KR101605965B1 - Internally Cushioning Type Check Valve - Google Patents

Abstract

The present invention relates to an internal buffering check valve, which comprises: a body part (3) installed on a duct (10), in which a fluid flows, and forming the outer appearance; a disk part (5) installed in the body part (3) to be pivoted, and controlling the flow of the fluid passing through the body part (3); and a buffer part (7) installed in the body part (3) to be pressurized by a pressurizing protrusion (21), protruding from a side of the disk part (5), in a valve closing position in order to relieve an impact by the disk part (5) on the body part (3) when a valve is closed. Therefore, a buffer part with a buffer structure such as a damper is installed in the valve body part while the fluid on the duct is used as a working fluid for buffering, and therefore, when the valve is closed, an impact by the disk part to the valve is effectively relieved by the buffer part with a simple structure without a leakage of the working fluid.

Description

[0001] The present invention relates to an internal cushioning type check valve,

More particularly, the present invention relates to an internal buffer check valve, and more particularly, to an internal buffer check valve provided with a valve body such as a valve body, The present invention relates to an internal buffer check valve capable of mitigating an impact applied to a system.

In general, the check valve refers to all the valves that block the reverse flow, and the phenomenon that the pressure of the outflow fluid flowing backward due to the starting and stopping of the pump or blocking of the valve is increased or decreased, Phenomenon. In general, a problem in such a water shock phenomenon is that the pump suddenly stops due to interruption of the pump power source due to power failure or the like.

The magnitude of the pressure rise and pressure drop caused by the water impact varies depending on the temporal change of the flow rate in the pipe, the state of the pipe length and the pipe gradient, the type of the pump motor, etc. However, when the pump suddenly stops, a pressure drop occurs first, A reverse flow from the discharge side to the suction side of the fluid is started and the pressure rises.

Therefore, in order to reduce the pressure rise, it is necessary to use a check valve for appropriately controlling the amount of backflow, and at the beginning, the disk portion that opens and closes the pipeline quickly closes, that is, abruptly closes, and then slowly closes Closing operation is often performed in two steps. In this case, a method has been widely used in which a hydraulic cylinder is provided at the end of the valve shaft to control the discharge amount of the working fluid in the hydraulic cylinder to control the closing of the check valve to reduce the pressure rise.

However, such a check valve is only involved in opening and closing the disc portion by adjusting the discharge amount of the working fluid, and the closing speed control of the disc portion is not smoothly performed, so that the impact applied to the valve or the water supply system can not be reduced.

Accordingly, the inventors of the present invention have proposed a shock absorbing cylinder for a check valve as shown in Figs. 1 and 2 (Patent No. 10-0992083), and a check valve 100 A shock absorber cylinder (not shown) in which a piston rod 105 and an inner piston interlock with the opening and closing of the disk portion 101 is connected to a rotary shaft 102 connected to open and close the disk portion 101 of the check valve 100 103 is provided in the shock absorbing cylinder 103 and a working fluid capable of controlling the closing speed of the disk portion 101 when the piston rod 105 and the piston descend in accordance with the closing of the disk portion 101 The control means is provided so that the closing of the disk portion 101 due to the reverse flow of the fluid in the check valve 100 is performed in two steps of leading to a gradual closing after the initial closing, The system can be protected from water impact by backflow of fluid. .

The check valve 100 having such a shock absorbing cylinder is provided with a shock absorbing cylinder 103, a piston rod 105, a cylinder lever (not shown) provided additionally to mitigate the impact imposed by the disk portion 101 102a, etc., complicate the structure of the entire valve 100, increasing the manufacturing cost and making maintenance difficult.

The check valve 100 is provided with a seal packing 107 for mounting the rotation shaft 102 in order to ensure water tightness of the rotation shaft 102. To increase the sealing performance of the seal packing 107, The rotation of the rotating shaft 102 is not smooth due to the increase in frictional resistance with the packing 107 and conversely the pressing force against the sealing packing 107 is lowered so that the sealing performance is lowered and the fluid in the valve 100 is leaked There is a problem that an operation failure or a failure occurs with respect to the rotation shaft 102 and the like.

In addition, during long-term use, the process of holding the high pressure applied to the disc portion 101 by the impact-absorbing cylinder 103 is repeated, causing the rotation shaft 102 to be deflected, resulting in malfunction of the disc portion 101 , The watertight performance of the seal packing 107 is undesirably degraded to cause not only failure but also shortening the service life in the long term.

KR 10-0992083

The present invention has been proposed in order to solve the problems of the conventional buffer check valve. When the disc is closed due to reverse flow in the valve-opened state, the buffer It is an object of the present invention to mitigate water impact applied to the entire water supply system as well as the valve including the body part by the disk part by attenuating the rotation of the part smoothly.

According to an aspect of the present invention, there is provided a fluidized-bed reactor comprising: a body portion formed on a conduit through which fluid flows; A disc portion pivotally mounted in the body portion and interrupting a flow of fluid passing through the body portion; And a cushioning portion provided in the body portion so as to be pressed by a pressing protrusion protruding from one side of the disk portion at a valve closing position to alleviate an impact applied to the body portion by the disk portion when the valve is closed An internal buffering valve is provided.

It is preferable that the buffer portion has a structure of a single acting hydraulic damper that uses the fluid as a working fluid.

The cushioning unit may include a hollow buffer cylinder having an upstream end opened through a water inlet to allow the fluid to flow in a forward flow direction and a downstream end opened through an opening so that the pressure projection is inserted when the fluid flows in a reverse direction; A piston reciprocably mounted in the buffer cylinder to form a pressure chamber between the upstream end of the buffer cylinder and the upstream end; And an orifice portion passing through the cylinder and connecting the inside of the pressure chamber to the outside so that the fluid to be compressed in the pressure chamber can be released when the piston is pressed by the pressure projection when the valve is closed .

The cushioning portion may further include a piston rod having one side inserted through the upstream end of the buffer cylinder in a watertight slidable manner, and the other side coaxially coupled to the piston.

Preferably, the buffer cylinder further includes a one-way valve installed in the water supply port to allow fluid to flow into the pressure chamber, but not allow fluid to flow out of the pressure chamber.

Preferably, the orifice portion further includes a needle valve for regulating the amount of fluid discharged from the pressure chamber.

According to the internal buffering check valve of the present invention, the impact applied from the disk portion at the valve closing end is mitigated by the buffer portion mounted inside the valve body portion, so that it is possible to avoid the complication of the structure due to the buffer structure, The overall equipment can be miniaturized, further reducing the cost of production and maintenance, and maximizing efficiency.

Further, since the cushioning portion of the cushioning structure such as the damper is located in the valve body portion and utilizes the fluid on the conduit as the working fluid for cushioning, the leaked fluid stays in the body portion even if the fluid in the cushioning portion leaks due to the cushioning operation, It is not necessary to worry about leakage of the fluid from the valve at all, and therefore it is possible to significantly reduce the leakage of the valve due to the buffering operation and thereby the performance degradation or failure of the valve, and further, .

 Furthermore, since the pressure of the cylinder pressure chamber can be easily changed at any time through the operation of the needle valves, the damping force against the disk portion can be adjusted, thereby improving the operating performance of the valve.

1 is a longitudinal side view showing a conventional check valve provided with a shock absorbing cylinder;
Figure 2 is a transverse front view of Figure 1;
3 is a longitudinal side view of a check valve according to an embodiment of the present invention;
Fig. 4 is an enlarged longitudinal side view of the cushioning portion of Fig. 3, showing a valve opening state in forward flow. Fig.
FIG. 5 is an enlarged longitudinal side view of the cushioning portion of FIG. 3, showing the valve closed state in the reverse flow; FIG.
6 is a longitudinal side view showing another embodiment of the present invention applied to a butterfly-type check valve;
7 is a longitudinal side view showing an example in which the cushioning portion of the present invention is applied to a flap valve provided at the end of a pipeline.

Hereinafter, an internal buffer check valve according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

The check valve of the present invention comprises a body portion 3, a disk portion 5, and a buffer portion 7, as indicated by reference numeral 1 in Fig.

3, the body part 3 is a part constituting the outer body of the check valve 1. The body part 3 is provided between the pipe 10 through which the fluid flows and the pipe 10, . The body portion 3 has a fluid flow hole 11 having an inner diameter equal to that of the conduit 10 on the inner circumferential surface and flanges 13 for coupling with the conduit 10 project radially at both ends of the outer circumferential surface. An annular body sheet 15 is mounted on the inner end of the fluid flow hole 11 along the inner circumferential surface.

The disk portion 5 is a portion for substantially interrupting the flow of the fluid passing through the body portion 3 as described above. As shown in FIG. 3, the fluid flow hole 11 is connected to the valve shaft 17 and a disc lever 19 connected to the valve shaft 17 so as to be pivotally mounted in the body part 3. [ At this time, depending on the type of the valve 1, for example, the valve shaft 17 is arranged to cross the fluid flow hole 11 at a position eccentric from the center when the valve is a butterfly check valve, . Particularly, in the disc portion 5 according to the present invention, the pressing projection 21 for operating the buffer portion 7 protrudes from the lower end of the lower surface of the upstream side facing the body sheet 15. 7, the disc portion 5 is installed at the end of the pipeline 10 by a valve shaft 17 to open and close the discharge port of the pipeline 10.

The buffer part 7 is a means for protecting the body part 3 and the like by mitigating an impact applied by the disk part 5 when the valve 1 is closed. As shown in FIG. 3, Is mounted on the inner circumferential surface of the fluid flow hole (11) in the body (3) so as to be adjacent to the body sheet (15) at a position that can be pressed by the pressure projection (21) The buffering portion 7 also serves to relieve the impact applied by the disk portion 5 when the valve is closed, even in the case of the butterfly-type check valve shown in Fig. 6 or the flap valve shown in Fig.

At this time, the buffer part 7 uses the fluid flow in the body part 3, that is, the fluid in the body part 3 is used as the working fluid, It is preferable to have a structure of a single acting type hydraulic damper using a fluid in the body portion 3, for example, as long as any kind of attenuation structure can be employed as long as it can alleviate the impact of the fluid.

4 and 5, the buffer part 7 mainly comprises a buffer cylinder 23, a piston 25, and an orifice part 27, and the piston rod 29, As shown in FIG.

The buffer cylinder 23 is a hollow body constituting the outer body of the buffer part 7. The buffer cylinder 27 is mounted through the body part 3 from the outside of the valve 1 as shown in FIG. So that the pressure inside the pressure chamber 31 can be adjusted by the user. Particularly, the damping cylinder 23 forms a pressure chamber 31 between the piston 25 and the piston 25. The upstream end, that is, the left end in the drawing is opened through the water supply port 33, The fluid flowing in the forward direction is introduced into the pressure chamber 31 through the water supply port 33 as shown by an arrow F in FIG.

At this time, the buffer cylinder 23 is connected to the one-way valve 35 mounted on the water supply port 33 to prevent the fluid in the pressure chamber 31 from flowing out of the pressure chamber 31 through the water supply port 33, As shown in FIG. Therefore, the one-way valve 35 allows the fluid to flow into the pressure chamber 31 from the body portion 3, but it is not allowed that the fluid in the pressure chamber 31 flows into the body portion 3. To this end, the one-way valve 35 is composed of a steel ball 51, a rebound spring 53, and a spring seat 55 as shown in Figs. 4 and 5, and is a well-known configuration, and thus its detailed description is omitted. Conversely, the damping cylinder 23 has a downstream end so that the pressure projection 21 is inserted to press the piston 25 or the piston rod 29 when the fluid flows in the opposite direction as shown by the arrow R in FIG. 5 That is, the right end in the drawing is opened to the inside of the body part 3 through the opening 37. A stopper 39 is formed around the right end opening 37 of the buffer cylinder 23 to prevent the piston 25 from falling off.

4 and 5, the piston 25 is a member which is mounted inside the shock absorber cylinder 23 so as to form a pressure chamber 31 inside the shock absorber cylinder 23, (23), and one or more sealing rings (42) are wound around the outer circumferential surface so as to be slidable in a watertight state.

4 and 5, the orifice portion 27 is a passage through which the fluid to be compressed in the pressure chamber 31 is discharged into the body portion 3 when the valve is closed. The cylinder 23 And a discharge passage 41 connecting the pressure chamber 31 and the inner space of the body portion 3 through the discharge passage 41. The knee valve 41 is provided on the discharge passage 41 to open and close the discharge passage 41, (43). Accordingly, the orifice portion 27 compresses the fluid in the pressure chamber 31 by the piston 25 pressed by the pressure projection 21 at the time of closing the valve, and accordingly, the fluid inside the pressure chamber 31, And is discharged into the body part 3 through the flow path 41.

In the absence of the needle valve 43, the discharge flow path 41 varies the diameter to determine the amount of fluid discharged from the pressure chamber 31, and the internal pressure of the pressure chamber 31, that is, Can be set as desired. However, once the diameter of the discharge passage 41 is determined in this case, the repulsive force of the piston 25 is also determined, so that the repulsive force of the piston 25, that is, the damping ability of the cushioning portion 7, can not be changed. However, as shown in Figs. 4 and 5, when the needle valve 43 is provided, the diameter of the discharge passage 41 is simply controlled by manipulating the needle valve 43 outside the valve 1, The internal pressure of the pressure chamber 31, that is, the repulsive force of the piston 25 can be changed.

4 and 5, the upstream side of the piston rod 29 is connected to the through-hole 45 of the damping cylinder 23, and the piston rod 29 is coupled to the piston 25 through a coaxial penetration. And one or more sealing rings 46 for keeping the watertight state along the inner circumferential surface of the through hole 45 are wound. The downstream side of the piston rod 29 is coaxially fitted to the center of the piston 25 and is integrally coupled to the piston 25 by a fixing nut 48 fastened to the downstream side end.

As another embodiment of the present invention, although the buffering portion 7 is not shown, the inside of the buffering cylinder 23 may be constituted by only the piston 25 by omitting the piston rod 29. [

Now, the operation of the internal buffering check valve 1 according to the preferred embodiment of the present invention will be described as follows.

When the flow on the pipeline 10 is to be interrupted by the check valve 1 of the present invention and the flow on the pipeline 10 is in the forward direction F first, But pivotally rotates about the valve axis 17 toward the downstream side of the flow, that is, to the right in the drawing.

Therefore, the fluid passes through the valve 1 and moves to the downstream side without clogging. At this time, since forward flow is also applied to the buffer 7 as shown in FIG. 4, flow pressure is applied to the water supply port 33 of the buffer cylinder 23. Accordingly, when the one-way valve 35 is opened, the fluid flows into the pressure chamber 31 and is filled therein. Even if the pressure inside the pressure chamber 31 is released through the orifice portion 27, And pushes the piston 25 to the downstream side, that is, to the right side in the drawing. Therefore, in the valve-opened state in which the fluid in the valve chamber 31 is filled with a larger amount of fluid and the flow pressure is equal to or higher than a certain level, the piston 25 is moved to the right- .

5, the disk portion 5 rotates about the valve axis 17 in the state shown in Fig. 4 (see Fig. 5) That is, the valve 1 is pivoted to the left side to close the valve 1 as shown in FIG.

5, the pressing protrusion 21 at the distal end of the disc portion 5 is pressed against the piston rod 29 of the cushioning portion 7 before the disc portion 5 completely closes the valve 1 as described above, Or when the piston rod 29 is not present, the piston 25 is directly pressed. The fluid in the pressure chamber 31 is compressed by the piston 25 so that the orifice portion 27 is closed by the piston 25. As a result, The pressure applied to the piston 25 from the pressing protrusion 21, that is, the piston portion 5, is attenuated to be relaxed. At this time, when the needle valve 43 is attached to the orifice portion 27, the discharge amount of the internal fluid is determined according to the opening degree of the needle valve 43, so that the cushioning strength of the buffer portion 7 Can be adjusted. Even when there is no needle valve 43, the flow resistance can be generated due to the difference in diameters of the discharge passage 41 and the pressure chamber 31, and the shock transmitted to the piston 25 can be attenuated and mitigated, It is not possible to adjust the cushioning strength because the diameter of the cylinder 41 can not be changed.

When the disk unit 5 closed at a gentle speed by the cushioning operation of the piston 25 is brought into close contact with the body sheet 15, the valve 1 is closed. At this time, the piston 25 maintains its current position .

In this way, when a series of valve closing operations by the back flow is completed, and then the flow of the fluid changes in the forward direction, the valve 1 interrupts the fluid flow by repeating the series of valve opening and closing operations described above.

1: Check valve 3: Body part
5: disk portion 7: buffer portion
10: conduit 11: fluid distribution hole
15: Body seat 17: Valve shaft
21: pressing projection 23: cylinder
25: piston 27: orifice part
29: Piston rod 31: Pressure chamber
33: water supply port 35: one-way valve
37: aperture 39: stopper
41: Discharge channel 43: Needle valves
45: Through hole

Claims (6)

A body part (3) provided on the channel (10) through which the fluid flows and constituting an outer body;
A disc portion 5 pivotally mounted in the body portion 3 for interrupting the flow of fluid passing through the body portion 3; And
(3) by a pressing protrusion (21) protruding to one side of the disc portion (5) at a valve closing position, and is provided in the body portion (3) by the disc portion (5) And a shock absorber (7) for relieving the shock applied to the motor
The buffer part (7)
The upstream end is opened through the water supply port 33 so that the fluid flows in the forward direction and the downstream end is opened through the opening 37 so that the pressure projection 21 is inserted when the fluid flows in the reverse direction. A buffer cylinder 23;
A piston (25) reciprocably mounted in the buffer cylinder (23) and forming a pressure chamber (31) between the upstream end of the buffer cylinder (23); And
(23) so that the fluid to be compressed in the pressure chamber (31) can be released when the piston (25) is pressed by the pressure projection (21) when the valve is closed, And an orifice portion (27) for connecting the inside of the valve body (31) to the outside. The method according to claim 1,
Wherein the buffer part (7) has a structure of a single acting hydraulic damper that uses the fluid as a working fluid. delete The method according to claim 1,
The cushioning portion 7 has a piston rod 29 having one side inserted through the upstream side end of the buffer cylinder 23 in a watertight slidable manner and the other side coaxially coupled to the piston 25 Further comprising an internal buffering check valve. The method according to claim 1 or 4,
The buffer cylinder 23 further includes a one-way valve 35 mounted on the water supply port 33 to allow fluid to flow into the pressure chamber 31 but not allow fluid to flow out of the pressure chamber 31 And an internal buffering check valve. The method of claim 5,
Wherein the orifice portion (27) further comprises a needle valve (43) for regulating the amount of fluid discharged from the pressure chamber (31).

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