KR100561512B1 - Vane type air volume control device - Google Patents

Abstract

The present invention relates to a vane-type air volume control device which is smooth in opening and closing operation of vanes, less noise due to vibration, and excellent durability because damage is prevented by vibration shock, which is advantageous for automatic air volume control.

According to the present invention, a center support member 14 disposed inside the air passage of the blower air guide 1 or the duct, and radially disposed between the inner circumferential surface of the air passage and the center support member 14 is rotatable. A plurality of vanes (2) coupled and spaced apart coaxially with the center support member (14) and adjusting the opening degree of the air passage, and the center rotating member (15) fixed to the axial surface radially on its circumferential surface (15) ), And one side thereof is coupled to the shaft member 16 of the center rotating member 15 and the other side thereof is coupled to the vane 2 to link the member 17 for rotating the vane 2, and the shaft member. And a ring member 18 through and coupled to the outer surface of the link member 17, the outer surface of the ring member 18 being in contact with the outer surface of the ring member 18. At least one of the bearing portions 19 of the link member 17 is formed to have a curved surface, so that the link member 17 has a shaft portion. A vane flow rate control device is provided that is rotatably and axially movable to the ash 16.

Description

Vane type air volume control device             

1 is a perspective view of a conventional vane-type air flow control device

2 is a cross-sectional view of the device

Figure 3 is a perspective view of the vane-type airflow control apparatus according to the present invention

4 is a cross-sectional view of the embodiment

5 is a perspective view of a closed state of the vane-type airflow control apparatus according to the present invention;

Figure 6 is a cross-sectional view of the ring member installation state of another embodiment according to the present invention

Figure 7 is a cross-sectional view of a spring without another embodiment according to the present invention

Figure 8 is a perspective view of the mounting state of the vane-type airflow control apparatus according to the present invention

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

 2. Vane 14. Center support member

15. Center rotating member 16. Shaft member

17. Link member 18. Ring member

19. Bearing 20. Spring

21. Grease cap 22. Joint

The present invention relates to a vane-type air volume control device, and more particularly, the opening and closing operation of the vane for adjusting the amount of air flowing in or out while passing through the air volume control device is smooth, and the noise due to vibration during operation is small, Since the damage to the operating unit due to the vibration shock is prevented and excellent in durability, it relates to a vane-type air volume control device advantageous for the air volume control by automatic control.

In general, the air volume control device is installed in the air duct or blower air guide of the air conditioner that supplies cold air, warm air, clean air, etc. to the room, or removes the muddy air from the room to control the inflow or outflow of air. Used. This air flow control device has various types according to the shape of the damper plate that guides or blocks the air flowing into or out of the device. The damper plate has a louver or butterfly wing shaped butter with one plate. Fly-type air flow control device is widely used. In recent years, however, a vane type air flow rate regulating device having a plurality of vanes disposed radially to generate a tornado while passing air between the vanes and increasing air passage efficiency is more useful.

Figure 1 is a perspective view of such a conventional vane-type air flow control device, the air flow control device is a plurality of vanes (2) are disposed radially inside the air guide (1) for the duct or blower, the plurality of vanes (2) is installed to be rotated between the inner circumferential surface of the air guide (1) and the center guide member (4) inside the air guide (1) by the shaft (3) coupled across the center of each vane (2). The center rotating member 5 is in close contact with the upper surface of the center support member 4 so as to be rotatable, and the plurality of shaft members 6 are radially protruded and fixed to the outer circumferential surface of the center rotating member 5. Then, the shaft 3 connected to the center support member 4 is fixed to one end of the link member 7, and the other end of the link member 7 is formed with a slot-shaped groove 8 is formed in this groove The outer circumferential surface of the shaft member 6 is slidably connected along the inner circumferential surface (8). Accordingly, when the center rotating member 5 is rotated, the link member 7 connected to the shaft member 6 of the center rotating member 5 is interlocked, and the link member 7 moves the shaft 3. By rotating, the vane 2 fixed to the shaft 3 is rotated to adjust the air passage opening degree of the air duct 1 of the duct or the blower to adjust the amount of air.

However, the vane-type air volume control device is easily contaminated by dust, impurities, oil, moisture, etc. in the air passing through the air volume control device, the sliding surface of which the center support member 4 and the center rotating member 5 contact each other. Or rusted and corroded, the center rotating member 5 is not easily rotated, and thus, the rotational movement of the vanes 2 is not well performed, which makes it difficult to control the amount of air by manual and automatic control.

In addition, this vane type air flow control device has a shaft member 6 spaced apart from each other in the groove 8 of the link member 7 to which the vanes 2 are connected when the vanes 2 are rotated to adjust the air volume. Since the guide is operated in a state, the link structure of the link member 7 and the shaft member 6 is not firm. Therefore, when the air pressure is large, the link member 7 and the vane 2 are vibrated by the collision with the flowing air, causing noise pollution. When the vibration shock is accumulated, the operating part is damaged or broken. There is a problem.

In addition, this vane type air volume adjusting device is easily worn due to friction of the groove 8 of the link member 7 with the outer circumferential surface of the shaft member 6 by repeated rotation of the vane 2. The groove 8 of the link member 7 and the outer circumferential surface of the shaft member 6 are operated in the state of being exposed to pollutants and moisture in the air, and this operation part is contaminated and corroded, resulting in poor operation or severe operation. If not, it happens. Therefore, such a conventional vane-type air volume control device is virtually impossible to control automatically, which is a serious obstacle to factory automation for automatically adjusting the temperature, humidity, and cleanliness of a clean room or a measurement room.

The present invention has been proposed to solve the above problems, and an object of the present invention is to contact the pollutants or moisture in the air to which the opening and closing operation structure of the vane to adjust the amount of air flowing in or out while passing through the air volume control device. It operates smoothly regardless of the vane's opening / closing operation structure, so the noise generated by the vane and the vane's opening / closing operation part collides with the air is small. Since the operating part is not damaged, it is excellent in durability, and in particular, to provide a vane type air volume control device which is suitable and advantageous for the air volume control by automatic control.

According to the present invention, a center support member 14 disposed inside the air passage of the blower air guide 1 or the duct, and radially disposed between the inner circumferential surface of the air passage and the center support member 14 is rotatable. A plurality of vanes (2) coupled and spaced apart coaxially with the center support member (14) and adjusting the opening degree of the air passage, and the center rotating member (15) fixed to the axial surface radially on its circumferential surface (15) ), And one side thereof is coupled to the shaft member 16 of the center rotating member 15 and the other side thereof is coupled to the vane 2 to link the member 17 for rotating the vane 2, and the shaft member. And a ring member 18 through and coupled to the outer surface of the link member 17, the outer surface of the ring member 18 being in contact with the outer surface of the ring member 18. At least one of the bearing portions 19 of the link member 17 is formed to have a curved surface, so that the link member 17 has a shaft portion. A vane type air volume control device is provided, which is connected to the ash 16 so as to be rotatable and axially movable.

According to another feature of the invention, the shaft member 16 is characterized in that the spring 20 for elastically supporting the ring member 18 in the axial direction with respect to the bearing portion 19 of the link member 17 is installed. There is provided a vane-type air volume adjusting device.

According to another feature of the invention, the outer surface of the ring member 18 is formed in a spherical surface, the bearing portion 19 is characterized in that formed into a concave spherical surface corresponding to the outer surface of the ring member 18 A vane air flow control device is provided.

According to another feature of the invention, the coupling portion 22 is formed along the circumferential surface of the bearing portion 19 of the link member 17, the inner circumferential surface of the coupling portion 22 is in close contact with the And a grease cap 21 covering the shaft member 16 to prevent the grease inside the grease cap 21 from corroding the ring member 18, the bearing portion 19, and the spring 20. Provided is a vane air flow rate control device characterized in that.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. Figure 3 is a perspective view of the vane type air flow control device according to the invention, Figure 4 is a cross-sectional view of the embodiment, Figure 5 is a perspective view of a closed state of the vane air flow control device according to the invention, Figure 6 Figure 7 is a cross-sectional view of a ring member installation state according to another embodiment, Figure 7 is a cross-sectional view of the spring-free state of another embodiment according to the present invention, Figure 8 is a perspective view of the mounting state of the vane-type air volume control apparatus according to the present invention.

Referring to this, in the vane type air flow control apparatus of the present invention, a plurality of vanes 2 are disposed radially inside an air passage of the air guide 1 for the duct or the blower. These vanes 2 traverse the center of each vane 2 and the shafts 3 are coupled to each other, and the shafts 3 are formed on the inner circumferential surface of the air passage of the duct or air guide 1 and inside the air passage. It is rotatably coupled between the provided center support member (14). Therefore, the vanes 2 are rotated by the rotation of the shaft 3. In addition, a center rotating member 15 which is rotated coaxially spaced apart from the center supporting member 14 is provided, and a plurality of shaft members 16 are fixed radially to the circumferential surface of the center rotating member 15. do. The shaft member 16 of the center rotating member 15 is provided with a link member 17 having one end contacted thereto, and the other end of the link member 17 has a shaft 3 having the vanes 2 fixed thereto. Is coupled to, the link member 17 is configured to rotate the vane (2) by interlocking by the rotation of the center rotating member (15). At this time, the shaft member 16 is penetrated by a ring member 18 having a through hole 23 formed in the center thereof, and the through hole 23 of the ring member 18 slides along the outer circumferential surface of the shaft member 16. The ring member 18 is installed on the shaft member 16 and is configured to elastically support one side of the ring member 18 in contact with the other side of the spring 20 supported by the head of the shaft member 16. In addition, the outer surface of the ring member 18 of the shaft member 16 is in contact with the bearing portion 19 formed at one end of the link member 17 and forms a slide surface, so that the link member 17 is a shaft. It is connected to the member 16 to be rotatable and axially movable. Here, the bearing portion 19 is preferably formed in a concave shape in the link member 17, it may be formed by coupling a separate casing piece formed in the concave shape in the center portion to the link member 17. In addition, at least one of the outer surface of the ring member 18 and the bearing portion 19 of the link member 17 in contact with each other is formed in a curved surface, so that the connection angle between the shaft member 16 and the link member 17 is adjusted. It is preferable to be able to adjust, but both the outer surface of the ring member 18 and the bearing portion 19 of the link member 17 are formed in a spherical surface so that the shaft member 16 and the link member to guide the contact of both sides more smoothly ( 17 may be connected. In the accompanying drawings, it is shown that the rotational operation of the vanes 2 such as the shaft member 16, the ring member 18, the link member 17, and the like is formed outside the center rotating member 15. Rotating operation unit may be formed inside the center rotating member (15). In addition, a coupling portion 22 protruding in a ring shape is formed along the circumferential surface of the bearing portion 19, and a grease cap 21 is provided on the outer circumferential surface of the coupling portion 22 to be in close contact with the inner circumferential surface thereof. , The coupling method of the coupling portion 22 and the grease cap 21 is preferably a screw coupling, but of course, it can be other coupling, such as fitting coupling or clamping coupling.

Fig. 6 shows another embodiment of this vane type air flow control device, in which a ring member 18 which is closer to a general ring shape than a spherical ring member 18 is provided, and thus the shaft member 16 and the link member 17 are installed. It is configured to adjust the connection angle of).

7 shows another embodiment of this vane type air flow regulating device, in which a ring member 18 that slides on the shaft member 16 is included in the bearing portion 19 of the link member 17 so as not to be detached. It is configured not to. Here, in order to embed the ring member 18 in the bearing portion 19 of the link member 17, the bearing portion 19 is fixed in a split type so that the ring member 18 cannot be separated from the bearing portion 19. do. Therefore, the ring member 18 is able to operate without the spring 20, because the spring 20 does not need to be elastically supported.

FIG. 8 shows that the vane type air flow regulating device is installed in the blower, and the amount of air forcibly sucked or drawn out by the impeller rotated inside the blower is rotated by the vane 2 installed in the air guide 1 of the blower. It is configured to control. In the drawing, the center support member 14 and the center rotation member 15 are shown in a ring shape with a central portion drilled therein, but in the absence of interference of the impeller drive shaft of the blower, the center support member 14 and the center rotation member 15 are shown. The central portion of the can be formed in a clogged disc shape, it is possible to further increase the opening and closing efficiency of the air passage.

According to such a configuration, when the lever (not shown) connected to the center rotating member (15) is manually operated, or by connecting the motor shaft (not shown) to the lever, the center rotating member (15) is automatically rotated. The link member 17 is coupled to and supported by the bearing unit 19 to the ring member 18 which is slid from the shaft member 16 of the crank shaft 16 to rotate and move in the axial direction. Accordingly, the shaft 3 coupled to the other side of the link member 17 is rotated by the rotation and movement of the link member 17, and the vanes 2 coupled to the shaft 3 are rotated to open and close. The opening degree of the air passage of the duct or the air guide 1 is adjusted. At this time, the grease cap 21 covered with the shaft member 16 is filled with grease therein, and the grease is filled with the ring member 18, the bearing portion 19, and the spring (provided with the shaft member 16). 20 is not only prevented from being rusted by moisture in the air that is in contact, but also lubricated at the contact portion between the ring member 18 and the bearing portion 19 so that the ring member 18 is smooth in the bearing portion 19. Slide it.

As described above, according to the present invention, when the vane is rotated to control the air amount, the center rotating member and the center support member are spaced apart from each other without forming a sliding contact surface which is vulnerable to contamination or corrosion during operation of the vane. It works. Therefore, the center rotating member rotates smoothly regardless of contaminants or moisture in the air passing through the air passage inside the air guide for the duct or the blower, so that the vane rotation works well. Therefore, the air volume is controlled by manual and automatic control. This has the effect of being easier.

In addition, the vane-type air volume control device of the present invention is operated when the vane is rotated, the bearing portion of the link member connected to the vane is in contact with the ring member of the shaft member and slidably engaged, so that the shaft in the groove of the link member is conventionally The member is structurally strong as compared to the guided in the state of play. Accordingly, even if the vane or link member collides with the vane or the link member due to the air pressure automatically sucked or drawn out according to the conditions of the room, the vibration of the vane or link member is generated less. In addition, even if the impact caused by the vibration is repeated, the opening and closing operation of the vane is not damaged, so it is excellent in durability, in particular, it can be used suitably for adjusting the air volume by automatic control.

In addition, since the vane-type airflow control device of the present invention operates with a grease cap on a ring member, a bearing portion, a spring, and the like, provided in the shaft member, the ring member, the bearing portion, the spring, and the like are used in the indoor condition This prevents rust and corrosion by moisture in the air that is automatically sucked in or drawn out, and also lubricates the contact portion between the ring member and the bearing to facilitate the opening and closing operation of the vanes. Therefore, such a vane-type air flow control device is advantageous for automatic control as well as manual operation, and can be usefully used for factory automation for automatically adjusting temperature, humidity, cleanliness, etc., such as a clean room or a measurement room.

Claims (4)

A center support member 14 disposed inside the air passage of the blower air guide 1 or the duct and radially disposed between the inner circumferential surface of the air passage and the center support member 14 are rotatably coupled to each other. A plurality of vanes 2 for adjusting the opening degree, a center rotating member 15 which is coaxially spaced apart from the center support member 14, and the shaft member 16 is fixed radially to the circumferential surface thereof, and one side thereof Is coupled to the shaft member 16 of the center rotating member 15 and the other side thereof is coupled to the vane 2 and passes through the link member 17 and the shaft member 16 for rotating the vanes 2. And a ring member 18 coupled to and coupled to the outer surface of the link member 17. The link member 17 is in contact with the outer surface of the ring member 18 and the outer surface of the ring member 18. At least one of the bearing portions 19 is formed in a curved surface so that the link member 17 is rotated and shafted on the shaft member 16. A vane type airflow control device, characterized in that the direction movement is connected. The method of claim 1, wherein the shaft member 16 is characterized in that the spring 20 for elastically supporting the ring member 18 in the axial direction with respect to the bearing portion 19 of the link member 17 is installed. Vane-type air flow regulator. 3. An outer surface of the ring member 18 is formed as a spherical surface, and the bearing portion 19 is formed as a concave spherical surface corresponding to the outer surface of the ring member 18. Vane-type air flow control device. The method of claim 1, wherein the coupling portion 22 is formed along the circumferential surface of the bearing portion 19 of the link member 17, the inner circumferential surface of the coupling member 22 is in close contact with the shaft member ( It further comprises a grease cap (21) overlaid on the 16, the grease inside the grease cap 21 to prevent corrosion of the ring member 18, the bearing portion 19, the spring (20) A vane type air flow control device characterized in that.

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