JP3668169B2 - Control valve operation diagnosis device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a control valve operation diagnostic apparatus suitably used for controlling, for example, a fluid flow, and more particularly to a control valve operation diagnostic apparatus that can perform a control valve failure diagnosis even during operation.
[0002]
[Prior art]
For example, thermal power plants, nuclear power plants, and the like are configured to control the flow rate of a working fluid (for example, steam or high-temperature water) using a plurality of control valves and also control the pressure thereof.
[0003]
A control valve according to this type of prior art includes a valve housing having an inlet and an outlet for a working fluid to be controlled, a valve seat provided between the inlet and the outlet, and the valve housing. A valve body that is slidably provided in the valve seat and communicates with and shuts off the inlet and outlet by being separated from and seated on the valve seat, and is provided in the valve housing away from the valve body according to a command signal Valve driving means for opening and closing the valve body, and driving force transmitting means provided between the valve driving means and the valve body for transmitting a driving force by the valve driving means to the valve body; Command means for outputting a command signal for instructing the opening degree of the valve body to the valve driving means, and an opening degree detecting means for detecting the opening degree of the valve body.
[0004]
In this case, the valve driving means, for example, a spring that normally biases the valve body in the valve closing direction, and a gas pressure such as air supplied from the outside against the biasing force of the spring. The actuator is driven in the valve opening direction, and this actuator generates a driving force that is increased or decreased according to the air pressure when supplied with the air pressure corresponding to the command signal output from the command means.
[0005]
When a command signal for fully closing the valve body is output, since the air pressure supplied to the actuator becomes the minimum pressure, the valve body is urged to the valve closing position by the spring, and the valve is fully closed. Kept in a state. Further, when a command signal for fully opening the valve body is output, the air pressure supplied to the actuator becomes the maximum pressure, so the actuator drives the valve body in the valve opening direction against the biasing force of the spring. Thereby, the valve body is moved to the fully open position.
[0006]
On the other hand, when a command signal for setting the opening of the valve body to an intermediate opening is output, the air pressure supplied to the actuator becomes an intermediate pressure corresponding to the command signal. With the corresponding driving force, the actuator drives the valve body against the spring, so that the valve body has an intermediate force that balances the force in the valve opening direction by the air pressure and the biasing force of the spring (force in the valve closing direction). It is moved to the opening position.
[0007]
The opening degree detecting means sequentially detects the opening degree (including the fully closed state) of the valve body, and the opening and closing control of the valve body is performed with the opening degree corresponding to the command signal by the command means. It is possible to determine whether or not there is.
[0008]
[Problems to be solved by the invention]
By the way, in the above-described prior art, whether or not the opening degree of the valve body is an opening degree corresponding to the command signal by the command means is detected by, for example, an opening degree detection means provided in the valve housing or the like. Therefore, there is a problem that it is difficult to perform operation diagnosis (failure diagnosis) of the control valve during operation.
[0009]
In other words, the valve body slidably provided in the valve housing may gradually wear and damage the sliding surface of the valve body as it is repeatedly opened and closed according to the operation of the control valve. is there. However, even in such a state, as long as the damaged part is small, the valve body is controlled to open and close according to the command signal. There is.
[0010]
In addition, even when a minute foreign object or the like is caught between the valve seat and the valve body when the valve body is closed, it is difficult to detect the entry of the foreign object only by the opening signal from the opening detection means. There is a problem that a deadline (valve closed state) failure cannot be detected at an early stage.
[0011]
In addition, when a sealing failure occurs with respect to the seal member provided between the valve housing and the valve shaft, there is a possibility that the fluid flowing in the valve housing leaks to the outside. However, there is a problem that such a sealing failure cannot be found only by using the opening degree detecting means.
[0012]
The present invention has been made in view of the above-described problems of the prior art, and an object of the present invention is to detect a control valve monitoring diagnosis and the like during operation by detecting an axial load or the like acting on a valve body or a valve shaft. It is an object of the present invention to provide a control valve operation diagnosis device that can be performed and can quickly discriminate a valve element, foreign object biting, sealing failure, and the like.
[0013]
[Means for Solving the Problems]
  In order to solve the above-described problem, the structure adopted by the invention of claim 1 is a valve housing having a fluid inlet and an outlet and a valve seat provided between the inlet and the outlet. And a valve body that is slidably provided in the valve housing and communicates and blocks between the inflow port and the outflow port by being separated and seated on the valve seat, and separated from the valve body, and A valve drive means provided in the valve housing for opening and closing the valve body in accordance with a command signal; and provided between the valve drive means and the valve body; A driving force transmitting means for transmitting to the body; a command means for outputting a command signal for commanding an opening degree of the valve body to the valve driving means; and the driving force transmitting means. Load detecting means for detecting an applied load, and a command signal from the command means. And movement of the valve body is configured to diagnose whether or not normal according to the load detection signal from the load detecting meansAnd the load detection means determines whether the flow of fluid flowing from the inlet to the outlet of the valve housing is normal or not, while holding the valve body at a predetermined opening degree. It is configured to detect pressure fluctuations in the fluid flowing in the valve housing.ing.
[0014]
  With this configuration, the load applied to the driving force transmission means can be detected by the load detection means while the opening degree of the valve body is variably controlled according to the command signal from the command means. By comparing the load detection signal with the command signal and the opening detection signal, it is possible to determine at an early stage whether the movement of the valve body is normal or abnormal.In addition, the load detecting means detects the pressure fluctuation of the fluid flowing from the inlet to the outlet of the valve housing with the valve body held at a predetermined opening degree. From the waveform of the load detection signal output from, it is possible to determine whether the flow of fluid flowing through the valve housing is smooth or whether a pressure fluctuation or the like has occurred.
[0015]
  The invention of claim 2Has a fluid inlet and outlet, a valve housing provided with a valve seat between the inlet and outlet, a valve housing provided in a displaceable manner in the valve housing, A valve body that communicates and blocks between the inflow port and the outflow port by being separated from and seated on the valve seat, and is provided in the valve housing apart from the valve body, and opens the valve body in accordance with a command signal; A valve driving means for driving in the valve closing direction; a driving force transmitting means provided between the valve driving means and the valve body; for transmitting a driving force by the valve driving means to the valve body; and for opening the valve body. Command means for outputting a command signal to command the degree to the valve drive means, load detection means provided in the drive force transmission means for detecting a load applied to the drive force transmission means, andAn opening degree detection means for detecting the opening degree of the valve body, and an opening degree detection signal output from the opening degree detection means;SaidLoad detection signal from load detection means andSaidA control unit to which each command signal from the command means is input, the control unit according to the command signal from the command means, the opening detection signal from the opening detection means, and the load detection signal from the load detection means. Determine whether the valve is moving normallyThe pressure of the fluid flowing from the inlet to the outlet of the valve housing in a state in which the valve body is held at a predetermined opening by an opening detection signal from the opening detector. By detecting the fluctuation by the load detection means, it is determined whether or not the flow of fluid flowing through the valve housing is normal.With a configuration toThatThe
[0016]
  With this configuration, the control unit can automatically determine whether the movement of the valve body is normal or abnormal while comparing the load detection signal with the command signal and the opening detection signal. .In addition, the control unit is a waveform of the load detection signal output from the load detection means for the pressure variation of the fluid flowing from the inlet to the outlet of the valve housing with the valve body held at a predetermined opening degree. Thus, it is possible to determine whether the flow of fluid flowing in the valve housing is smooth or whether pressure fluctuation or the like is occurring.
[0025]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, a control valve operation diagnosis apparatus according to an embodiment of the present invention will be described in detail with reference to FIGS. 1 to 11 of the accompanying drawings.
[0026]
In the figure, reference numeral 1 denotes a control valve employed in the present embodiment, and the control valve 1 includes a valve housing 2, a valve body 7, a drive mechanism 8, a valve shaft 22, a gland packing 23, and the like which will be described later. .
[0027]
Reference numeral 2 denotes a valve housing constituting an outer shell of the control valve 1, and the valve housing 2 includes a valve box 3 disposed in the middle of a flow path of a fluid to be controlled, a valve body guide 4 and a support frame 5 described later. The high-temperature water supply etc. distribute | circulate in the valve box 3 as a control object fluid.
[0028]
The valve box 3 is provided with an inlet 3A and an outlet 3B of the water supply, and a through hole 3C that is positioned between the inlet 3A and the outlet 3B and into which a valve body guide 4 described later is fitted. The partition wall 3D is formed, and the through hole 3C of the partition wall 3D is opposed to the upper and lower sides and has a cylindrical opening 3E formed with a diameter larger than that of the through hole 3C.
[0029]
Reference numeral 4 denotes a cylindrical valve body guide provided in the valve box 3, and the valve body guide 4 is inserted into the valve box 3 from the cylindrical opening 3E side. The valve element guide 4 is positioned in the valve box 3 by fitting one end side of the valve body guide 4 into the through hole 3C and the other end side of the valve body guide 4 to a lid 5A described later. Further, the inner peripheral surface of the valve body guide 4 is a sliding surface 4A for a valve body 7 which will be described later, and an annular valve seat 4B on which the valve body 7 is attached and detached is integrally formed on the lower end side of the sliding surface 4A. ing.
[0030]
The valve body guide 4 is formed with radial flow holes 4C, 4C at positions slightly above the valve seat 4B. These flow holes 4C are opened and closed by the valve body 7, whereby the valve box 3 communicates and blocks between the inlet 3A and the outlet 3B.
[0031]
Reference numeral 5 denotes a support frame provided in the cylindrical opening 3E of the valve box 3, and one end side of the support frame 5 is a lid 5A that closes the cylindrical opening 3E from above, and the center side of the lid 5A Is formed with an insertion hole 5B through which a later-described valve shaft 22 is inserted. A support plate 6 that supports a diaphragm 13 (described later) from below is attached to the other end of the support frame 5 using means such as bolts.
[0032]
Further, guide portions 5C, 5C,... Are provided on the other end side of the support frame 5 below the support plate 6, and each guide portion 5C points to a movable shell 12 described later with an arrow A. , Guide in such a manner that it can move in the B direction (movable up and down).
[0033]
Reference numeral 7 denotes a valve body slidably fitted in the valve body guide 4. The valve body 7 is formed as a covered cylindrical body as shown in FIG. 2, and one end side thereof is separated from the valve seat 4B. By being seated, the inlet 3A and the outlet 3B of the valve box 3 are communicated and blocked via the respective flow holes 4C of the valve body guide 4.
[0034]
Also, the valve body 7 is provided with pressure relief holes 7A, 7A,..., And these pressure relief holes 7A prevent a pressure difference from being generated between the valve body guide 4 and the valve body 7, This compensates for smooth opening and closing of the valve body 7.
[0035]
Reference numeral 8 denotes a drive mechanism as valve drive means provided on the other end side of the support frame 5 so as to be separated from the valve body 7, and the drive mechanism 8 is disposed between a spring receiver 18 and a support plate 6 which will be described later. A spring 9 that normally urges the valve body 7 in the valve closing direction, a pneumatic actuator 10 described later, a positioner 27 described later shown in FIG.
[0036]
Reference numeral 10 denotes a pneumatically operated actuator that drives the valve body 7 against the spring 9 in the valve opening direction. The actuator 10 includes upper and lower movable shells 11 and 12 and an outer peripheral side between the movable shells 11 and 12. And a diaphragm 13 serving as a movable partition wall sandwiched between the two. The diaphragm 13 defines a pressure chamber 14 between the diaphragm 13 and the upper movable shell 11.
[0037]
Here, the movable shells 11 and 12 are arranged so as to surround the support plate 6 on the support frame 5 together with the diaphragm 13 from above and below. The diaphragm 13 has a central portion fixed to the support plate 6 and reinforced (backed up) from the back side by the support plate 6.
[0038]
The lower movable shell 12 is provided with a plurality of insertion holes 12A, 12A,... Through which the respective guide portions 5C of the support frame 5 are inserted, and the movable shell 12 is supported by the support frame 5 through these insertion holes 12A. On the other hand, it is attached along each guide portion 5C so as to be movable up and down. The movable shell 12 has an inner peripheral end fixed to an outer peripheral side of a yoke 16, which will be described later, and moves (upward and downward) in the directions indicated by arrows A and B together with the yoke 16.
[0039]
Reference numeral 15 denotes a gas pressure supply / exhaust port provided in the upper movable shell 11, and an operation air pressure pipe 38, which will be described later, is connected to the supply / exhaust port 15. The air pressure is supplied and discharged. While the air pressure in the pressure chamber 14 is at the minimum pressure, the movable shells 11 and 12 and the yoke 16 are urged by the spring 9 in the direction indicated by the arrow A. As shown, the valve is kept closed.
[0040]
On the other hand, the actuator 10 is supplied with operating air pressure from the supply / exhaust port 15 into the pressure chamber 14 and increases the volume in the pressure chamber 14 as the air pressure increases. Due to the air pressure in the pressure chamber 14, the movable shells 11 and 12 are pushed in the direction of arrow B against the biasing force of the spring 9 together with the yoke 16 and the like, whereby the valve body 7 is moved as shown in FIG. The valve opening is increased.
[0041]
Reference numeral 16 denotes a yoke as a movable frame provided in the support frame 5 so as to be movable up and down. The yoke 16 is formed as a bottomed frame body and covers the spring 9 from the outside in the radial direction. . Further, an axial force sensor 25 (to be described later) is attached together with the valve shaft 22 to the bottom portion 16A side of the yoke 16, and the yoke 16 constitutes a driving force transmission means together with the valve shaft 22.
[0042]
Reference numeral 17 denotes a fixing bolt provided on the bottom portion 16A of the yoke 16, and 18 denotes a spring receiver screwed to the fixing bolt 17 together with a loosening nut 19. The spring receiver 18 loosens the screwing position with respect to the fixing bolt 17. By changing together with the lock nut 19, the biasing force of the spring 9 is variably adjusted.
[0043]
Reference numerals 20 and 21 denote tool insertion holes provided in the support frame 5 and the yoke 16. When the screwing positions of the spring receiver 18 and the locking nut 19 with respect to the fixing bolt 17 are changed in the tool insertion holes 20 and 21, For example, a tool such as a spanner or a wrench is inserted.
[0044]
Reference numeral 22 denotes a valve shaft that constitutes a driving force transmission means together with the yoke 16, and the valve shaft 22 moves upward and downward (in the axial direction) into the insertion hole 5B of the support frame 5 (lid portion 5A) as shown in FIG. The lower end side is connected to the valve body 7 in the valve body guide 4. The upper end side of the valve shaft 22 is connected to the bottom portion 16A of the yoke 16 via an axial force sensor 25 described later. The valve shaft 22 transmits the movement of the yoke 16 to the valve body 7, and opens and closes the valve body 7 upward and downward.
[0045]
23 is a gland packing as a seal member for sealing between the lid portion 5A of the support frame 5 and the valve shaft 22, and the gland packing 23 is mounted in the insertion hole 5B of the lid portion 5A. The outer peripheral surface is in sliding contact with a tightening margin. A gland retainer 24 that holds the gland packing 23 in a retaining state is detachably attached to the lid 5A of the support frame 5.
[0046]
Reference numeral 25 denotes an axial force sensor as a load detecting means provided between the bottom 16A of the yoke 16 and the valve shaft 22, and the axial force sensor 25 is configured by using, for example, a load cell, a strain gauge, etc. The load (for example, the tensile force and the compressive force in the axial direction) applied to is detected as shown in FIGS.
[0047]
Reference numeral 26 denotes an opening degree sensor as opening degree detecting means for detecting the opening degree of the valve body 7, and the opening degree sensor 26 is configured by using, for example, an optical displacement sensor or the like, and is a yoke that is integrally displaced with the valve body 7. 16 or the movement of the movable shells 11 and 12 is detected as a relative displacement amount with respect to the support frame 5 or the support plate 6 (diaphragm 13). FIG. 1 illustrates the case where the opening sensor 26 is provided on the movable shell 11.
[0048]
A positioner 27 for the control valve 1 is provided outside the valve housing 2 as shown in FIG. 3, and is connected to, for example, a pilot pipe 28, an input side pneumatic pipe 29, and an output side pneumatic pipe 30. Has been. The positioner 27 converts the amount of compressed air supplied from the pressure source 31 such as an air compressor or an air tank through the pressure reducing valve 32 and the input side pneumatic piping 29 to the pilot pressure from the pilot piping 28. Corresponding control is performed to increase or decrease, and the controlled air pressure is supplied to the pneumatic piping 30 on the output side.
[0049]
As a result, the positioner 27 proportionally controls the opening degree of the valve body 7 according to a command signal (pilot pressure from the pilot pipe 28) from a command device 34, which will be described later, as indicated by a characteristic line 33 shown in FIG. . That is, the valve body 7 of the control valve 1 is variably controlled in proportion to the command signal as indicated by a characteristic line 33 shown in FIG.
[0050]
Reference numeral 34 denotes a command device as a command means for outputting a command signal for commanding the opening degree of the valve body 7. The command device 34 is a command whose current value is variably set within a range of about 4 to 20 mA (milliampere), for example. The signal is output to an electropneumatic converter 35, a control unit 43 and the like which will be described later.
[0051]
Reference numeral 35 denotes an electropneumatic converter that converts a command signal from the command device 34 into a pilot pressure. The electropneumatic converter 35 converts a low-pressure air pressure supplied from a pressurized air source 31 through a pressure reducing valve 36 into a pilot pipe 28. The pilot pressure at this time is variably adjusted in proportion to the current value of the command signal. Note that the set pressure of the pressure reducing valve 36 is set to a pressure sufficiently lower than the pressure reducing valve 32 (for example, 1/10 or less).
[0052]
37 is a booster relay that multiplies the air pressure from the pneumatic pipe 30 and supplies it to the operation pneumatic pipe 38 side. The booster relay 37 is connected to the branch pipe 39 in order to multiply the air pressure from the pneumatic pipe 30. The branch pipe 39 replenishes the booster relay 37 with the air pressure from the pneumatic pipe 29.
[0053]
The drive mechanism 8 of the control valve 1 is supplied with the increased operating air pressure from the booster relay 37 side through the operating air pressure piping 38 and the supply / exhaust port 15 into the pressure chamber 14 shown in FIG. By expanding and contracting the pressure chamber 14, the yoke 16, the valve shaft 22 and the valve body 7 are driven in the directions indicated by arrows A and B.
[0054]
Reference numerals 40, 41, and 42 denote pressure sensors. Among the pressure sensors 40 to 42, the pressure sensor 40 detects the pressure in the operation pneumatic piping 38, and the pressure sensor 41 detects the pressure in the pneumatic piping 30. The sensor 42 detects the pilot pressure in the pilot pipe 28.
[0055]
43 is a control unit constituted by a microcomputer or the like. The control unit 43 includes an axial force sensor 25, an opening sensor 26, pressure sensors 40, 41 and 42, a command device 34 and the like on the input side as shown in FIG. Connected to the output side are a display 44 such as a display, a printer 45 as a printing machine, a notification device 46 and the like.
[0056]
Here, the control unit 43 displays the command signal output from the command device 34, the opening signal of the valve body 7 output from the opening sensor 26, and the axial force signal output from the axial force sensor 25. As shown in FIGS. 6 to 11, the display 44 is used for display, and these are printed by the printer 45 as necessary.
[0057]
The control unit 43 determines whether the operating state of the control valve 1 is normal or abnormal based on detection signals from the axial force sensor 25, the opening sensor 26, and the pressure sensors 40, 41, and 42 as described later. When (failure diagnosis) is performed and it is determined that there is an abnormality, this is notified by using a notification device 46 such as a warning lamp, a warning buzzer, or a voice synthesizer. The diagnosis result at this time can also be displayed on the screen of the display 44.
[0058]
The operation diagnosis device for the control valve 1 according to the present embodiment has the above-described configuration, and the operation thereof will be described next.
[0059]
First, when the command signal output from the command device 34 is equal to or less than the signal value Sa shown in FIG. 5, the pilot pressure output from the electropneumatic converter 35 shown in FIG. 3 to the pilot pipe 28 is, for example, about atmospheric pressure. Place in low pressure.
[0060]
Then, the positioner 27 of the control valve 1 sets the inside of the pneumatic piping 30 to a low pressure state close to the atmospheric pressure corresponding to the pilot pressure at this time, and the pressure in the operating pneumatic piping 38 via the booster relay 37 is also almost equal. Set to atmospheric pressure. Thereby, the actuator 10 of the drive mechanism 8 is maintained in a minimum pressure state in which the air pressure in the pressure chamber 14 is close to the atmospheric pressure.
[0061]
Therefore, in the drive mechanism 8, the movable shells 11, 12 and the yoke 16 are urged in the direction indicated by the arrow A by the spring 9, and the urging force at this time is applied to the valve body 7 via the axial force sensor 25 and the valve shaft 22. , The valve body 7 is seated on the valve seat 4B of the valve body guide 4 as shown in FIG.
[0062]
Next, when the command signal output from the command device 34 becomes larger than the signal value Sa shown in FIG. 5, the pilot pressure output from the electropneumatic converter 35 shown in FIG. 3 to the pilot pipe 28 is proportional to the command signal. For example, it is set to a pressure state higher than atmospheric pressure.
[0063]
Then, the positioner 27 of the control valve 1 sets the inside of the pneumatic pipe 30 to a pressure state higher than the atmospheric pressure corresponding to the pilot pressure at this time, and the booster relay 37 sets the air amount based on the pressure in the pneumatic pipe 30. And the doubled operating air pressure is supplied into the pressure chamber 14 of the actuator 10 through the operating air pressure pipe 38 and the supply / discharge port 15.
[0064]
As a result, the actuator 10 increases the volume in the pressure chamber 14 in accordance with the air pressure supplied from the supply / exhaust port 15, and the movable shell 11, 12 is moved together with the yoke 16 and the spring 9 by the air pressure in the pressure chamber 14. Push in the direction of arrow B against the urging force. The driving force (pushing force) in the direction indicated by the arrow B is transmitted to the valve body 7 via the axial force sensor 25 and the valve shaft 22.
[0065]
As a result, the valve body 7 is separated from the valve seat 4B of the valve body guide 4 as shown in FIG. And in the state which the valve body 7 opened, water supply flows in the direction of arrow C from the inlet 3A of the valve box 3 toward the outlet 3B, and the flow rate of the water supply is controlled according to the opening degree of the valve body 7. Is done.
[0066]
Further, the opening degree of the valve body 7 is controlled so as to increase or decrease along the characteristic line 33 shown in FIG. 5, and when the signal value of the command signal increases to Sm, the valve body 7 is fully opened. is there.
[0067]
In this case, the opening degree sensor 26 is provided in the control valve 1, and the opening degree sensor 26 determines whether or not the opening degree of the valve body 7 is controlled almost in proportion to the command signal from the command device 34. Can do.
[0068]
Further, whether or not the pilot pressure in the pilot pipe 28 is controlled substantially in proportion to the command signal can be detected by a pressure sensor 42 provided in the middle of the pilot pipe 28.
[0069]
Further, the pressure in the pneumatic piping 30 can be detected by the pressure sensor 41, and the pressure in the operating pneumatic piping 38 can be similarly detected by the pressure sensor 40. Therefore, the pressure in the pneumatic piping 30 and the operating pneumatic piping 38 is controlled by the command. It can be determined whether or not the control is performed in response to the signal and the pilot pressure.
[0070]
However, with only the detection signals from the opening sensor 26 and the pressure sensors 40 to 42, for example, it is difficult to perform an operation diagnosis (failure diagnosis) of the control valve 1 during the operation, and to find the failure location etc. at an early stage. Is real.
[0071]
That is, the valve body 7 slidably provided in the cylindrical valve body guide 4 is repeatedly opened and closed in accordance with the operation of the control valve 1, and the sliding surface 4A of the valve body guide 4 and the valve body 7 During this time, wear and damage may gradually occur, and galling may occur. However, even in such a state, as long as the damaged portion is small, the valve body 7 is controlled to open and close according to the command signal, so that galling of the valve body 7 cannot be detected early.
[0072]
Therefore, in the present embodiment, an axial force sensor 25 is provided as a load detection means between the bottom portion 16A of the yoke 16 and the valve shaft 22, and a tensile force applied in the axial direction of the valve shaft 22 by the axial force sensor 25 is provided. The force or compressive force is detected as shown in FIGS.
[0073]
When the command signal output from the command device 34 is gradually and gradually increased between the minimum signal value Sa and the maximum signal value Sm as indicated by the characteristic line 51 shown in FIG. It was confirmed that the opening degree detection signal output from No. 26 gradually increased substantially corresponding to the command signal as indicated by the characteristic line 52 in FIG. 6, and the opening degree of the valve body 7 gradually increased.
[0074]
At this time, the valve body 7 is lifted in the direction of arrow B as shown in FIG. 2 together with the valve shaft 22 and the yoke 16, and the axial force sensor 25 includes the sliding surface 4 A of the valve body guide 4 and the valve body 7. The axial force (thrust force) in the pulling direction acts due to the sliding resistance acting between them. For this reason, the axial force detection signal output from the axial force sensor 25 is detected as an almost constant output value in the pulling direction (positive direction) as indicated by the characteristic line 53 in FIG.
[0075]
However, when the sliding surface of the valve element 7 is worn or damaged, the axial force detection signal temporarily increases at time tx illustrated in FIG. It can be detected that the sliding resistance acting with the body 7 is partially increased.
[0076]
In addition, when galling or the like does not occur, the axial force detection signal maintains a substantially constant output value like the characteristic line 53 as shown by a characteristic line 54 indicated by a one-dot chain line in FIG. Thus, by using the axial force sensor 25, it is possible to detect early whether or not galling due to wear, damage or the like has occurred between the valve element 7 and the valve element guide 4.
[0077]
Next, as indicated by the characteristic line 61 shown in FIG. 7, the command signal output from the command device 34 is set to an arbitrary signal value Si (Sa) between the minimum signal value Sa and the maximum signal value Sm at time ta1. When it is reduced from <Si <Sm) to the minimum signal value Sa, the valve element 7 is driven by the spring 9 toward the fully closed side with a slight time delay.
[0078]
Therefore, the opening degree detection signal output from the opening degree sensor 26 changes in the fully closed direction from time ta2 to ta3 with a slight delay from time ta1 as shown by the characteristic line 62 in FIG. In this case, when the valve element 7 is not closed and no foreign matter is caught between the valve seat 4B and the valve body 7 is closed, the opening degree detection signal is completely transmitted to the fully closed position as shown by a characteristic line 63 shown by a one-dot chain line in FIG. Will move to.
[0079]
However, if the foreign matter at this time is very small, there is almost no difference between the characteristic lines 62 and 63, and therefore the presence or absence of foreign matter is determined by the opening degree detection signal output from the opening degree sensor 26. That is often difficult.
[0080]
On the other hand, the axial force detection signal output from the axial force sensor 25 is the sliding of the valve body guide 4 during the time ta2 to ta3 when the valve body 7 starts to move in the valve closing direction as indicated by the characteristic line 64 in FIG. Under the influence of the static friction force f1 acting between the surface 4A and the valve body 7, it changes greatly from the pulling direction (positive direction) to the compression direction (negative direction), and thereafter, under the influence of the dynamic friction force f2. Outputs axial force in the compression direction.
[0081]
When the time ta3 is reached, the valve body 7 outputs a force f3 (foreign matter biting force) in the compression direction by biting the foreign matter with the valve seat 4B. As a result, it is possible to detect, for example, as a force f3 in the compression direction, whether or not a foreign body is caught between the valve body 7 and the valve seat 4B when the valve body 7 is closed. It can be determined early.
[0082]
In this case, although the opening degree detection signal (characteristic line 62) from the opening degree sensor 26 becomes a substantially constant value after the time ta3, the valve closing of the valve body 7 is detected. Since the axial force detection signal detects the force f3 in the compression direction, it is possible to reliably determine the presence or absence of foreign matter even if it is a small foreign matter.
[0083]
Next, as indicated by the characteristic line 71 shown in FIG. 8, the command signal output from the command device 34 is set to an arbitrary signal value Sj (Sa) between the minimum signal value Sa and the maximum signal value Sm at time tb1. Even when the signal value Sa is decreased from <Sj <Sm) to the minimum signal value Sa, the valve body 7 is driven by the spring 9 toward the fully closed side with a slight time delay.
[0084]
A sliding resistance is added to the valve shaft 22 that is displaced integrally with the valve body 7 in the valve closing direction (the direction indicated by arrow A in FIG. 2) by the gland packing 23, and the tightening margin (frictional force) of the gland packing 23 ) Causes a time difference between times T1 and T2 (T1 <T2) until the valve body 7 is fully closed.
[0085]
For this reason, when the frictional force of the gland packing 23 is small as shown by the characteristic line 72 shown by the solid line in FIG. When the frictional force of the gland packing 23 is increased, the time T2 until it is fully closed becomes longer as indicated by a characteristic line 73 indicated by a one-dot chain line in FIG.
[0086]
However, it is difficult to determine the sealing property (presence or absence of leakage) by the gland packing 23 only by comparing the times T1 and T2 based on such an opening detection signal, and the closing force of the valve body 7 (the shut-off for the valve seat 4B). It is difficult to determine whether or not (force) is set within a specified range.
[0087]
On the other hand, the axial force detection signal output from the axial force sensor 25 is grounded when the valve body 7 starts to move in the valve closing direction after the time tb1 as shown by a characteristic line 74 shown by a solid line in FIG. The frictional force F1 as the dynamic frictional resistance by the packing 23 can be directly detected and output, and when the valve body 7 reaches the fully closed position, the valve closing force F2 can be directly output.
[0088]
Further, when the tightening allowance is excessive due to the hardening of the gland packing 23 or the like, the frictional force F3 of the gland packing 23 is output by the axial force detection signal as shown by a characteristic line 75 shown by a one-dot chain line in FIG. The valve closing force F4 can also be detected directly.
[0089]
When the frictional force F1 is smaller than the reference value, the allowance for the gland packing 23 is reduced, the sealing performance is lowered, and fluid leaks from the valve shaft 22 and the gland packing 23 (valve box 3 There is a possibility that leakage of the feed water flowing inside), so that the occurrence of the leakage can be diagnosed at an early stage and the replacement timing of the gland packing 23 can be notified using, for example, the notification device 46 or the like.
[0090]
Further, by determining whether or not the valve closing force F2 is within a predetermined closing force range, it is possible to determine whether or not the urging force of the spring 9 is set to a normal spring force.
[0091]
When adjusting the urging force of the spring 9, the tool is inserted through the tool insertion holes 20 and 21 shown in FIG. 1, and the screwing position of the spring receiver 18 and the locking nut 19 to the fixing bolt 17 is changed. The urging force can be easily adjusted.
[0092]
On the other hand, even when it is determined that the frictional force F3 by the characteristic line 75 is excessive, it is a case where the gland packing 23 is hardened due to deterioration over time or the like. The replacement time of the gland packing 23 can be notified using 46 or the like.
[0093]
Further, when it is determined that the valve closing force F4 is too small, there is a risk of fluid leakage between the valve body 7 in the closed state and the valve seat 4B. Since the cut-off force of the body 7 is small, it is possible to notify that in this case as well, the work for adjusting the biasing force of the spring 9 should be performed early as described above.
[0094]
Next, as indicated by the characteristic line 81 shown in FIG. 9, the command signal output from the command device 34 is a signal from an arbitrary signal value Sk2 between the minimum signal value Sa and the maximum signal value Sm at time tc1. When the value is reduced to the value Sk1 (Sa <Sk1 <Sk2 <Sm), the valve element 7 is driven in the valve closing direction with a slight time delay, and the urging force of the spring 9 and the air pressure in the pressure chamber 14 are balanced. The valve body 7 stops at the intermediate opening position.
[0095]
The opening degree detection signal output from the opening degree sensor 26 should be kept substantially constant at an intermediate opening position as indicated by a characteristic line 82 indicated by a one-dot chain line in FIG. However, when the gland packing 23 is hardened and the sliding resistance (frictional force) applied to the valve shaft 22 becomes excessive, the opening detection signal has a long cycle as indicated by a characteristic line 83 shown by a solid line in FIG. The valve body 7 may vibrate and continue to move up and down slowly in the vicinity of the intermediate opening.
[0096]
Further, in the case where the air pressure supplied to and discharged from the pressure chamber 14 of the drive mechanism 8 is reversed excessively (sensitively) due to abnormalities in the positioner 27, the booster relay 37, etc. shown in FIG. The opening degree detection signal vibrates at a short cycle as indicated by the characteristic line 84 indicated by a two-dot chain line, and the valve body 7 frequently repeats upward and downward movements near the intermediate opening degree.
[0097]
In such a case, when the axial force detection signal from the opening sensor 26 vibrates with a long period along the characteristic line 85 shown by a solid line in FIG. Can detect and output overload. Further, when the axial force detection signal vibrates in a short surrounding like the characteristic line 86 indicated by a two-dot chain line, it can be determined early that the positioner 27, the booster relay 37, etc. shown in FIG. 3 are not operating normally.
[0098]
Next, when the command signal output from the command device 34 is changed so as to draw a sine curve (sine wave) as shown by the characteristic line 91 shown in FIG. As shown, the intermediate opening changes to move up and down and fluctuates substantially following the command signal.
[0099]
At this time, the axial force detection signal also fluctuates following the command signal as indicated by a characteristic line 93 in FIG. However, in the vicinity of the times td1, td2, td3, and td4 corresponding to the inflection points of the command signal, fluctuations (small mountain-shaped vibrations) may occur in the axial force detection signal.
[0100]
Accordingly, when the state of the operating air pressure (the air pressure in the operating air pressure piping 38) in such a case is examined, supply shortage occurs in the air pressure supplied from the booster relay 37 to the operating air pressure piping 38 side, for example, the operating air pressure It was confirmed that this was a case where a failure occurred in the piping 38 and the like.
[0101]
As a result, it is possible to quickly detect an insufficient operating air pressure on the operating air pressure piping 38 side using the axial force detection signal. Even in such a case, the detection signal from the axial force sensor 25 can quickly detect an insufficient operating air pressure. Measures can be taken.
[0102]
Next, as indicated by the characteristic line 101 shown in FIG. 11, the command signal output from the command device 34 is converted into an arbitrary signal value Sl (Sa <Sl <<) between the minimum signal value Sa and the maximum signal value Sm. In the state maintained at Sm), the opening degree of the valve element 7 is also held at an intermediate opening degree corresponding to the signal value Sl, and the opening degree detection signal is kept substantially constant as shown by the characteristic line 102.
[0103]
In this case, an axial force detection signal is also output as indicated by the characteristic line 103. However, for example, when the axial force detection signal changes in a peak shape at times te1, te2, etc., shock pressure fluctuations or the like occur in the water supply flowing in the valve box 3 when the valve body 7 is at an intermediate opening. It can be detected as occurring, and for example, it can be determined whether or not the flow state of the feed water flowing through the main feed water control valve 1 of the nuclear power plant is normal.
[0104]
That is, when the water supply is continuously flowing in the direction of arrow C from the inlet 3A to the outlet 3B of the valve box 3 with the valve body 7 opened as shown in FIG. While the water supply flow is smooth, the axial force acting on the valve body 7, the valve shaft 22 and the like is kept constant. However, when the flow of the water supply fluctuates for some reason and an impact pressure or the like is generated, the axial force acting on the valve body 7, the valve shaft 22, etc. changes instantaneously, for example, as shown by the characteristic line 103. It can be inferred that the axial force detection signal has changed to a peak at te1, te2, etc.
[0105]
Therefore, according to the present embodiment, the axial force sensor 25 is used to detect the axial tensile force, compressive force, etc. acting on the valve body 7 and the valve shaft 22, thereby monitoring the control valve 1 and operating diagnosis. Can be performed in the middle of the operation, and galling of the valve body 7, foreign matter biting, seal failure, etc. can be determined at an early stage.
[0106]
Further, the sliding resistance of the gland packing 23 with respect to the valve shaft 22 can be detected as the frictional forces F1, F3, etc. shown in FIG. Is hardened, the sliding resistance is increased, and whether or not the closing force of the valve body 7 by the spring 9 is reduced can be diagnosed during the operation of the control valve 1.
[0107]
Furthermore, it is possible to detect at an early stage whether the control of the operating air pressure by the positioner 27 and the booster relay 37 is normal, whether the condition of the water supply flowing through the valve box 3 is normal, and promptly deal with when an abnormality occurs. can do.
[0108]
In the above embodiment, the control valve 1 used in a nuclear power plant or the like has been described as an example. However, the present invention is not limited to this, and for example, a control valve used in a petrochemical complex, a chemical plant, or a refinery. The present invention can also be applied to control valves that control the flow of various fluids, etc., and failure diagnosis can be performed early during the operation.
[0109]
In the above embodiment, the control valve 1 of the type in which the valve body 7 is urged in the valve closing direction by the spring 9 has been described as an example. However, the present invention is not limited to this, for example, a gas pressure such as air pressure. When the valve body is driven in the valve closing direction using the valve, and the valve body is opened, the valve body may be applied to a control valve that lowers the gas pressure and biases the valve body in the valve opening direction by a spring.
[0110]
In the above embodiment, the control valve 1 in which the feed water flows in the direction indicated by the arrow C from the inlet 3A to the outlet 3B of the valve box 3 has been described as an example. However, the present invention is not limited to this. For example, it is good also as a structure which a fluid flows in the reverse direction to the arrow C direction shown in FIG.
[0111]
Further, in the above-described embodiment, it has been described that the urging force of the spring 9 is variably adjusted using the spring receiver 18 and the locking nut 19 or the like. There is nothing.
[0112]
【The invention's effect】
  As described in detail above, according to the first aspect of the present invention, the command means for outputting the command signal for commanding the opening degree of the valve body to the valve driving means, and the load applied to the driving force transmitting means. Load detecting means for detecting, etc., and diagnosing whether or not the movement of the valve body is normal according to the command signal from the command means and the load detection signal from the load detection means.And the load detection means determines whether the flow of fluid flowing from the inlet to the outlet of the valve housing is normal or not, while maintaining the valve body at a predetermined opening degree. It is configured to detect pressure fluctuations of the fluid flowing in the housing.Therefore, the load applied to the driving force transmission means can be detected by the load detection means while the opening degree of the valve body is variably controlled according to the command signal from the command means, and the load detection signal is compared with the command signal. By doing so, it is possible to diagnose and discriminate early whether the movement of the valve body is normal or abnormal. Therefore, by detecting the axial load acting on the valve body, valve shaft, etc., control valve monitoring, operation diagnosis, etc. can be performed during operation, valve body caulking, foreign object biting, poor seal, etc. Can be determined early.Moreover, since the load detection means detects the pressure fluctuation of the fluid flowing in the valve housing while the valve body is held at a predetermined opening, the load detection signal waveform output from the load detection means is used. It is possible to determine whether the flow of fluid flowing in the valve housing is smooth or whether pressure fluctuations are occurring, and it is possible to continue monitoring the flow of fluid from the outside while the control valve is operating.
[0113]
  The invention according to claim 2 includes an opening degree detecting means for detecting an opening degree of the valve body and a control unit, and the control unit is configured to control the valve according to a command signal, an opening degree detection signal, and a load detection signal. Since it is configured to determine whether or not the body movement is normal, by using the control unit, the movement of the valve body is normal while comparing the load detection signal with the command signal and the opening detection signal. Or whether it is abnormal can be automatically determined.In addition, the control unit is configured to change the pressure of the fluid flowing from the inlet to the outlet of the valve housing in a state where the valve body is held at a predetermined opening by an opening detection signal from the opening detector. Is detected by the load detecting means to determine whether or not the flow of the fluid flowing through the valve housing is normal. Therefore, the waveform of the load detection signal output from the load detecting means It is possible to determine whether the flow of the fluid flowing through the housing is smooth or whether a pressure fluctuation or the like has occurred, and the flow of the fluid can be continuously monitored from the outside while the control valve is operated.
[Brief description of the drawings]
FIG. 1 is a longitudinal sectional view showing a closed state of a control valve provided with an operation diagnosis device according to an embodiment of the present invention.
FIG. 2 is an enlarged cross-sectional view of a main part showing the control valve of FIG. 1 in an open state.
FIG. 3 is a control circuit diagram of the control valve shown in FIG. 1;
FIG. 4 is a control block diagram showing a control valve operation diagnosis device;
FIG. 5 is a characteristic diagram showing a relationship between a command signal and a valve opening degree of a control valve.
FIG. 6 is a characteristic diagram showing a command signal, an opening detection signal, and an axial force detection signal in a state where galling occurs in the valve body.
FIG. 7 is a characteristic diagram showing a command signal, an opening degree detection signal, and an axial force detection signal in a state where biting of foreign matter has occurred.
FIG. 8 is a characteristic diagram showing a command signal, an opening detection signal, and an axial force detection signal in a state where the frictional force due to the gland packing is changed.
FIG. 9 is a characteristic diagram showing a command signal, an opening degree detection signal, and an axial force detection signal when the gland packing is hardened or the operating air pressure varies.
FIG. 10 is a characteristic diagram showing a command signal, an opening degree detection signal, and an axial force detection signal when the operating air pressure is insufficient.
FIG. 11 is a characteristic diagram showing a command signal, an opening detection signal, and an axial force detection signal in a state where the pressure of the feed water flowing through the control valve fluctuates.
[Explanation of symbols]
1 Control valve
2 Valve housing
3 Valve box
4 Valve body guide
4A Sliding surface
4B Valve seat
5 Support frame
6 Support plate
7 Disc
8 Drive mechanism (valve drive means)
9 Spring
10 Actuator
11,12 Movable shell
13 Diaphragm
14 Pressure chamber
16 York
22 Valve shaft (drive force transmission means)
23 Gland packing (seal member)
25 Axial force sensor (load detection means)
26 Opening sensor (opening detection means)
27 Positioner
28 Pilot piping
29,30 Pneumatic piping
31 Pressure source
32, 36 Pressure reducing valve
34 Command device (command means)
35 Electropneumatic converter
37 Booster Relay
38 Operating pneumatic piping
40, 41, 42 Pressure sensor
43 Control unit
44 Display
46 Notification device

Claims (2)

A valve housing having a fluid inlet and outlet, and a valve seat provided between the inlet and outlet;
A valve body that is displaceably provided in the valve housing and communicates and blocks between the inflow port and the outflow port by being separated from and seated on the valve seat;
Valve drive means provided in the valve housing apart from the valve body, for driving the valve body in a valve closing direction according to a command signal;
A driving force transmitting means provided between the valve driving means and the valve body, for transmitting a driving force by the valve driving means to the valve body;
Command means for outputting a command signal for commanding the opening of the valve body to the valve drive means;
A load detecting means provided in the driving force transmitting means for detecting a load applied to the driving force transmitting means;
According to a configuration for diagnosing whether or not the movement of the valve body is normal according to a command signal from the command means and a load detection signal from the load detection means ,
The load detecting means determines whether the fluid flowing from the inlet to the outlet of the valve housing is normal or not while maintaining the valve body at a predetermined opening degree. operation diagnosis device configuration as to become the control valve for detecting the pressure fluctuations of the fluid flowing through the housing. A valve housing having a fluid inlet and outlet, and a valve seat provided between the inlet and outlet;
A valve body that is displaceably provided in the valve housing and communicates and blocks between the inflow port and the outflow port by being separated from and seated on the valve seat;
Valve drive means provided in the valve housing apart from the valve body, for driving the valve body in a valve closing direction according to a command signal;
A driving force transmitting means provided between the valve driving means and the valve body, for transmitting a driving force by the valve driving means to the valve body;
Command means for outputting a command signal for commanding the opening of the valve body to the valve drive means;
A load detecting means provided in the driving force transmitting means for detecting a load applied to the driving force transmitting means;
An opening degree detecting means for detecting the opening degree of the valve body ;
And a control unit for opening detection signal outputted from said opening detection means, the command signal from the load detection signal and the command means from said load detecting means are input,
The control unit determines whether the movement of the valve body is normal according to a command signal from the command means, an opening detection signal from the opening detection means, and a load detection signal from the load detection means ,
In addition, the control unit is configured to change the pressure of the fluid flowing from the inlet to the outlet of the valve housing in a state where the valve body is held at a predetermined opening by an opening detection signal from the opening detector. the load by detecting by the detection means, the valve operation diagnosis device name Ru system valve as a fluid flow it is determined whether or not the normal flow in the housing.

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