KR100701328B1 - A Damper Apparatus for Air Conditioning System - Google Patents

Abstract

A damper device for an air conditioner is provided to restrain over flow of air through damper blades by modifying a structure of the damper device, thereby realizing precise control of a air amount. A damper device for an air conditioner includes a plurality of damper blades(20) rotating in a duct(10) for opening or closing a path, and an actuator for driving the damper blades to rotate. Path dividing elements(40) define the path in the duct in front of the damper blades into upper and lower areas with respect to rotation shafts(20a) of the damper blades, so that air flow between the damper blades, which are inclined toward the air inlet, are applied with resistance. Mean pressure measuring parts(50) are provided to the path dividing elements for measuring dynamic pressure of air flowing through the duct.

Description

Damper device for air conditioning system {A Damper Apparatus for Air Conditioning System}

1 is a configuration diagram showing an overall air conditioning system according to the prior art.

2 is a block diagram showing a damper device for an air conditioning system according to the prior art.

3 is a graph showing a flow rate change rate line obtained from a damper device for an air conditioning system according to the related art in comparison with an opening rate and a direct proportion line.

Figure 4 is an external perspective view showing a damper device for an air conditioning system according to the present invention.

5 is a cross-sectional view showing a damper device for an air conditioning system according to the present invention.

Figure 6 is an enlarged cross-sectional view showing in detail the damper device for an air conditioning system according to the present invention.

7 is an enlarged partial perspective view illustrating the flow path dividing unit and the average pressure measuring unit provided in the damper device for an air conditioning system according to the present invention.

8 is a cross-sectional view illustrating a modified embodiment in which the rotation axis and the channel dividing means of the damper blade are eccentric from the center of the damper blade in the damper device for an air conditioning system according to the present invention.

9 is a graph showing the airflow rate change rate line obtained in the damper device for an air conditioning system according to the present invention in comparison with the opening rate and a direct rate line.

       <Description of the symbols for the main parts of the drawings>

1 ..... Damper device for air conditioning system according to the present invention

10 .... duct 20 .... damper blade

20a ... axis of rotation 30 .... actuator

40 .... Means for dividing the euro 42 .... Separation plate

50 .... Average pressure measurement section 52 .... Average voltage measurement section

52a ... Air induction section 54 .... Average static pressure measurement section

52b ... Voltage gauge 54a ... Static pressure gauge

200 .... conventional damper device 221 .... filter

222 .... Heating 223 .... Cooling System

224 .... Humidifier 230 .... Damper Blade

232 .... Air supply fan 234 .... Exhaust fan

240 .... Actuator 260 .... Controller

A .... Opening rate and direct proportion B .... Conventional air volume change rate line

B '... air volume change rate line L .... eccentric distance of this invention

K .... Center of damper blade S1 .... Upper area

S1-1 ... Upper open area S2 .... Lower area

S2-1 ... Lower open area S3 .... Enclosed space

The present invention relates to a flow rate control device (hereinafter referred to as a damper device) for automatically adjusting the amount of air supplied and exhausted to the room according to the change in the temperature of the room, and more specifically, damper to the air flow through the duct By generating air resistance according to the opening angle of the blade, it is possible to effectively reduce the overflow of air due to the inclination of the damper blade and to calculate the average wind speed by measuring the average differential pressure, or dynamic pressure, in many places in the duct. And, accordingly relates to a damper device for an air conditioning system that can achieve more accurate air volume control according to the opening rate of the damper blade.

In general, an air conditioning control system (hereinafter referred to as an air conditioning system) in an automatic building control system is used to control the amount of air to be supplied and exhausted for the purpose of maintaining a comfortable room temperature and saving energy by optimal control by air conditioning in a building. A damper device is provided.

Such an air conditioning system schematic is shown in FIG. 1.

The damper device 200 according to the related art provided in the air conditioning system shown in FIG. 1 includes a duct 210 for introducing external air (hereinafter referred to as air supply) and exhausting indoor air (hereinafter referred to as exhaust). And a plurality of damper blades 230 mounted on the duct 310 and also the duct 410 for returning indoor air (hereinafter referred to as return), for adjusting the amount of air passing therethrough, Actuator (240) for making it.

The conventional air conditioning system includes a filter 221 for filtering foreign matter on the air supply side, a heating device 222 for heating the air supply to a constant temperature, a cooling device 223 for lowering the air supply to a constant temperature, and an air supply. And a humidifier 224 for supplying water in the air.

In addition, an air supply fan 232 is mounted to the air supply duct 210, and an air exhaust fan 234 is mounted to the air exhaust duct 310.

In the conventional air conditioner damper device 200, as shown in FIG. 2, when the outside air first flows into the air inlet duct 210, the differential pressure sensor 250, the front and rear pressure of the damper blade 230 Detects the differential pressure and inputs the differential pressure to the controller 260. The controller 260 arithmetically calculates the differential pressure of the outside air sensed by the differential pressure sensor 250 and the cross-sectional area of the flow path of the duct 210 to calculate the amount of air in the duct 210 flowing into the room from the outside.

In addition, the controller 260 calculates the difference between the current room temperature and the room temperature desired by the user in order to adjust the opening rate of the damper blade 230, and the amount of air to be supplied to the room in consideration of the volume of the room. It calculates, and calculates the opening rate of the damper blade 230 to reach the air volume.

In addition, the actuator 240 is operated to control the damper blade 230 according to the calculated opening degree.

Accordingly, in the conventional air conditioner damper device 200, the actuator 240 rotates the damper blade 230 according to the calculation result of the controller 260, and increases or decreases the opening rate of the room temperature. To adjust to the desired temperature. Thus, since the conventional damper device 200 for the air conditioning system obtains the desired air volume control by adjusting the opening rate of the damper blade 230, it is essential that the air volume be precisely adjusted in accordance with the opening rate.

3 is a graph showing characteristic values of the opening rate / air volume change rate for the conventional damper device 200 for the air conditioner as described above.

The most ideal characteristic values in the damper device 200 for the air conditioning system are that the air flow rate change rate line B coincides with the opening rate and the directly proportional line A, respectively. In this case, the controller 260 provided in the damper device 200 for the air conditioning system can adjust the desired opening rate through the actuator 240 and the damper blade 230 to provide an accurate air volume corresponding thereto. It is the most desirable.

As shown in FIG. 3, when the damper blade 230 is rotated by an arbitrary angle θ, even if the opening ratio of the damper blade 230 is about 50%, the air flow rate change rate line B may be opened at this time. The rate of change of the wind volume corresponds to about 80% or more, and the rate of change of the wind volume compared to the opening rate indicates saturation due to the overflow flow.

The reason is that at any opening rate, the damper blade 230 guides the air flow in its upper region (front of the air flow) to its lower region (rear of the air flow) about its axis of rotation 230a. In this process, the damper blade 230 in an inclined state generates an acceleration force in the air flow, thereby forming an overflow flow such that more air flows in the lower region of the damper blade 230.

As a result, if the air flow rate change rate is displayed in comparison to the opening rate, it is possible to form a saturation curve as shown by the "B" line in FIG. 3, which can be seen to be significantly different from the opening rate and the "A" line.

Therefore, the air volume change rate line B of the damper device 200 for a conventional air conditioning system is completely different from the line A in direct proportion to the opening rate, and as a result, the user is quite difficult to adjust the air volume through the opening angle manipulation. In this way, the overflow flow generated in the conventional air conditioner damper device 200 must be suppressed to achieve accurate air volume adjustment according to the opening degree.

On the other hand, a technique for solving such problems has been proposed in the prior art.

An example of such a prior art is shown in Japanese Patent Laid-Open No. Hei 6-337162.

The prior art divides a plurality of blades of a damper device into a plurality of zones, and controls each of the blades individually in different directions so that the rate of change of the air volume of the damper device is close to a direct line of the opening rate of the damper device. will be.

However, this conventional technique requires a large number of actuators for rotating the damper blades in each zone and controlling them in different directions, and such a large number of actuators resulted in an increase in the manufacturing cost of the entire damper device.

In addition, such a conventional damper device was such that the rate of change of air volume did not come close to a satisfactory level of the opening rate.

As another conventional technique, US Pat. No. 5,730,652 (named Damper With Stationary Pitot-Static Sensing Vanes) is presented.

Such a conventional damper device is provided with sensors for detecting the amount of air flowing through the damper blades between the damper blades, and adjusts the opening ratio of the damper blades using dynamic pressure measured through these sensors.

Such a conventional structure is practical, so that the air volume control through the opening ratio of the damper blade can be achieved through accurate dynamic pressure measurement.

However, such a problem of the prior art is that when a certain time passes, a measurement error occurs in the structure of the sensor device. That is, the positive pressure measuring sphere of the sensor had a problem that the positive pressure measuring sphere was blocked by foreign matter due to back flow of air passing through the damper blade.

Therefore, such a conventional damper device has a problem in that accuracy and operation reliability deteriorate with time.

And such a conventional device at a low opening rate is too small open area rate is almost no air volume control, so there is a need to improve it.

In addition, such a conventional structure has a structure in which the number of sensors measuring dynamic pressure to detect the air volume is smaller than the number of damper blades. That is, three sensors are arranged in comparison with four damper blades. This is because the sensor is disposed between the damper blades, in which the number of sensors corresponds to the number of damper blades-1.

Therefore, the conventional technique as described above is required to measure the average dynamic pressure at more points and more accurate air flow detection and there is room for improvement.

The present invention is to solve the above conventional problems, the object is to provide a damper device for an air conditioning system that can achieve accurate air volume control by effectively suppressing the overflow of air through the damper blade through a simple structural improvement In providing.

In another aspect, the present invention provides an air-conditioning system capable of accurately measuring the air flow rate by making the average differential pressure, that is, the dynamic pressure measurement, at more various positions in the duct and as many places as measurement points. It is to provide a damper device for.

The present invention to achieve the above object,

In the damper device for an air conditioning system to adjust the amount of air in the duct,

A plurality of damper blades rotated in the duct to open and close the flow path;

An actuator for rotating the damper blade; And

Splitting the flow path in the duct at the inlet side of the damper blade into an upper region and a lower region around the axis of rotation of the damper blade, thereby dividing the flow path between the damper blades inclined toward the inlet side of the air and providing resistance to the air flow. It provides a damper device for an air conditioning system, characterized in that it has a.

And the present invention preferably

In the damper device for an air conditioning system to adjust the amount of air in the duct,

A plurality of damper blades rotated in the duct to open and close the flow path;

An actuator for rotating the damper blade;

Splitting the flow path in the duct at the inlet side of the damper blade into an upper region and a lower region around the axis of rotation of the damper blade, thereby dividing the flow path between the damper blades inclined toward the inlet side of the air and providing resistance to the air flow. Way; And

And an average pressure measuring unit having an average voltage measuring unit and an average static pressure measuring unit respectively provided in the flow path dividing unit, the average pressure measuring unit measuring an average differential pressure of the air flowing in the duct, i.e., a dynamic pressure. to provide.

In addition, the present invention preferably

The flow path dividing means provides a damper device for an air conditioning system, characterized in that consisting of a separation plate (separation plate) mounted on the front side of the damper blade.

And the present invention preferably

The separating plate provides a damper device for an air conditioning system, characterized in that the sealing member is mounted at both ends and both ends thereof so that airtightness is maintained between the rotary shaft portion of the damper blade and the duct.

In addition, the present invention preferably

The number of average pressure measuring units is provided with a damper device for an air conditioning system, characterized in that the number of damper blades.

And the present invention preferably

The average voltage measuring unit provides a damper device for an air conditioning system, characterized in that a plurality of voltage measuring holes formed through the air induction unit formed in the inclined groove to the front of the flow path dividing means, that is, the inlet of the air.

In addition, the present invention preferably

The static pressure measuring sphere of the average static pressure measuring unit provides a damper device for an air conditioning system, characterized in that formed in the number of the lower surface side of the flow path dividing means, that is, the air flow backward side of the damper blade.

And the present invention preferably

The rotation axis of the damper blade and the flow path dividing means provide a damper device for an air conditioning system, characterized in that it is eccentrically positioned in one of the up and down directions from the center of each damper blade.

In addition, the present invention preferably

When the axis of rotation of the damper blade and the channel dividing means are moved downward from the center of the damper blade, the damper blade has an upper side open forward of the air flow, and a lower side thereof It provides a damper device for an air conditioning system, characterized in that the structure is opened backward.

And the present invention preferably

When the axis of rotation of the damper blade and the channel dividing means are moved upwardly from the center of the damper blade, the damper blade has its upper side open backward of the air flow, and its lower side forward of the air flow. It provides a damper device for an air conditioning system, characterized in that the structure is opened in (forward).

Hereinafter, a preferred embodiment of the present invention will be described in detail.

As shown in FIGS. 4 and 5, the damper device 1 for the air conditioning system according to the present invention is rotated in the duct 10 to open and close the flow path, and a plurality of damper blades 20 and actuators for rotating the same. 30).

And the present invention partitions the flow path in the duct 10 at the inlet side of the air of the damper blade 20 into an upper region and a lower region around the rotation axis 20a of the damper blade 20, and the air inlet side The flow path dividing means 40 which imparts resistance to the air flow between the photo damper blade 20 is provided.

In addition, the flow path dividing means 40 is preferably arranged to coincide with the axis of rotation 20a of the damper blade 20 at the front side of the respective damper blades 20, and the damper blades 20 It consists of a separation plate 42 for dividing the air flow passing up and down, and can be mounted using a separate mounting device (not shown) inside the duct 10.

A sealing material (not shown) is mounted at one end and both ends of the separation plate 42 of the flow path dividing means 40, that is, the damper blade 20 in the rotational axis 20a direction and the side surface of the duct 10. The airtightness is maintained between the rotation shaft of the damper blade 20 and the side surface of the duct 10.

In the present invention, the flow path dividing means 40 includes an average voltage measuring unit 52 and an average static pressure measuring unit 54 to measure an average differential pressure, that is, a dynamic pressure of air flowing in the duct 10. The measurement unit 50 is included.

The average pressure measuring unit 50 is disposed in correspondence with the number of damper blades 20, and as shown in FIGS. 6 and 7, the average voltage measuring unit 52 of the average pressure measuring unit 50 is respectively. A plurality of voltage measuring holes 52b through the air induction part 52a formed as an inclined groove are formed on the front side of the flow path dividing means 40, that is, the inlet side of the air, so that the air is smoothly introduced to measure the average voltage. It is.

In addition, the average static pressure measuring unit 54 forms a plurality of static pressure measuring holes 54a on the lower surface side of the flow path dividing means 40, that is, on the air flow backward side of the damper blade. This structure minimizes the inflow of foreign substances in the air and minimizes the effects of turbulence so that accurate static pressure measurements can be made.

As shown in FIG. 7, the average voltage measuring unit 52 and the average static pressure measuring unit 54 of the average pressure measuring unit 50 are blocked by plugs 56a and 56b, and the other side is averaged. The structure is connected to a sensor (not shown) of the pressure measuring unit 50.

In addition, the present invention has a structure in which the rotation shaft 20a of the damper blade 20 and the flow path dividing means 40 are eccentrically positioned to one side in an up and down direction from the center of each damper blade 20. Such a structure may be a structure in which the rotation shaft 20a of the damper blade 20 and the flow path dividing means 40 are biased toward the lower side as illustrated in FIG. 8.

In such an eccentric structure, the closed space S3 formed by the flow path dividing means 40 interacting with the damper blade 20 is made larger so that the resistance region of the air flow becomes larger, and thus the air It is possible to more effectively prevent excessive flow phenomenon.

In the damper device 1 for an air conditioning system according to the present invention configured as described above, as shown in FIG. 5, the damper blade 20 is vertically disposed to block the flow path, that is, the flow path completely from the angle θ of 0 °. The amount of air is adjusted between the open position at the open state, that is, the angle (θ) 90 °.

In this operation process, the damper device 1 for the air conditioning system according to the present invention, as shown in Figure 6, when a plurality of damper blades 20 at the same time by the actuator 30 is opened at any angle (θ), On each of the damper blades 20, the air flow of the upper region S1 and the air flow of the lower region S2 are provided from the air inlet side by the flow path dividing means 40.

In the upper region S1 where the upper air flow is provided, since the upper side of each damper blade 20, that is, the damper blade 20 is inclined in the forward direction, the flow path dividing means 40. In each of the closed spaces (S3) formed by interacting with the air flow from the top to the bottom of the damper blade 20 is blocked and causes a large air flow resistance, the air flowing into the corresponding closed space (S3) The upper direction of the damper blade 20 is finely turned to flow finely into the open area S1-1.

In this process, the present invention blocks the air flow moving from the upper region S1 to the lower region S2 of each damper blade 20 due to the closed space S3.

On the other hand, the air flow in the lower region S2 of the flow path dividing means 40 is damped by the damper blade 20 in the backward direction, so that the air introduced to the lower side of the flow path dividing means 40 is damper. The air flows smoothly along the inclined surface of the blade 20 to the open area S2-1, and there is no air moved from the upper area S1 to the pulling phenomenon.

As described above, in the damper device 1 for the air conditioning system, the closed space S3 formed by each damper blade 20 and the flow path dividing means 40 is formed from the upper region S1 of the damper blade 20. Since it blocks the flow of air moving to the lower region S2, and causes a large resistance to the air flow by the closed space S3 in the upper region S1, the damper plate 30 in which the air is inclined as in the prior art 30 The excessive flow of air flowing through the circumference is effectively prevented.

In addition, the present invention is to measure the average value of the total pressure and the static pressure of the air flow in the duct 10 at each of the average pressure measuring section 50 provided in the flow path dividing means 40, The average differential pressure, ie, dynamic pressure, is transmitted as an electrical signal to a controller (not shown) by the differential pressure measuring device, and the controller calculates the air volume based on this.

In this process, the average voltage measuring unit 52 of the average pressure measuring unit 50 measures the air induction unit 52a and the voltage measurement formed on the front surface of the flow path dividing means 40, that is, the inclined groove on the air inlet side. Since the structure is formed of a sphere 52b, a smooth inflow of the voltage can be achieved, and the average static pressure measuring unit 54 of the average pressure measuring unit 50 moves toward the lower surface of the flow path dividing means 40, that is, of the damper blade. It is to form a plurality of positive pressure measuring holes (54a) to the air flow backward side to minimize the inflow of foreign matter contained in the air and to minimize the influence of turbulence to ensure accurate static pressure measurement.

In particular, the average pressure measuring unit 50 of the present invention facilitates the introduction of smooth air even at low wind speeds, so that it is easy to measure the ultra-fine average differential pressure, and the positive pressure measuring port 54a is the airflow backward surface of the damper blade. Since it is located on the lower surface is less affected by turbulence.

In addition, since the average pressure measuring unit 50 of the present invention is formed integrally with the flow path dividing means 40 mounted for each damper blade 20, the average pressure measuring unit 50 is averaged at more various positions in the duct 10 and at more positions. By measuring the differential pressure, that is, the dynamic pressure, it is possible to measure air flow more precisely than in the related art, and achieve accurate air flow control based thereon.

In addition, the damper device 1 ′ for the air conditioning system of the present invention is shifted away from the center of the damper blade 20 by the rotation axis 20a of the damper blade 20 and the flow path dividing means 40 by a distance L. It is offset.

Such a structure is shown in FIG. The damper device 1 ′ for the air conditioning system of the present invention shown in FIG. 8 has the center of the damper blade 20 as long as the rotation axis 20a of the damper blade 20 and the flow path dividing means 40 are distance L. It is moved downward from K). Such a structure is useful in the structure in which the upper side of the damper blade 20 opens forward and the lower side opens backward.

This structure is such that the damper blade 20 and the flow path dividing means 40 move the damper blade 20 and the flow path dividing means 40 downward from the center K of the damper blade 20. The enclosed space S3 formed by the 40 can be further increased, and the air resistance in the upper region of the damper blade 20 is further increased to cause the air to flow from the top to the bottom through the damper blade 20. This can reduce the flow phenomenon more effectively.

8 illustrates a structure in which the rotary shaft 20a of the damper blade 20 and the flow path dividing means 40 are moved downward from the center K of the damper blade 20 by the distance L. FIG. However, the present invention is not limited thereto, and the rotation shaft 20a and the flow path dividing means 40 of the damper blade 20 are moved upwardly from the center K of the damper blade 20 unlike the above. It also includes things.

In such a case, even if the upper side of the damper blade 20 is opened backward, and the lower side is opened forward, the overflow phenomenon can be effectively reduced.

Accordingly, the present invention adjusts the rotation axis 20a of the damper blade 20 and the eccentric distance L of the flow path dividing means 40 from the center K of the damper blade 20 as described above. It is possible to adjust the flow resistance of the air flowing through 20, and to more effectively control the overflow phenomenon due to the inclination of the damper blade 20.

9, the air flow rate change rate according to the present invention is shown as a graph along with the opening rate.

In the damper device 1 for an air conditioning system according to the present invention, the airflow rate change rate line B 'is substantially close to the opening rate and the proportional line A, respectively. In this way, the controller provided in the damper device 1 for the air conditioning system of the present invention achieves the desired opening rate adjustment through the actuator 30 and the damper blade 20, and provides an accurate air flow amount to the room. It can be.

The air volume change rate line (B '), even if the opening rate of the damper blade 20 reaches 50%, the air volume change rate corresponding to the opening rate is reduced by more than about 80% of the conventional, so that the air overflow phenomenon It is greatly improved compared to the conventional.

The reason for this is that the flow path dividing means 40 is mounted in front of the rotation shaft 20a of the damper blade 20 so that the flow path in the duct 10 is centered on the rotation axis 20a of the damper blade 20, respectively. It partitions downward and imparts an airflow resistance between the damper blades 20 inclined toward the air inlet side, thereby effectively suppressing the overflow flow.

As a result, if the airflow rate change rate of the damper device 1 for the air conditioning system according to the present invention is displayed in comparison with the opening rate, a curve B 'is formed in FIG. 9, which is more than the conventional airflow rate change line B. It can be seen that it is very close to the rate and the proportional line (A).

Therefore, the damper device 1 for the air conditioning system of the present invention can achieve a precise air volume adjustment close to the user through the opening rate operation.

As described above, according to the present invention, by effectively suppressing the overflow flow of air through the damper blade by the flow path dividing means, it is possible to reduce the amount of air deviating excessively from the opening rate, thereby achieving more accurate air volume control.

In addition, according to the present invention, by measuring the average differential pressure, that is, the dynamic pressure, at more various locations in the duct and at more locations, accurate airflow measurement is possible, and the effect of achieving accurate airflow control based thereon is obtained.

While the invention has been shown and described with respect to specific embodiments thereof, it has been described by way of example only to illustrate the invention, and is not intended to limit the invention to this particular structure. Those skilled in the art will appreciate that various modifications and changes of the present invention can be made without departing from the spirit and scope of the invention as set forth in the claims below. Nevertheless, it will be clearly understood that all such modifications and variations are included within the scope of the present invention.

Claims (10)

In the damper device for an air conditioning system to adjust the amount of air in the duct, A plurality of damper blades rotated in the duct to open and close the flow path; An actuator for rotating the damper blade; And Splitting the flow path in the duct at the inlet side of the damper blade into an upper region and a lower region around the axis of rotation of the damper blade, thereby dividing the flow path between the damper blades inclined toward the inlet side of the air and providing resistance to the air flow. Means; damper device for an air conditioning system. In the damper device for an air conditioning system to adjust the amount of air in the duct, A plurality of damper blades rotated in the duct to open and close the flow path; An actuator for rotating the damper blade; Splitting the flow path in the duct at the inlet side of the damper blade into an upper region and a lower region around the axis of rotation of the damper blade, thereby dividing the flow path between the damper blades inclined toward the inlet side of the air and providing resistance to the air flow. Way; And And an average pressure measuring unit having an average voltage measuring unit and an average static pressure measuring unit respectively provided in the flow path dividing unit, the average pressure measuring unit measuring an average differential pressure of the air flowing in the duct, i.e., a dynamic pressure. The damper device according to claim 1 or 2, wherein the flow path dividing means comprises a separation plate mounted on the front side of the damper blade. [4] The damper device of claim 3, wherein the separating plate is provided with sealing members at end and side ends thereof to maintain airtightness between the rotation shaft of the damper blade and the duct. 3. The damper device according to claim 2, wherein the number of the average pressure measuring units corresponds to the number of damper blades. 3. The damper device of claim 2, wherein the average voltage measuring part is formed of a plurality of voltage measuring holes through the air induction part formed as the inclined grooves in front of the flow path dividing means, i.e., toward the inlet of the air. . 3. The damper device for an air conditioning system according to claim 2, wherein a plurality of static pressure measuring spheres of said average static pressure measuring unit are formed in the lower surface side of said flow path dividing means, that is, the air flow backward side of a damper blade. The damper device according to claim 1 or 2, wherein the rotation axis of the damper blade and the flow path dividing means are eccentrically positioned to one side in an up and down direction from the center of each damper blade. The damper blade according to claim 8, wherein when the rotary shaft and the flow path dividing means of the damper blade are moved downwardly from the center of the damper blade, the damper blade is opened at its upper side forward of the air flow. A damper device for an air conditioning system, characterized in that the lower side is opened to the rear of the air flow (backward). 9. The damper blade according to claim 8, wherein, when the rotation axis and the flow path dividing means of the damper blade are moved upwardly from the center of the damper blade, the damper blade opens at its upper side backwards of the air flow, and at its lower portion. Damper device for an air conditioning system, characterized in that the side is opened to the forward (forward) of the air flow.

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