KR102550352B1 - Butterfly damper with multi-axis motion structure - Google Patents

Abstract

The present invention relates to a butterfly damper with a multi-axis motion structure, which comprises: a body (10) having a seat (11) fixed on an inner surface and a disc (15) connected to a driving axis (13); a joint (20) installed in the center of the disc (15) for allowing the free movement of the seat (11); a link member (30) connecting the driving axis (13) and the joint (20) by a first link (31), a second link (32), and a third link (33) and causing the disc (15) to be opened/closed; and a sealing member (40) having a large number of sealing plates (41) for increasing the airtight condition on the edge of the disc (15). Therefore, in a process of blocking and controlling high-temperature gas on a flow path, sufficient airtight conditions can be maintained and simultaneously a high opening rate can be secured by realizing an opening/closing operation. Therefore, operation reliability can be guaranteed and durability can be improved.

Description

Butterfly damper with multi-axis motion structure}

The present invention relates to a butterfly damper, and more particularly, to a butterfly damper having a multi-axis motion structure for opening and closing a flow path of fluid during the operation of various industrial facilities.

In general, systems for handling fluids in industrial facilities are equipped with valves or dampers for changing or blocking the flow of fluids. In the case of chemical plants, steel mills, and power plants, dampers that block and control high-temperature gases are essential. Butterfly dampers are relatively simple and inexpensive, and are suitable for harsh environments of high temperature and humidity. In particular, when even a small leakage of fluid on the pipeline affects the process, it is recommended to apply a structure with improved durability due to low friction of the operating part.

Korean Patent Registration No. 0892073 (Prior Document 1) and Korean Patent Registration No. 0883646 (Prior Document 2) are known as prior art documents that can be referred to in this regard.

According to Prior Document 1, it is a water film valve that opens and closes the disk through multi-axis drive, and since the horizontal movement and rotation of the disk are simultaneously performed with one drive shaft operation, there is an effect of conveniently opening and closing the disk, and the disk moves horizontally and rotationally. Since it is opened and closed by proceeding, the friction between the disk and the adapter is minimized, and the effect of increasing the durability of the water film valve is expected.

In Prior Document 2, since the blade moves in the vertical direction and then rotates sideways during the opening and closing operation, a good contact relationship between the airtight member of the blade and the damper sheet is maintained, and the abrasion of the airtight member can be completely excluded. It is expected to reduce the maintenance cost due to the replacement of the airtight member, and to secure stable operation by reducing the operating resistance of the blade.

However, according to the above prior literature, there is room for improvement in that it is insufficient to secure a high open rate while maintaining airtightness in a high-temperature gas flow path.

Korean Patent Registration No. 0892073 "Water film valve with multi-axis operation gearbox" (Publication date: 2008.10.16.) Korean Registered Patent Publication No. 0883646 "Toggle Butterfly Damper" (Publication Date: 2009.02.18.)

An object of the present invention to improve the above conventional problems is to maintain sufficient airtightness in the process of blocking and controlling high-temperature gas on the flow path, and at the same time, a butter of a multi-axis motion structure that implements an opening and closing operation to secure a high opening rate. It is to provide a fly damper.

In order to achieve the above object, the present invention is a butterfly damper having a multi-axis motion structure: a body having a seat fixed to an inner surface and a disk connected to a driving shaft; a joint installed at the center of the disk to allow free movement with respect to the seat; a link member that connects the drive shaft and the joint through a first link-second link-third link to cause opening and closing of the disk; and a sealing member having a plurality of sealing plates to increase airtightness at the edge of the disk.

As a detailed configuration of the present invention, the joint is characterized in that the sphere supported at the center of the cross socket is pressed by each of the pressing pieces and the elastic body in four directions.

As a detailed configuration of the present invention, the pressing piece and the sphere are characterized in that they are engaged in a concavo-convex structure by a protrusion and a concave portion.

As a detailed configuration of the present invention, the link member maintains the center line of the first link parallel to the contact surface of the disk in a state of close contact between the sheet and the disk and at the same time maintains the center line of the second link at an obtuse angle with the center line of the first link characterized by

As a detailed configuration of the present invention, the sealing member is characterized in that the sealing plate formed of the Inconel steel plate is supported by the elastic plate and the fixing table.

As a detailed configuration of the present invention, the sealing plate is in contact with the driving shaft through the sliding portion, and the elastic plate maintains a linear contact state with the sealing plate.

As described above, according to the present invention, since the opening and closing operation is implemented to ensure a high open rate while maintaining sufficient airtightness in the process of blocking and controlling high-temperature gas on the flow path, there is an effect of guaranteeing operational reliability and improving durability.

1 is a configuration diagram showing a damper as a whole according to the present invention
Figure 2 is a schematic diagram showing the joint of the damper according to the present invention
Figure 3 is a schematic diagram showing a link member of the damper according to the present invention
4 is a configuration diagram showing an operation example of a damper according to the present invention

Hereinafter, embodiments of the present invention will be described in detail based on the accompanying drawings.

The present invention proposes a butterfly damper having a multi-axis motion structure. Dampers that block and control high-temperature gases in chemical plants, steel mills, power plants, etc. are targeted, but are not necessarily limited thereto. Multi-axis motion, as described later, is a technical idea that reduces impact and wear of the contact area with free motion of two or more axes.

According to the present invention, the body 10 has a structure having a seat 11 fixed to the inner surface and a disk 15 connected to a driving shaft 13.

Referring to FIG. 1 , a seat 11 constituting the body 10, a drive shaft 13, a disk 15, an actuator 17, and the like appear. The body 10 is based on a structure with flanges at both ends of a straight tube forming a flow path. The seat 11 is formed in an annular shape and fixed to the inner surface of the straight pipe of the body 10 by welding. The driving shaft 13 is rotatably supported while horizontally crossing the straight pipe of the body 10 . The disk 15 opens and closes the flow path while being in close contact with or separated from the seat 11 by the power of the drive shaft 13 . The driver 17 is connected to one end of the drive shaft 13 and applies hydraulic pressure or electric power.

In addition, according to the present invention, the joint 20 has a structure installed at the center of the disk 15 to allow free movement with respect to the seat 11.

Referring to FIGS. 1 and 2 , a state in which the joint 20 is concentrically connected to the disk 15 is shown. In the process of opening and closing the passage of the body 10, the moment the disk 15 comes into close contact with the seat 11, the joint 20 preferably allows free movement in two or more axes. When the joint 20 is excluded, the pressure at which the disk 15 contacts the seat 11 is not uniform, causing shock and noise as well as uneven wear.

As a detailed configuration of the present invention, the joint 20 is characterized in that the sphere 26 supported at the center of the cross socket 21 is pressed with each of the pressing pieces 22 and the elastic body 24 in four directions .

In FIG. 2, a cross socket 21, a pressure piece 22, an elastic body 24, a sphere 26, and the like constituting the joint 20 are shown. The cross socket 21 has subspaces extending in four directions from the central main space. The pressing piece 22 is supported in the subspace so as to swing through each elastic body 24 . The sphere 26 is connected to the drive shaft 13 through a link member 30 to be described later centered on one surface and is rotatably supported in the main space of the cross socket 21. Since the four pressing pieces 22 contact the sphere 26 in four directions and apply elastic force, the free movement of the disk 15 is allowed while suppressing minute fluctuations. In general, the connection of the ball joint method induces minute fluctuations of the disk 15 due to pressure fluctuations of opening and closing of the passage.

On the other hand, although not shown, the elastic force of the elastic body 24 may be adjusted by installing each adjusting bolt and adjusting plate at the four-direction outer ends of the cross socket 21. While using the damper for a long period of time, it is possible to maintain a constant pressing force of the pressure piece 22 on the sphere 26 using the control bolt.

As a detailed configuration of the present invention, the pressing piece 22 and the sphere 26 are characterized in that they are engaged in a concavo-convex structure by the protrusion part 23 and the concave part 27.

2 shows a state in which the protrusion 23 is formed on the pressing piece 22 and the groove 27 is formed on the sphere 26. The protrusion 23 and the concave portion 27 may be configured opposite to each other, and in any case, it is preferable to set the material and tolerance so that they are slidably engaged. In addition, it is better to intervene the sliding plate (not shown) rather than contacting the pressing piece 22 and the elastic body 24 directly. According to this configuration, the free movement of the disk 15 relative to the seat 11 is limited to two-axis movement.

In addition, according to the present invention, the link member 30 connects the drive shaft 13 and the joint 20 to the first link 31 - the second link 32 - the third link 33 to form a disc 15 It has a structure that causes the opening and closing of

Referring to FIGS. 1 and 3 , link pins 35 and 36 together with the first link 31 , the second link 32 , and the third link 33 constituting the link member 30 are shown. The first link 31 is connected to the driving shaft 13 at an upstream end and connected to the second link 32 via a first link pin 35 at a downstream end. The second link 32 is connected to the sphere 26 of the joint 20 on one side based on the first link pin 35 and connects to the third link 33 through the second link pin 36 on the other side. Connected. The third link 33 is connected to the second link pin 36 at the upstream end and connected to the hinge shaft 37 at the downstream end. The hinge shaft 37 may be directly supported by the body 10 or supported by the drive shaft 13 using a separate bracket. According to the rotation direction of the drive shaft 13, the first link 31, the second link 32, and the third link 33 interlock and cause the disk 15 to rotate.

As a detailed configuration of the present invention, the link member 30 maintains the center line of the first link 31 parallel to the contact surface of the disk 15 in a state of close contact between the seat 11 and the disk 15, and at the same time It is characterized by maintaining the center line of the two links 32 at an obtuse angle with the center line of the first link 31.

In FIG. 3, a state in which the second link 32 connected to the disk 15 rotates approximately 90 degrees is shown. The center line of the first link 31 is a straight line connecting the center of the driving shaft 13 and the center of the first link pin 35 . The center line of the second link 32 is a straight line connecting the center of the first link pin 35 and the center of the second link pin 36 . 3, the center line of the first link 31 is parallel to the disk 15, and the center line of the second link 32 is maintained at 90 degrees or more with the center line of the first link 31. Accordingly, while the first link 31 rotates by 90°, the second link 32 and the disk 15 are rotated by 90° as indicated by the signs 32', 35', and 36'.

Referring to FIG. 4 , a state in which the disk 15 is opened and closed in parallel with the passage of the body 10 as shown by numeral 15' by the mechanism of FIG. 3 is shown. According to such a configuration, a higher open rate can be secured compared to the prior art. Of course, the free movement of the disk 15 through the aforementioned joint 20 is not restricted.

In addition, according to the present invention, the sealing member 40 has a structure provided with a plurality of sealing plates 41 to increase airtightness at the edge of the disk 15.

1 shows a state in which the sealing plate 41 constituting the sealing member 40 is in contact with the seat 11 of the body 10 at the edge of the disk 15 . The sealing plate 41 is thinner than the disk 15 and has high rigidity, and is divided into an appropriate number according to the size of the disk 15 and fixed. In the process of opening and closing the passage, contact the seat 11 through the sealing plate 41 rather than the edge of the disk 15.

As a detailed configuration of the present invention, the sealing member 40 is characterized in that the sealing plate 41 formed of an Inconel steel plate is supported by an elastic plate 44 and a fixing table 47.

The sealing plate 41 uses Inconel 625 material and maintains a thickness of about 0.5 mm. Inconel material has excellent heat resistance, corrosion resistance, and fatigue strength, and is suitable for coping with dusty environments. A plurality of sealing plates 41 are installed on the edge of the disk 15 so as to be closely adjacent to each other without gaps. Each sealing plate 41 is mounted on the disk 15 together with the elastic plate 44 and the fixing table 47. The elastic plate 44 and the fixing table 47 are also divided into the same number as the sealing plate 41 and installed. The elastic plate 44 reinforces the rigidity of the sealing plate 41 to cause a quick elastic return and contribute to improving durability. The fixing table 47 closely adheres the sealing plate 41 and the elastic plate 44 to the disk 15 .

As a detailed configuration of the present invention, the sealing plate 41 is in contact with the driving shaft 13 and the sliding portion 42, and the elastic plate 44 maintains a line contact state with the sealing plate 41 to be characterized

In FIG. 1, the sliding portion 42 and the contact portion 45 constituting the sealing member 40 are shown. During the opening and closing process of the disk 15, sliding friction in a direction orthogonal to the flow path occurs in addition to the rotational motion at right angles. The sliding portion 42 of the sealing plate 41 increases durability by increasing the thickness or adding a wear-resistant material at a portion in contact with the seat 11 by sliding. The elastic plate 44 is bent into a corrugated structure and brought into contact with the sealing plate 41 through the linear (arc) contact portion 45 . The fixing table 47 is also formed in a structure bent to match the corrugated elastic plate 44 . When the elastic plate 44 is in line contact with the sealing plate 41 by the contact portion 45, it is advantageous in terms of elastic recovery and heat dissipation.

The present invention is not limited to the described embodiments, and it is obvious to those skilled in the art that various modifications and variations can be made without departing from the spirit and scope of the present invention. Therefore, such variations or modifications should fall within the scope of the claims of the present invention.

10: body 11: seat
13: drive shaft 15: disk
17: actuator 20: joint
21: cross socket 22: pressure piece
23: protrusion 24: elastic body
26: sphere 27: groove
30: link member 31: first link
32: second link 33: third link
35, 36: link pin 37: hinge axis
40: sealing member 41: sealing plate
42: slide part 44: elastic plate
45: contact part 47: fixing table

Claims (6)

In the butterfly damper having a multi-axis motion structure:
a body (10) having a seat (11) fixed on an inner surface and a disk (15) connected to a driving shaft (13);
A joint 20 installed at the center of the disk 15 to allow free movement relative to the seat 11;
a link member 30 that causes the disk 15 to open and close by connecting the drive shaft 13 and the joint 20 to the first link 31 - the second link 32 - the third link 33; and
A sealing member 40 having a plurality of sealing plates 41 to increase airtightness at the edge of the disk 15; including,
The joint 20 presses the sphere 26 supported at the center of the cross socket 21 with each of the pressing pieces 22 and the elastic body 24 in four directions Butterfly damper of multi-axis motion structure . delete The method of claim 1,
The pressure piece 22 and the sphere 26 are multi-axis motion structure butterfly damper, characterized in that engaged in a concavo-convex structure by the protrusion 23 and the concave portion 27. The method of claim 1,
The link member 30 maintains the center line of the first link 31 parallel to the contact surface of the disk 15 in a state of close contact between the seat 11 and the disk 15, and at the same time the center line of the second link 32 Butterfly damper of multi-axis motion structure, characterized in that for maintaining the center line of the first link 31 and the obtuse angle. The method of claim 1,
The sealing member 40 is a multi-axis motion structure butterfly damper, characterized in that for supporting the sealing plate 41 formed of an inconel steel plate with an elastic plate 44 and a fixing table 47. The method of claim 5,
The sealing plate 41 is in contact with the drive shaft 13 and the sliding portion 42, and the elastic plate 44 maintains a line contact state with the sealing plate 41 of the multi-axis motion structure, characterized in that Butterfly damper.

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