flow path is opened by the rotation of the blade according to an embodiment of the present invention,
4 is a perspective view of a blade according to a preferred embodiment of the present invention;
5 is a cross-sectional view of a blade according to a preferred embodiment of the present invention;
6 is a cross-sectional view of a damper structure according to a preferred embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In describing the present invention, if it is determined that the detailed description of the related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

1 is a perspective view of a sound absorbing damper according to a preferred embodiment of the present invention, FIG. 2 is a cross-sectional view of the sound absorbing damper according to a preferred embodiment of the present invention, and FIG. 3 is shown by rotating a blade according to a preferred embodiment of the present invention. 4 is a perspective view of a blade according to a preferred embodiment of the present invention, and FIG. 5 is a cross-sectional view of a blade according to a preferred embodiment of the present invention.

Sound absorbing damper 100 according to the present invention is composed of a damper housing 110, a rotating shaft (120 _n ), a blade (130 _n ).

The damper housing 110 is composed of a tubular body having a rectangular cross-sectional structure consisting of two opposing side surfaces, that is, the front and rear surfaces are opened, and an air flow path 111 connecting the front and rear surfaces is formed therein.

The damper housing 110 may be composed of galvanized steel sheet.

The rotation shaft 120 _n is for rotating the blade 130 _n , and a plurality of the rotation shafts 120 _n are installed to have parallel postures spaced apart from each other in the vertical direction from the inside of the damper housing 110.

On the other hand, the rotary shaft 120 _n is connected to a driving mechanism (not shown) and configured to rotate the blade 130 _n while rotating by the driving mechanism.

The blade 130 _n is disposed inside the damper housing 110 and is coupled to the rotating shaft 120 to rotate or rotate together with the rotating shaft 120 to adjust or block the flow rate of air flowing through the air flow path 111. It is configured to.

The blade 130 _n is composed of a plurality, the plurality of blades 130 _n are arranged adjacent to each other in the vertical direction from the inside of the damper housing 110 to control the area blocking or opening the air flow path 111. Done.

On the other hand, the blade 130 _n according to a preferred embodiment of the present invention is composed of a blade body 131 made of a hexahedral block shape, and the sound absorbing material 132 filled in the blade body 131.

More specifically, the blade body 131 is the air inlet side of the damper housing 110 so as to face the air flowing into the damper housing 110 and the left / right sides 131e and 131f connected to the rotation shaft 120 _n . front (131a) and located at the top surface facing the bottom surface of the back surface (131b) and a blade (130 _n), a top end or adjacent to the air flow 111 is positioned at the air exhaust side of the damper housing 110 ( 131c), and including a bottom surface (131d) facing the upper surface of the air flow by 111, a blade (130 _n or the neighborhood of the lower end) is made as a whole in block form of the cube.

At this time, the front surface (131a) / rear surface (131b) / top surface (131c) / bottom surface (131d) is based on the position when the blade 130 _n is standing in a vertical position to completely block the air flow path (111). I did it.

On the other hand, the front surface (131a) and the rear surface (131b) is composed of a perforated plate perforated with a plurality of holes for smooth inflow of noise.

In addition, the upper surface 131c and the bottom surface 131d are formed of a flat plate inclined to have an inclined posture with respect to the flow direction of air, and the upper surface 131c and the bottom surface 132d have the same direction and angle. It is formed to be inclined.

Therefore, the blade body 131 including the front surface 131a and the rear surface 131b of the vertical posture and the top surface 131c and the bottom surface 131d of the inclined posture has a parallelogram cross section.

According to the blade body 131 having a parallelogram cross-sectional structure and a block shape of a hexahedron, the sound absorbing material 132 can be formed to a sufficient thickness, thereby improving noise reduction efficiency and reducing low frequency noise. and can be reduced more effectively, close the two blades _{(130 n, 130 n + 1} ) a bottom surface (131d) and an upper surface (131c) of the two blades _{(130 n, 130 n + 1} ) adjacent to the top and bottom to come into close contact with each other Even when arranged to enable smooth rotation of the blades (130 _n , 130 _{n + 1} ) for opening the air flow path (111).

Meanwhile, the two blades 130 _n and 130 _{n + 1} disposed adjacent to each other up and down are spaced apart from each other, so that the bottom surface 131d of the upper blade 130 _n and the top surface 131c of the lower blade 130 _{n + 1 are} disposed. The space is formed between the), and the space formed as described above is closed by the protrusions 133 and 134 additionally formed on the blade body 131 to form a resonance chamber S for reducing noise.

That is, having a structure that extends to a blade (130 _n) a top surface (131c) and the rear surface (131d) has two blades _{(130 n, 130 n + 1} ) blade (130 _n) adjacent to close the space formed between the Protrusions 133, 134 are formed, the blade 130 _n according to a preferred embodiment of the present invention protrudes in the vertical lower direction to be in close contact with the front surface (131a) of the lower blade (130 _{n + 1} ) in front of the bottom (131d) The protrusion 133 is formed, and another protrusion 134 protruding in the vertical upper direction is formed at the rear end of the upper surface 131c to closely contact the rear surface 131b of the upper blade 130.

Meanwhile, the upper surface 131c of the blade 130 ₁ disposed at the uppermost end of the plurality of blades 130 _n disposed in the damper housing 110 faces the damper housing 110 and has the corresponding blade 130. No protrusions are formed on the upper surface 131c of ₁ ), and similarly, no protrusions are formed on the bottom surface 131d of the blade 130 ₄ disposed at the lowermost end.

In addition, an elastic pad 136 may be further installed on the inner surfaces of the protrusions 133 and 134 to stably seal the resonance chamber S and to prevent the occurrence of shock and noise during connection between the blades 130.

The blade body 131 configured as described above further includes a shielding plate 135 to block the flow of air.

The shielding plate 135 is formed of a plate in a vertical posture installed to connect the top surface 131c and the bottom surface 131d of the blade 130 _n to the inside of the blade body 131 (the front surface of the blade 130 _n ) It is configured to block the air introduced into 131a to be discharged to the rear surface (131b).

The blade body 131 configured as described above may be formed of a galvanized steel sheet, and the upper surface 131c of the blade 130 _n located at the air discharge side of the damper housing 110 when the air flow path 111 is opened is a perforated plate. It can be configured to further increase the absorption efficiency of the noise.

In particular, when the upper surface 131c of the blade 130 _{n is} formed of a perforated plate, and the resonance chamber S is formed between two adjacent blades 130 _n and 130 _{n + 1} , the inside of the blade body 131 Since a considerable amount of noise introduced into the absorber 132 is absorbed by the sound absorbing material 132 and part of the noise is canceled while colliding with the sound wave of the opposite phase in the process of being propagated and reflected through the upper surface 131c of the perforated plate to the resonance chamber S, Noise can be effectively reduced.

The sound absorbing material 132 is filled in the blade body 131 to form a sound absorbing layer in the blade body 131, it may be composed of a known glass wool.

Sound absorbing damper 100 according to the present invention configured as described above, when the plurality of blades 130 _n is switched to a vertical posture to block the air flow path 111 formed in the damper housing 110, a plurality of Blades 130 _n are connected to each other to form a vertical wall structure to block the flow of air.

In this case, as the resonance chamber S is formed between the two blades 130 _n and 130 _{n + 1} disposed up and down, the sound absorbing material 132 formed in the blade 130 _n and the resonance chamber S are combined. Through this action, the noise emitted to the outside can be more effectively reduced.

On the other hand, even when the blade 130 _n is inclined or switched to a horizontal position for the purpose of adjusting the flow rate of air, the noise is extensively provided through the front surface 131a, the rear surface 131b, and the upper surface 131c made of perforated plates. As it is absorbed while being introduced into the interior of the 130 _n , it is possible to increase the noise reduction effect.

6 illustrates a cross-sectional view of a damper structure in accordance with a preferred embodiment of the present invention.

The damper structure according to the present invention includes a plurality of sound absorbing dampers 100 _n and a controller 200 for integrally controlling the plurality of sound absorbing dampers 100 _n .

The plurality of sound absorbing dampers 100 _n are arranged in series to have side-by-side structures while being in close contact with each other along a flow direction of air.

In this case, two sound absorbing dampers 100 _n disposed to be adjacent to each other are disposed to have a structure in which the blades 130 of each other are symmetric.

That is, when the blade 130 of the front sound absorbing damper 100 ₁ is configured to open the air flow path 111 while rotating clockwise, the blade 130 of the rear sound absorbing damper 100 ₂ rotates counterclockwise. It is configured to open the air flow path 111 while.

Meanwhile, each of the sound absorbing dampers 100 _n has been described with reference to FIGS. 1 to 5, and thus, a detailed description of the structure of the sound absorbing dampers 100 _n will be omitted.

For reference, FIG. 6 illustrates a structure in which two sound absorbing dampers 100 _{1 and} 100 ₂ are arranged in a direct connection structure.

When the controller 200 is required to rotate the blade 130 to adjust the flow rate of air, the plurality of blades 130 are rotated by rotating the blades 130 disposed adjacent to each other along the air flow direction. Is configured to include a function of controlling each sound absorbing damper to form a wavy structure.

The damper structure using the sound absorbing damper configured as described above can change the posture of the blade 130 to more various structures, thereby further increasing the noise reduction effect.

The present invention is not limited to the above-described specific preferred embodiments, and various modifications can be made by any person having ordinary skill in the art without departing from the gist of the present invention claimed in the claims. Of course, such changes will fall within the scope of the claims.

<Explanation of symbols for the main parts of the drawings>
100: sound absorption damper 110: damper housing
111: air flow path 120 _n : rotation axis
130 _n : blade 131a: front
131b: back side 131c: top side
131d: Bottom 131: Blade Body
132: sound absorbing material 133, 134: protrusion
135: shield plate 200: controller

Claims (5)

A damper housing 110 having two opposite sides open and an air flow path 111 connecting the two open sides; A plurality of rotation shafts 120 _n installed in the damper housing 110 to have parallel structures spaced apart from each other by a predetermined distance; And in the damper comprising a plurality of blades (130 _n) for adjusting the flow rate of air or block which rotates with the rotary shaft (120 _n), the rotation axis (120 _n) she is provided to flow through 111 to the air flow ,
When the blade 130 _n is converted to a standing position for blocking the air flow path 111, the front surface 131 a and the rear surface 131 b positioned at the inflow side and the exhaust side of the air are perpendicular to each other. The upper surface 131c and the bottom surface 131d formed of perforated plates and facing the damper housing 110 or the neighboring blade 130 _n are formed of a plate having an inclined posture in the direction of air flow, so that the cross section has a parallelogram shape. It is made to have, but the upper surface (131c) and the bottom surface (131d) is formed in the inclined in the same direction and angle blade body (131); And a sound absorbing material 132 filled in the blade body 131.
An upper surface (131c) of the blade (130 _n) is made of a perforated plate, an upper surface (131c) of the blade (130 _n) consisting of a perforated plate when the rotating blade (130 _n) for the opening of the air flow 111 , Is formed to be located on the discharge side of the air,
Of the bottom surface (131d) and the upper face (131c), while facing remain spaced apart from one another is made so as to form an open area, the two blades _{(130 n, 130 n + 1} ) of the adjacent two blades _{(130 n, 130 n + 1} ) Sound absorbing damper, characterized in that the bottom surface (131d) and the upper surface (131c) is formed with protrusions (133, 134) are extended to the adjacent blades to form a resonance chamber (S) while closing the empty space. delete The method according to claim 1,
And a shielding plate 135 installed to connect the top surface 131c and the bottom surface 131d of the blade 130 _n to the inside of the blade body 131 to block the flow of air. Damper. delete Comprising a plurality of sound-absorbing dampers (100 _n ) according to claim 1 or claim 3, comprising a controller 200 for integrally controlling a plurality of sound-absorbing dampers (100 _n ),
Multiple Dissipative damper (100 _n) wherein is installed the blade 130 of the two Dissipative damper _{(100 n, 100 n + 1} ) A side-by-side and adjacent while being in close contact with each other along the direction of flow of the air so as to have a symmetrical structure to each other ,
When the rotation of the blades 130 is required to adjust the flow rate of air, the controller 200 is adjacent to form a structure in which a plurality of blades 130 arranged along a flow direction of the air form a straight line or a straight line structure. Damper structure using a sound-absorbing damper, characterized in that it comprises the function of rotating the two blades 130 in different directions.

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