KR101514115B1 - Disk pressurized butterfly valve - Google Patents

Abstract

The present invention relates to a butterfly valve installed on a flow path of a fluid to control the flow of a fluid. When the disk is rotated at a predetermined angle, the butterfly valve is disengaged from the rotation axis, The present invention relates to a uniaxial disk pressurized butterfly valve having a structure capable of being separately moved toward the main body sheet.
The present invention can provide a structure capable of simultaneously configuring a valve to allow rotation of the disk and movement of the disk by only one rotation of the rotation axis, thereby minimizing wear of the disk and body sheets, So that the sealing force can be improved.

Description

Disk pressurized butterfly valve < RTI ID = 0.0 >

The present invention relates to a butterfly valve installed on a flow path of a fluid to control the flow of a fluid. When the disk is rotated at a predetermined angle, the butterfly valve is disengaged from the rotation axis, The present invention relates to a uniaxial disk pressurized butterfly valve having a structure capable of being separately moved toward the main body sheet.

The present invention can provide a structure capable of simultaneously configuring a valve to allow rotation of the disk and movement of the disk by only one rotation of the rotation axis, thereby minimizing wear of the disk and body sheets, So that the sealing force can be improved.

Generally, a butterfly valve is a valve installed in a connection portion of a fluid passage that supplies various kinds of water such as drinking water, industrial water, agricultural water, and chemicals such as chemicals and chemical agents, A valve that opens and closes a passage to control the flow rate or flow rate.

Such a butterfly valve has a structure in which a disc-shaped disc is rotatably fixed to a rotating shaft provided in the main body, and the disc is rotated by the rotating shaft to intermittently circulate the fluid in the channel. When the valve is closed, And the disk sheet are in contact with each other.

At this time, in order to maintain the watertightness of the valve, either the body sheet or the disc seat is made of an elastic sheet made of rubber, urethane, silicone, Teflon, or a thin sheet metal having constant elasticity.

However, the elastic sheet has a fatal problem that it is weak to heat, foreign substances in the fluid, and chemical substances such as chemicals and chemical agents, and is easily worn and has poor water tightness.

In order to solve such a problem, a disk pressurized butterfly valve is disclosed. The disk pressurized butterfly valve has a structure in which the rotating shaft has a double shaft structure of an inner shaft and an outer shaft, and the inner shaft is provided with a cam device for causing the disk to perform forward and backward linear motion, and the outer shaft is configured to rotate the disk .

Therefore, when the disc is rotated by the outer shaft and the disc is completely opened, the flow direction of the fluid and the surface of the disc are 90 degrees. In this state, the disk rotates linearly in the direction of the main body sheet by rotation of the inner shaft, so that the main body sheet and the disk sheet are compressed and sealed.

When the valve is opened, the inner shaft is rotated to linearly move the disk in the backward direction so that the respective sheets are separated from each other. Then, the disk is rotated using the outer shaft to open the disk.

As described above, the disk-pressurized butterfly valve can operate both forward and backward movement and rotational movement of the disk without friction of the seat, so that it is possible to operate even if a cushion sheet having no elasticity is used for the main body seat and the disk seat. And the abrasion of the sheet is suppressed.

However, as described above, the conventional disk-pressurized butterfly valve has a double shaft structure of inner and outer shafts, which complicates the structure and configuration. Accordingly, the number of parts used is large, And the maintenance is not easy.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and provides a structure for simultaneously rotating the disk for interrupting the fluid and the forward and backward movement of the disk for pressing action of the sealing force by using only one rotary shaft installed inside the body There is purpose in.

In order to achieve the above-mentioned object, the present invention is configured such that the disk is fixed to the rotating shaft while rotating the disk to intermittently rotate the fluid, and when the disk is moved forward and backward to improve the sealing force, Thereby providing a separate structure.

According to another aspect of the present invention, there is provided a structure in which a cam structure for enhancing a hermetic force is formed by pushing a disk in a linear direction after the disk is separated from a rotary shaft to closely contact the disk sheet.

According to the present invention having the above structure, since the disk is separated from the rotation shaft, the disk can be pushed by the kinematic structure or the fluid pressure to enhance the adhesion with the main body sheet, and the sealing force can be improved.

Further, wear of the disc seat and the main body sheet is minimized, and durability is improved.

In addition, when the cam structure is added, the rotation and linear motion of the disk can be performed by only one rotation axis, so that the structure and the configuration are simple, and the number of parts used thereby reduces the manufacturing time and manufacturing cost of the valve, There is an effect that maintenance can be facilitated.

1 is an overall perspective view of an embodiment in which two disk separating apparatuses and two disk closing apparatuses are installed,
2 is a partially cutaway front view of an embodiment in which two disk separation devices and two disk contact devices are installed,
Fig. 3 is a lateral cross-sectional view of an embodiment in which two disk separating apparatuses and two disk-
Fig. 4 is a longitudinal sectional view of the front side of the embodiment in which the disk separating device and the disk closing device are provided one by one, respectively
5 is a detailed perspective view of the disk separating device and the disk-
6 is an exploded perspective view of the slide pin of the disk separating device.
7 is an exploded perspective view of another embodiment of the slide pin.
Figs. 8 to 11 are diagrams showing operating states of the disk separating device and the disk-
12 is a diagram showing an embodiment of the eccentric cam and the inclined cam of the disk-
Fig. 13 is a lateral cross-sectional view of an embodiment in which two disk sticking devices and two disk separating devices,
14 is a vertical cross-sectional view of an embodiment in which a disc-closing device and a disc-separating device, to which a warp cam is applied,

1, 2, 3, and 13, the uniaxial disk pressurized butterfly valve 100 according to the present invention is provided with two disk separators 7 and two disk coaters 6, Or may be implemented one by one as shown in FIGS. 4 and 14, respectively.

As described above, the present invention can be variously implemented. One or more disk attachment devices 6 and disk separating devices 7 may be installed according to various situations including the size of the valves, The position of each of the adhered device 6 and the disk separating device 7 is not limited to the position shown in the drawings, and can be variously changed.

Hereinafter, for ease of explanation and clarity of the working relationship, the description will be focused on the embodiment in which the disk sticking device 6 and the disk separating device 7 are installed one by one, and in the case where description of two or more installed embodiments is necessary, .

A uniaxial disk pressurized butterfly valve (100) according to the present invention comprises a main body (5); A rotating shaft (2) penetrating the main body (5) and formed with an insertion groove (14); A disk 1 fastened to the rotary shaft 2; A slide pin 16 provided on one surface of the disk 1 and one end of which is inserted into the insertion groove 14 and the other end of which is formed with a projection 15; And a guide plate 18 having a guide groove 17 formed in a specific shape.

With this arrangement, when the disc 1 is rotated by the rotary shaft 2, one end of the slide pin 16 is inserted into the insertion groove 14, so that the disc 1 and the rotary shaft 2 move integrally, The protrusion 15 is moved along the guide groove 17 and the disc 1 is brought into the position for completely closing the main body 5 by the action of the protrusion 15 and the guide groove 17 The one end of the slide pin 16 is disengaged from the insertion groove 14 and the disk 1 is separated from the rotary shaft 2. [

The structure of the slide pin 16 may be variously arranged on one side of the disk 1. The structure of the slide pin 16 may be a through hole 12 may be formed on one surface of the disc 1 and the slide pin 16 may be inserted into the through hole 12 to be moved in a rectilinear motion.

The slide pin 16 may be variously configured, and may be configured as shown in FIG. 6 as an example of the embodiment. A pin body 22 having a step 19 formed at one end thereof and formed with a bolt insertion groove 20 on the outer circumferential surface thereof and a thread 21 at the other end thereof and a collar 23 inserted into the pin body 22, A spring 24 inserted into the collar 23 so as to be inserted into the pin body 22 so that the fastening bolt 25 is inserted into the bolt insertion groove 20, A protrusion 15 screwed to the thread 21 of the pin body 22 and a nut 27 fastened to the outer side of the protrusion 15.

7, the slide pin 16 may include a pin body 22 having a step 19 formed at one end thereof and a thread 21 formed at the other end thereof, A pin inserted into the pin body 22, a spring 24 inserted into the pinch body 22, a pin housing 28 inserted into the pin body 22, A projection portion 15 inserted into the inside of the projection portion 28 and screwed to the thread 21 of the pin body 22 and a nut 27 fastened to the outside of the projection portion 15.

Here, the step 19 formed at the end of the pin body 22 of the slide pin 16 may be omitted, and a separate member such as a snap ring may be used to replace the step 19.

Also, the spring 24 inserted into the outer circumferential surface of the pin body 22 has no problem in operation of the slide pin 16 even if the use thereof is omitted. However, the reciprocating movement of the slide pin 16 is maintained smoothly for a long time, In order to continue the performance of the role, a structure having the spring 24 as described above is suitable.

On the upper surface of the guide plate 18, guide grooves 17 of a rounded arc shape or a straight line are formed as shown in Figs. 5 and 8, and the like. 2 and 8, the guide plate 18 can be fastened to the guide plate fastener 29 provided on the main body 5 with bolts 30 and fixed thereto. The guide plate fastener 29 functions as a stopper for preventing the disc 1 from rotating further in a state in which the disc 1 is rotated by the series of operations of the valve as shown in Fig. .

When the guide groove 17 is formed in a specific shape, when the slide pin 16 comes to a position where the disc 1 is completely closed by the protruding portion 15 inserted into the groove and moving along the shape of the groove, So that one end of the one end is completely removed from the insertion groove 14 formed in the rotary shaft 2. That is, the guide groove 17 is not limited to the shape shown in the drawing, but may be a shape in which the protrusion 15 of the slide pin 16 can be inserted. When the valve is in the fully closed position, Any structure may be used as long as it can be detached from the housing 2.

In addition, the present invention can further include the disk sticking device 6 in the above structure. That is, the disk sticking device 6 may be provided on one surface of the disk 1. [ The disc closing device 6 is fixed to a part of a rotating shaft 2 penetrating the inside of the cam insertion space 33 and a boss 9 provided on one surface of the disc 1 and having a cam insertion space 33 formed therein And an eccentric cam 11 provided so as to be in contact with the inner surface of the boss 9. Therefore, it becomes possible to interlock with the disk separating device 7 by one rotary shaft 2.

The cam support jaw 8 may protrude from the inside of the boss 9. The eccentric cam 11 may be formed with a cam chin 10 that interacts with the cam follower chin 8. Therefore, the reliability of the operation can be improved by the engagement of the cam pedal jaw 8 and the cam chuck 10 at the time of cam action.

The above-mentioned disk-tightening device 6 is a basic embodiment having a general cam structure, and may have other embodiments that are implemented with a cam having a sloped structure deviated from the general cam structure.

In this case, an oblique surface 35a which is provided on one surface of the disc 1 and is inclined at an angle to the disc 1 in the vertical direction toward the disc 1 can be used as the disc close- A boss 9 having a cam insertion space 33 formed therein; A vertical screw hole 34 which is inserted into the cam insertion space 33 and formed with an inclined surface 35b contacting the inclined surface 35a and which is screwed with the screw portion of the rotating shaft 2 passing through the cam insertion space 33, And an inclined cam 32 formed on the cam surface.

14, one of the inclined cams 32 may be provided, and two inclined cams 32 may be provided as shown in FIG. The direction of the inclined surfaces 35a and 35b and the shape of the screw formed on the rotary shaft 2 and the direction of the inclined surfaces 35a and 35b are adjusted so that the direction in which the respective disk- The shape of the screw of the vertical screw hole 34 formed inside the inclined cam 32 should be appropriately configured.

The present invention may also be embodied in a structure in which only the disc adhering device 6 having the inclined cam 32 as a component is installed. In this case, the main body 5; A rotation shaft 2 provided so as to penetrate the main body 5; A disk 1 which is fastened to the rotary shaft 2 to open and close the internal flow path of the main body 5; A boss 9 provided on one side of the disk 1 and having a cam insertion space 33 having an inclined surface 35a inclined at a predetermined angle toward the disk 1 in the vertical direction on the inside, And a vertical screw hole 34 screwed into the screw portion of the rotating shaft 2 passing through the cam insertion space 33 is formed in the inclined surface 35b, And a disc closing device 6 composed of a cam 32.

The present invention of various embodiments as described above is characterized in that the disk 1 and the rotary shaft 2 are integrally fixed and rotate together during a rotation interval between a position where the disk 1 fully opens the valve and a position where the disk 1 completely closes the valve . When the disc 1 is moved forward or backward to increase the sealing force at the position where the disc 1 completely blocks the valve 1, the disc 1 is separated from the rotating shaft 2, So that the disk sheet 3 and the main body sheet 4 are pressed against each other.

Hereinafter, the operation of the present invention will be described in detail through a process from a fully opened state to a fully closed state.

When the slide pin 16 is inserted into the insertion groove 14 of the rotation shaft 2 through the through hole 12 of the pin fastening member 13 as shown in Figure 8 (a) , And the eccentric cam 11 also maintains the correct position as shown in FIG. 8 (b).

When the rotary shaft 2 is operated to interrupt the fluid in this state, the disk 1 fixed by the slide pin 16 to the rotary shaft 2 as shown in FIG. 8 (a) And the eccentric cam 11 is also integrally rotated in the same direction with the eccentric cam 11 fixed in the fixed position as shown in Fig. 8 (b).

9 (a), before the rotation shaft 2 and the disk 1 are rotated to a certain point and are parallel to the main body 5, the guide groove 18 of the guide plate 18 provided on the main body 5 The projecting portion 15 of the slide pin 16 connected to the rotating shaft 2 is inserted into the eccentric cam 11 and the eccentric cam 11 is inserted into the rotating shaft 2 without any particular change as shown in Figure 9 (b) In the same direction.

When the projection 15 of the slide pin 16 is inserted into the guide groove 17 of the guide plate 18 and the rotary shaft 2 continues to rotate, the projection 15 is engaged with the guide groove 17 And one end of the slide pin 16 inserted into the insertion groove 14 of the rotary shaft 2 is naturally inserted into the insertion groove 14 by the operation of the mechanical structure of the projection 15 and the guide groove 17. [ 14).

For such an operation, the straight line distance from the center of the rotary shaft 2 to the starting point of the guide groove 17 must be different from the straight line distance to the last point. In this case, the distance gradually increases from the starting point to the last point. It is natural.

When the slide pin 16 is completely detached from the rotary shaft 2 in this way, the disk 1 can move independently of the rotary shaft 2 and is no longer rotated by the rotary shaft 2, Only the rotating shaft 2 is continuously rotated as shown in Fig. 11 (a).

Therefore, the state up to the above-described state is the operation of the disk separating device 7, and the operation of the disk separating device 6 is started.

11 (b), the eccentric cam 11 inserted into the boss 9 is rotated in the same direction as the rotating shaft 2 and the eccentric cam 11 is rotated in the same direction as the rotating shaft 2, The disk sheet 3 is pressed against the main body sheet 4 by pushing the disk sheet 3 toward the main body 5 so as to be in a completely closed state.

At this time, as the cam supporting jaw 31 formed on the inner surface of the boss 9 and the eccentric cam 11 come into close contact with each other, the disc seat 3 and the main body seat 4 are kept in a firmly fixed state . Of course, it is not necessary to form a separate cam support jaw 31.

On the contrary, the operation from the fully closed state to the completely opened state and the operation state will be described as follows.

The eccentric cam 11 fixed to the rotary shaft 2 is also rotated in the same direction as the rotary shaft 2 is rotated in the opposite direction to the closing direction of the rotary shaft 2, 5 and the pressed disk 1 move away from the main body 5 while moving backward in the direction of the rotating shaft 2 so that the main body sheet 4 and the disk seat 3 are separated from each other in a compressed state, As shown in FIG. 10 (a), is kept in a parallel state with the main body 5 without being rotated because it is in a state separated from the rotating shaft 2.

When the rotation shaft 2 is continuously rotated, the protrusion 15 of the slide pin 16 is moved along the guide groove 17 of the guide plate 18 to move the slide pin 16 in the direction of the rotation axis 2 do. One end of the slide pin 16 is inserted into the insertion groove 14 formed in the rotary shaft 2 so that the rotary shaft 2 and the disk 1 are formed as a single structure, .

The camshaft 10 formed on the outer surface of the eccentric cam 11 is engaged with the inner surface of the boss 9 so that the rotation shaft 2 and the disk 1 are coupled to each other by the disk separator 7, The disc 1 is also rotated together with the cam follower 8 in a direction in which the valve is fully opened in the same direction as the rotating shaft 2. [

In this process, the operation of the present invention is not required without the configuration of the cam jaw 10 and the cam support jaw 8, but the rotation of the disc 1 and the rotation shaft 2, So that a series of operations can be performed more smoothly.

Although the present invention may be practiced with a valve having the above-described disk-tightening device 6 having a general cam structure, the structure of the cam may be the inclined cam 32 to achieve the object of the present invention.

That is, as shown in Figs. 12 to 14, the cam, which is one of the components of the disk sticking device 6, is the inclined cam 32. [ The inclined cam 32 is composed of an inclined cylindrical body or a polygonal cylinder with the upper and lower surfaces being parallel to each other and the center of the upper surface and the center of the lower surface being separated from each other by a certain distance on a horizontal plane. And the screw holes 34 formed in the center are formed vertically. The outer surface has an inclined surface 35b inclined by a predetermined angle. The entire outer surface may be formed as one inclined surface 35b, or only a portion of the outer surface may be formed as the inclined surface 35b.

In other words, the inclined surface 35b formed on the outside needs to be inclined all over the outer surface because the inclined surface 32b is vertically moved, and the other portion coupled with the inclined surface 35b is pushed to the left or right. There is no.

A boss 9 having a cam insertion space 33 having an inclined surface 35a inclined at a predetermined angle toward the disc 1 in the vertical direction is provided on one side of the disc 1. The rotary shaft 2 is formed with a screw to be screwed with the screw hole 34 of the inclined cam 32.

The screw portion of the rotating shaft 2 passing through the cam insertion space 33 of the boss 9 and the vertical screw hole 34 of the inclined cam 32 are screwed together so that the inclined surface 35a of the boss 9, And the inclined surface 35b of the inclined cam 32 come into contact with each other.

The operation and the operating state from the fully open state to the fully closed state of the present invention to which the inclined cam 32 is applied will be described in detail as follows.

First, the operation of the disk separating device 7 from the open state to the closed state is the same as that described above. Hereinafter, the operation of the disk closing device 6 constituted by the inclined cam 32 will be described.

The rotation of the disk 1 from the completely opened state to the fully closed position is achieved by the common disk separation device 7 of the present invention. When the disc 1 is completely closed, the disc 1 is separated from the rotating shaft 2. [

The subsequent rotation of the rotary shaft 2 does not rotate the disc 1 but acts to move the disc 1 by the disc close-up device 6. That is, when the rotary shaft 2 is rotated, since the screw thread formed on the vertical or bore hole 34 of the inclined cam 32 and the outer peripheral surface of the rotary shaft 2 are threadedly engaged, And is moved upward or downward. In the example shown in Fig. 13, the upper inclined cam 32 is moved downward by the rotation of the rotary shaft 2, and the lower inclined cam 32 is moved upward.

The inclined cam 32 pushes the boss 9 and pushes the boss 9 against the disk 9 provided with the boss 9 so that the inclined surface 35b of the inclined cam 32 moves in close contact with the inclined surface 35b of the boss 9. Therefore, The disc 1 is pushed toward the main body sheet 4 and eventually the disc seat 3 is brought into close contact with the main body sheet 4 to increase the sealing force.

When the rotary shaft 2 is rotated in the opposite direction, the upper inclined cam 32 is moved upward and the lower inclined cam 32 is moved downward by the thread formed on the rotary shaft 2 in Fig. 13, Whereby the disc 1 is moved in a direction away from the main body sheet 4. [

The disc sheet 3 and the main body sheet 4 are spaced apart from each other and the rotation of the rotating shaft 2 continues to be transmitted to the slide pin 16 by the action of the protruding portion 15 of the disc separating device 7 and the guide groove 17, One end of the disk 1 is inserted into the insertion groove 14 of the rotary shaft 2 so that the disk 1 and the rotary shaft 2 are integrally coupled.

The rotation of the rotary shaft 2 after the above-described state is performed by rotating the disk 1 to open the valve.

As described above, according to the present invention, since the disc 1 is separated from the rotary shaft 2, it is possible to enhance the adhesion with the main body sheet 4 by pushing the disc with a kinematic structure or fluid pressure, . Wear of the disk sheet 3 and the main body seat 4 is minimized and durability is improved. In addition, when the cam structure is added, the disk 1 can be rotated and rectilinearly moved by only one rotating shaft, The number of parts to be used can be reduced and the number of parts to be used can be reduced, so that the manufacturing time and manufacturing cost of the valve can be reduced, and maintenance can be facilitated.

1: Disk 2:
3: disc sheet 4: main body sheet
5: Main body 6: Disk close device
7: disk separating device 8: cam rest chin
9: Boss 10:
11: eccentric cam 12: through hole
13: pin fastening member 14: insertion groove
15: protrusion 16: slide pin
17: guide groove 18: guide plate
19: Step 20: Bolt insertion groove
21: thread 22: pin body
23: Kara 24: Spring
25: fastening bolt 26: fastening nut
27: Nut 28: Pin housing
29: Guide plate fastener 30: Bolt
31: cam supporting jaw 32: inclined cam
33: cam insertion space 34:
35a, 35b: inclined surface 100: uniaxial disk pressurized butterfly valve

Claims (3)

A main body 5; A rotating shaft (2) penetrating the main body (5) and formed with an insertion groove (14); A disk 1 which is fastened to the rotary shaft 2 to open and close the internal flow path of the main body 5; One end of the slide pin 16 is inserted into and pulled out from the insertion groove 14 and the other end of the slide pin 16 is formed with a protrusion 15 so as to be inserted into the pin fastening member 13, And a disk separating device 7 composed of a guide plate 18 formed in the main body 5 and formed with a guide groove 17 into which a protrusion 15 is inserted and guided in a specific shape. Pressurized butterfly valve.
2. The disk cartridge according to claim 1, further comprising: a boss (9) formed on one surface of the disk (1) and formed with a cam insertion space (33) and a cam receiving jaw (8) The cam jaw 10 is fixed to a portion of the rotation shaft 2 penetrating into the cam insertion space 33 so as to be in contact with the inner surface of the boss 9, (6) which is composed of an eccentric cam (11) formed in a substantially flat shape.
The disc cartridge according to claim 1, wherein a cam insertion space (33) provided on one surface of the disc (1) and having an inclined surface (35a) inclined at an angle to the disc (1) A boss 9 formed therein; A vertical screw hole 34 which is inserted into the cam insertion space 33 and formed with an inclined surface 35b contacting the inclined surface 35a and which is screwed with the screw portion of the rotating shaft 2 passing through the cam insertion space 33, And a slanting cam (32) formed on the disc slider (32).

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