KR100537484B1 - Device for diagonosing an air operated valve system - Google Patents

Abstract

The present invention relates to an apparatus for more accurately diagnosing an air driven valve system.

In the air-driven valve system, the first and second air pressure sensors provided on the supply pipe between the control air supply unit and the drive unit, and the strain gauge is provided on one axis of the stem of the valve to measure the strain of the stem, A displacement sensor provided on the stem other side of the valve to measure the position displacement of the stem, first and second fluid pressure sensors provided on the inlet and outlet sides of the plant's pipeline with the bonnet of the valve, and the plant's pipeline A flow rate sensor and a fluid temperature sensor for measuring the flow rate and temperature of the fluid flowing in the conduit installed on the air passage, an air temperature sensor and an air humidity sensor for measuring the temperature and humidity of the control air installed and supplied to the control air supply side; And a controller for analyzing and processing the measured data input from each sensor.

Description

Device for diagonosing an air operated valve system

The present invention relates to an air driven valve system in which valves are opened and closed by control air, and more particularly, to an apparatus for more accurately diagnosing an air driven valve system.

As is well known, an air operated valve system is one of the representative valve systems for controlling high temperature and high pressure fluids flowing into various pipelines installed in large plants such as power plants. It not only controls the direction, direction, etc. but also performs the main functions such as opening and closing of the flow path, throttling, check, and overpressure prevention.

Such an air driven valve system is divided into a diaphragm type and a cylinder type according to the shape of the driving part, and is further classified into a single acting type and a double acting type according to the air inflow method.

1 is a conceptual view illustrating one embodiment of an air-driven valve system to which a diaphragm-type drive unit is applied.

As shown, the air-driven valve system includes a current-pressure converter 1 for converting a current applied from a valve control unit (not shown) into a pneumatic signal form, and a pneumatic signal converted from the current-pressure converter 1. The valve body 4c is operated by the positioner 2 whose opening degree is determined, the valve 4 provided on the pipeline 7 of the plant, and the control air supplied through the positioner 2 to operate the valve 4c. Drive portion 5 for opening and closing the flow path in the inside), and a control air supply portion (not shown) for supplying control air to the drive portion 5 side through the positioner 2 from an external supply source (not shown). Here, the inside of the drive unit 5 is provided with a diaphragm 5a that returns to its original position by the elastic force when the external force (that is, the supplied control air) is removed, and the positioner 2, the drive unit 5, and the control air supply unit ( (Not shown) communicate with each other through the supply pipe.

In addition, the valve 4 has a bonnet 4a and bonnet provided on the plant conduit, a valve seat 4b mounted on the flow path inside the bonnet 4a, and a plug type for opening and closing the valve seat 4b. It consists of the valve body 4c and the stem 4d connected to the upper part of the valve body 4c.

With this configuration, when the current applied from the valve control unit (not shown) is converted into a pneumatic signal form proportional to the amount of current in the current-pressure converter 1, the positioner is converted by the pneumatic signal converted in the current-pressure converter 10. (2) determines the opening degree, so that the control air flows into the drive unit 5 side through the positioner 2 from the control air supply unit (not shown).

When the control air is introduced into or discharged from the driving unit 5 in this way, the diaphragm 5a of the driving unit 5 is activated to move the stem 4d of the valve 4 up and down, and to move the stem 4d up and down. As a result, the opening ratio of the conduit 7 of the plant is determined as the valve body 4c opens and closes the valve seat 4b.

On the other hand, such an air driven valve system needs to carry out an accurate diagnosis on its operating state.

Accordingly, conventionally, the indicator bar 4e mounted on the axis of the stem 4d of the valve 4 has been visually checked to diagnose the state of the valve 4 for the diagnosis of the air-driven valve system. There is a disadvantage that it involves many measurement errors and also cannot analyze the correlation between the air pressure flowing into the drive section 5 and the opening degree of the valve 4 according to the given conditions.

In addition, the conventional diagnosis method of the air-driven valve system has a disadvantage in that it is not possible to analyze how the input / output condition of the valve affects the response characteristics of the valve by simply considering the opening / closing amount of the valve.

The present invention has been made in view of the above, the input and output conditions of the valve (that is, the input power of the current-pressure converter and the air pressure flowing into the drive unit), the opening ratio of the valve, the driving force of the drive unit and the response speed of the valve By comprehensively considering and analyzing the components, the components of the valve system, such as the failure of the driving unit, the sealing failure of the driving unit, the correction of the current-pressure transducer and the positioner, the opening range of the valve, the friction force of the packing and the valve seat, etc. It is an object of the present invention to provide a diagnostic device for an air-operated valve system that can perform a comprehensive diagnosis.

The present invention for achieving the above object, the current-pressure converter for converting the current applied from the valve control unit in the form of a pneumatic signal; A positioner whose opening degree is determined by a pneumatic signal converted in the current-pressure converter; A drive unit through which control air supplied through the positioner flows in and out; A valve consisting of a bonnet mounted on the plant's pipeline, a valve seat provided on the flow path inside the bonnet, a stem installed so as to be movable by the driving unit, and a valve body coupled to the lower end of the stem to open and close the valve seat. Wow; In the air-driven valve system including a control air supply for supplying control air to the drive unit side through the positioner,

The first and second air pressure sensors provided on the supply pipe between the control air supply unit and the driving unit, a strain gauge provided on one stem of the stem of the valve to measure the strain of the stem, and on the other axis of the stem of the valve. Displacement sensor for measuring position displacement, first and second fluid pressure sensors provided respectively at the inlet and outlet side of the pipe line of the plant equipped with the bonnet of the valve, and the flow rate of the fluid flowing in the line installed on the pipe line of the plant And a flow sensor and a temperature sensor for measuring temperature, an air temperature sensor and an air humidity sensor for measuring the temperature and humidity of the control air installed and supplied to the control air supply, and the measured data input from each sensor It includes a control unit for processing.

Preferably, the displacement sensor may be configured to measure the positional displacement of the stem moving up and down via a guide bar clamped in a direction perpendicular to the other axis of the stem.

Preferably, the diagnostic apparatus of the present invention may further include a vibration sensor installed on the valve side and a sound sensor disposed close to the outside of the valve.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 illustrates a diagnostic apparatus of an air driven valve system according to an embodiment of the present invention.

As shown, the present invention is the opening degree is determined by the current-pressure converter (1) for converting the current applied from the valve control unit in the form of a pneumatic signal, and the pneumatic signal converted in the current-pressure converter (1) The positioner 2, the drive unit 5 through which the control air supplied through the positioner 2 flows in and out, the valve 4 driven by the drive unit 5, and the drive unit 5 through the positioner 2. In the air-driven valve system comprising a control air supply unit for supplying control air to the side),

The first and second air pressure sensors 11 and 12 provided on the supply pipes 21 and 22 between the control air supply unit 20 and the driving unit 5 and on one shaft of the stem 4d of the valve 4. A strain gauge 13 for measuring the strain of the stem, a displacement sensor 14 provided on the other axis of the stem 4d of the valve 4, for measuring the displacement of the stem, and a bonnet of the valve 4 Flow in the conduit 7 provided on the conduit 7 of the plant and the first and second fluid pressure sensors 15 and 16 provided on the inlet side and the outlet side of the conduit 7 of the plant equipped with 4a), respectively. Flow rate sensor and fluid temperature sensor (17, 18) for measuring the flow rate and temperature of the fluid, and air temperature sensor and air humidity sensor for measuring the temperature and humidity of the control air supplied to the control air supply unit 20 side 19a, 19b, and a control unit 30 for analyzing the measured data input from each of the sensors 11, 12, 13, 14, 15, 16, 17, 18, 19a, 19b. All.

The first air pressure sensor 11 is installed on the supply pipe 21 between the control air supply unit 20 and the positioner 2 to measure the pressure of the control air supplied from the control air supply unit 20, and the second The air pressure sensor 12 is configured on the supply pipe 22 between the positioner 2 and the drive unit 5 and configured to measure the pressure of the control air flowing into the drive unit 5.

The measured pressure data of the control air is A / D signal converted and transmitted to the control unit 30 side, the control unit 30 diagnoses the pressure state of the control air based on the air pressure data. For example, if the pressure of the air supplied to the driving unit 5 side is excessive, the air pressure will damage the driving unit 5. On the contrary, if the air pressure is too low, opening and closing of the valve 4 may not be performed smoothly. You can diagnose this.

Strain gauge 13 is a strain generated when the stem 4d is moved by the diaphragm 5a of the drive unit 5 installed on one axis of the stem 4d of the valve 4 and operated by the pressure of the control air. and to measure the strain. Here, the strain gauge 13 is measured after the initial value is set by the correction mode of the controller 30 to be described later.

The measured strain data is transmitted to the control unit 30 after A / D signal conversion, and the control unit 30 measures the axial force transmitted from the driving unit 5 in the axial direction of the stem 4d based on the strain data. Done.

On the other hand, the axial force of the stem 4d measured by the strain gauge 13 is changed by the driving force of the driving unit 5, the friction force of the valve seat 4b / packing, the fluid differential pressure, and the like. It will be diagnosed separately according to the diagnosis mode and the dynamic diagnosis mode. Here, the driving force of the drive part 5 is calculated | required from the inflow air pressure and the effective cross-sectional area of the drive part 5, and a fluid differential pressure is measured from the 1st and 2nd fluid pressure sensors 15 and 16 mentioned later.

According to the present invention, the friction force of the valve seat 4b / packing can be analyzed based on the axial force of the stem 4d, the driving force of the driving part 5, and the fluid differential pressure data. Thus, the valve seat 4b can be analyzed. / Features the ability to adjust the friction of the packing.

The displacement sensor 14 is adapted to measure the position displacement of the stem 4d, which swings through the guide bar 27 clamped in a right angle on the other axis of the stem 4d, as shown in FIG. It is composed.

The measured position displacement data is transmitted to the control unit 30 after A / D signal conversion, and the control unit 30 determines whether the opening and closing of the valve operates within the effective range using the lowest value and the highest value of the position displacement data. By determining the start point and the end point of the valve, the movement state of the stem is diagnosed.

On the other hand, the displacement sensor 14 is measured after the initial value is set by the correction mode of the controller 30 to be described later.

As shown in FIG. 3, the displacement sensor 14 may adopt a linear variable differential transformer (LVDT) or a wire type contact sensor or a non-contact sensor such as a laser displacement sensor. .

The first and second fluid pressure sensors 15 and 16 are respectively installed on the inlet side and the outlet side of the plant pipeline 7 on which the bonnet 4a of the valve 4 is mounted, and the fluid flowing into the bonnet 4a. The pressure of the fluid and the pressure of the fluid flowing out of the bonnet 4a are measured.

The measured inflow and outflow pressure data of the fluid is transmitted to the control unit 30 after A / D signal conversion, and the control unit 30 calculates the fluid differential pressure data using the inflow and outflow pressure data of the fluid. The calculated fluid differential pressure data is used in the dynamic diagnosis mode of the controller 30 described later.

On the other hand, such fluid differential pressure data, the resistance due to the differential pressure of the fluid generated on the inlet and outlet side of the valve 4 affects the behavior of the valve, which causes a slow response of the valve or vibration and noise in the valve It may be used as a variable for diagnosing a phenomenon or the like which is caused.

The flow rate sensor and the fluid temperature sensors 17 and 18 are respectively installed on the conduit 7 of the plant to measure the flow rate and the temperature of the fluid flowing into the conduit 7.

The flow rate and temperature data of the fluid thus measured are transmitted to the control unit 30 after A / D signal conversion, and the flow rate and temperature data of the fluid is used in the dynamic diagnosis mode of the control unit 30 to be described later.

Air temperature sensor and air humidity sensor (19a, 19b) is installed on the pipe between the control air supply unit 20 and the regulator 23 to measure the temperature and humidity of the control air supplied, and to measure the temperature and The humidity data is transmitted to the control unit 30 after the A / D signal conversion.

When the humidity of the air flowing into the driving unit 5 changes according to the temperature of the external atmosphere, the driving unit 5 is damaged, and the sealing function of the driving unit 5 is reduced. Therefore, the above temperature and humidity data of the air may be used as a diagnostic parameter of the valve for such a factor.

Preferably, the diagnostic apparatus of the present invention may further include a vibration sensor 25 installed on the side of the valve 4 and a sound sensor 26 disposed close to the outside of the valve 4.

The vibration sensor 25 measures a vibration value generated as the fluid flows into the valve 4, and the measured vibration data is transmitted to the controller 30 after the A / D signal is converted. The acoustic sensor 26 measures high frequency noise generated by cavitation or the like in the valve 4, and the measured acoustic data is transmitted to the controller 30 after A / D signal conversion.

By the vibration and sound sensor 25, 26, it is possible to perform a diagnostic function for the vibration and noise in accordance with the operation of the valve (4).

The control unit 30 is basically configured to process various control signals for driving the valve 4, for example, by converting a control input current into a D / A signal and transmitting the signal to the current-pressure converter 1 for the current. -Drive the pressure transducer (1).

In addition, the controller 30 analyzes the measurement data input from each of the sensors 11, 12, 13, 14, 15, 16, 17, 18, 19a, 19b, 25, and 26 to perform various diagnosis of the valve system. The diagnostic mode of the controller 30 is divided into a correction mode, a static diagnosis mode, and a dynamic diagnosis mode.

The correction mode of the control unit 30 performs a correction function for setting initial values of the displacement sensor 14 and the strain gauge 13, and also through the appropriate correction of the current-pressure converter 1 and the positioner 2. 5) To adjust the air pressure flowing into.

The static diagnosis mode of the controller 30 performs a diagnostic function in a state in which no fluid flows into the bonnet 4a of the valve 4, and the valve 4 by the current input to the current-pressure converter 1 is performed. The diagnostic function is performed by using the relationship between the opening amount of air and the air pressure flowing into the driving unit.

In the dynamic diagnosis mode of the controller 30, a diagnostic function is performed in a state in which fluid flows into the bonnet 4a of the valve 4, and the relationship between the opening amount of the valve 4 and the air pressure flowing into the driving unit 5 is provided. In addition to using the above, the diagnostic function is performed by using the data measured by the above-described fluid pressure sensor 15, 16, flow sensor and fluid temperature sensor 17, 18.

As described above, the present invention uses the data measured by the sensors 11, 12, 13, 14, 15, 16, 17, 18, 19a, 19b, 25, 26 to control the input and output conditions of the valve in the controller 30 ( That is, by analyzing the input power of the current-pressure converter and the air pressure flowing into the driving unit), the opening ratio of the valve, the driving force of the driving unit, and the response speed of the valve, etc. It is characterized by performing a comprehensive diagnosis of each component of the valve system, such as the correction of the current-pressure transducer and the positioner, the opening degree of the valve, the friction force of the packing and the valve seat, and the like.

On the other hand, the present invention is not limited to the air-driven valve system to which the diaphragm-type driving unit shown by way of example in Figures 1 and 2 will be applicable to other types of air-driven valve system.

As described above, the present invention analyzes in consideration of the input and output conditions of the valve (that is, the input power of the current-pressure converter and the air pressure flowing into the driving unit), the opening degree of the valve, the driving force of the driving unit, and the response speed of the valve. By doing so, it is possible to carry out a comprehensive diagnosis of each component of the valve system, such as damage to the drive unit, poor sealing of the drive unit, correction of the current-pressure transducer and positioner, opening range of the valve, friction force of the packing and valve seat, etc. There are advantages to it.

In the above, the present invention has been illustrated and described with respect to certain preferred embodiments. However, the present invention is not limited only to the above-described embodiments, and those skilled in the art to which the present invention pertains may vary without departing from the spirit of the technical idea of the present invention described in the claims below. It may be changed.

1 is a partial cross-sectional view showing an exemplary air-driven valve system to which a general diaphragm type drive unit is applied.

Figure 2 is a conceptual diagram showing a diagnostic apparatus of an air driven valve system according to an embodiment of the present invention.

Figure 3 is an exemplary view showing in detail the displacement sensor portion of the diagnostic device of the present invention.

Explanation of symbols on the main parts of the drawings

11, 12: first and second air pressure sensor

13: strain gauge 14: displacement sensor

15, 16: first and second fluid pressure sensor

17, 18: flow sensor and fluid temperature sensor

19a, 19b: air temperature sensor and air humidity sensor

30: control unit

Claims (3)

A current-pressure converter for converting a current applied from the valve controller into a pneumatic signal; A positioner whose opening degree is determined by a pneumatic signal converted in the current-pressure converter; A drive unit through which control air supplied through the positioner flows in and out; A valve consisting of a bonnet mounted on the plant's pipeline, a valve seat provided on the flow path inside the bonnet, a stem installed so as to be movable by the driving unit, and a valve body coupled to the lower end of the stem to open and close the valve seat. Wow; In the air-driven valve system including a control air supply for supplying control air to the drive unit side through the positioner, First and second air pressure sensors installed on a supply pipe between the control air supply unit and the driving unit; A strain gauge provided on one stem of the stem of the valve and measuring the strain of the stem; A displacement sensor provided on the other axis of the stem of the valve and measuring a displacement of the stem; First and second fluid pressure sensors provided at the inlet and outlet sides of the pipe line of the plant in which the bonnet of the valve is mounted; A flow rate sensor and a fluid temperature sensor for measuring the flow rate and the temperature of the fluid flowing in the pipeline installed on the pipeline of the plant; An air temperature sensor and an air humidity sensor installed at the control air supply unit to measure temperature and humidity of the supplied control air; And a control unit for analyzing and processing the measured data input from each sensor. The method of claim 1, And the displacement sensor is configured to measure a position displacement of the stem moving in and out through a guide bar clamped in a direction perpendicular to the other axis of the stem. The method according to claim 1 or 2, The side of the valve further comprises a vibration sensor, the diagnostic device of the air-driven valve system, characterized in that further comprising a sound sensor disposed close to the outside of the valve.