KR102030788B1 - Buttryfly valve - Google Patents

Abstract

The present invention relates to a butterfly valve and, more specifically, to a butterfly valve which can prevent a fluid from rising to an actuator that rotates a disc with respect to a valve body, and can increase watertightness when the disc is rotated to close the valve. The butterfly valve suppresses the rise of the fluid to the actuator by using a fluid discharge unit to prevent damage to a rotation control unit, thereby increasing durability. Moreover, the butterfly valve rapidly guide the fluid flowing into the fluid discharge unit to be discharged while the butterfly valve is rotated in a rotational direction of a rotary shaft in the fluid discharge unit, thereby increasing fluid rise suppression efficiency.

Description

Butterfly Valve {Buttryfly valve}

The present invention relates to a butterfly valve, and more particularly, to a butterfly valve which can prevent the fluid from being raised to the actuator for rotating the disk with respect to the valve body, and the valve is hermetically sealed when the disk is rotated. It is about.

In general, pipes composed of pipes are used for the transfer of various fluids. In some cases, the fluids to be supplied need to be cut off or the flow rate appropriately adjusted.

Accordingly, a valve is provided at a predetermined position of the pipeline to open or close the flow of fluid moving therein or to adjust the flow rate.

There are various types of valves according to the purpose and shape of the valve. The butterfly valve refers to a valve in which the flow rate of the pipeline is adjusted as the disk rotates about the disk center line in the valve. It is simple to open and close a functional group, so it is quick to operate and is widely used for high pressure water, steam, air and gas as well as low pressure.

The general butterfly valve has a structure capable of maintaining watertightness as the outer circumferential surface of the disk rotatably installed about the rotation axis in the valve body and the inner circumferential surface of the valve seat mounted on the inner circumferential surface of the valve body are interviewed with each other. Korean Utility Model Publication No. 20-2011-0001907 discloses a flange-type high performance butterfly valve. Republic of Korea Utility Model Publication No. 20-0188898 shows a sealing device of a flanged butterfly valve. The butterfly valve has a structure in which the valve seat and the actuator are coupled to each other by the flange of the valve seat and the actuator. In this case, the fluid flows into the actuator along the axis of rotation, thereby damaging the actuator.

Korean Utility Model Publication No. 20-2011-0001907: Flanged Type High Performance Butterfly Valve Republic of Korea Utility Model Registration No. 20-0188898: Sealing device for flanged butterfly valve Republic of Korea Utility Model Publication No. 20-0202917 has a fixed structure of rubber seat of the butterfly valve

In order to solve the above problems, the present invention is to provide a butterfly valve that can prevent the fluid is controlled to move in accordance with the opening and closing of the pipeline is moved to the actuator side to damage the control unit.

In addition, the present invention is to provide a butterfly valve that can increase the water-tightness by forcibly sandwiching the disk to reduce the contact shock between the valve seat and the disk when the disk is rotated so that the pipeline is closed by the actuator drive.

Butterfly valve of the present invention for achieving the above object is a valve body formed with a through hole connected to the pipe for fluid transfer, and is formed extending in the radial direction of the through hole rotatably mounted to the valve body A rotating shaft penetrating through the through hole of the head portion formed in the valve body, a disk fixed to the rotating shaft to be positioned in the through hole of the valve body, the rotatable opening and closing of the through hole, and mounted in the through hole of the valve body. A valve unit having first and second through-holes formed in one side and the other side corresponding to the head part, respectively, through which the rotating shaft penetrates, and having a valve seat in close contact with an inner circumferential surface thereof; And a rotation control unit supporting a driving shaft coupled to the rotation shaft of the valve unit and having a second flange portion coupled to a first flange portion provided on the head portion, wherein the valve is provided on an upper surface of the first flange portion. In order to prevent the fluid controlled by the unit from flowing into the rotation control unit side through the head portion is formed with respect to the upper surface of the first flange portion and extends in the outward direction from the rotating shaft to discharge the rising fluid to the outside Characterized in that the fluid discharge portion is formed.

The fluid discharge portion is formed to be drawn into the lower surface of the upper surface of the first flange portion so that the fluid rising through the head portion is formed extending along the circumference of the rotating shaft to prevent the rise of the fluid; And a fluid discharge groove extending from one side of the fluid rise preventing groove to an edge of the first flange portion.

A ring-shaped fluid lift suppressing portion having an inner diameter corresponding to the rotation shaft and having a smaller outer diameter than the fluid lift prevention groove and being rotated together with the rotation shaft in the fluid lift prevention groove, and on one side of the fluid lift suppression ring portion; Fluid provided with a transfer guide rib portion extending radially in contact with the inner circumferential surface of the fluid lift prevention groove to rotate and move the fluid introduced into the fluid lift prevention groove to be discharged to the fluid discharge groove while being rotated together with the fluid lift suppression ring. It has a conveying member.

The rotation control unit includes an actuator for opening and closing the through hole of the valve body by rotating the drive shaft coupled with the rotation shaft such that the disk is rotated, and mounted in the actuator so as to be integrally rotatable with the drive shaft and with a stopper on one side. A rotating stopper having a surface and a rotating angle limiting unit contacting the stopper surface of the rotating stopper to limit the rotating angle of the rotating stopper, wherein the rotating angle limiting unit enters into the inner space of the actuator. And a plurality of limiting members, each of which is mounted in the through space and restricts rotation angles in both directions of the rotary stopper according to the length entered into the inner space, wherein the plurality of limiting members are buffered at an end side in contact with the stopper surface. Rotating the disk is formed of a material to close the through hole of the valve body It is provided in a protruding portion of the valve seat to project toward the disc the disc is in contact interference fit shock reduction that the repulsive force is reduced to be contracted about the rotation of the disk when the fitting parts of each interference.

The butterfly valve of the present invention has an advantage of increasing durability because the rise of the fluid is suppressed by the fluid discharge part to prevent the damage of the rotation control unit.

In addition, the butterfly valve of the present invention has the advantage of increasing the fluid rise suppression efficiency because it is induced to quickly discharge the fluid introduced into the fluid discharge portion to the outside while rotating in the rotational direction of the rotating shaft in the fluid discharge portion.

1 is a butterfly valve according to a first embodiment of the present invention,
Figure 2 is a side view of the butterfly valve of Figure 1,
Figure 3 is a partial perspective view of the butterfly valve of Figure 1,
4 is a cross-sectional view of the actuator of the butterfly valve of Figure 1,
5 is a partial perspective view of a butterfly valve according to a second embodiment of the present invention,
6 is a plan sectional view of the butterfly valve of FIG.

Hereinafter, a butterfly valve according to a preferred embodiment of the present invention will be described in more detail with reference to the accompanying drawings.

1 to 4 illustrate a butterfly valve according to a first embodiment of the present invention.

The butterfly valve 5 according to the first embodiment of the present invention includes a valve unit 10 equipped with a disk 18 for opening and closing a pipeline through which fluid is moved, and a disk mounted on an upper portion of the valve unit 10. And a rotation control unit 50 for controlling the rotation of 18.

The valve unit 10 is formed with a valve body 11 having a through hole 12 connected to a conduit, and extends in a radial direction of the through hole 12 so as to be rotatably mounted to the valve body 11, and having a valve body ( The rotating shaft 16 penetrating the head portion 14 formed on the upper portion of the 11, and the disk 18 is fixed to the rotating shaft 16 to be located in the through hole 12 of the valve body 11, the rotatable disk 18 to open and close the pipeline And first and second through holes (not shown) mounted in the through-hole 12 of the valve body 11 and penetrating through one side and the other side corresponding to the head portion 14 and passing through the rotating shaft 16. Each of which is provided with a valve seat 20 which is in close contact with the disk 18 on the inner peripheral surface.

The valve body 11 corresponds to a rotating shaft through-hole 17 through which the rotating shaft passes through the upper portion of the head portion 14 so that the rotating shaft 16 across the through hole 12 can be mounted, and the rotating shaft through-hole. Rotating shaft insertion groove (not shown) is formed in which the lower end of the rotating shaft 16 is inserted. The rotating shaft through-hole and the rotating shaft insertion groove have a diameter through which the rotating shaft 16 can be penetrated or inserted to rotate. Although not shown, the valve body 11 is formed with a circular groove (not shown) drawn in the circumferential direction on the inner circumferential surface formed by the through hole. The circular groove is a portion into which the first protrusion (not shown) of the valve seat 20 to be described later is inserted.

In addition, the head portion 14 has a first flange portion 15 having an outer diameter for coupling with the rotation control unit 50 to be described later is formed on the top.

1 and 3, the valve seat 20 has a ring shape mounted to an inner circumferential surface formed by a through hole of the valve body 11. Since the valve seat 20 should be mounted between the valve body 11 and the disk 18 to maintain watertightness or airtightness, synthetic rubber having flexibility and elasticity is used. However, the valve seat 20 is not limited as long as it is a material that can be installed between the valve body 11 and the disk 18 in addition to synthetic rubber to maintain airtightness and watertightness.

Although not shown in detail, the valve seat 20 includes a first through hole through which the upper portion of the rotary shaft 16 passes, a second through hole through which the lower portion of the rotary shaft 16 passes, and a circular groove of the valve body 11. A first protrusion (not shown) and a second protrusion 27 may be provided to insert and fix the valve seat. The first through hole of the valve seat 20 is a portion formed at an upper portion thereof, and when the valve seat 20 is mounted to the valve body 10, the rotation axis through hole 17 and the central axis coincide with each other.

The second through hole of the valve seat 20 is formed in a portion corresponding to the first through hole in the lower portion of the valve seat 20, and the central axis of the rotary shaft mounting groove when the valve seat 20 is mounted to the valve body 10. Is matched with In addition, the diameter of the first through hole and the second through hole is formed to be equal to or smaller than the diameter of the rotation shaft 16, to prevent the fluid from leaking through the contact portion of the rotation shaft 16 and the valve seat 20. do.

When the valve seat 20 is mounted on the inner circumferential surface of the valve body 11, the first protrusion protrudes on the outer circumferential surface of the valve seat 20 corresponding to the circular groove of the valve body 11, and is inserted into the circular groove. . The circular groove and the first protrusion increase the coupling force between the valve body 11 and the valve seat 20, prevent deformation and push of the valve seat 20, and constantly contact the valve seat 20 and the disk 16 constantly. Be sure to

The second protrusion 27 is a portion in which the diameter of the valve seat 20 is narrowed by protruding from the inner circumferential surface of the valve seat 20 along the circumferential direction. The second protrusion 27 is a portion in which the disk 18 is in contact with the valve seat 20 when the through hole 12 of the valve body 11 is closed while the disk 18 is rotated by the rotation of the rotary shaft 16. . The second protrusion 27 has an advantage of increasing the adhesion between the inner circumferential surface of the valve seat 20 and the outer circumferential surface of the disk 18.

The rotating shaft 16 penetrates from one side to the other side constituting the diameter of the disk 18 and is coupled to the disk 18. One side of the rotating shaft 16 coupled to the disk 18 passes through the first through hole of the valve seat 20 and the rotating shaft through hole 17 of the valve body 10, and the other side passes through the second through hole. It is inserted into the rotating shaft insertion groove.

The disk 18 is rotated at the same angle as the rotation shaft 16 rotates, opening and closing the through hole of the valve body (11). When the disk 18 closes the through hole, the outer peripheral surface of the disk 18 comes into contact with the inner peripheral surface of the valve seat 20.

The rotation control unit 50 has a reduction shaft 60 which is connected to the head shaft 14 of the valve body 11 through which the rotating shaft 16 protruding upward with respect to the head portion 14 is connected to the gear body and the valve body 11; Opening and closing the through-hole 12 of the valve body 11 by rotating the drive shaft 78 is coupled to the reducer 60 to be located above the reducer 60 and the drive shaft 78 coupled to the rotary shaft 16 so that the disk 18 is rotated. An actuator 70, a pressure oil supply unit 90 for supplying pressure oil into the actuator 70 to control rotation of the drive shaft, a rotation angle limiting unit 100 for limiting the rotation angle of the drive shaft 78, and a drive shaft The indicator 150 which displays the rotation angle of 78 is provided.

The reducer 60 is connected to the drive shaft 78 of the actuator 70 and converts the direction and speed of the rotational force of the drive shaft 78 and transmits it to the rotating shaft 16 coupled with the disk 18.

Although not shown in detail, the reduction gear 60 of the rotation shaft 16 rotatably mounted to the actuator 70 extends inwardly and protrudes upwardly with respect to the valve body 11. The upper part may be inserted into the driving shaft 78 and the rotation shaft 16.

In the reducer 60, a wheel (not shown) and a wheel (not shown) or a bevel gear (not shown) for converting the direction and the speed of the rotational force of the drive shaft 78 may be installed. It is not limited to.

The rotation control unit 50 includes a second flange portion 66 for coupling with the first flange portion 15 of the head portion 14 at the lower end of the reducer 60.

The second flange portion 66 may be integrally formed at the lower end of the reducer 60, has a separation structure from the reducer 60, and has a ring shape having a rotating shaft through-hole 67 through which the rotating shaft 16 passes. It may be formed as.

As shown in FIGS. 2 and 3, the second flange portion 66 prevents the fluid controlled by the valve unit 10 from flowing into the rotation control unit 50 through the head portion 14. To this end, the fluid discharge portion 68 is formed upwardly with respect to the bottom surface of the first flange portion 15 and discharges the fluid rising outwardly from the rotation shaft 16 to the outside.

The fluid discharge portion 68 is introduced into the lower gear of the second flange portion 66 in the direction of the speed reducer 60, and the fluid discharge groove 69 extends from the rotary shaft through hole 67 to the edge of the second flange portion 66. It is provided. The fluid discharge groove 69 also discharges the fluid raised along the outer circumferential surface of the rotation shaft 16 in the lateral direction.

The second flange portion 66 preferably has a larger diameter than the first flange portion 15 to prevent the fluid from rising to the side.

On the other hand, unlike the illustrated, the fluid discharge portion is not formed in the second flange portion 66, it may be formed in the first flange portion 15. Specifically, the fluid discharge groove of the fluid discharge portion may be introduced into the upper surface of the first flange portion 15 in the direction of the valve body 11, but may extend from one side of the edge of the first flange portion 15 to the rotation axis.

The actuator 70 includes a housing 71, a drive shaft 78, first and second slide pistons 81 and 82, and a plurality of piston pressure springs 89.

The housing 71 has a first pressure oil supply hole 75 and a plurality of second pressure oil supply spaces in which an inner space 72 is formed and penetrates from the outside to the inner space 72, and spaced apart from each other in the longitudinal direction of the housing 71. The ball 76 is formed. The first pressure oil supply holes 75 are located at the center side in the longitudinal direction of the housing 71, and the plurality of second pressure oil supply holes 76 are formed at both side end sides in the longitudinal direction of the housing 71.

The drive shaft 78 is coupled to the rotating shaft 16 of the valve unit 10 through the center of the inner space 72 of the housing 71 to rotate the disk 18 by rotation to open and close the conduit.

The first gear 79 is formed on the outer circumferential surface of the portion located in the internal space of the drive shaft 78. The first gear 79 is engaged with the first and second slide pistons 81 and 82.

The first and second slide pistons 81 and 82 are engaged with the first gear 79 in the inner space of the housing 71 and are disposed to face each other about the drive shaft 78 so as to interlock with the drive shaft 78. It is installed to move linearly.

The plurality of piston pressure springs 89 support the first slide piston 81 and the second slide piston 82 at both sides in the longitudinal direction of the inner space of the housing, and thus, the first slide piston 81 and the second slide piston. The elastic 82 is elastically biased in a direction closer to each other.

In addition, the housing 71 communicates with the first pressure oil supply hole 75 so that the first and second slider pistons 81 and 82 are separated from each other so as to press the oil pressure between the first and second slider pistons 81 and 82. Internal space in the longitudinal direction of the housing 70 in communication with the first pressure oil supply passage 73 to be supplied and the second pressure oil supply hole 76 so that the first and second slide pistons 81 and 82 are close to each other. A second pressure oil supply passage 77 for supplying pressure oil in a direction closer to each other is formed.

The hydraulic oil supply unit 90 is installed outside the housing 71 and controls the rotation of the driving shaft 78 by controlling the direction and flow rate of the oil flowing in and out of the housing 71, and a control valve ( A first pressure oil supply pipe 93 connecting the 91 and the first pressure oil supply hole 75, a second pressure oil supply pipe 95 connecting the control valve 91 and the second pressure oil supply hole 76, and a control; A hydraulic oil storage tank (not shown) connected to the valve 91 and storing the hydraulic oil, and installed between the hydraulic oil storage tank and the control valve 91 to supply the hydraulic oil to the first and second hydraulic oil supply pipes 93 and 95. It is provided with a pressure oil supply pump (not shown) for pumping, and a control unit (not shown) for controlling the driving of the pressure oil supply pump and the control valve.

The rotation angle limiting unit 100 is rotatably mounted integrally with the drive shaft 91 and has a stopper surface 105.106 on one side thereof, a stopper surface 105 and 106 of the rotation stopper 101, It is provided with a plurality of limiting members (111, 113) to contact and limit the rotation angle of the rotary stopper (101).

The rotary stopper 101 is formed in a disk shape having an outer diameter larger than the first gear 79 at a position different from the position at which the first gear 79 is formed on the drive shaft 78 in the inner space 72 of the housing 71. And a drive shaft coupling portion 102 having a coupling hole 103 fitted to the outer circumferential surface of the drive shaft 78 at the rotation center, and a drive shaft coupling radially away from the drive shaft 78 at one side of the outer circumferential surface of the drive shaft coupling portion 102. It is provided with a drive shaft rotation angle limiting part 104 protruding relative to the part 102 and extending in the circumferential direction and having stopper surfaces 105 and 106 formed at both ends thereof.

The plurality of limiting members 111 and 113 are formed in a bolt shape and screwed into the housing 71 to enter the inner space 72 of the housing 71. The plurality of limiting members 111 and 113 contact the stopper surfaces 105 and 106 of the rotary stopper 101 to limit the rotation angle in the inner space 72 of the housing 71.

The plurality of limiting members 111 and 113 are divided into a clockwise rotation limiting member 111 and a counterclockwise rotation limiting member 113 for limiting rotation angles in both directions of the rotary stopper 101.

The clockwise rotation restricting member 111 and the counterclockwise rotation restricting member 113 are each screwed to one side of the housing 70 with a predetermined distance therebetween so that one of the two stopper surfaces 105.106 of the rotary stopper 101 is rotated. Are in contact with each other.

As shown in FIG. 6, the clockwise rotation limiting member 111 contacts one stopper surface 105 to rotate clockwise rotation of the rotary stopper 101 when the rotary stopper 101 rotates clockwise. On the contrary, the counterclockwise rotation limiting member 113 contacts the other stopper surface 106 and rotates the counterclockwise rotation of the rotary stopper 101 when the rotary stopper 101 rotates counterclockwise. Will stop.

That is, when the clockwise rotation limiting member 111 and the counterclockwise rotational limiting member 113 are screwed or loosened, the distance to the stopper surface 12 of the rotary stopper 101 can be adjusted, thereby The allowable angle at which the rotary stopper 101 rotates can be adjusted. When the restricting members 111 and 113 are tightened to narrow the distance from the stopper surfaces 105 and 106, the rotation angle of the rotary stopper 101 decreases. On the contrary, the limiting members 111 and 113 are released to stop the stopper surfaces 105 and 106. If the distance to the far away) will be to increase the rotation angle of the rotary stopper 101.

Each of the clockwise rotation limiting member 111 and the counterclockwise rotational limiting member 113 is provided with first and second interference fit impact reducing parts 114 and 115 at each end contacting the stopper surfaces 105 and 106, respectively.

The first and second interference fit shock reduction parts (114, 115) is formed on the side of the buffer material such as rubber is pressed to the stopper surface contacted during the rotation of the disk 18 so that the pipeline is closed and protrudes toward the disk 18 side When the disk 18 is pressed against the protrusion 27 of the valve seat 20, the repulsive force with respect to the rotational force of the disk 18 is reduced.

The indicator 150 is coupled to the drive shaft 78 to represent the rotation angle of the drive shaft 78. Although not shown in detail, the indicator 150 is rotated in accordance with the rotation of the drive shaft 78 and is mounted therein with a rotating needle (not shown) to display the rotation angle, and the rotation angle of the rotation needle can be recognized from the outside. So that the upper part is made of transparent material.

The operation of the butterfly valve according to the first embodiment of the present invention having the structure as described above will be described.

The opening and closing of the control valve 91 is controlled by the controller to open or close the first pressure oil supply pipe 93 or the second pressure oil supply pipe 95 so that the pressure oil flows into or out of the inner space 72 of the housing 71.

When pressure oil is supplied to the inner space 72 of the housing 71 between the first and second slide pistons 81 and 82 through the first pressure oil supply hole 75 of the housing 71, The first and second slide pistons 81 and 82 are moved away from each other, in this process, the drive shaft 86 is rotated counterclockwise, and the rotation shaft 16 and the disc 18 rotate in the drive shaft rotation direction. While the through hole 12 of the valve body 11 is opened.

At this time, the rotation stopper 101 is a clockwise rotation restriction bolt 111 or counterclockwise rotation restriction bolt 111 and the counterclockwise rotation restriction bolt 113 in accordance with the length entered into the inner space of the housing. The rotation angle is determined while the contact position with the restriction bolt 113 is changed.

In this state, the hydraulic oil is supplied to the inner space 72 of the housing 71 between the first and second slide pistons 81 and 82 and the piston pressure spring 89 through the second pressure oil supply hole 76. When the first and second slide pistons 81 and 82 are moved closer to each other by the supplied hydraulic oil, the driving shaft 86 is rotated clockwise in this process, and the rotating shaft connected to the driving shaft 86 16 and the disk 18 is rotated to close the tube hole 12 of the valve body (11).

 As described above, the butterfly valve 5 according to the first embodiment of the present invention has an outer circumferential surface of the rotation shaft 16 when the disk 18 and the rotation shaft 16 rotate along the drive shaft 78 along the supply direction of the hydraulic oil. Since the fluid to be lifted up is discharged induced in the lateral direction by the fluid discharge unit 69, the fluid can be prevented from flowing into the rotation control unit 50 and the reducer 60.

In addition, in the butterfly valve 5 according to the first embodiment of the present invention, the rotation range of the rotary stopper 101 is adjusted according to the position where the plurality of limiting members 111 and 113 enter the housing 71. It provides the advantage of freely adjusting the upper and lower limits for the opening angle of

Meanwhile, FIG. 5 shows a butterfly valve 6 according to a second embodiment of the present invention. Components having the same functions as in the above-described drawings are denoted by the same reference numerals.

The butterfly valve 6 according to the second embodiment of the present invention has the same structure as the butterfly valve 5 according to the first embodiment of the present invention except for the fluid discharge portion, and further includes a fluid transfer member 180. Equipped.

The fluid discharge part 168 according to the second embodiment of the present invention is formed to be drawn downward with respect to the upper surface of the first flange portion 15 so that fluid ascending through the head portion 14 flows in the rotary shaft 16. A fluid discharge groove 169 extending toward the edge of the first flange portion 15 from one side of the circular fluid rise prevention groove 170 and the fluid rise prevention groove 170 to extend along the circumference to prevent the rise of the fluid It is provided.

The fluid transfer member 180 is located in the fluid elevation preventing groove 170 and rotates together with the rotating shaft to induce the fluid introduced into the fluid elevation preventing groove 170 to the fluid discharge groove 169.

The fluid transfer member 180 has an inner diameter corresponding to the rotation shaft 16 and has an outer diameter smaller than the fluid lift prevention groove 170 so as to rotate in the fluid lift prevention groove 170 together with the rotation shaft in a ring-shaped fluid lift suppressing portion. 181 and the transfer guide rib portion 183 extending radially in contact with the inner circumferential surface of the fluid elevation preventing groove 170 at one side of the fluid elevation suppression ring 181 and rotated together with the fluid elevation suppression ring 181. Equipped. The transfer guide rib unit 183 rotates in the circumferential direction and pushes the fluid so that the fluid introduced into the fluid rise preventing groove 170 is quickly discharged into the fluid discharge groove 169.

In the butterfly valve 6 according to the second embodiment of the present invention, since the fluid raised to the head 14 is quickly discharged to the outside, the fluid is raised to the reducer 60 or the rotation control unit 50. There is a fundamentally preventable advantage

The butterfly valve according to the present invention has been described with reference to an example shown in the drawings, but this is merely illustrative, and those skilled in the art may make various modifications and other equivalent embodiments therefrom. Will understand. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

5, 6: butterfly valve 10: valve unit
11 valve body 14 head
15: first flange portion 16: rotation axis
18: disc 20: valve seat
50: rotation control unit 60: reducer
70: actuator 71: housing
78: drive shaft 81: first slide piston
82: second slide piston 89: piston pressure spring
66: second flange portion 67: through the rotating shaft
68,168 fluid discharge part 69 fluid discharge groove
90: hydraulic oil supply unit 91: control valve
93: first pressure oil supply pipe 95: second pressure oil supply pipe
100: rotation angle limiting unit 101: stopper
111: clockwise rotation limiting member 113: counterclockwise rotation limiting member
114: first interference fit shock reduction unit 115: second interference fit shock reduction unit
170: fluid rise prevention groove 180: fluid transfer member
181: fluid rise suppression ring 183: transfer guide rib portion

Claims (4)

A valve body having a through hole connected to a conduit for fluid transfer, a rotation shaft extending in the radial direction of the through hole and rotatably mounted to the valve body, and passing through a through hole of a head portion formed in the valve body; A disk fixed to the rotary shaft to be positioned in the through hole of the valve body, the disk being rotatable to open and close the through hole, and mounted to the through hole of the valve body and penetrating through one side and the other side corresponding to the head part, and the rotating shaft A valve unit having first and second through holes formed therein, the valve unit having a valve seat in close contact with an inner peripheral surface thereof;
And a rotation control unit supporting a driving shaft coupled to the rotation shaft of the valve unit and having a second flange portion coupled to the first flange portion provided on the head portion.
On the upper surface of the first flange portion
In order to prevent the fluid controlled by the valve unit from flowing into the rotation control unit through the head portion, the fluid is introduced into the upper surface of the first flange and extends outward from the rotation shaft to discharge the fluid to the outside. The fluid discharge part is formed,
The fluid discharge portion
A circular fluid rise preventing groove formed in the upper surface of the first flange portion so as to flow through the head portion and extending along a circumference of the rotation shaft to prevent the fluid from rising; and the fluid rise prevention It has a fluid discharge groove extending from one side of the groove to the edge side of the first flange,
And a fluid transfer member positioned in the fluid rise prevention groove and rotating with the rotation shaft to induce discharge of the fluid introduced into the fluid rise prevention groove into the fluid discharge groove.
The fluid transfer member
A ring-shaped fluid lift suppressing portion having an inner diameter corresponding to the rotation shaft and having an outer diameter smaller than the fluid lift prevention groove and rotated together with the rotation shaft in the fluid lift prevention groove;
One side of the fluid lift ring is extended in the radial direction in contact with the inner circumferential surface of the fluid lift prevention groove rotates with the fluid lift ring to rotate the fluid introduced into the fluid lift prevention groove into the fluid discharge groove Butterfly valve characterized in that it comprises a transfer guide rib portion for pushing the feed. delete delete According to claim 1, wherein the rotation control unit
An actuator for opening and closing the through hole of the valve body by rotating the drive shaft coupled with the rotation shaft such that the disk is rotated;
A rotary stopper mounted on the actuator so as to be axially rotatable with the driving shaft and having a stopper surface on one side thereof;
A rotation angle limiting unit contacting the stopper surface of the rotation stopper to limit the rotation angle of the rotation stopper;
The rotation angle limiting unit
It is provided with a plurality of limiting members for penetrating through the actuator to enter the inner space of the actuator, respectively limiting the rotation angle in both directions of the rotary stopper according to the length entered into the inner space,
The plurality of limiting members
The disk is formed of a cushioning material on the end side in contact with the stopper surface and the disk is in contact with the protrusion of the valve seat protruding toward the disk when the disk is rotated to close the through hole of the valve body when the disk is pressed Butterfly valve, characterized in that each having an interference fit shock reduction portion that is contracted to reduce the repulsive force against the rotational force of.

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