KR101439957B1 - Apparatus for evaluating and testing performance of posrv - Google Patents

Abstract

The present invention relates to a pilot-operated safety relief valve (POSRV) performance evaluation testing apparatus and, more specifically, to a POSRV performance evaluation testing apparatus wherein a lift cylinder having a disk, lifted by inflow of fluid, inside is stably fixed and attached to an upper plate to enable precise testing under a structurally stable condition; a gap between an upper plate and a lower plate can be adjusted to correspond to various sizes of spring-operated pilot valves or lift cylinders; and a load cell interposed between a lift stem and a spring stem to effectively measure a force applied to the lift stem or pressure applied to the lift cylinder. The POSRV performance evaluation testing apparatus includes: a lower plate installed on an upper portion of a spring-operated pilot valve; an upper plate disposed above the lower plate in parallel to face the lower plate; a frame bar connecting the lower plate and the upper plate; a lift cylinder fixed and attached to a bottom surface of the upper plate having a disk, lifted by a fluid introduced from the outside, disposed inside; and a lift stem wherein one end is connected to a bottom surface of the disk and the other end is vertically extended downwards to be connected to the spring stem of the spring-operated pilot valve while being exposed outside the lift cylinder.

Description

[0001] POSRV PERFORMANCE OF POSRV [0002]

[0001] The present invention relates to a POSRV performance evaluation test apparatus, and more particularly to a POSRV performance evaluation test apparatus, in which a lift cylinder having a disk which is lifted by inflow of a fluid into an internal space is stably fixedly attached to an upper plate, And the distance between the upper plate and the lower plate can be adjusted so as to accommodate various sizes of the spring drive pilot valve or the lift cylinder and by interposing the load cell between the lift stem and the spring stem, To a POSRV performance evaluation test apparatus capable of effectively measuring a force acting on a lift cylinder or a pressure acting on a lift cylinder.

POSRV (Pilot Operated Safety and Relief Valve) is installed on the pressurizer of nuclear power plant. It is a valve that can perform safety valve function and safety decompression function of RCS (Reactor Coolant System) system of nuclear power plant.

The POSRV configuration consists of a combination of three valves. Specifically, the POSRV includes a main valve directly connected to the upper nozzle of the pressurizer and having an inlet and an outlet, a spring-loaded pilot valve performing a safety valve function, and a safety- And a motor-driven pilot valve to be operated.

As the spring-actuated pilot valve is opened at a set pressure, the spring-actuated pilot valve is opened in the same driving manner as the safety valve, and the main valve is opened to protect the components of the pusher and the RCS system against overpressure do.

The motor-driven pilot valve opens the main valve by opening the motor-driving pilot valve with an electric signal in order to rapidly depressurize the RCS system by introducing coolant from the outside in the case of a design reference accident, thereby rapidly depressurizing the RCS system .

Therefore, it is very important to verify the performance of the spring drive pilot valve and the motor drive pilot valve in the performance evaluation of POSRV.

The test equipment for carrying out the performance evaluation of the POSRV shall be data acquisition to perform the set pressure test, which is the safety valve function of POSRV, and the data acquired during the safety decompression test shall be collected.

The set pressure test, POSRV's safety valve function, can be performed in two ways. The first method is to test the incompressible fluid at the inlet of the main valve to the set pressure or higher by testing with the bench set test equipment to determine whether POSRV is open at the set pressure and whether it is closed at the closing pressure It is a test method.

The second method is to connect the lifting device to the spring stem of the spring drive pilot valve and to test whether the valve is open at the set pressure of POSRV and whether it is closed at the return pressure using the lifting force.

The first test method is difficult to measure the correct POSRV set pressure and reclosing pressure because the POSRV is decomposed at the top of the pressurizer and tested in the bench set and incompressible fluid is used as the test fluid, which is different from the fluid during operation of the nuclear power plant.

On the other hand, in the second test method, the POSRV set pressure and the reclosing pressure are set to the first test (using the system pressure (working pressure) and the lifting device lifting force by directly installing the lifting device on POSRV without disassembling the POSRV from the top of the pressurizer Method (method of using benchset test equipment), and has a merit that test method is convenient.

As a second test method, a conventional POSRV performance evaluation test apparatus for testing the set pressure and the reclosing pressure using the system pressure and the lifting force of the lifting device will be described as follows.

The existing POSRV performance evaluation test apparatus is installed on the upper end of the spring drive pilot valve or the spring cover, and can perform the POSRV set pressure test in connection with the spring stem of the spring drive pilot valve.

Such a conventional POSRV performance evaluation test apparatus increases the force (tensile force) for lifting the spring stem of the spring drive pilot valve by gradually increasing the pressure in the lift cylinder. Then, when the force for lifting the spring stem is continued, the spring drive pilot valve opens instantaneously. At this time, the pressure (lifting pressure) applied to the lift cylinder is measured and the differential pressure (pressure obtained by subtracting the system pressure from the set pressure) is calculated do.

Here, the set pressure of the spring drive pilot valve corresponding to the safety valve is the sum of the calculated pressure difference and the system pressure (system pressure, working pressure), and the set pressure (Pset) = differential pressure (psi) + Psystem .

Here, when the spring force of the spring drive pilot valve is Fspring, it can be expressed as follows.

Fspring = ASeat x PSet

Here, ASeat = the effective area of the spring drive pilot valve disk (in ² ), and PSet = the set pressure (psi) of the spring drive pilot valve.

In addition, the equilibrium relation of force when POSRV performance evaluation test apparatus is used is as follows.

Spring set point of spring drive pilot valve = force by POSRV performance evaluation test device + system pressure (working pressure).

That is, Fspring = Fsystem + FAssist

= ASeat x Psystem + ACylinder x PCylinder

Therefore, the set value Pset = Psystem + (ACylinder x PCylinder) / ASeat

= Psystem + FAssist / ASeat

= Differential pressure + Psystem

(Psi), ACylinder: Effective area of lift cylinder (in ² ), PCylinder: Lift cylinder pressure (psi), FAssist: Spring drive pilot valve can be opened instantaneously This is equivalent to the force lifted using the POSRV performance evaluation test equipment.

Through this process, it is possible to test whether the valve is normally open at the set pressure of the spring drive pilot valve and whether it is normally closed at the return pressure using the POSRV performance evaluation test equipment.

The systematic pressure corresponds to the actual system pressure when the POSRV performance evaluation system is applied during system operation and corresponds to the operating pressure when the system is not in operation, that is, when the system pressure is applied during the test process.

In such a conventional POSRV performance evaluation test apparatus, a lift cylinder in which a disk is formed is fixed to an upper portion of the upper plate. As a result, only the lower portion of the cylinder shell forming the outer cylinder of the lift cylinder is supported by the upper plate, and the upper portion is not supported at all.

Therefore, when pressure is applied into the lift cylinder, as pressure is applied upward in the cylinder shell, only a continuous force is applied to the upper side of the cylinder shell, which causes the cylinder shell to be subjected to a force. As a result, the accurate pressure in the lift cylinder can not be measured, and the pressure is more inaccurate over time.

In addition, the existing POSRV performance evaluation test apparatus maintains a state where the frame bar connecting between the lower plate and the upper plate is always fixed. Therefore, when it is necessary to adjust the distance between the lift cylinder and the spring drive pilot valve (when the size of the lift cylinder or the spring drive pilot valve is variable), it is necessary to replace the whole equipment or replace the frame bar .

SUMMARY OF THE INVENTION The present invention has been devised to solve the problems of the prior art as described above, and it is an object of the present invention to provide a refrigerator which has a structure in which a lift cylinder having a disk, which is lifted by inflow of a fluid, And the distance between the upper plate and the lower plate can be adjusted so that it is possible to cope with various sizes of the spring drive pilot valve or the lift cylinder and the load cell between the lift stem and the spring stem The present invention aims to provide a POSRV performance evaluation test apparatus capable of effectively measuring a force acting on a lift stem or a pressure applied to a lift cylinder.

In order to solve the above-described problems, the POSRV performance evaluation test apparatus of the present invention is a POSRV performance evaluation test apparatus. The POSRV performance evaluation test apparatus includes a lower plate installed on an upper portion of a spring drive pilot valve, A lift cylinder fixedly attached to a lower surface of the upper plate and provided with a disk which is lifted by a fluid introduced into the inner space from the outside, And a lift stem connected at one end to the lower surface of the disk and vertically extended at the other end in a downward direction and exposed to the outside of the lift cylinder to the spring stem of the spring drive pilot valve .

Here, the lift cylinder includes an engaging plate attached to a lower face of the upper plate, an inner space formed with the upper portion attached to the engaging plate, the disk disposed above the inner space, And a cylinder shell in which a fluid outlet through which the fluid can flow out is formed and a through hole through which the lift stem penetrates is formed on a lower surface of the cylinder shell.

The frame bar is coupled to the upper plate or the lower plate so as to move up and down in order to adjust a distance between the upper plate and the lower plate.

In addition, an LVDT stem for measuring the vertical displacement of the disk is installed on the upper surface of the disk.

A load cell is interposed between the spring stem of the spring drive pilot valve and the lift stem.

According to the POSRV performance evaluation test apparatus of the present invention having the above-described problems and solutions, since the lift cylinder having the disk in the inner space is attached to the upper plate by the inflow of the fluid, And the distance between the upper plate and the lower plate can be adjusted, so that it is possible to cope with various sizes of the spring drive pilot valve or the lift cylinder, and by interposing the load cell between the lift stem and the spring stem, The force acting on the stem or the pressure on the lift cylinder can be effectively measured.

1 is a perspective view of a POSRV performance evaluation test apparatus according to an embodiment of the present invention.
2 is a partial perspective view of a POSRV performance evaluation test apparatus according to an embodiment of the present invention.
3 is a cross-sectional view of a POSRV performance evaluation test apparatus according to an embodiment of the present invention.
4 is a schematic diagram of a system for testing a set pressure using a POSRV performance evaluation test apparatus according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the POSRV performance evaluation test apparatus of the present invention having the above-described problems, solutions, and effects will be described in detail with reference to the accompanying drawings.

The sizes and shapes of the components shown in the drawings may be exaggerated for clarity and convenience. In addition, terms defined in consideration of the configuration and operation of the present invention may be changed according to the intention or custom of the user, the operator. Definitions of these terms should be based on the content of this specification.

FIG. 1 is a perspective view of a POSRV performance evaluation test apparatus 100 according to an embodiment of the present invention, FIG. 2 is a partial perspective view of a POSRV performance evaluation test apparatus 100 according to an embodiment of the present invention, Sectional view of a POSRV performance evaluation test apparatus 100 according to an embodiment of the present invention.

1 to 3, a POSRV performance evaluation testing apparatus according to an embodiment of the present invention includes a lower plate 10, an upper plate 20, a frame bar 30, a lift stem 40, (50).

The lower plate 10 is attached to the upper portion of the spring drive pilot valve 1. Specifically, it is fixedly attached to the upper portion of the flange of the spring drive pilot valve 1 or the upper portion of the housing.

1 to 3, the lower plate 10 has a disc shape as a whole, and a through hole is formed in the center portion so that the spring stem 1a of the spring drive pilot valve 1 can be lifted in the vertical direction Respectively.

Further, the lower plate 10 is formed with a coupling hole through which the lower end of the frame bar 30 can be coupled along the circumferential portion, and furthermore, can be bolted to the flange portion of the spring- A bolt coupling hole is formed.

An upper plate 20 spaced apart from the lower plate 10 is disposed above the lower plate 10. That is, the upper plate 20 is arranged to face the lower plate 10 in parallel.

As shown in FIGS. 1 to 3, the upper plate 20 is formed in a disc shape similar to the lower plate 10. A coupling hole through which the upper end of the frame bar 30 can be coupled is formed along the circumference.

A bolt coupling hole is formed in the upper plate 20 so that the lift cylinder 50 can be fixed to the lower surface thereof. That is, on the lower surface of the upper plate 20, the lift cylinder 50 is stably fixed by bolt connection.

The lower plate (10) and the upper plate (20) are connected by the frame bar (30). That is, the frame bar 30 connects the lower plate 10 and the upper plate 20 to each other.

The frame bar 30 is interposed between the lower plate 10 and the upper plate 20 so as to be vertically disposed with an upper end coupled to the upper plate 20 and a lower end connected to the lower plate 10 .

Specifically, the upper end of the frame bar 30 is inserted into a coupling hole formed along the periphery of the upper plate 20, and the lower end of the frame bar 30 is inserted into a coupling hole formed along the periphery of the lower plate 10 . The lower plate 10 and the upper plate 20 can be maintained at a constant distance by the frame bar 30 and maintained in a stable state.

1 to 3, a plurality of frame bars 30 are coupled to coupling holes formed along the peripheries of the lower plate 10 and the upper plate 20, respectively. In FIGS. 1 to 3, four frame bars 30 illustrate a state where the lower plate 10 and the upper plate 20 are connected to each other.

The lift cylinder 50 is fixed to the lower surface of the upper plate 20 in an inner space defined by the plurality of frame bars 30. That is, the lift cylinder 50 is fixedly attached to the lower surface of the upper plate 20. The lift cylinder 50 can be stably held on the lower surface of the upper plate 20 without any vibrations or vibrations during the lifting of the spring stem 1a by the lift cylinder 50. [ have. As a result, the pressure applied to the lift cylinder 50 can be precisely measured.

As shown in FIGS. 1 to 3, the lift cylinder 50 is formed with an inner space, and the inner space is provided with a disk 57 that is lifted by a fluid introduced from the outside.

The lift cylinder 50 may be in the form of either a cylinder type or a diaphragm and the fluid that is introduced into the inner space of the lift cylinder 50 to lift the disk 57 may be argon , Nitrogen or the like, or oil. That is, the lift cylinder 50 may be operated by pneumatic or hydraulic pressure.

3, the lift cylinder 50 includes an engaging plate 51a, a cylinder shell 51, and a disk 57. As shown in Fig. The coupling plate 51a is attached to an upper portion of the cylinder shell 51 forming the inner space and the disk 57 is disposed in the inner space of the cylinder shell 51. [

Specifically, the coupling plate 51a is attached to the lower surface of the upper plate 20, and is coupled to the upper portion of the cylinder shell 51 to seal the inner space of the cylinder shell. The coupling plate 51a is fixedly attached to the lower surface of the upper plate 20 by bolting.

As shown in Figs. 1 to 3, the cylinder shell 51 has a cylindrical shape as a whole. The cylinder shell 51 forms an inner space in a state where an upper portion of the cylinder shell 51 is attached to the coupling plate 51a.

As shown in FIGS. 3 to 5, the disk 57 is disposed above the inner space of the cylinder shell 51 and includes a fluid inlet 53 through which the fluid can flow downwardly, A fluid outlet 55 capable of flowing out is formed, and a through hole through which the lift stem 40 can penetrate is formed on the lower surface.

1 to 3, one end of the lift stem 40 is connected to a lower surface of the disk 57, and the other end of the lift stem 40 is vertically extended downward to be exposed to the outside of the lift cylinder 50 And is connected to the spring stem 1a of the spring drive pilot valve 1 in a state where the spring is actuated.

The lift stem 40 is lifted together with the disk 57 as the disk 57 is lifted by the pressure of the fluid and consequently the spring stem 1a connected to the lift stem 40 is lifted upwards And the spring drive pilot valve 1 can be opened.

Since the lift stem 40 ascends and descends through the through hole formed in the lower surface of the cylinder shell 51, a gasket is formed in the through hole to prevent leakage of the fluid.

The POSRV performance evaluation test apparatus according to the embodiment of the present invention thus constructed is fixedly attached to the upper portion of the flange of the spring drive pilot valve 1 as described above. In this state, the disk 57 is lifted by the fluid flowing into the lift cylinder 50, and as a result, the spring stem 1a connected to the lift stem 40 can be lifted upwards.

The spring stem 1a is lifted by measuring the pressure of the inner space of the lift cylinder 50, the force acting on the lift stem 40, the displacement of the disk 57, The differential pressure for opening the pilot valve 1 can be calculated. Here, the differential pressure means the pressure obtained by subtracting the system pressure (system pressure, working pressure) from the set pressure of the spring drive pilot valve, as described above.

By using the differential pressure thus calculated, it is possible to test whether the set pressure of the spring drive pilot valve 1 is maintained normally, and thereby the performance of the POSRV can be evaluated.

For example, as previously noted, the set pressure needs to be the same within the pressure and error ranges plus system pressure (working pressure) and differential pressure. Therefore, when the lift cylinder 50 opens the spring drive pilot valve 1, the differential pressure is calculated, and the pressure obtained by adding the calculated differential pressure to the system pressure (working pressure) The performance of the spring drive pilot valve 1 and the performance of the POSRV including the main valve 2 connected to the spring drive pilot valve 1 can be evaluated according to whether or not the spring drive pilot valve 1 is the same.

Referring to FIG. 3, the operation of the POSRV performance evaluation test apparatus according to the embodiment of the present invention and the performance evaluation process of the POSRV using the same will be described briefly.

As shown in FIG. 3, the lift cylinder 50 receives the fluid supplied from the fluid supply device 80 through the fluid inlet 53. The fluid supply device 80 regulates the flow rate and pressure of the fluid to supply the fluid to the lift cylinder 50 through the fluid inlet 53.

At this time, the fluid discharge device (90) prevents the fluid from being discharged through the fluid outlet (55). For example, the fluid discharge device 90 may have various open / close valves, and by closing the open / close valves, the fluid can not flow out through the fluid outlet 55.

Then, fluid pressure is applied to the disk 57 formed in the inner space of the lift cylinder 50, and the pressure disk 57 is lifted. The spring 57 is lifted so that the spring stem 1a connected to the lift stem 40 is lifted upward so that the spring drive pilot valve 1 is opened The pressure or the flow rate of the fluid is controlled to be supplied to the lift cylinder 50.

The control unit (not shown) controls the tensile force applied to the lift stem 40 from various sensors provided in the POSRV performance evaluation test apparatus, the pressure in the lift cylinder 50, And receives various data such as the displacement of the disk and calculates the pressure difference due to the lifting force of the lift cylinder at the moment when the spring drive pilot valve 1 is opened using the various sensing data.

The performance of the spring drive pilot valve 1 is determined depending on whether the pressure difference thus calculated plus the system pressure (system pressure, operating pressure) is the same within the allowable error range of the set pressure of the spring drive pilot valve 1 Evaluation can be performed.

Meanwhile, the POSRV performance evaluation test apparatus according to the present invention can evaluate the validity of the set pressure as described above, and further evaluate whether the back pressure of the spring drive pilot valve 1 is valid.

Specifically, when the spring drive pilot valve 1 is opened, the fluid supply device 80 blocks further supply of fluid to the fluid inlet 53, So that the fluid in the lift cylinder (50) can be discharged through the outlet (55).

That is, the fluid supply device 80 has various on-off valves, and closes the on-off valves to block the supply of fluid to the fluid inlets 53, And opens the on-off valve so that the fluid in the lift cylinder (50) can be discharged through the fluid outlet (55).

As the fluid in the lift cylinder 50 is discharged, the disk 57 descends and the lift stem 40 connected to the disk and the spring stem 1a connected to the lift stem 40 descend, The spring drive pilot valve 1 is closed at any moment.

At this time, the control unit (not shown) uses the sensing data related to the force acting on the lift stem 40, the pressure of the lift cylinder 50, the displacement of the disk, etc. from various sensors, It can be assessed whether it is closed at normal recoil pressure.

For example, the reclining pressure calculated from the formula of recoil pressure = system pressure (system pressure, working pressure) + (lift cylinder pressure * lift cylinder disk area) / disk effective area of spring drive pilot valve The performance of the spring drive pilot valve can be evaluated depending on whether the pressure is within the tolerance range of the pressure.

The POSRV performance evaluation test apparatus according to the present invention having the above-described configuration features and operations can use various lift cylinders 50. That is, the lift cylinder 50 applied to the present invention may be a cylinder type or diaphragm type of various sizes. In addition, lift cylinders 50 of various sizes and types can be used depending on the size of the spring drive pilot valve 1.

As described above, the lift cylinder 50 for checking the set pressure of the spring drive pilot valve 1 of various sizes can be variously varied in kind or size. As a result, in order to easily connect the lift stem 40 and the spring stem 1a, the distance between the lower plate 10 and the upper plate 20 needs to be adjusted.

The frame bar 30 of the present invention is connected to the lower plate 10 and the upper plate 20 so as to adjust the distance between the lower plate 10 and the upper plate 20, do.

That is, the frame bar 30 may be coupled to the upper plate 20 or the lower plate 10 so as to be vertically movable in order to adjust a distance between the upper plate 20 and the lower plate 10, do.

For example, the upper side of the frame bar 30 is fixedly coupled to the upper plate 20, and the lower side of the frame bar 30 penetrates through the lower plate 10 to be vertically movable, The distance between the lower plate 10 and the upper plate 20 can be adjusted.

The lower side of the frame bar 30 may be fixed to the lower plate 10 so as not to be moved through the lower plate 10 after the distance between the lower plate 10 and the upper plate 20 is adjusted. For example, a thread is formed on a lower part of the frame bar 30, and the frame bar 30 can be fixed to the lower plate 10 by tightening a nut.

Meanwhile, as shown in FIGS. 1 to 3, the POSRV performance evaluation test apparatus according to the embodiment of the present invention includes an LVDT (Linear Variable Differential Transformer) stem 60. The LVDT (Linear Variable Differential Transformer) stem 60 is vertically coupled to the upper surface of the disk 57.

That is, an LVDT (Linear Variable Differential Transformer) stem 60 for measuring the vertical displacement of the disk 57 is installed on the upper surface of the disk 57. The LVDT (Linear Variable Differential Transformer) stem 60 measures the displacement of the disk 57 to easily determine whether the spring drive pilot valve 1 is opened or closed.

Specifically, the displacement of the disk 57 is increased (varied) during the lifting process, and when the spring drive pilot valve 1 is opened, the change of the displacement hardly occurs as it is lifted to some extent. That is, the lifted disc 57 hardly changes in displacement when the spring drive pilot valve 1 is opened.

Therefore, when the displacement value of the disk 57 sensed by the LVDT (Linear Variable Differential Transformer) stem 60 is substantially unchanged (when there is only variation within about 0.1%), It can be determined that the driving pilot valve 1 is in the open state and the above-described differential pressure is calculated using sensing data input from various sensors.

In the present invention, it is necessary to easily measure the force acting on the lift stem 40, that is, the lifting force, during the POSRV performance evaluation test process, that is, during the lifting of the disk 57.

3, a load cell 70 (see FIG. 3) is provided between the spring stem 1a of the spring drive pilot valve 1 and the lift stem 40 to measure a lifting force. ) Are interposed and connected.

More specifically, one end of the load cell 70 is connected to the lift stem 40 through a first adapter 41, and the other end of the load cell 70 is connected to the spring stem (1a). Therefore, the load cell 70 can measure the lifting force in the process of lifting the spring stem 1a upward.

The measured value of the load cell 70 is input to a control unit (not shown), and the controller receives the measurement value of the load cell 70 when the spring drive pilot valve 1 is opened, The differential pressure can be calculated.

For example, the auxiliary force applied by the POSRV performance evaluation test apparatus according to the present invention is obtained by (the disk area of the lift cylinder 50) * (lift cylinder pressure) (The auxiliary pressure) / (the effective area of the spring drive pilot valve disk) is obtained by subtracting the pressure difference (system pressure (system pressure, working pressure) + (differential pressure)

As a result, the differential pressure is calculated by (the measured force of the load cell) / (the effective area of the spring drive pilot valve disk), and using the set pressure = system pressure + (measured force of the load cell) / And it is possible to perform the performance evaluation of the POSRV and the validity of the set pressure of the spring drive pilot valve.

4 is a schematic view showing a system for testing the set pressure using the POSRV performance evaluation test apparatus 100 in a state where the spring drive pilot valve 1 and the main valve 2 are connected.

4, the system for testing the set pressure using the POSRV performance evaluation test apparatus 100 is constructed by connecting the POSRV performance evaluation test apparatus 100 to the spring drive pilot valve 1, And the fluid control unit 5 adjusts the flow rate or pressure of the fluid supplied from the fluid supply unit 6 to control the POSRV performance evaluation Is supplied to the lift cylinder of the test apparatus (100).

With this configuration, the set pressure can be tested. To this end, the data collection unit 7 collects data sensed by various sensors disposed in various parts of the system. Then, the control unit 8 can evaluate the performance of the spring drive pilot valve and the POSRV including the spring drive pilot valve by determining whether the set pressure is valid by using the sensing data collected by the data collecting unit 7.

For example, the data collecting unit 7 may calculate the tensile force measured in the load cells installed in the POSRV performance test apparatus 100, the disk vertical movement displacement value measured by the displacement sensor provided in the LVDT stem 60, And collects pressure values measured by a pressure sensor provided in each of the lift cylinder and the fluid supply line that supplies the fluid to the lift cylinder from the fluid regulating portion 5.

The control unit 8 calculates the above-described differential pressure using various sensing data collected by the data collecting unit 7, and determines whether the pressure obtained by adding the differential pressure thus calculated and the system pressure is within the allowable error of the set pressure It is possible to perform the performance evaluation of the spring drive pilot valve 1 and the POSRV performance evaluation according to whether the pressure is equal to the pressure in the range.

While the invention has been shown and described with reference to certain preferred embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention as defined by the appended claims. Accordingly, the true scope of the present invention should be determined by the following claims.

1: spring drive pilot valve 1a: spring stem
2: Main valve
4: pressurizer 5: fluid regulator
6: fluid supply part 7: data collection part
8: control unit 10: lower plate
20: upper plate 30: frame bar
40: lift stem 41: first adapter
50: lift cylinder 51: cylinder shell (Shall)
51a: coupling plate 53: fluid inlet
55: fluid outlet 57: disk
60: LVDT stem 70: load cell
71: second adapter 80: fluid supply device
90: Fluid discharge device 100: POSRV performance evaluation test device

Claims (5)

In a POSRV performance evaluation test apparatus,
A lower plate installed on an upper portion of the spring drive pilot valve;
An upper plate disposed parallel to the upper side of the lower plate;
A frame bar connecting the lower plate and the upper plate;
A lift cylinder fixedly attached to a lower surface of the upper plate, the lift cylinder having a disk lifted by a fluid introduced from the outside into the inner space;
And a lift stem connected to the spring stem of the spring drive pilot valve in a state that one end is connected to the lower surface of the disk and the other end is vertically extended downward and exposed to the outside of the lift cylinder. Performance evaluation test equipment.
The method according to claim 1,
Wherein the lift cylinder has a coupling plate attached to a lower surface of the upper plate, an inner space formed with the upper part attached to the coupling plate, the disk disposed above the inner space, And a cylinder shell in which a fluid inlet port through which the fluid can flow and a fluid outlet port through which the fluid can flow out are formed and a through hole through which the lift stem penetrates can be formed on the lower surface of the cylinder shell. Device.
The method according to claim 1,
Wherein the frame bar is vertically coupled to the upper plate or the lower plate to adjust a distance between the upper plate and the lower plate.
The method according to claim 1,
And an LVDT stem for measuring the vertical displacement of the disk is installed on the upper surface of the disk.
The method according to any one of claims 1 to 4,
And a load cell is interposed between the spring stem of the spring drive pilot valve and the lift stem.

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