RU2743735C1 - Pressure control device and safety control of safety valve and method of operation thereof - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: inventions relate to control of pressure and check of tightness of safety valve. Device comprises pressure source (13) connected with spider through control valve (1). Second branch of spider is connected with safety valve (12). First valve (2), standard vessel (3) with pressure sensor (8), reduction valve (4), the second shut-off valve (5) and the second pressure sensor (9) are connected to the third branch of the crosspiece. Third branch valve (6) and the standard vessel of smaller volume (7) are connected with the fourth branch of the crosspiece, the output of which is connected to the T-joint. T-joint is connected with test safety valve (10), third branch of T-joint is connected with second shut-off valve (5). Pressure sensors (8) and (9) are connected to computer (11). In the method, gas is first supplied through open valve (6) and pressure is adjusted before actuation of test valve (10). Computer (11) records the pressure peak of the second pressure sensor (9), which is the pressure setting of tested valve (10). Then gas is supplied through open valves (2) and (5), pressure regulator (4) is regulated to pressure of tested valve (10) and shutoff valve (2) is closed.

EFFECT: technical result is wider range of tests, higher reliability and simplicity.

3 cl, 1 dwg

Description

The claimed group of inventions relates to the field of testing the performance of a safety valve, in particular, to a device and method for regulating the pressure and monitoring the tightness of the safety valve.

At present, the methods for testing the pressure and tightness of safety valves are performed mainly with the help of a pressure calibration stand. In a valve tightness test, external leakage is monitored with a leak detection fluid or helium, and internal leakage occurs through the inlet. After closing the outlet, control is carried out using a bypass pipe and volumetric glassware (test medium - liquid) or accounting for bubbles (test medium - gas). The existing method for regulating the pressure and monitoring the tightness of the safety valve has the following disadvantages:

1.Existing test benches are usually large and fixed to a specific location. If the valve needs to be checked, it is raised to the indicated position. In this case, there is a risk of impact and fall of the valve, in addition, the time and labor costs for lifting and removing the valve increase;

2. for valves that do not leak at the outlet, pressure and tightness tests cannot be performed;

3. low degree of accuracy of tightness control for a closed safety valve;

4. for valves with a large outlet, a special overflow device must be provided;

5. When adjusting the pressure of the safety valve, it is necessary to determine the set point for the sudden drop in pressure of the gauge, with the problem of human error and low degree of accuracy.

A safety valve test system (CN 103954440 A, 07/30/2014) containing a gas source, a pressure flow meter, an adapter pipe, a safety valve, shut-off solenoid valves, a tee and a safety valve to be tested is adopted as a prototype for the claimed device. The gas source is connected to the adapter. A needle valve is installed between the gas source and the adapter. The branch of the tee is connected to a shut-off valve.

From CN103954440A, a method for testing a safety valve is known in which the safety valve and the first solenoid valve are opened and the second solenoid valve is closed at the same time. In this case, the air flow passes through the first solenoid valve and the pressure flow meter, and reaches the tested safety valve. After this, the test of the safety valve to be tested begins.

Thereafter, close the first solenoid valve and simultaneously open the second solenoid valve, so that the tested safety valve is reset and a single test is performed.

Changes in pressure and flow in each cycle of the tested safety valve are determined by the pressure flow meter.

The disadvantage of the prototype is that the pressure is recorded at only one point. At the same time, pressure fluctuations are present in the system, which affects the accuracy of the safety valve test.

The technical problem to be solved is the need to eliminate the above-mentioned disadvantages of analogs. At the same time, it is necessary to create a device and method for pressure regulation and leakage control, which can implement pressure adjustment and leak measurement by connecting to the inlet of the valve under test and assess the leakage taking into account the leakage through the outlet of the valve under test. It is also necessary to solve the problem when the valve leak cannot be detected taking into account the leak at the outlet, as well as to increase the intellectualization and portability of the method and device.

In view of the above problems, a more convenient and scientific way to solve the problem of checking the safety valve has been proposed. This method is highly accurate and convenient; no visual determination of the safety valve pressure setting is required. The tightness test does not require the connection of a bypass fixture or bypass pipe to the outlet of the valve under test. This allows the workplace to be relocated to test the valve. To carry out the test, you only need to connect the declared device to the inlet of the valve under test.

The technical result provided by the claimed group of inventions is to expand the range of tests, increase the reliability and simplicity of the device and method.

Other technical results are:

- the pressure drop can quantify the amount of leakage from the equipment under test, and the invention is suitable for valves of any size;

- effective measurement of the amount of leakage in the valve in the case when no leakage through the valve outlet is possible, while the device is a new portable means of testing the safety valve;

- accurate determination of the valve pressure setting, elimination of errors caused by the perception of sound when the valve is triggered and a sharp drop in pressure during artificial observation of the pressure gauge;

- no special bypass device is required for the valve under test;

- automatic leakage measurement, while the device implements intellectualization and automation;

- the invention is suitable for automatic control of the tightness of other valves.

The technical result of the device is achieved by the fact that the device for regulating the pressure and monitoring the tightness of the safety valve contains a standard vessel (3), a standard vessel of a smaller volume (7), a first pressure sensor (8), a second pressure sensor (9), a computer (11), safety valve (12) and a pressure source (13) connected to the crosspiece through a control valve (1), while the second branch of the cross is connected to the safety valve (12), and the first shutoff valve (2) is connected in series with the third branch of the cross, standard vessel (3), a pressure reducing valve (4) and a second shut-off valve (5), while the third shut-off valve (6) and a standard vessel of a smaller volume (7) are connected in series with the fourth branch of the cross, while the outlet of a standard vessel of a smaller volume (7 ) is connected to the tee, the second branch of the tee being connected to the tested safety valve (10), the third branch of the tee is connected with a second shut-off valve (5) on the third branch of the cross, while the first pressure sensor (8) is installed on a standard vessel (3), and the second pressure sensor (9) is installed on the third branch of the cross, in addition, the first pressure sensor (8) and the second pressure sensor (9) is connected to the computer (11), while the second pressure sensor (9) is installed between the second stop valve (5) and the tee.

The technical result of the method is achieved in that it includes the following stages:

- all elements of the device for setting the pressure and monitoring the tightness of the safety valve are connected in series, while the pressure source supplies gas, and through the open control valve, check the tightness of the joints of the elements, then close the control valve;

- close the first and second stop valves, then open the third stop valve;

- regulate the pressure by the control valve until the safety valve is triggered, while the computer records the pressure peak of the second pressure sensor, this pressure peak is the pressure setpoint for the safety valve;

- close the third stop valve and open the first and second stop valves;

- adjust the pressure reducing valve to the pressure of the safety valve and close the shut-off valve;

- the time is counted using a computer, the pressure drop переп P of the first pressure sensor (8) is measured for a set time, until the pressure of the second pressure sensor (9) becomes constant;

- in the seventh step, the leakage volume V _{x is calculated.} ;

- in the seventh step, the leakage volume V _{x is} calculated.

Calculate the leakage volume V _x. can be according to the equation of state of an ideal gas: PV = nRT. From this equation deduce V _x = ΔP × V ₀ / P ₀ , where P ₀ - atmospheric pressure.

The drawing shows a schematic diagram of a pressure regulating device and a safety valve tightness control.

Implementation of the device.

As shown in the drawing, the pressure regulating and sealing control device of the safety valve includes a control valve 1, a first shutoff valve 2, a standard vessel 3, a pressure reducing valve 4, a second shutoff valve 5, a third shutoff valve 6, a small standard vessel with a smaller volume 7. first pressure sensor 8, second pressure sensor 9, tested safety valve 10, computer 11, safety valve 12, pressure source 13.

The pressure source 13 is connected by a pipeline to the cross, while a control valve 1 is installed on the pipeline. The second branch of the cross is connected to the safety valve 12.The third branch of the cross is connected in series with the first shutoff valve 2, a standard vessel 3, a pressure reducing valve 4, and a second shutoff valve 5. The fourth branch of the cross is connected in series with the third stop valve 6 and a standard vessel of a smaller volume 7. In this case, the outlet of the standard vessel of a smaller volume 7 is connected to the tee, the second branch of the tee is connected to the tested valve 10. The third branch of the tee is connected to the second stop valve 5. The first sensor pressure 8 is installed on a standard vessel 3. The second pressure sensor 9 is installed between the second stop valve 5 and the tee.

The first pressure sensor 8 and the second pressure sensor 9 are connected to the computer 11.

Implementation of the method.

Stage 1. As shown in the figure, connect the vessel and pipelines between the shut-off valve 2 and the pressure reducing valve 4. First, fill the vessel and pipelines with water, and then pour water into a large measuring glass, measure the total volume V _{0 of the} vessel and pipelines between the shut-off valve 2 and pressure reducing valve 4.

Step 2. Connect all the elements as shown in the figure.

Step 3. Close the first and second stop valves 2 and 5, then open the third stop valve 6.

Step 4. Regulate the pressure through the control valve 1 until the test valve 10 is triggered, the pressure of the computer records the pressure peak of the second pressure sensor 9, this pressure peak is the pressure setting of the test valve 10.

Step 5. The third check valve 6 is closed and the first and second check valves 2 and 5 are opened.

Step 6. Regulate the pressure reducing valve 4 to the pressure of the tested valve 10 and close the stop valve 2.

Step 7. The time is counted using a computer, the pressure drop △ P of the first pressure sensor 8 is measured for a set time, until the pressure of the second pressure sensor 9 becomes constant.

Stage 8. According to the formula V _x = ΔP × V ₀ / P ₀ calculate the volume of leakage V _x where P ₀ - atmospheric pressure.

The proposed invention, described in detail above with reference to the figure, is not limited to the above exemplary embodiment. Other examples of implementation, including changes in size, can be made without changing the essence of the invention within the scope of knowledge of a person skilled in the art. Details not described in the present invention can be taken from the prior art.

Claims (10)

1. A device for regulating the pressure and monitoring the tightness of the safety valve, containing a standard vessel (3), a standard vessel of a smaller volume (7), a first pressure sensor (8), a second pressure sensor (9), a computer (11), a safety valve (12) and a pressure source (13) connected to the cross through the control valve (1), while the second branch of the cross is connected to the safety valve (12), and the first stop valve (2), a standard vessel (3), are connected in series with the third branch of the cross, a pressure reducing valve (4) and a second shut-off valve (5), while the third shut-off valve (6) and a standard vessel of a smaller volume (7) are connected in series with the fourth branch of the cross, while the outlet of a standard vessel of a smaller volume (7) is connected to a tee, where the second branch of the tee is connected to the tested safety valve (10), the third branch of the tee is connected to the second shutoff valve (5) on the third branch the crosspiece, while the first pressure sensor (8) is installed on a standard vessel (3), and the second pressure sensor (9) is installed on the third branch of the crosspiece, in addition, the first pressure sensor (8) and the second pressure sensor (9) are connected to computer (11), while the second pressure sensor (9) is installed between the second shut-off valve (5) and the tee. 2. A method for regulating pressure and monitoring the tightness of a safety valve, which includes the following steps: all the elements of the device for setting the pressure and monitoring the tightness of the safety valve are connected in series, while the pressure source (13) supplies gas, and through the open control valve (1) check the tightness of the joints of the elements, then close the control valve (1); close the first and second stop valves (2) and (5), then open the third stop valve (6); regulate the pressure with the control valve (1) until the test valve (10) is triggered, while the computer (11) records the pressure peak of the second pressure sensor (9), this pressure peak is the pressure setting for the test valve (10); closing the third stop valve (6) and opening the first and second stop valves (2) and (5); adjust the pressure reducing valve (4) to the pressure of the tested valve (10) and close the shut-off valve (2); counting the time using a computer (11), measuring the pressure drop ΔP of the first pressure sensor (8) for a set time until the pressure of the second pressure sensor (9) becomes constant; calculate the leakage volume V _x. 3. The method according to claim 2, wherein the leakage volume V _{x is} calculated by the formula V _x = ΔP × V ₀ / P ₀ , where P ₀ is atmospheric pressure.

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