JPH1137391A - Diagnosis device for trap and valve - Google Patents

Abstract

PROBLEM TO BE SOLVED: To diagnose a trap and a valve by one device. SOLUTION: Ultrasonic vibration and casing surface temperatures of a trap and a valve as diagnosis objects are measured by a probe 10, and vibration data and temperature data obtained by the measuring are treated by a CPU 23 in a device main body 20. In the CPU 23, each datum from the probe 10 is processed in compliance with a program for diagnosis the trap 24a in a memory unit 24 when a diagnosis object is the trap, and thereby, correct trap diagnosis is realized. On the other hand, when the diagnosis object is the valve, the CPU 23 processes each datum from the probe 10 in compliance with a program for diagnosing the valve 24b to realized diagnosis of the valve. Each program 24a and 24b is switched in compliance with a control program 24c by the CPU 23.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a diagnostic device used for diagnosing traps and valves provided in a piping system of a steam plant or the like, and more particularly, to a diagnostic device provided with a bypass pipe for bypassing a trap. The present invention relates to a diagnostic device suitable for diagnosing a trap and a valve in a piping system.

[0002]

2. Description of the Related Art As a piping system of a steam plant having the above-mentioned bypass pipe, there is, for example, one shown in FIG. In the figure, reference numeral 1 denotes a main pipe having a steam trap 2 and the steam trap 2 in the main pipe 1.
On both sides, for example, one manual opening / closing valve 3, 4 is provided in series with the trap 2, respectively. And
In the figure, reference numeral 5 denotes the bypass pipe. The bypass pipe 5 is in a state of bypassing the series piping system composed of the trap 2 and the valves 3 and 4, that is, the traps 2 of the valves 3 and 4 are connected. The main pipe 1 is connected to the opposite side of the main pipe 1 so as to be directly connected to each other. In the bypass pipe 5, for example, one manual opening / closing valve 6 is provided.

In such a piping system, the plant is normally operated with the valves 3 and 4 in the main pipe 1 opened and the valve 6 in the bypass pipe 5 (hereinafter referred to as a bypass valve) closed. Let it. In this case, the steam flows through the main pipe 1 via the valve 3, the trap 2, and the valve 4, for example, as shown by a dashed line arrow in FIG. Therefore,
When condensed water or condensed water (drain) is generated in the main pipe 1, these are automatically discharged by the trap 2.

On the other hand, when an abnormality such as a steam leak occurs in the trap 2 and the trap 2 must be repaired or replaced, the valves 3 and 4 in the main pipe 1 are closed, and the bypass valve 6 is closed. Open. As a result, the steam does not flow to the trap 2 side but flows around the bypass pipe 5 side, as shown by the dotted arrow in FIG. In this case, although the condensed water discharge operation and the condensed water discharge operation by the trap 2 cannot be obtained, at least the operating state of the plant is maintained. Therefore, the trap 2 can be repaired or replaced without stopping the operation of the plant.

[0005] By the way, as a diagnostic device for diagnosing the above-mentioned abnormality such as steam leakage in the trap 2, there is a conventional diagnostic device as shown in FIG. 5, for example. This is because when a vapor leak occurs in the trap 2 (not shown in the figure), ultrasonic vibration is generated in the trap 2 (casing) itself, and the magnitude of the ultrasonic vibration is increased. That is, it utilizes the fact that the vibration level correlates with the amount of steam leakage. That is, the vibration level of the ultrasonic vibration is measured, and from the correlation between the measured vibration level and the amount of steam leakage, it is determined whether or not steam is leaking in the trap 2 and steam is leaking. In such a case, the degree of the leakage is automatically determined.

It is known that the correlation between the vibration level and the amount of steam leakage strictly changes according to the steam pressure in the trap 2. Therefore, in this device,
The steam pressure in the trap 2 is also taken into account as a parameter in the correlation between the vibration level and the amount of steam leakage. That is, when diagnosing trap 2,
While detecting the ultrasonic vibration, the trap 2 (housing)
Also detects the surface temperature. Then, the saturated steam pressure is obtained from the detected temperature, the saturated steam pressure is set as the steam pressure in the trap 2, and from the correlation between the vibration level and the steam leakage amount using the steam pressure as a parameter,
It is determined whether or not a steam leak has occurred in the trap 2 and the degree of the steam leak.

In order to realize this, this diagnostic device
A probe 10 for detecting a vibration level of the ultrasonic vibration and a housing surface temperature of the trap 2;
The apparatus main body 20 automatically determines the presence / absence of the steam leak from the trap 2 and the degree of the leak based on the vibration level and the surface temperature detected by the detection of zero.

That is, the probe 10 has a vibration detector (not shown) at its tip for detecting the ultrasonic vibration.
And a temperature detector (not shown) for detecting the surface temperature of the housing. Each of these detectors is attached to the surface of the housing of the trap 2 to be diagnosed by the probe 10.
For the first time, the ultrasonic vibration and the surface temperature of the housing are detected by pressing the tip of the sensor, and a detection signal corresponding to these is output. The detection signal is transmitted to the cable 11
Is supplied to the apparatus main body 20 via the.

The apparatus main body 20 has a CPU 23 to which so-called vibration data and temperature data obtained by amplifying the supplied detection signal by an amplifier 21 and digitizing the amplified signal by an A / D converter 22 are inputted. I have. The CPU 23 processes the input data based on the above-described correlation stored in the storage unit 24 having, for example, a ROM or a RAM. Then, it is automatically determined whether or not a steam leak has occurred in the trap 2 to be diagnosed, and if a steam leak has occurred, the degree of the leak of the apparatus is automatically determined. The result is displayed on the display unit 25 having a liquid crystal panel configuration, for example. At the same time, the CPU 23 temporarily stores (stores) the diagnosis result in the storage unit 24. The contents stored in the storage unit 24 can be confirmed (called) at any time.

Further, the CPU 23 is capable of communicating with, for example, a host computer (not shown) via the input / output interface 26. Therefore, for example, the CPU 23
(Or the diagnosis result temporarily stored in the storage unit 24) can be transferred to the host computer side, and the host computer side can collect and analyze the result in more detail.

In this diagnostic apparatus, as described above, when a leak occurs in the trap 2, the amount of the leak is determined using the steam pressure in the trap 2 (the surface temperature of the casing of the trap 2) as a parameter. The diagnosis of the trap 2 is performed by utilizing the correlation with the vibration level of the sound wave vibration. It is known that the correlation differs depending on the standard (model name) of the trap 2 to be diagnosed. . Therefore, a plurality of correlations (correlation data) corresponding to various standards of the trap 2 are stored in the storage unit 24 that stores the correlation. Then, when diagnosing the trap 2, from among the plurality of correlation data, the one corresponding to the standard of the trap 2 to be actually diagnosed is selected, and the diagnosis is performed based on the selected correlation data. It is necessary to realize accurate trap diagnosis for the first time. At this time, selection of which correlation data is to be used for the diagnosis is made by operating the operation unit 27 having a plurality of push buttons (keys), for example.
3 processes the above-described vibration data and temperature data based on the selected correlation data.

According to the diagnostic apparatus, the trap 2
Although the steam pressure in the trap 2 is indirectly determined by detecting the surface temperature of the casing, when the exact steam pressure in the trap 2 is known, the steam pressure is
What is necessary is just to input directly from the operation part 27. Thus, the CPU 23 determines the steam pressure of the trap 2 from the accurate steam pressure directly input from the operation unit 27 and the vibration data, instead of the steam pressure indirectly obtained from the casing surface temperature of the trap 2. Since the presence or absence of the leakage and the degree of the leakage are determined, more accurate diagnosis can be realized. In addition, each procedure for realizing these accurate diagnosis (that is, selecting the correlation data according to the standard of each trap 2 and directly inputting the value if the accurate steam pressure is known) ) Is not directly related to the gist of the present invention, and will not be described in further detail. A series of operations of the CPU 23 is controlled according to a control program stored in the storage unit 24.

As described above, there is a dedicated diagnostic device for the trap 2. However, the bypass valve 6 provided as a pair with the trap 2 has not conventionally been diagnosed. Therefore,
Conventionally, there has been no diagnostic device that exclusively diagnoses the bypass valve 6.

[0014]

That is, the problem to be solved by the present invention is that there is no device for diagnosing the bypass valve 6 exclusively. Therefore, an object of the present invention is to provide a diagnostic device that can diagnose not only the trap 2 but also the bypass valve 6 with a single device. It is another object of the present invention to provide a diagnostic apparatus particularly suitable for alternately diagnosing the trap 2 and the bypass valve 6 alternately.

[0015]

In order to achieve the above-mentioned object, the invention according to claim 1 of the present invention provides a trap diagnostic procedure used when diagnosing a trap as a diagnostic object, and a diagnostic procedure. A valve diagnosis procedure used when diagnosing a valve as an object; storage means in which a valve diagnosis procedure is stored in advance; and selection means for selecting one of the above diagnosis procedures in accordance with a procedure selection command given from outside. And diagnostic means for diagnosing the diagnostic object based on the diagnostic procedure selected by the selecting means.

The above-mentioned trap refers to, for example, a steam trap provided in a piping system of a steam plant, or an air trap or a gas trap provided in a piping system of compressed air or gas. In addition, the above valves include an automatic control valve, a pressure control valve, and the like, in addition to the above-described manual opening / closing valve.

According to the first aspect of the present invention, the storage means stores in advance a trap diagnosis procedure for trap diagnosis and a valve diagnosis procedure for valve diagnosis. When diagnosing a trap, if a procedure selection command for selecting a trap diagnosis procedure is given from the outside, the selection means selects the trap diagnosis procedure, and the diagnosis means operates according to the selected trap diagnosis procedure. The diagnosis of the trap is performed. On the other hand, when diagnosing a valve, if a procedure selection command for selecting a valve diagnosis procedure is given from the outside, the selection means selects the valve diagnosis procedure, and the diagnosis means selects the valve diagnosis procedure according to the selected valve diagnosis procedure. The diagnosis of the valve is performed.

According to a second aspect of the present invention, a trap diagnostic procedure used when diagnosing a trap as a diagnostic object and a valve diagnostic procedure used when diagnosing a valve as a diagnostic object are stored in advance. Storage means, a selection means for selecting one of the diagnosis procedures according to a procedure selection command given from the outside, and a diagnosis of the diagnosis object based on the diagnosis procedure selected by the selection means. And a predetermined number of times, for example, once, of the diagnosis of the diagnosis target based on the diagnosis procedure selected by the selection means, and then the diagnosis of the diagnosis target based on the other diagnosis procedure. Is performed a predetermined number of times, for example, once, and a second diagnosis is performed in which the above-described diagnosis is performed while automatically switching the respective diagnosis procedures each time the diagnosis is performed once. And diagnostic means for diagnosing the diagnostic object in accordance with one of the first and second diagnostic modes in response to an externally provided mode selection command. Things.

According to the second aspect of the present invention, the storage means stores in advance a trap diagnosis procedure for trap diagnosis and a valve diagnosis procedure for valve diagnosis. When only a trap is diagnosed as a diagnostic object, for example, a procedure selection command for selecting a trap diagnosis procedure may be given from the outside, and a mode selection command for selecting the first diagnosis mode may be given. . by this,
The selection means selects a trap diagnosis procedure, and the diagnosis means
According to the selected trap diagnosis procedure, the diagnosis of the trap is performed.

On the other hand, when diagnosing only a valve as an object to be diagnosed, for example, a procedure selection command for selecting a valve diagnosis procedure is given from outside, and a mode selection command for selecting the first diagnosis mode is issued. Just give it. Thus, the selection means selects the valve diagnosis procedure, and the diagnosis means performs the diagnosis of the valve according to the selected valve diagnosis procedure.

Further, when diagnosing both the trap and the valve, if the object to be diagnosed first, for example, this is a trap, a trap diagnosis procedure for this trap diagnosis is selected from outside. It is sufficient to give a procedure selection command and a mode selection command to select the second diagnostic mode. This allows the selection means
A trap diagnosis procedure is selected, and the diagnosis means diagnoses the trap according to the selected trap diagnosis procedure. Then, after this, the diagnosis unit performs the valve diagnosis according to the other diagnosis procedure (not selected by the selection unit), that is, the valve diagnosis procedure. From then on, the trap diagnosis based on the trap diagnosis procedure,
Diagnosis of the valve based on the valve diagnosis procedure is performed alternately. If it is desired to diagnose a valve first, a procedure selection command for selecting a valve diagnosis procedure for valve diagnosis may be given from outside.

That is, if the mode selection command is given in accordance with a case where either one of the trap and the valve is continuously diagnosed and a case where both the trap and the valve are alternately diagnosed, the above-mentioned respective diagnoses can be performed. The diagnostic procedure to be used is set automatically.

According to a third aspect of the present invention, in the trap and valve diagnostic apparatus according to the first or second aspect of the present invention, the diagnostic means includes a vibration detecting means for detecting a vibration occurring in the diagnostic object itself. Processing means for receiving a vibration detection signal detected and detected by the vibration detection means, and processing the input vibration detection signal based on a diagnosis procedure which is actually used for diagnosis among the above diagnosis procedures; Wherein the trap diagnostic procedure determines in the processing means a correlation between a leakage amount of a fluid to be controlled by the trap stored in advance and a magnitude of vibration generated in the trap itself due to the leakage. Processing the vibration detection signal based on the vibration detection signal to derive the amount of leakage of the fluid. That it is configured to a state to derive the magnitude of the vibration, and is characterized in.

The above-mentioned fluid indicates steam if the trap and the valve are provided, for example, in a piping system of a steam plant, and if the fluid is provided in a compressed air or gas piping system. Refers to compressed air or gas.

According to the third aspect of the present invention, the procedure for diagnosing the trap is such that when a fluid leaks from the trap, the magnitude of vibration generated in the trap itself (housing) due to the leakage, that is, the vibration level However, using the correlation with the leakage amount of the fluid, the leakage amount is obtained from the vibration level. That is, when the diagnosing means diagnoses the trap based on the trap diagnosing procedure, the vibration detecting means detects the vibration generated in the trap housing.
Then, the processing means processes the detected vibration detection signal to derive a leakage amount of the fluid leaking from the trap. Therefore, from the derived amount of fluid leakage, it can be determined whether or not the fluid to be diagnosed has leaked to the trap, and if so, to what extent.

On the other hand, in the valve diagnosis procedure, when a fluid leaks from a valve, the valve itself (housing) is caused by the leakage.
This utilizes the fact that vibration occurs. That is, when the diagnosing means diagnoses the valve based on the valve diagnosing procedure, the vibration detecting means detects the vibration generated in the valve housing. Then, the processing means processes the detected vibration detection signal to derive the magnitude of the vibration, that is, the vibration level. By the way, in general, a valve provided in a plant or the like sometimes generates minute vibration due to the influence of background noise (background noise). However, according to the third aspect of the present invention, since the vibration level is determined, it is determined whether the vibration is caused by background noise or leakage of fluid from the valve. Therefore, it can be determined whether or not the fluid has leaked to the valve.

According to a fourth aspect of the present invention, in the trap and valve diagnostic apparatus according to the first or second aspect of the present invention, the diagnostic means includes a vibration detecting means for detecting a vibration occurring in the diagnostic object itself. Temperature detection means for detecting the temperature of the object to be diagnosed, and a vibration detection signal and a temperature detection signal obtained by detection by the respective detection means are inputted. Processing means for performing processing based on a diagnosis procedure actually used for diagnosis, wherein the trap diagnosis procedure is performed by the processing means, wherein a leakage amount of a fluid which is stored in advance as a control target of the trap and is stored in the processing means. The detection signals are processed based on the correlation between the magnitude of the vibration generated in the trap itself due to the leakage and the temperature of the trap itself, and the leakage of the fluid is performed. Is configured in a state to derive the said valve diagnostic procedure, the above processing means, it is composed of at least the vibration detection signal to the state to derive the magnitude of the vibration, and is characterized in.

That is, according to the fourth aspect of the present invention,
In the trap diagnosis procedure, similar to the invention described in claim 3, when a fluid leaks from the trap, the level of vibration generated in the trap itself due to the leak correlates with the amount of leakage of the fluid. Is used to determine the leakage amount from the vibration level. However, the correlation between the vibration level and the leakage amount of the fluid is strictly related to the fluid pressure in the trap. Therefore, claim 4 of the present invention
In the invention described in (1), the temperature of the trap itself (housing) is detected, the fluid pressure is indirectly obtained from the temperature data obtained by the detection, and the correlation using the obtained fluid pressure as a parameter is obtained. Based on the vibration level, the amount of fluid leakage is determined based on the vibration level.

On the other hand, in the valve diagnosis procedure, when fluid leaks from the valve, similarly to the above-described invention,
This is based on the fact that vibration occurs in the valve itself (housing) due to the leakage. However, in the invention according to claim 4, the processing means derives the magnitude of the vibration from a vibration detection signal obtained by detecting at least the vibration of the valve itself by the vibration detecting means. In addition to the vibration detection signal, a temperature detection signal obtained by detecting the temperature of the valve itself (housing) by the temperature detection means is also input. Therefore, if the processing means processes this temperature detection signal, the temperature of the housing surface of the valve can be derived.

[0030]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of a trap and valve diagnostic apparatus according to the present invention will be described with reference to FIGS. The diagnostic device of the present embodiment aims at diagnosing, for example, the steam trap 2 and the bypass valve 6 shown in FIG.

FIG. 2 is a block diagram showing a schematic configuration of the present embodiment. As shown in the figure, the diagnostic device of the present embodiment has a trap diagnostic program 24a and a bypass valve diagnostic program (hereinafter, referred to as a program) in a storage unit 24 of the conventional diagnostic device dedicated to traps shown in FIG. This is provided with a valve diagnostic program 24b) and a control program 24c. Of these, the trap diagnosis program 24a is the same as the program stored in the storage unit 24 in FIG. 5 described above, and is a program for diagnosing the trap 2. That is, in other words, in the present embodiment, the valve diagnosis program 24b and the control program 24c are newly provided in the storage unit 24 in FIG.
2 is the same as FIG. 5 except that the valve diagnostic program 24b and the control program 24c are provided in the block diagram of FIG. A detailed description thereof will be omitted.

The valve diagnosis program 24b is
This is a program for diagnosing the bypass valve 6.
That is, similarly to the case where the steam leaks to the trap 2, generally, when the steam leaks to the bypass valve 6, the ultrasonic vibration is generated in the bypass valve 6 itself (housing). Are known. Therefore, it can be determined from the vibration level of the ultrasonic vibration whether or not steam leakage has occurred in the valve.

Therefore, in the present embodiment, the vibration generated in the bypass valve 6 is transmitted to the probe 10 (vibration detector).
, The magnitude of the vibration, that is, the vibration level is derived from the detected vibration data, and the derived vibration level is displayed on the display unit 25.
A program for temporarily storing in the storage unit 24 is provided in the storage unit 24 as the valve diagnosis program 24b. Therefore, when diagnosing the bypass valve 6, by diagnosing based on the valve diagnosis program 24b, the diagnosis of the bypass valve 6, which was conventionally impossible, can be realized. This is the most characteristic feature of the present embodiment. Of course, trap 2
Is diagnosed, the trap diagnosis program 24a
Needless to say, the diagnosis is made according to the following.

When the vibration generated in the bypass valve 6 is detected by the probe 10, the temperature of the housing surface of the bypass valve 6 is simultaneously detected by the probe 10 (temperature detector). Therefore, the valve diagnosis program 24a derives the surface temperature of the housing from the temperature data obtained by detection by the probe 10 (temperature detector), and also derives the derived surface temperature.
Along with the vibration level, the information is displayed on the display unit 25 and stored in the storage unit 24. Thereby, not only the vibration level of the bypass valve 6 but also the surface temperature of the housing can be confirmed.

By the way, as described above, according to the present embodiment, depending on whether the object to be diagnosed is the trap 2 or the bypass valve 6, either the trap diagnosis program 24a or the valve diagnosis program 24b is used. It is necessary to select (switch) whether to diagnose. Therefore, in the present embodiment, the programs 24a and 24b can be switched by a key input from the operation unit 27. In the present embodiment, the diagnosis of the trap 2 or the bypass valve 6 is performed a predetermined number of times in addition to the so-called manual (manual) switching mode in which the programs 24a and 24b are switched by the key input of the operation unit 27 as described above. For example, each time the program is executed once, the programs 24a and 24b can be switched by a so-called automatic (Auto) switching mode in which the programs 24a and 24b are automatically and alternately switched. It is possible to select which of the manual switching mode and the automatic switching mode to switch between the programs 24a and 24b by a key input of the operation unit 27.

As shown in FIG. 3, the keys constituting the operation section 27 are divided into a power switch key group, a function key group, a trap type selection key group, and a numerical key group according to their respective roles. In this state, it is arranged on the surface of the palm-sized device main body 20, for example. As described above, the operation unit 27 includes a number of keys. Of these keys, keys that are directly related to the present embodiment (except for the power switch key group) will be described later. For example, "EN" assigned to a numeric key group
T ”key and“ FUN ”assigned to function keys.
Only the “C (function)” key and the “5” key assigned to the numerical key group. For other keys,
Since it is not directly related to the present embodiment, it is not particularly described here. In the figure, reference numeral 25 disposed above the surface of the apparatus main body 20 is a display unit having the above-described liquid crystal panel configuration, which is, for example, a two-row display format. An input terminal 28 provided at the upper end of the apparatus main body 20 is connected to the probe 10 via the cable 11.

Hereinafter, according to the diagnostic apparatus of the present embodiment,
CPU for diagnosing trap 2 and bypass valve 6
The operation of 23 will be described in detail with reference to FIG.
FIG. 3 is a state transition diagram conceptually showing the operation of the CPU 23. The control program 24c controls the operation of the CPU 23 based on the state transition diagram of FIG. In the figure, the trap diagnostic mode M10 indicates that the CPU 23 processes each data from the probe 10 according to the trap diagnostic program 24a. On the other hand, the valve diagnosis mode M20 indicates that the CPU 23 processes each data from the probe 10 according to the valve diagnosis program 24b.

For example, it is assumed that the diagnostic apparatus is not operating, that is, the power of the apparatus main body 20 is off. In this state, when the power of the apparatus main body 20 is turned on, that is, when the "ON" key in the power switch key group is pressed, the CPU 23 receives this and takes a predetermined time, for example, about 3 seconds to perform a predetermined self-diagnosis. (Self-check)
And then enters the idle state 100.

The idle state 100 is defined by the CPU 23
Indicates that the apparatus is in a so-called command waiting state in which it waits for a command from the operation unit 27. In the idle state 100, the CPU 23
Is in a state ready to start the diagnosis of the trap 2 or the bypass valve 6, that is, in a state where the diagnosis of the trap 2 or the bypass valve 6 can be started at any time. However, in the idle state 100 immediately after the power is turned on as described above, the CPU 23 is in the trap diagnosis mode M10, that is, the state in which the diagnosis of the trap 2 can be started at any time. Immediately after the power is turned on, the CPU 23 is set to automatically operate based on the above-described manual switching mode. In the idle state 100, the CPU 23 is currently in the idle state 100.
, And information (message) indicating that the apparatus is in the trap diagnosis mode M10 and operates based on the manual switching mode, etc., is displayed on the display unit 23.

Here, in the idle state immediately after the power is turned on, for example, diagnosis of the trap 2 is to be performed. In this case, if the tip of the probe 10 is pressed against the surface of the housing of the trap 2 to be diagnosed, the probe 10
Start switch (not shown) provided at
Then, the probe 10 starts measuring the ultrasonic vibration and the housing surface temperature of the trap 2 to be diagnosed. At the same time, the CPU 23 executes the measurement process 2
Enter 00.

In the measurement processing 200, the CPU 2
3 displays on the display unit 25 information indicating that the ultrasonic vibration of the trap 2 and the surface temperature of the housing are currently being measured. It should be noted that it takes some time to accurately measure the ultrasonic vibration of the trap 2 and the physical quantity of the housing surface temperature. Therefore, in the present embodiment, the measurement process 200 is performed for a relatively long time of about 15 seconds from the start of measurement, that is, after the tip of the probe 10 is pressed against the housing surface of the trap 2 to be diagnosed. I'm spending time. Of course, during this time, the tip of the probe 10 is kept pressed against the housing surface of the trap 2 to be diagnosed.

When the ultrasonic vibration of the trap 2 and the measurement of the surface temperature of the casing are completed, the CPU 23 proceeds to a judgment process 300.
Here, vibration data and temperature data obtained by measuring the ultrasonic vibration and the housing surface temperature are processed according to the trap diagnosis program 24a, that is, based on the above-described correlation data. Then, it is automatically determined whether or not steam leak has occurred in the trap 2 to be diagnosed, and if steam leak has occurred, the degree of the leak is automatically determined. , Is displayed on the display unit 25, and is temporarily stored in the storage area 24b.

Then, the CPU 23 executes the determination processing 30
When the various processes at 0 are completed, the system automatically returns to the above-described idle state 100, whereby the diagnosis of the trap 2 can be started again. Therefore, when it is desired to perform the trap diagnosis again, the tip of the probe 10 may be pressed against the surface of the housing of the trap 2 to be diagnosed.

When it is desired to diagnose the bypass valve 6 instead of diagnosing the trap 2 as described above, when the CPU 23 is in the idle state 100, the "ENT" key of the operation section 27 is pressed by one. Press it twice. As a result, the CPU 23 transitions from the trap diagnosis mode M10 to the valve diagnosis mode M20, and enters a state where the diagnosis of the bypass valve 6 can be started at any time. At the same time, the CPU 23 sets the trap diagnosis mode M10
Is displayed on the display unit 25 indicating that the mode has shifted to the valve diagnostic mode M20.

When the bypass valve 6 is diagnosed, the tip of the probe 10 is automatically pressed by pressing the tip of the probe 10 against the surface of the housing of the bypass valve 6 to be diagnosed in the same manner as the diagnosis of the trap 2. Diagnosis is started.
That is, in the measurement process 200, the CPU 23 obtains, from the probe 10, vibration data obtained by measuring the ultrasonic vibration of the bypass valve 6 and temperature data obtained by measuring the housing surface temperature. Then, in the determination processing 300, the CPU 23 processes the vibration data and the temperature data according to the valve diagnosis program 24b. Then, the vibration level of the ultrasonic vibration and the housing surface temperature are obtained, and the obtained values are displayed on the display unit 25 and the storage area 2 is displayed.
4b temporarily.

Then, the CPU 23 executes the above-described determination processing 30
After the execution of the various processes at 0, the process automatically returns to the idle state 100, whereby the diagnosis of the bypass valve 6 can be started again. Therefore, again
When diagnosing the bypass valve 6,
What is necessary is just to press the tip of the probe 10 against the housing surface of the bypass valve 6 to be diagnosed. On the other hand, if it is desired to diagnose the trap 2 instead of the bypass valve 6, the CPU 23 may be shifted to the trap diagnostic mode M10 by depressing the "ENT" key once.

As described above, in the manual switching mode, when the CPU 23 is in the idle state 100 and the "ENT" key of the operation unit 27 is pressed, the trap diagnosis mode M10 and the valve diagnosis mode M20 are mutually switched. Can be switched. In other words, according to the manual switching mode, the trap diagnostic mode M10 and the valve diagnostic mode M20 are not switched to each other unless the "ENT" key is pressed when the CPU 23 is in the idle state 100. . This is because trap 2
This is effective when only one of the bypass valve 6 and the bypass valve 6 is continuously diagnosed. However, in the case of diagnosing different objects that form a pair with each other alternately as in the case of the combination of the trap 2 and the bypass valve 6, the trap diagnosis mode M10 and the bypass valve diagnosis mode M20 are switched every time the objects change. Must be alternately switched (that is, the "ENT" key must be pressed), and the operation is troublesome.

Therefore, when the diagnosis of the trap 2 and the bypass valve 6 is performed alternately as described above, the CPU 23 may be operated according to the above-described automatic switching mode. Note that the switching between the automatic switching mode and the manual switching mode is performed by pressing the “FUNC” key and pressing “5” when the CPU 23 is in the idle state 100.
This is executed by pressing the number key.

That is, as described above, the CPU 23 is set to operate based on the manual switching mode.
And in the idle state 100, the above-mentioned "FUN
After pressing the "C" key, the "5" key is pressed. As a result, the CPU 23 switches from the manual switching mode to the automatic switching mode, and displays information indicating that the automatic switching mode has been set on the display unit 25. Note that even in this automatic switching mode, the CPU 23 is in the idle state 10.
When the “ENT” key is pressed when it is at 0, the trap measurement mode M10 and the valve measurement mode M2 are pressed.
0 can be switched between each other.

For example, now, the CPU 23 is set to the automatic switching mode, and the diagnostic mode of the CPU 23 is
It is assumed that the mode is in the trap diagnosis mode M10. In this state, first, the trap 2 is diagnosed. That is, when the tip of the probe 10 is pressed against the surface of the casing of the trap 2 to be diagnosed, the CPU 23 makes a transition from the measurement processing 200 to the determination processing 300 in the trap diagnosis mode M10 as described above, and Perform a diagnosis. After completing the various processes in the determination process 300, the CPU
23 returns to the idle state 100 after shifting to the valve diagnosis mode M20.

Then, diagnosis of the bypass valve 6 is performed. That is, when the tip of the probe 10 is pressed against the housing surface of the bypass valve 6 to be diagnosed, the CPU 2
3 transitions from the measurement process 200 to the determination process 300 in the valve diagnostic mode M20, and diagnoses the bypass valve 6. After completing the various processes in the determination process 300, the CPU 23 sets the trap diagnosis mode M1.
After the transition to 0, the process returns to the idle state 100.

That is, according to the automatic switching mode, C
After performing the diagnosis based on one of the trap diagnosis mode M10 and the valve diagnosis mode M20, the PU 23 automatically switches to the other diagnosis mode. Therefore, in a case where the paired trap 2 and the bypass valve 6 are alternately diagnosed, if the diagnosis is performed in accordance with the automatic switching mode, it is necessary to manually depress the (ENT) key in the idle state 100. This saves the trouble of switching between the diagnostic modes M10 and M20. In the case where one of the trap 2 and the bypass valve 6 is to be continuously diagnosed, for example, twice while the diagnosis is being performed in accordance with the automatic switching mode, when the CPU 23 is in the idle state 100, the above-mentioned “ENT” is set. Press the key and press the trap diagnostic mode M
10 and the bypass diagnosis mode M20 may be interchanged.

As described above, according to the present embodiment, the valve diagnostic mode M2 for diagnosing the bypass valve 6
Since 0 (valve diagnosis program 24b) is provided, the bypass valve 6 can be diagnosed exclusively. Further, in a piping system in which the trap 2 and the bypass valve 6 are provided as a pair, when diagnosis is performed in the automatic switching mode, the diagnosis modes M10 and M20 corresponding to each diagnosis target are automatically set. , The work efficiency is improved. Different objects such as the trap 2 and the bypass valve 6 can be diagnosed by one device.

The trap diagnosis mode M10 and the valve diagnosis mode M20 in the present embodiment correspond to the trap diagnosis procedure and the valve diagnosis procedure described in claims. Pressing the “ENT” key of the operation unit 27 to switch between the diagnostic modes M10 and M20 corresponds to a procedure selection command described in the claims. The manual switching mode and the automatic switching mode in the present embodiment respectively correspond to the first and second diagnostic modes described in the claims. To switch between these diagnostic modes, the operation unit “FUNC”
Pressing the “5” key after pressing the key corresponds to the mode selection command.

In the present embodiment, when diagnosing the trap 2, whether or not steam leakage has occurred in the trap 2 is determined based on the vibration level of the ultrasonic vibration of the trap 2 and the surface temperature of the housing. If a steam leak has occurred, the degree of the leak is determined, but the present invention is not limited to this determination. For example, a quantitative value of the amount of steam leakage may be accurately calculated.

Further, in order to more accurately diagnose the trap 2, in the present embodiment, not only the vibration level of the ultrasonic vibration generated in the trap 2 but also the surface temperature of the housing is measured. Although the presence / absence of the steam leak from the trap 2 and the degree of the leak are determined from the vibration level and the housing surface temperature, the present invention is not limited to this. That is, when not so high diagnostic accuracy is required, the presence / absence of steam leakage of the trap 2 and the degree of leakage can be determined only from the vibration level of the ultrasonic vibration without measuring the housing surface temperature. Good.

On the other hand, with respect to the bypass valve 6, the vibration level of the ultrasonic vibration generated thereby and the surface temperature of the housing are determined by
Although displayed on the display unit 25 and stored in the storage unit 24, when the housing surface temperature is not required, only the vibration level is displayed on the display unit 25 and stored in the storage unit 24. Good.

In the automatic switching mode described above, the trap diagnostic mode M10 and the valve diagnostic mode M20 are alternately switched every time the diagnosis of the trap 2 or the bypass valve 6 is performed once. However, the present invention is not limited to this. .
For example, the diagnosis of the trap 2 or the bypass valve 6
The trap diagnostic mode M10 and the valve diagnostic mode M20 may be alternately switched each time the predetermined number of times is performed. Also, the predetermined number of times that the diagnosis of the trap 2 or the bypass valve 6 is continuously performed may be configured to be variable.

Further, in the present embodiment, the case where the trap 2 and the bypass valve 6 are diagnosed has been described, but the present invention is not limited to this. For example, it goes without saying that the present embodiment can be applied to a case where a valve other than the bypass valve 6, for example, the on-off valves 3 and 4 in FIG. 4 is diagnosed. In addition to the steam plant, the present invention can be applied to a diagnostic device that diagnoses traps and valves provided in a piping system of, for example, compressed air or gas.

The control program 24c may be configured in the apparatus main body 20 (CPU 23) so as to realize the same processing as the above-described detailed counting and analysis of the diagnosis results by the host computer.

[0061]

As described above, the diagnostic apparatus according to the first aspect of the present invention has a diagnostic procedure for valve diagnosis in addition to a diagnostic procedure for trap diagnosis. Therefore,
There is an effect that not only the trap but also the valve can be exclusively diagnosed. Also, a single diagnostic device is provided with a dedicated diagnostic procedure for each of the trap and the valve, and when actually performing a diagnosis, diagnosis is performed based on a diagnostic procedure corresponding to each. Therefore, with one diagnostic device, both the trap and the valve are
This has the effect that accurate diagnosis can be made.

According to the diagnostic apparatus of the second aspect of the present invention, a mode selection command is issued depending on whether one of the trap and the valve is diagnosed and the case where both the trap and the valve are alternately diagnosed. , A diagnostic procedure corresponding to each diagnosis of the trap and the valve is automatically set. Therefore, every time the trap and the valve are diagnosed, the trouble of selecting a diagnostic procedure to be used for the diagnosis, that is, the trouble of giving a procedure selection command can be saved. This is very effective in the case of diagnosing both the trap 2 and the bypass valve 6 forming a pair with the trap 2 in a piping system having the bypass pipe 5 as shown in FIG.

According to a third aspect of the present invention, when diagnosing a trap, when a fluid leaks from the trap, the level of vibration generated in the trap itself is reduced by the amount of leakage of the fluid. The correlation is used to determine the amount of leakage of the fluid. Therefore, whether or not fluid leakage has occurred in the trap from this fluid leakage amount,
If a leak has occurred, the degree of the leak can be determined. On the other hand, when diagnosing a valve,
When the fluid leaks from the valve, the level of the vibration is determined by utilizing the fact that the valve itself generates vibration. Therefore, it can be determined from the vibration level whether or not fluid leakage has occurred in the valve.
Therefore, the same effect as the first and second aspects of the invention can be effectively obtained.

According to the diagnostic apparatus of the present invention, when diagnosing the trap, the correlation between the vibration level and the leakage amount of the fluid is strictly related to the fluid pressure in the trap. Thus, the fluid leakage amount is obtained based on the correlation using the fluid pressure as a parameter. As for the fluid pressure, the case temperature of the trap is detected, and the temperature is indirectly obtained from the temperature data obtained by the detection. Therefore, it is possible to more accurately derive the amount of the fluid leakage as compared with the invention described in claim 3, and it is possible to more accurately determine the presence or absence of the fluid leakage and the degree of the leakage. effective.

On the other hand, when diagnosing a valve, the surface temperature of the housing of the valve can be obtained in addition to the vibration level. Therefore, more information about the valve can be obtained than in the invention described in the third aspect.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a schematic configuration of an embodiment of a trap and valve diagnostic device according to the present invention.

FIG. 2 is a state transition diagram conceptually showing the operation of the CPU in the embodiment.

FIG. 3 is a front view of an apparatus main body constituting the embodiment.

FIG. 4 is a schematic view of a piping system of a steam plant having a bypass pipe.

FIG. 5 is a block diagram showing a schematic configuration of a conventional trap diagnostic device.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 10 Probe (vibration detection means, temperature detection means) 20 Device main body 23 CPU (selection means, processing means) 24 Storage part (storage means) 27 Operation part

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁶ Identification code FI G01M 3/24 G01M 3/24 A

Claims (4)

[Claims] 1. A storage means in which a trap diagnosis procedure used when diagnosing a trap as a diagnosis target and a valve diagnosis procedure used when diagnosing a valve as a diagnosis target are stored in advance. According to a procedure selection command given from, selecting means for selecting one of the diagnostic procedures, diagnostic means for diagnosing the diagnostic object based on the diagnostic procedure selected by the selecting means, A diagnostic device for traps and valves, comprising: 2. A storage means in which a trap diagnostic procedure used when diagnosing a trap as a diagnostic object and a valve diagnostic procedure used when diagnosing a valve as a diagnostic object are stored in advance. Selecting means for selecting one of the diagnostic procedures in accordance with a procedure selecting command given from the first step, and a first diagnosis for diagnosing the diagnostic object based on the diagnostic procedure selected by the selecting means After performing the diagnosis of the diagnosis target based on the diagnosis procedure selected by the selection means by the predetermined number of times, the diagnosis is performed in a state in which the diagnosis of the diagnosis target based on the other diagnosis procedure is performed the predetermined number of times. A second method for performing the above-mentioned diagnosis while automatically and alternately switching the above-mentioned diagnosis procedures every time the predetermined number of times is performed
Diagnostic means for diagnosing the object to be diagnosed in accordance with one of the first and second diagnostic modes in response to an externally provided mode selection command. A diagnostic device for traps and valves provided. 3. A vibration detecting means for detecting a vibration generated in the diagnosis object itself, a vibration detecting signal obtained by the vibration detecting means being inputted, and the inputted vibration detecting signal Processing means for processing based on the diagnosis procedure actually used for diagnosis among the respective diagnosis procedures, wherein the trap diagnosis procedure is stored in the processing means as a control target of the trap stored in advance. Based on the correlation between the leakage amount of the fluid and the magnitude of the vibration generated in the trap itself due to the leakage, the vibration detection signal is processed, and the leakage amount of the fluid is derived. 3. The truck according to claim 1, wherein the valve diagnosis procedure is configured to cause the processing unit to derive the magnitude of the vibration from the vibration detection signal. And diagnostic apparatus of the valve. 4. The diagnostic device according to claim 1, wherein said diagnostic means detects a vibration generated in said diagnostic object itself, a temperature detecting means for detecting a temperature of said diagnostic object itself, and a temperature detected by each of said detecting means. Processing means for receiving the vibration detection signal and the temperature detection signal, and processing each of the input detection signals based on a diagnostic procedure actually used for diagnosis among the diagnostic procedures. The diagnosis procedure is performed by the processing unit, and the correlation between the leakage amount of the fluid to be controlled by the trap stored in advance in the processing unit, the magnitude of the vibration generated in the trap itself due to the leakage, and the temperature of the trap itself. And processing the respective detection signals to derive an amount of leakage of the fluid based on the valve diagnostic procedure. Trap and diagnostic device of the valve according to claim 1 or 2 that is configured to a state to derive the magnitude of the vibration, and wherein the issue.