KR102654246B1 - Both sides damper - Google Patents

Abstract

The present invention relates to a two-way damper, wherein a rotary door is selectively rotated in the direction of the first or second discharge port by a drive motor, and selectively communicates between the inlet and the first or second discharge port to the guide curved portion, and an opposing damper is provided. The first or second discharge port is closed with a sealed curved part that rotates in the same direction as the guide curved part, so that the gas flowing into the inlet slides smoothly in the direction of the first or second outlet by the guide curved part to prevent collisions and vibrations. Guide it to be discharged.
According to the present invention, the guide curved portion of the rotating door guides the flow of gas flowing through the inlet to slide smoothly in the direction of the first discharge port or the second discharge port, eliminating the risk of gas colliding with the inner wall of the housing and preventing the gas from colliding with the inner wall of the housing. By preventing collision, collision noise and vibration are generated within the housing, and at the same time, the vortex phenomenon is eliminated, thereby increasing the gas discharge efficiency. By selectively opening the first or second discharge port through the guide curved part of the rotary door, a different first discharge port is opened. Alternatively, the second discharge port is simultaneously closed with a closed curved portion, so that the opening and closing of the first discharge port and the second discharge port are automatically performed at the same time. In particular, while injecting gas such as internal or external air through the inlet, internal or external air is connected to the first outlet. Alternatively, by cross-discharging each other through the second outlet, outdoor air can be supplied indoors or internal air can be discharged outdoors.

Description

Both sides damper}

The present invention relates to a two-way damper, and more specifically, to selectively communicate between an inlet and a first discharge port or a second discharge port through a guide curved portion of a rotating door, and to close the opposing first discharge port or second discharge port with a sealed curved portion. , relates to a two-way damper that guides the gas flowing into the inlet to slide smoothly by the guide curved portion and be discharged to the first discharge port or the second discharge port.

Generally, a diffuser is a device that is attached to an indoor ceiling, wall, or end of an air conditioning duct to control wind direction.

At this time, these diffusers mainly supply air generated from air conditioning equipment that cools and heats the interior of a building or the interior of a vehicle, or air supplied from outdoors, in a designated direction indoors.

Patent Document 1 shows a conventional diffuser assembly. Referring to this, the central part is penetrated and separated into upper and lower parts, a bracket having a ring-shaped support on the inner circumferential surface, and a spherical shape that is hooked and fixed to the support of the bracket, A first ball socket forming a first through hole exposed to the upper part of the bracket on the outer surface, a first communication hole formed on the outer surface opposite to the first through hole, and a second communication port communicating with the first communication hole on the outer surface in a spherical shape. It is composed of a second ball socket that forms a sphere and has a second through hole formed on the outer surface orthogonal to the second communication hole.

Here, the first ball socket is rotated at a predetermined angle while supported on the support to change the direction of the first communication port, and at this time, the second communication port connected to the first communication port is rotated integrally to provide the second communication port. The direction of the sphere changes.

That is, when air is supplied to the first through hole of the first ball socket exposed at the top of the bracket, the air is supplied to the second ball socket through the second communication port connected to the first communication port of the first ball socket, It is discharged to the outside through the second through hole.

And, when changing the direction of the second through hole of the second ball socket, the direction of the first ball socket is changed as the second ball socket is rotated, and in that state, the first ball socket and the second ball are connected as above. The air moving into the socket is discharged in a designated direction through the second through hole.

However, in Patent Document 1 as described above, the air introduced through the first through-hole is simply discharged through the second through-hole of a single passage, and the direction of the second through-hole of the second ball socket is changed at any time according to the air discharge direction. There is the inconvenience of having to change it, and the inconvenience of having to determine the air discharge location by manually adjusting the position of the second through hole while holding the second ball socket, and changing the air discharge location at a set time interval. If this is necessary, the second ball socket must be rotated repeatedly. In particular, it is a structure that supplies indoor air or outdoor air alone through the first through hole, discharges indoor air or outdoor air unilaterally, and is bent in a right orthogonal shape. As the air passes through the formed second through-hole, the air collides with the bottom surface of the second ball socket and is then discharged through the second through-hole, creating an impact sound or vibration and simultaneously creating a vortex within the second ball socket, and thus, the air There is a problem in that the reliability of the product decreases due to the rapid decrease in discharge efficiency.

KR 10-0569697 B1

The present invention is to solve the problems described above. The purpose of the present invention is to provide a housing with an inlet at the bottom, a first outlet and a second outlet at the outer surface, and a rotation support plate on the inner wall. A rotary door is installed on the rotation support plate of the housing to rotate in the direction of the first discharge port or the second discharge port to selectively open and close the first discharge port or the second discharge port, and a drive motor to rotate the rotary door is installed on the outer surface of the housing. Installed, the rotary door is selectively rotated in the direction of the first discharge port or the second discharge port using a drive motor, and selectively communicates between the inlet and the first discharge port or the second discharge port through the guide curved portion, and the first discharge port or the second discharge port is opposite to this. It is closed with a closed curved part that rotates in the same direction as the guide curved part, and guides the gas flowing into the inlet to slide smoothly toward the first or second outlet by the guide curved part to prevent collisions and vibrations. It provides a damper.

In order to achieve the object of the present invention as described above, the two-way damper according to the present invention has a hollow shape, forms an inlet at the bottom, and forms a first discharge port on the outer surface orthogonal to the inlet, and the first discharge port and a housing having a second discharge port formed on an opposing outer surface; a rotatable door rotatably installed in the housing and operated to rotate to selectively open and close the first or second discharge outlet; In the two-way damper consisting of a drive motor installed on the outer surface of the housing, one end of which is connected to the rotary door to rotate the rotary door, the housing has a rotary motor on its inner wall that supports the rotation of the rotary door. A support plate is further formed, and the rotation door is formed to have a curved structure, both ends of which are rotatably coupled to the rotation support plate, and is rotated in the direction of the first discharge port or the second discharge hole with respect to the rotation support plate, A closed curved portion that closes the first discharge port or the second discharge port; A curved structure formed to cover an inner peripheral surface of the closed curved portion, rotated integrally with the closed curved portion, and the inlet and the closed curved portion opposite to the closed curved portion. It consists of a guide curved portion that communicates between the first discharge port or between the inlet and the second outlet, and guides the gas flowing in through the inlet to smoothly slide and be discharged to the first or second discharge port. It is characterized by

In the two-way damper according to the present invention, the housing is formed in a curved structure on its inner peripheral surface to correspond to the sealed curved portion of the rotary door, and the sealed curved portion is allowed to be in close contact with the first discharge port or It is characterized by further forming an inner curved portion that supports rotation in the direction of the second discharge port.

In the two-way damper according to the present invention, the rotary door 200 is characterized in that its central axis, which is rotatably coupled to the drive motor, is formed to correspond to the center of the curved surface value (R1) of the sealed curved portion.

In the two-way damper according to the present invention, the rotating door has a curved surface of the guide curved portion relatively more gently than the curved surface of the sealing curved portion, so that the gas flowing into the inlet is discharged from the first outlet or the second outlet. It is characterized by guiding it to slide smoothly toward the discharge port direction.

In the two-way damper according to the present invention, the housing forms a first border along the inner edge of the inlet, a second border along the inner edge of the first outlet, and the guide curved portion of the rotary door is at the top. An upper curve is formed that is rotated to match the first border of the inlet or the second border of the first outlet, and the lower end opposite to the upper curve is coincident with the first border of the inlet or is exposed in the direction of the second outlet. It is characterized by further forming a bottom curve that is rotated as much as possible.

In the two-way damper according to the present invention, the guide curved portion of the rotary door is rotated so that the upper curve coincides with the second border and the lower curve coincides with the first border, so that the gas introduced through the inlet It is guided to be discharged by sliding smoothly in the direction of the first outlet, and the upper curve is aligned with the first border, but is rotated so that the lower curve is exposed to the second outlet, so that the gas flowing in through the inlet is the second outlet. 2 It is characterized by sliding smoothly in the direction of the discharge port to be discharged.

According to the present invention, the guide curved portion of the rotating door guides the flow of gas flowing through the inlet to slide smoothly in the direction of the first discharge port or the second discharge port, eliminating the risk of gas colliding with the inner wall of the housing and preventing the gas from colliding with the inner wall of the housing. By preventing collision, collision noise and vibration are generated within the housing, and at the same time, the vortex phenomenon is eliminated, thereby increasing the gas discharge efficiency. By selectively opening the first or second discharge port through the guide curved part of the rotary door, a different first discharge port is opened. Alternatively, the second discharge port is simultaneously closed with a closed curved portion, so that the opening and closing of the first discharge port and the second discharge port are automatically performed at the same time. In particular, while injecting gas such as internal or external air through the inlet, internal or external air is connected to the first outlet. Alternatively, by cross-discharging each other through the second outlet, outdoor air can be supplied indoors or indoor air can be discharged outdoors. In addition, as the rotary door is automatically rotated by the drive motor, the first or second outlet can be automatically operated. It is very easy to use by opening and closing, but has the advantage of improving the reliability of the product by freely changing the discharge direction of the gas discharged in the room, inside or outside through the first or second discharge ports that are formed to face different directions.

1 is a perspective view showing a two-way damper according to the present invention.
Figure 2 is a side view of Figure 1.
Figure 3 is an exploded perspective view of a two-way damper according to the present invention.
Figure 4 is a side cross-sectional view showing a state in which gas is discharged through the first discharge port of the two-way damper according to the present invention.
Figure 5 is a side cross-sectional view showing a state in which gas is discharged through the second discharge port of the two-way damper according to the present invention.

Hereinafter, embodiments of the present invention will be described in more detail with reference to the attached drawings.

Referring to FIGS. 1 to 5, the housing 100 is hollow and has an inlet 101 at the bottom, and a first outlet 102 is formed on the outer surface orthogonal to the inlet 101. A second outlet (103) is formed on the outer surface opposite to the first outlet (102).

The housing 100 allows internal and external gases to flow into the housing 100 through the inlet 101.

The housing 100 is installed in an air purifying device (not shown) or an air conditioning device (not shown) for cooling and heating, and selectively discharges internal and external gases through the first outlet 102 or the second outlet 103. can do.

It is preferable that the housing 100 is separated from each other on the left and right so that the rotating door 200 is installed inside it.

The housing 100 further forms a rotation support plate 104 on its inner wall to support the rotation of the rotation door 200.

The rotation support plate 104 supports rotation of the rotary door 200 in the direction of the first discharge port 102 or the second discharge port 103.

The rotation support plate 104 allows the drive motor 300 to be fixedly installed on its outer surface, and one end of the drive motor 300 is connected to one surface of the closed curved portion 201 of the rotary door 200. One end of the drive motor 300 is passed through.

The rotation support plates 104 are formed to face each other and support the rotation of the rotation door 200.

The housing 100 is formed in a curved structure on its inner peripheral surface to correspond to the sealed curved portion 201 of the rotary door 200, and allows the sealed curved portion 201 to be in close contact with the sealed curved portion 201. ) further forms an inner curved portion 105 that supports rotation in the direction of the first discharge port 102 or the second discharge port 103.

The inner curved portion 105 is formed to have the same curved surface value (R2) as the curved surface value (R2) of the sealing curved portion 201 of the rotary door 200, and the sealing curved portion 201 closely supports the sealing curved portion 201. It prevents flow from being generated in the closed curved portion 201 while the curved portion 201 is rotated.

The housing 100 forms a first border 101a along the inner edge of the inlet 101 and a second border 102a along the inner edge of the first outlet 102.

The first border 101a is aligned with the upper curve 202a of the guide curved portion 202 or the lower curve 202b, so that the first discharge port 102 or the second discharge port 103 is formed. Select and connect.

The second border 102a aligns the upper curve 202a of the guide curved portion 202 so that the inlet 101 and the first outlet 102 communicate with each other.

The rotary door 200 is rotatably installed in the housing 100 and rotates to selectively open and close the first outlet 102 or the second outlet 103.

The rotary door 200 is rotated at a predetermined angle in the forward or reverse direction by the drive motor 300 to selectively open and close the first outlet 102 or the second outlet 103.

The rotating door 200 is preferably formed in a hollow shape to open and close the first outlet 102 or the second outlet 103.

The rotary door 200 is formed to have a curved structure, both ends of which are rotatably coupled to the rotation support plate 104, and the first discharge port 102 or the second discharge port is connected to the rotation support plate 104. It is rotated in the (103) direction and is formed in a curved structure to cover a closed curved portion 201 that closes the first discharge port 102 or the second discharge port 103 and an inner peripheral surface of the closed curved portion 201, It is rotated integrally with the closed curved portion 201, but communicates between the inlet 101 and the first discharge port 102 so as to be opposite to the closed curved portion 201, or the inlet 101 and the second discharge port 102 are rotated integrally with the closed curved portion 201. Consists of a guide curved portion 202 that communicates between the discharge ports 103 and guides the gas flowing in through the inlet 101 to smoothly slide and be discharged to the first discharge port 102 or the second discharge port 103. do.

The rotating door 200 has a double-walled structure in which the sealing curved portion 201 and the guiding curved portion 202 are rotated as one body.

The closed curved portion 201 is rotated in the same direction as the guide curved portion 202 to close the first discharge port 102 or the second discharge port 103 opposite to the guide curved portion 202.

The sealed curved portion 201 is in close contact with the inner curved portion 105 of the housing 100 and is supported on the inner curved portion 105, thereby forming the first discharge port 102 or the second discharge port 103. ) direction.

It is preferable that the curved surface value (R2) of the closed curved portion 201 is formed to be the same as that of the inner curved portion 105 and is supported in close contact with the inner curved portion 105.

The rotary door 200 has a curved surface value (R2) of the guide curved portion 202 that is relatively gentler than the curved surface value (R1) of the sealing curved portion 201, so that it flows into the inlet 101. The incoming gas is guided to slide smoothly toward the first outlet 102 or the second outlet 103.

The guide curved portion 202 is formed relatively more gently than the sealed curved portion 201, so that the gas flowing into the inlet 101 is directed toward the first outlet 102 or the second outlet 103. It is prevented from colliding with the inner wall of the housing as it slides rapidly toward.

The guide curved portion 202 of the rotary door 200 has an upper curve ( 202a), and a lower curve 202b is formed at the lower end opposite to the upper curve, which coincides with the first edge 101a of the inlet 101 or is rotated to be exposed in the direction of the second outlet 103. form

The upper curve 202a and the lower curve 202b are preferably formed symmetrically at the top and bottom of the guide curved portion 202.

The guide curved portion 202 of the rotary door 200 is rotated so that the upper curve 202a matches the second border 102a and the lower curve 202b matches the first border 101a. This guides the gas flowing in through the inlet 101 to slide smoothly toward the first outlet 102 and be discharged.

The guide curved portion 202 of the rotary door 200 is rotated so that the upper curve 202a matches the first border 101a and the lower curve 202b is exposed to the second outlet 103. This guides the gas flowing in through the inlet 101 to slide smoothly toward the second outlet 103 and be discharged.

The upper curve 202a is rotated at a predetermined angle by the driving motor 300 and matches the first border 101a or the second border 102a, and the lower curve 202b is rotated by the driving motor 300 ( It is rotated at an angle determined by 300 to match the first border 101a or to be exposed to the second outlet 103.

The rotary door 200 is formed so that its central axis, which is rotatably coupled to the drive motor 300, corresponds to the center of the curved surface value R1 of the sealed curved portion 201.

The drive motor 300 is installed on the outer surface of the housing 100, and one end of it is connected to the rotary door 200 to rotate the rotary door 200.

The driving motor 300 preferably passes through the rotation support plate 104 of the housing 100 and is connected to one side of the closed curved portion 201.

The drive motor 300 is rotated at a predetermined angle to control the rotary door 200 to selectively open and close the first outlet 102 or the second outlet 103.

The driving motor 300 has the upper curve 202a of the guide curved portion 202 aligned with the first border 101a or the second border 102a, and the lower curve 202b is aligned with the first border 102a. (101a) or the guide curved portion 202 is rotated at a predetermined angle so that it is exposed to the second discharge port 103.

The driving motor 300 is preferably connected to an external device (e.g., a control unit, an operation panel) and is automatically operated at a set time according to a setting value set by the user, or is operated by the user's operation.

The two-way damper according to the present invention configured as above is used as follows.

First, the housing 100 is separated to the left and right, and in that state, the rotating door 200 is placed within the housing 100, so that both ends of the rotating door 200 are connected to the rotating support plate of the housing 100. Make sure it is in close contact with (104).

At this time, one end of the closed curved portion 201 of the rotary door 200 is brought into close contact with the rotation support plate 104 of the housing 100, and in that state, the drive motor ( One end of the drive motor 300 is passed through one end of the drive motor 300 to be connected to one end of the closed curved portion 201.

Then, the drive motor 300 is closely fixed to the outer surface of the rotation support plate 104 to connect the drive motor 300 and the sealed curved portion 201.

Thereafter, the housings 100 separated to the left and right are combined, and in that state, the housings 100 coupled to each other are fastened and fixed with a fastening member (not shown) to form the rotary door ( 200) is rotatably combined.

Next, the two-way damper combined as described above is installed in an air purifying device (not shown) or an air conditioning device (not shown) for cooling and heating, and is positioned so that the inlet 101 faces directly downward.

In the following description, an example will be given in which a two-way damper is installed in an air purification device (not shown) to selectively supply internal or external air through the inlet 101 of the housing 100.

First, when it is desired to supply outdoor air into the room through an air purification device (not shown), the rotary door 200 is rotated using the drive motor 300 to close the sealed curved portion 201 of the rotary door 200. ) seals the second outlet 103 and at the same time allows the guide curved portion 202 to communicate between the inlet 101 and the first outlet 102.

That is, when the rotary door 200 is rotated with the drive motor 300, the upper curve 202a of the guide curved portion 202 coincides with the second border 102a of the first discharge port 102. , the bottom curve 202b is aligned with the first border 101a of the inlet 101, and the guide curved portion 202 is positioned to communicate between the inlet 101 and the first outlet 102. do.

Here, both ends of the sealed curved portion 201 of the rotary door 200 are rotated in place about the rotation support plate 104 of the housing 100, and the outer surface is formed on the inner curved portion 105 of the housing 100. ) is supported to prevent flow from occurring in the closed curved portion 201.

And, the closed curved portion 201 is rotated by the drive motor 300, thereby integrally rotating the guide curved portion 202.

At this time, the guide curved portion 202 is opposite to the first discharge port 102 or the second discharge port 103 sealed by the sealed curved portion 201. ) is opened.

That is, as the guide curved portion 202 opens between the inlet 101 and the first outlet 102, on the contrary, the closed curved portion 201 is located at the second outlet 103, The second discharge port 103 is closed.

Thereafter, the outside air introduced through the inlet 101 enters the housing 100, is guided to the guide curved portion 202, and slides smoothly toward the first outlet 102, thereby causing the housing to External air whose direction is changed within 100 is prevented from colliding with the housing 100 and generating vibration or noise.

In addition, the outdoor air that slides smoothly by the guide curved portion 202 is discharged into the indoor space through the first outlet 102, so that the outdoor air introduced through the inlet 101 is supplied to the indoor space.

On the other hand, when it is desired to discharge the indoor space to the outdoors by allowing the indoor air to flow into the air purification device (not shown), the rotary door 200 is rotated with the drive motor 300 to open the rotary door ( The sealing curved portion 201 of 200 seals the first discharge port 102 and at the same time, the guide curved portion 202 communicates between the inlet port 101 and the second discharge port 103.

Here, the upper curve 202a of the guide curved portion 202 is aligned with the first edge 101a of the inlet 101, and the lower curve 202b is positioned to be exposed to the second outlet 103. Thus, the guide curved portion 202 is positioned to communicate between the inlet 101 and the second outlet 103.

Then, the bet flowing in through the inlet 101 enters the housing 100, is guided to the guide curved portion 202, and slides smoothly toward the second discharge port 103, and thus, the bet As the air is discharged outdoors through the second discharge port 103, the air flowing in through the inlet port 101 is discharged into the outdoor space.

In the above, the rotary door 200 is rotated according to the operation of the rotary door 200 to supply outside air to the inside or discharge indoor air to the outside by the drive motor 300 to open the first outlet 102. Alternatively, the explanation was given as an example of selectively opening the second outlet 103, but the internal and external gases are introduced solely into the inlet 101 and move through the first outlet 102 or the second outlet 103. The flow direction of the gas can be changed.

Additionally, the drive motor 300 may be connected to an external device (eg, an operation panel or control unit) and may be automatically operated at a set time or operated by a user.

As described above, the first and second discharge ports 102 and 103 are selectively opened by the rotating door 200, and the gas is smoothly flowed into the first discharge port 102 or the second discharge port 103 by the guide curved portion 202. The structure that allows sliding and moving discharge is that the guide curved portion 202 of the rotary door 200 smoothly flows the gas flowing in through the inlet 101 in the direction of the first outlet 102 or the second outlet 103. By guiding it to slide, there is no risk of the gas colliding with the inner wall of the housing 100, and by preventing collision of the gas, collision noise and vibration are generated within the housing 100 and the vortex phenomenon is eliminated, thereby improving gas discharge efficiency. As it rises, the first discharge port 102 or the second discharge port 103 is selectively opened through the guide curved portion 202 of the rotary door 200, and another first discharge port 102 or second discharge port 103 is opened. By simultaneously closing the closed curved portion 201, the first outlet 102 and the second outlet 103 are automatically opened and closed at the same time.

The two-way damper according to the present invention described above is not limited to the above-described embodiments, and can be varied by anyone skilled in the art without departing from the gist of the present invention as claimed in the claims below. The technical spirit exists to the extent that it can be implemented by changing it.

100: housing 101: inlet
101a: first border 102: first discharge port
102a: second border 103: second discharge port
104: rotation support plate 105: inner curved portion
200: Rotating door 201: Closed curved portion
202: Guide curve part 202a: Top curve
202b: Bottom curve 300: Drive motor
R1, R2: Curved surface value

Claims (6)

In a hollow shape, an inlet 101 is formed at the bottom, a first outlet 102 is formed on the outer surface perpendicular to the inlet 101, and a second outlet is formed on the outer surface opposite to the first outlet 102 ( A housing 100 forming 103);
A rotary door (200) rotatably installed in the housing (100) and rotated to selectively open and close the first discharge port (102) or the second discharge port (103);
A drive motor 300 installed on the outer surface of the housing 100, one end of which is connected to the rotary door 200 to rotate the rotary door 200;
In a two-way damper consisting of,
The housing 100 is,
A rotation support plate 104 is further formed on the inner wall to support the rotation of the rotation door 200,
The rotating door 200,
It is formed to have a curved structure, both ends of which are rotatably coupled to the rotation support plate 104, and is rotated in the direction of the first discharge port 102 or the second discharge port 103 with respect to the rotation support plate 104. , a closed curved portion 201 that closes the first discharge port 102 or the second discharge port 103;
It is formed in a curved structure to cover the inner peripheral surface of the closed curved portion 201, rotates integrally with the closed curved portion 201, and has the inlet 101 and the first discharge port so as to be opposite to the closed curved portion 201. (102) or communicates between the inlet 101 and the second outlet 103, so that the gas flowing in through the inlet 101 flows into the first outlet 102 or the second outlet 103. ) A guide curved portion (202) that guides smooth sliding and discharge;
It consists of,
The housing 100 is,
The inner circumferential surface is formed in a curved structure to correspond to the sealed curved portion 201 of the rotary door 200, and the sealed curved portion 201 is allowed to be in close contact, so that the sealed curved portion 201 is formed at the first outlet. Characterized in that an inner curved portion 105 is further formed to support rotation in the direction of (102) or the second discharge port (103),
The rotating door 200,
Characterized in that the central axis rotatably coupled to the drive motor is formed to correspond to the center of the curved surface value (R1) of the sealed curved portion,
The rotating door 200,
The curved surface value (R2) of the guide curved portion 202 is relatively more gently formed than the curved surface value (R1) of the sealed curved portion 201, so that the gas flowing into the inlet 101 is the first gas. A two-way damper characterized by guiding it to slide smoothly toward the discharge port (102) or the second discharge port (103). delete delete delete According to clause 1,
The housing 100 is,
A first border (101a) is formed along the inner edge of the inlet 101, and a second border 102a is formed along the inner edge of the first outlet 102,
The guide curved portion 202 of the rotary door 200 is,
An upper curve 202a is formed at the upper end, which is rotated to match the first border 101a of the inlet 101 or the second border 102a of the first outlet 102, and at the lower end opposite to the upper curve. A two-way damper, characterized in that it further forms a bottom curve (202b) that matches the first edge (101a) of the inlet (101) or is rotated to be exposed in the direction of the second outlet (103). According to clause 5,
The guide curved portion 202 of the rotary door is,
The upper curve 202a coincides with the second border 102a, and the lower curve 202b is rotated to coincide with the first border 101a, so that the gas flowing in through the inlet 101 is It is guided to be discharged by sliding smoothly in the direction of the first discharge port (102),
The upper curve (202a) coincides with the first border (101a), but is rotated so that the lower curve (202b) is exposed to the second discharge port (103), so that the gas flowing in through the inlet port (101) is A two-way damper characterized in that it slides smoothly in the direction of the second discharge port (103) and discharges.

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