KR101299987B1 - Disk of nonreturn valve - Google Patents

Abstract

According to the present invention, the circumferential surfaces of the disks have the same circumferential surface to make the disks easy to process, and also smoothly and slowly open when the closed disks are opened, so that the impact sound or the pressure change due to the disks are smoothed. The present invention relates to a check valve disc which can lower the driving load of the transfer pump and prevent the shortening of the service life of the pipe. The present invention provides a disc for the check valve according to the present invention. Therefore, it is possible to solve the problem that the sealing member is separated from the annular coupling groove, and also because the outlet side circumferential surface is secondarily pressed onto the surface of the pipe line, it can perform the double sealing effect and prevent the disk from being pushed. Manufacture of the disc by making the entire circumferential surface of the disc at the same angle It is much easier and the manufacturing cost can be greatly reduced.

Description

Check valve disc {DISK OF NONRETURN VALVE}

The present invention is a nonreturn valve that shuts off the pipeline so that the fluid being conveyed along the pipe does not flow back along the pipe when the fluid pump transfer pump is suddenly stopped due to power failure or other unforeseen circumstances. In more detail, the circumferential surface of the disk installed in the check valve is inclined at the same angle to facilitate the processability in the manufacture of the disk, and to make the disc open slowly and smoothly when the closed disk is opened, thereby making the impact sound of the disk open. However, the present invention relates to a check valve disc which can reduce the driving load of a transfer pump due to a rapid pressure change of a fluid and prevent the life of a pipe from being shortened.

In general, when the fluid is transferred to a specific region in a pump station provided in a hydro power plant, a dam or a reservoir or a water purification plant, the fluid pumped in a large amount by the transfer pump is transferred along the transfer pipe.

The pumping station is basically equipped with a pump, a transfer pipe, a surge tank check valve, a flow control valve, a shutoff valve for maintenance of the pipeline, and a safety valve for safe fluid pumping, but the transfer pump suddenly fails due to a power failure or other unexpected situation. When stopped, water hammer is generated in the pipe due to the pressure of the fluid flowing back against the disk, which causes a fatal impact on the pump and the pipe or other facilities.

In order to prevent such a problem, a check valve is installed in the pipeline of the transfer pipe to prevent the backflow of the fluid and to buffer the water pressure and the water shock to protect the pipe and various pumping facilities.

As an example of the check valve, reference can be made to Korean Laid-Open Patent Publication No. 2000-0030247 (pump control high pressure butterfly valve) and Korean Utility Model No. 20-0206590 (pump control valve) created by the present inventor.

Functional features according to the conventional check valve as described above will be briefly described with reference to FIGS. 1 and 2.

Figure 1 is a cross-sectional view of the main portion of the check valve disk from the front, Figure 2 is a cross-sectional view of the main part conceptually illustrating the opening and closing operation of the check valve disk in order to improve the clarity and understanding of the function of the check valve.

As shown in FIG. 2, the check valve 10 includes a flange 11 connected to a transfer pipe (not shown), and a disk 20 for opening and closing the conduit 12 is provided therein. The shaft 30 is installed across the conduit 12 so that the disk can rotate together with the shaft 30 for the opening and closing operation of the disk 20.

The fluid 20 flows in the direction of the arrow in FIG. 2, and the disk 20 opens and closes the conduit 12 of the check valve by rotating the shaft together with the shaft.

However, as described above, when the driving of the high power transfer pump is stopped, the fluid passing through the disk 20 flows back to the disk 20 due to the inherent weight load and the volume expansion phenomenon, wherein the hydraulic pressure is the disk 20. While acting on the rear surface of the disk 20 to close the pipe 12 rapidly to prevent the back flow of the fluid to securely protect the transfer pipe, high power transfer pump or various auxiliary equipment.

At this time, the damping device (see the prior art reference cited above) connected to the shaft 30 on the outside of the check valve casing 10a in order to prevent the closing of the disk 20 closed by the pressure of the fluid is the disk 20 It is designed to buffer the water hammer by slowly closing the disk while resisting the water hammer applied to it.

However, the conventional check valve disc 20 as described above is installed in an oblique direction with respect to the axis of the conduit 12 so that the ground angle of the circumferential surface of the disc in contact with the inner wall of the conduit 12 is not the same. 20) The manufacturing process of the circumferential surface of the disk 20 is very difficult and difficult in manufacturing.

That is, the check valve disk 20 as shown in Figure 3a is a triple eccentric form of the "C1" and "C2" angle of the circumferential surface, so the angle at the same time while rotating the disk when processing the circumferential surface of the disk 20 Machining is very demanding and difficult and requires a lot of work time.

In addition, although the sealing member 22 is attached to the circumferential surface of the disk 20 to seal the conduit 12 when the disk is closed, the disk 20 is caused by the pressure of the fluid acting on the back of the disk 20. In the case of fast closing or excessive pressure, the disk 20 may be pushed forward (fluid entry direction).

As shown in FIG. 3B, when the disk 20 is pushed forward by the pressure, the sealing member 22 is excessively compressed so that the disk 20 is caught in the conduit sheet 13 or the sealing member 22 is the disk ( Separation or detachment from the annular coupling groove 21 of 20) causes a problem that the sealing function is impaired. The annular coupling groove 21 is a groove to which the aforementioned sealing member is coupled to the circumferential surface of the disk, and the sealing member is made of a high elastic rubber material and coupled to the coupling groove.

In addition to the problem that the sealing member 22 is separated, the problem of the sliding of the disk 20 as described above, when the fluid is introduced into the front of the disk 20 by the transfer pump, the disk 20 is caught in the conduit 12 disk 20 does not open slowly and smoothly and does not open until the pressure rises excessively, but the disc 20 opens at a moment and generates a shock sound according to the opening, and the pressure of the fluid behind the disk rises rapidly. This rupture also adversely affects the service life of the transfer pump and piping. As a result, there is a problem that greatly reduces the reliability of the check valve.

The present invention has been made in order to solve the problems associated with the disc of the conventional check valve as described above, the object of the present invention is to increase the machinability of the disc by the circumferential surface of the disc in contact with the pipe seat of the conduit at the same inclination angle The present invention also provides a check valve disc that can smoothly and slowly open when a closed disc is opened, thereby lowering the load of impact sound or transfer pump and preventing shortening of pipe life.

Check valve disc implementation means of the present invention for achieving the object of the present invention,

In the disk of the check valve provided with a sealing member inserted into the annular engaging groove provided on the circumferential surface, opening and closing the pipeline of the fluid transfer pipe while rotating with the shaft,

The outer diameter of the circumferential surface of the outlet side of the disk and the outer diameter of the sealing member inserted into the annular coupling groove center on the annular coupling groove into which the sealing member is inserted into the circumferential surface of the disk. An outer diameter of the inlet side circumferential surface is formed to be relatively smaller than the outlet side outer diameter so as to have a stepped portion on the circumferential surface of the disc, the disc being inclined at the same angle;

It can be achieved by the configuration of the check valve casing is provided on the inner wall of the passageway adjacent to the sealing member and the pipe liner sheet in contact with the sealing member and the circumferential surface of the outlet side of the disk in the adjacent pipeline.

According to the present invention, by configuring the circumferential surface of the disk to the same inclination angle, it is possible to greatly improve the machinability of the disk, the disk can be manufactured very easily and inexpensively, and the circumferential surface of the disk is stepped. Since the circumferential surface of the exit side supports the sealing member when the disc is closed, the sealing member can effectively expect a sealing effect without being separated from the annular coupling groove, and the disc is closed when the disc is closed because there is no fear of pinching the pipe line. When the disc is opened, there is an effect of smooth opening and smooth opening in response to pressure.

Therefore, the present invention solves the problem of sudden opening of the disk, the impact noise caused by the opening of the disk does not occur, the pressure change of the fluid is smooth and the drive load of the high-power transfer pump can be lowered as well as the life of the pipe is shortened. Can be prevented to increase the reliability of the check valve.

1 is a cross-sectional view of the main portion of the check valve disc from the front,
Figure 2 is a sectional view of the main part conceptually illustrating the operating state of the check valve;
Fig. 3A is a sectional view of the main portion illustrating the angle of the circumferential surface of a conventional disk;
3B is an enlarged cross-sectional view of portion A shown in FIG. 3A;
Figure 4a is a cross-sectional view of the main portion illustrating the circumferential angle of the disk according to the present invention,
4B is an enlarged cross-sectional view of a disk circumferential surface according to the present invention, in a view similar to FIG. 3A.

Hereinafter, a preferred embodiment of the check valve disk according to the present invention will be described in detail with reference to FIGS. 4A and 4B.

Figure 4a of the accompanying drawings is a sectional view of the main portion illustrating the circumferential angle of the disk according to the present invention, Figure 4b is a view similar to Figure 3a, an enlarged cross-sectional view of the disk circumferential surface according to the present invention. The X axis defined in the present invention means a radial direction of the disc 200 (see FIG. 4A), and the Y axis means a direction perpendicular to the X axis, that is, the axis direction of the disc 200. In addition, the inlet circumferential surface 203 and the outlet circumferential surface 204 of the disk 200 (refer to FIG. 4A) described below will be described with reference to the X axis (X, the radial direction of the disk) shown in FIG. 4A. As shown in FIG. 2, the circumferential surface of the disk 200 on which the fluid flows is referred to as the circumferential surface 203 of the inlet side of the disk, and on the contrary, as shown in FIG. The circumferential surface is called the exit side circumferential surface 204 of the disk.

As shown in FIGS. 4A and 4B, the disk 200 which opens and closes the conduit 112 of the check valve 10 while rotating with the shaft 300 is disposed on the inner surface of the conduit 112 as shown in FIG. 4A. The circumferential surface of the disk 200 is in contact with the annular engaging groove 201 is inserted into the annular sealing member 202 in the circumferential direction.

The inner wall of the conduit 112 is attached to the conduit sheet 113 to be in contact with the annular sealing member 202 of the disk 200. By the opening and closing operation of the disk, the annular sealing member 202 provided on the circumferential surface of the disk seals or opens the surface of the conduit sheet 113 to open and close the conduit.

The disk 200 has an inlet circumferential surface 203 and an outlet circumferential surface 204 that are inclined at a predetermined angle in the axial direction with respect to the Y axis Y on the circumferential surface thereof. 204 and the inlet side circumferential surface are formed to be stepped T, and the inlet side circumferential surface 203 is formed relatively smaller than the diameter of the outlet side circumferential surface 204.

The disc 200 is provided with a step T in the circumferential surface of the disc 200 due to the difference in the outer diameter of the outlet circumferential surface 204 and the inlet side circumferential surface 203. In the annular coupling groove 201, the sealing member 202 is coupled to the entire circumference of the circumference. In addition, the inner diameter of the conduit sheet 113 attached to the inner diameter of the conduit is configured at the same angle as the inclination angle of the circumferential surfaces 203 and 204 described above.

Preferably, the inlet side circumferential surface 203 is inclined at a predetermined angle in the axial direction of the conduit 112 and the outer diameter of the sealing member 202 is smaller than the outer diameter of the outlet circumferential surface 204.

This is because when the outer diameter of the sealing member 202 is larger than the outer diameter of the outlet side circumferential surface 204, the sealing member 202 is in contact with the surface of the pipe line 113 of the check valve 100 when the disk 200 is closed. It is possible to prevent the problem that the sealing member 202 is detached from the annular coupling groove 201 caught on the edge of the pipe sheet 113 before being in close contact with the pipe sheet 113 by the pressure acting on the back of the disk 200. On the contrary, when the outer diameter of the sealing member 202 is smaller than the outer diameter of the exit circumferential surface 204, the sealing performance can be prevented from deteriorating when the disc 200 is closed.

In addition, the inlet side circumferential surface 203 is inclined at a predetermined angle in the axial direction of the disc to seal the surface of the sealing member 202, that is, the step T area when the disc 200 is closed. The end cross section of the member 202 is first brought into close contact with the surface of the conduit sheet 113, and the second end surface of the member 202 is brought into close contact with the surface of the conduit sheet 113. The disc can be prevented from being pushed by the vehicle sealing effect.

In addition, the outlet side circumferential surface 204 of the disc 200 is formed in parallel with the conduit sheet 113 so that the inlet side circumferential surface is spaced apart from the conduit sheet when the disc 200 is closed, and the sealing member 202 is formed. ) Is the sealing member 202 corresponding to the step (T) region has a sealing effect by the elastic compression action on the conduit sheet 113, the outlet circumferential surface 204 is compressed on the surface of the conduit sheet 113 It has the effect of supporting the rear of the sealing member 202, and the outlet side circumferential surface 204 is in close contact with the surface of the conduit sheet 113 to improve the sealing effect while preventing the disk 200 from pushing. Because it can be done.

The inlet side circumferential surface 203 and the outlet side circumferential surface 204 of the disc 200 are inclined at the same angle about the Y axis Y of the disc 200 as shown in FIG. 4B. . In FIG. 4A, reference numeral 111 is a flange, and 300 is a shaft for rotatably supporting the disk 200.

As described above, the disk of the check valve according to the present invention can solve the problem that the sealing member 202 is separated from the annular coupling groove 201 because the outlet circumferential surface 204 supports the sealing member 202 from behind. In addition, since the outlet side circumferential surface 204 is in close contact with the surface of the conduit sheet 113 in a secondary manner, it can not only perform a double sealing effect but also prevent the disc from being pushed, and also make the circumferential surface of the disc the same angle. The production of the disk makes it easier to manufacture the disk and can significantly reduce the manufacturing cost.

100: check valve
100a: check valve casing
111: flange
112: check valve line
113: pipeline sheet
200: disk
202: sealing member
201: annular coupling groove
203: circumferential surface of the inlet side of the disk
204: circumferential surface of the exit side of the disk

Claims (1)

In the check valve disc having a sealing member inserted into the sealing member coupling ring provided on the circumferential surface, and opening and closing the pipeline of the fluid transfer pipe while rotating with the shaft,
An annular coupling groove 201 to which the annular sealing member 202 is coupled to the circumferential surface of the disc 200, and the circumferential surface of the disc 200 based on the Y axis Y of the disc 200. The pipe 200 is configured to be inclined at the same inclination angle, and includes a disc 200 having an inlet side circumferential surface 203 and an outlet side circumferential surface 204 formed on the inclined surface thereof, and a circumferential surface of the disc 200 in contact with each other. When the inner diameter of the sheet 113 is processed at the same inclination angle, the disk 200 is rotated about the shaft 300 so that the circumferential surface of the disk 200 is in close contact with the inner surface of the conduit sheet 113. The inlet side circumferential surface 203 is spaced apart from the conduit sheet 113 by T), and the outlet side circumferential surface 204 is in close contact with the conduit sheet 113 when the sealing member 202 is compressed. Check valve disc, characterized in that configured to support the rear of the sealing member (202).

Images