KR20230068122A - Soundness test device between cylinder and spool of pumped storage power generation inlet valve - Google Patents

Abstract

The present invention relates to a device for testing soundness between a cylinder and a spool of an inlet valve of a pumped storage power station and, more specifically, to a device for testing soundness between a cylinder and a spool of an inlet valve of a pumped storage power station, capable of preventing personnel consumption due to reorganization work and stably operating power generation by checking the soundness of airtightness retentivity at a part which is linearly in contact between a cylinder and a spool, prior to installation of the cylinder and the spool in an inlet valve. To achieve the purpose of the present invention, the device for testing soundness between a cylinder and a spool of an inlet valve of a pumped storage power station includes: a body having an opening unit on one side and a hollow inner space in which the spool and the cylinder are inserted through the opening unit, wherein a pressure supply unit capable of raising the pressure of the inner space is installed on the other side of the body; a cover preventing the cylinder of the inner space from being separated from the body by being connected to the opening unit and having an exposure hole exposing the spool to the outside of the body; and a pressure gauge installed to measure pressure changes in the inner space of the body.

Description

Soundness test device between cylinder and spool of pumped storage power generation inlet valve}

The present invention relates to a soundness testing device between a cylinder and a spool of a pumped-storage inlet valve, and more particularly, to test the integrity of the airtightness between the cylinder and the spool before the cylinder and the spool are installed in the inlet valve. It is about a soundness test device between the cylinder and the spool of a pumped-storage power plant inlet valve.

Pumped-storage power generation uses surplus power generated by other power plants at night or at light load to pump water from a low place to a high place to generate power using this pumped water. It is economical, it is possible to increase the capacity of power generation facilities, and the unit cost of construction is relatively low. As shown in FIG. 1, pumped-storage power generation generates power by driving a generator motor 3 supplied with power generation water stored in an upper reservoir 1 through a pipe 2. Power generated by the power generation of the generator motor 3 is supplied to consumers through the transmission line 5 after passing through the transformer 4. The generator motor 3 generates power by rotating the pump aberration 6 by the power generation water supplied through the pipe 2, and the power generation water supplied to the generator motor 3 is generated by the pipe of the generator motor 3 It is controlled by the inlet valve 10 installed in (2).

The inlet valve 10 is subjected to a pressure that fluctuates greatly from a high water pressure of about 60 Kg/cm2 to a low water pressure of 0 Kg/cm2, and is frequently operated to adjust the frequency of the power system in a pumped-storage power plant. Because it is stationary, high quality and high reliability are required. As shown in FIG. 2, the inlet valve 10 is composed of a housing 11, a cylinder 12, and a spool 13. The housing 11 is connected between the inlet pipe 2 and the outlet pipe 2 and has a high-pressure water outlet 11a through which high-pressure water is discharged, and a hollow portion 11b capable of accommodating a cylinder is formed therein. has been The cylinder 12 is inserted into and fixed to the hollow part 11b of the housing 11 as a cylindrical structure. The spool 12 is installed to reciprocate up and down along the axial direction of the cylinder 11 in the cylinder 11 of the cylindrical structure. As the spool 12 is moved up and down by the actuator shaft 13 moving up and down inside the cylinder 11, it opens and closes a guide hole (not shown) formed in the cylinder 11, thereby regulating the flow of high-pressure water. do. A piston (not shown) interlocking with the inlet valve 10 is driven by the function of regulating the flow of high-pressure water, and the inlet valve through which the high-pressure water passes is opened and closed by driving the piston. Accordingly, the high pressure water is supplied to the pump aberration 6 to generate power, or the high pressure water is blocked from being supplied to the pump aberration 6 to stop power generation.

On the other hand, the spool 12 and the cylinder 11 constituting the inlet valve 10 are facilities that can completely block the upper dam and the lower dam, and when leakage occurs in the cylinder 11 and the spool 12, the pipe (2) ) Due to the delay in the opening and closing action time, the normal operation of the pumped storage power generation can be greatly affected. Furthermore, when the cylinder 11 and the spool 12 are disassembled to repair the leakage of the inlet valve 10, the work space is narrow and the workability deteriorates, and the operation of power generation due to the delay in work time may be affected. there is In addition, leaks frequently occur in the inlet valve 10 due to the installation of the cylinder 11 and spool 12, which have not been secured in soundness, resulting in the consumption of maintenance personnel and delay in preventive maintenance time due to rework of the inlet valve maintenance. there is.

Republic of Korea Patent No. 10-0432336

The present invention has been made to solve the above problems, and an object of the present invention is to test the integrity of the airtightness between the cylinder and the spool before the cylinder and the spool are installed in the inlet valve, thereby providing pumped storage power generation. It is intended to provide a soundness test device between the cylinder and the spool of the pumped-storage power generation inlet valve that enables stable operation and minimizes maintenance work due to leakage between the cylinder and the spool to minimize waste of manpower and budget.

In order to achieve the above object, the present invention forms an opening on one side, but forms a hollow inner space into which a spool and a cylinder can be inserted through the opening, and increases the pressure in the inner space on the other side. A body in which a pressure supply means is installed; a cover coupled to the opening to prevent the cylinder in the inner space from being separated from the body and having an exposure hole through which the spool can be exposed to the outside of the body; and a pressure gauge installed to measure a pressure change in the inner space of the body.

At this time, it is preferable that a pressure release means for releasing the pressure applied to the inside of the body is installed on the other side of the body.

The integrity test device between the cylinder and the spool of the pumped-storage inlet valve according to the present invention has the following effects.

The present invention can reduce manpower by preventing preventive maintenance and rework, and by preventing time waste such as air delay, stable operation of facilities, accident prevention, maintenance reliability improvement, labor cost reduction, assembly maintenance time reduction can be expected It works.

1 is a diagram schematically illustrating a pumped-storage power generation system.
2 is a cross-sectional view showing the main part of the inlet valve of the pumped-storage power generation system.
3 is a photograph showing a soundness test device between a cylinder and a spool of a pumped-storage inlet valve according to a preferred embodiment of the present invention.
4 is a cross-sectional view showing a state in which a cylinder and a spool are coupled to a soundness test device between a cylinder and a spool of a pumped-storage inlet valve according to a preferred embodiment of the present invention.

The terms or words used in this specification and claims are not limited to the usual or dictionary meanings, and the inventor can properly define the concept of the term in order to explain his or her invention in the best way. Based on this, it should be interpreted as a meaning and concept consistent with the technical spirit of the present invention.

Hereinafter, with reference to FIGS. 3 and 4 attached, a soundness test device between a cylinder and a spool of a pumped-storage power inlet valve according to a preferred embodiment of the present invention (hereinafter, referred to as a 'soundness test device') will be described.

The integrity test device was designed to check the integrity of the cylinder 11 and the spool 12, such as leakage, before they are installed in the inlet valve 10 of the pumped-storage system. Accordingly, the soundness test device does not cause maintenance work due to leakage of the inlet valve, and enables stable operation of the power generation facility.

As shown in FIGS. 3 and 4 , the soundness test device includes a body 100, a cover 200, a fixing means 300, and a pressure gauge 400.

The body 100 forms a hollow inner space 110 in which the cylinder 11 and the spool 12 to be measured for soundness can be accommodated, and one side of the body 100 has the cylinder 11 and the spool 12 An opening 120 that is an entrance that can be accommodated into the inner space 110 is formed. At this time, one side of the body 100 refers to the lower part in the drawing. The inner diameter of the opening 120 is formed to a size into which the cylinder 11 can be inserted, and the depth of the inner space 110 is formed to correspond to the height of the cylinder 11 . The shape of the body 100 is preferably formed in a cylindrical shape. In addition, a coupling flange 130 is formed around the opening 120 of the body 100 . The coupling flange 130 is configured for coupling with the cover 200, and the outer diameter of the coupling flange 130 is larger than that of the body 100. Coupling holes 131 through both sides are formed in the coupling flange 130 , and a plurality of coupling holes 131 are provided along the circumference of the coupling flange 130 . In addition, a pressure supply means 140 and a pressure release means 150 are installed on the other side of the body 100 . The pressure supply means 140 is configured to apply pressure to the inner space 110 of the body 100, and is connected to the pressurized hole 111 formed on the other side of the body 100. The pressure supply means 140 is provided to supply pressure through the pressure hole 111 . The pressure supply means 140 is not limited to specific equipment, and pressure generating equipment used in industrial sites may be used. The pressure release means 150 is a component that relieves pressure in the inner space 110 of the body 100, and is connected to the release hole 112 formed on the other side of the body 100. The pressure release means 150 is preferably provided as a valve capable of opening and closing the release hole 112 .

The cover 200 blocks the opening 120 of the body 100 to prevent the cylinder 11 from being separated from the inner space 110 . The cover 200 does not completely shield the inner space 110 of the body 100, and as can be seen through FIG. 4, the exposure hole 210 is provided so that the spool 12 can come out of the cover 200. form The exposure hole 210 is formed at the center of the cover 200 and has an inner diameter corresponding to the outer diameter of the spool 12 . An O-ring (O) for maintaining airtightness with the body 100 is installed on one surface of the cover 200 . Two O-rings (O) are installed in the concentric direction of the cover 200, one maintains airtightness with the body 100, and the other maintains airtightness with the cylinder 11. A screw hole 220 for coupling with the body 100 is formed in the cover 200 . The screw hole 220 is formed to correspond to the coupling hole 131 of the coupling flange 130.

The fixing means 300 serves to fix the cover 200 to the body 100, and is preferably provided as a bolt. The fixing means 300 is provided so that it can be screwed into the screw hole 220 through the coupling hole 131 as shown in FIG. 4 .

The pressure gauge 400 serves to measure the internal pressure of the internal space 110 of the body 100, precisely the cylinder 11, and is installed on the other side of the body 100. The pressure gauge 400 is not limited to a specific one, and a known pressure gauge may be applied. The pressure gauge 400 checks whether or not the pressure of the inner space 110 of the body 100, which has been raised through the pressure supply means 140, is maintained even after a certain period of time to maintain the airtightness of the cylinder 11 of the spool 12. This is to ensure that it is sound.

Hereinafter, a process for confirming the integrity of the airtightness of the cylinder and the spool through the integrity tester having the above configuration will be described.

Before installing the cylinder 11 and the spool 12 on the inlet valve 10 of the pumped-storage power generation system, the operator separates the cover 200 of the integrity test device from the body 100, and the inner space of the body 100 ( 110) is opened. Next, the operator inserts the cylinder 11 to which the spool 12 is coupled into the inner space 110 of the body 100. At this time, the end of the cylinder 11 is in close contact with the inner surface of the other side of the body 100, and the outer circumferential surface of the cylinder 11 is pressed against the inner circumferential surface of the body 100 through the O-ring (O). In addition, the inside of the cylinder 11 corresponds to the pressure supply means 140, the pressure release means 150, and the pressure gauge 400. Meanwhile, the spool 12 is lowered by the load, and the inclined surface 12a of the spool 12 comes into line contact with the inner step 11c of the cylinder 11. In fact, the soundness test device is a device for testing the soundness of the airtightness of the line contact area between the inner step 11c of the cylinder 11 and the inclined surface 12a of the spool 12, and the soundness test is performed on the spool 12 ) is made through the process of measuring the change in pressure inside the cylinder 11 in a state where the inclined surface 12a of the cylinder 11 is in line contact with the inner step 11c of the cylinder 11.

Next, the operator brings the cover 200 into close contact with the coupling flange 130 of the body 100, and then couples it using the fixing means 300. At this time, the spool 12 is exposed through the exposure hole 210 of the cover 200, and the operator alternately couples the fixing means 300 in the diagonal direction of the coupling flange 130. Thus, the coupling of the cylinder 11 and the spool 12 to the inner space 110 of the soundness testing device is completed.

Next, the operator increases the pressure of the inner space 110 of the body 100 through the pressure supply means 140. Specifically, the pressure supply unit 140 increases the internal pressure of the cylinder 11 . At this time, while checking the pressure gauge 400, the operator operates the pressure supply means 140 until the internal pressure of the cylinder 11 reaches a certain pressure. Thereafter, when the internal pressure of the cylinder 11 reaches a predetermined pressure, the pressure supply means 140 is stopped, and the pressure change inside the cylinder 11 is measured through the pressure gauge 400 for a predetermined period of time. At this time, if the pressure change inside the cylinder 11 does not occur for a certain period of time, the soundness of the cylinder 11 and the spool 12 is considered secured, and if the pressure change inside the cylinder 11 occurs, the cylinder 11 It is considered that the integrity of the air tightness at the line contact area between the and the spool 12 is insufficient. Thereafter, when the integrity test between the cylinder 11 and the spool 12 is completed, the operator releases the pressure inside the cylinder 11 by opening the pressure release means 150. Thereafter, the operator releases the fixing means 300 to separate the cover 200 from the body 100, and then removes the cylinder 11 and the spool 12 for which the integrity test has been completed in the inner space 110 of the body 100. separate With this, the soundness test between the cylinder and the spool using the soundness test device is completed.

As described so far, the soundness test device between the cylinder and the spool of the pumped-storage inlet valve according to the present invention checks the cylinder 11 and the spool before the cylinder 11 and the spool 12 are installed in the inlet valve 10. By making it possible to check the integrity of the liver in advance, it is possible to prevent unnecessary maintenance manpower consumption due to the prevention of reinstallation of the inlet valve 10, and to stably perform power generation operation.

Although the present invention has been described in detail with respect to the described embodiments, it is obvious to those skilled in the art that various changes and modifications are possible within the scope of the technical spirit of the present invention, and these changes and modifications belong to the appended claims.

10: inlet valve 11: cylinder
11c: inner step 12: spool
12a: slope 100: body
110: inner space 111: pressurized hole
112: release hole 120: opening
130: coupling flange 131: coupling hole
140: pressure supply means 150: pressure release means
200: cover 210: exposure hole
220: screw hole 300: fixing means
400: pressure gauge

Claims (2)

One side forms an opening, but forms a hollow inner space into which the spool and the cylinder can be inserted through the opening, and the other side is provided with a pressure supply means capable of increasing the pressure of the inner space;
a cover coupled to the opening to prevent the cylinder in the inner space from being separated from the body and having an exposure hole through which the spool can be exposed to the outside of the body; and
A soundness test device between the cylinder and the spool of the pumped-storage power generation inlet valve including a pressure gauge installed to measure the pressure change in the inner space of the body. According to claim 1,
A soundness test device between the cylinder and the spool of the pumped-storage power generation inlet valve, characterized in that the pressure release means for releasing the pressure applied to the inside of the body is installed on the other side of the body.

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