JP3033342B2 - Cavitation detector - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a pump cavitation detecting apparatus for detecting cavitation of a pump.

[0002]

2. Description of the Related Art In recent years, plants used in most industrial and chemical fields are automated by a computer-based process control system, and humans (operators) are located in a central control room. The system focuses on operations such as safety management and facility management.

By the way, in such a plant,
In many cases, the cause of a plant abnormality is caused by an abnormality of the equipment. If an abnormality of the plant equipment can be discovered (diagnosed) before the occurrence of the plant abnormality, appropriate measures should be taken in advance. This makes it possible to maintain high reliability of the plant and reduce maintenance costs.

[0004] In a plant, pumps are used in many places for sending various fluids and the like, but the cause of the failure is often cavitation phenomenon. Therefore, if the cavitation phenomenon of the pump can be accurately detected, it is possible to prevent a large-scale plant abnormality from occurring.

[0005]

However, hitherto, it has not been possible to accurately detect the occurrence of a cavitation phenomenon which causes an abnormality of the pump. The present invention
In view of the foregoing, it is an object of the present invention to provide a cavitation phenomenon detection device capable of accurately detecting a cavitation phenomenon causing an abnormality of a pump and improving the reliability of a plant.

[0006]

SUMMARY OF THE INVENTION In order to achieve the above object, the present invention provides a measurement signal relating to at least one of a measurement signal relating to a vibration acceleration of a pump, a measurement signal relating to a noise of a pump, and a measurement signal relating to a variable at a control output side of the pump. First absolute value comparison and evaluation means for comparing and evaluating the measurement signal with a prescribed reference value, and using the one of the measurement signals and the normal signal unique to the pump as initial values, The first to evaluate the relative state of the state
A relative value comparison and evaluation means, a second absolute value comparison and evaluation means for comparing and evaluating the measured signal and a prescribed reference value for a measurement signal relating to a variable on the operation input side of the pump, and an operation input side of the pump The relative value of the measurement signal relative to the measurement signal regarding the variable of the above and the normal signal specific to the pump is used as an initial value.
Relative value comparing and evaluating means, and first absolute value comparing and evaluating means,
A logic for performing a logical AND operation of each signal from the first relative value comparison and evaluation means with each signal from the second absolute value comparison and evaluation means and the second relative value comparison and evaluation means, and outputting a cavitation detection signal A cavitation detection device comprising a product processing means.

[0007]

The first and second absolute value comparison and evaluation means are provided by JI
A threshold value is determined based on various standards such as S, ISO, and VDI, and a reference value provided by the manufacturer, and the threshold value is compared with the measurement signal. The relative value comparison and evaluation means sets a normal signal specific to the used pump as an initial value, and evaluates a relative value of the state of the measured signal with respect to the signal.

[0008] The logical product processing means includes a signal from the first absolute value comparison and evaluation means, a signal from the first relative value comparison and evaluation means, and a second signal.
And logical AND processing with each signal from the absolute value comparison / evaluation means and the second relative value comparison / evaluation means, and outputs a cavitation phenomenon detection signal when signals are output from both.

[0009]

An embodiment of the present invention will be described in detail with reference to the drawings. FIG. 1 is a basic configuration block diagram of the present invention. In the figure, reference numeral 1 denotes a pump installed in a plant, which is installed in a pipeline 2 and has a function of sucking and discharging a fluid (gas, liquid, powder) flowing through the pipeline to move the fluid. have.

Reference numeral 3 denotes a block generally showing various sensors, a vibration detecting means for detecting a signal relating to the vibration acceleration of the pump 1, a vibration detecting means for detecting a signal relating to the noise of the pump, and an operation output side of the pump. Detecting means for detecting variables (discharge flow rate, discharge pressure controlled by pump, etc.), and pump input variable quantities (suction side flow rate, suction side pressure, suction side liquid level controlled by pump) And the like.

Reference numeral 41 denotes a first absolute value comparing / evaluating means, which measures at least one of a measurement signal relating to the vibration acceleration of the pump 1, a measurement signal relating to the noise of the pump, and a measurement signal relating to a variable on the operation output side of the pump 1. It is configured to compare and evaluate with a prescribed reference value. Here, the prescribed reference value corresponds to various standards such as JIS, ISO, VDI, etc., a reference value presented by an equipment manufacturer, or a reference value determined by a user.

Numeral 51 denotes a first relative value comparing / evaluating means, which uses the measured signal and the normal signal unique to the pump 1 as initial values and evaluates the relative value of the state of the measured signal with respect to the initial value. Is configured. 42 is a second absolute value comparing and evaluating means for comparing and evaluating the measured signal with respect to a variable on the operation input side of the pump 1 and a prescribed reference value, and 52 is a measurement signal regarding the variable on the operation input side of the pump 1 And a second relative value comparing / evaluating means for evaluating the relative value of the state of the measurement signal relative to the initial value of the signal in the normal state of the pump 1.

Reference numeral 6 denotes a first absolute value comparison and evaluation means 41,
Of the signals from the relative value comparison and evaluation means 51 and the signals from the second absolute value comparison and evaluation means 42 and the second relative value comparison and evaluation means 52 to output a cavitation detection signal. The logical product processing means 7 is a display means for displaying a cavitation phenomenon detection message based on a signal from the logical product processing means 6, and for example, a CRT or the like is used.

FIG. 2 is a structural block diagram showing an embodiment of the present invention. Components corresponding to those in FIG. 1 are denoted by the same reference numerals. In this embodiment, a vibration acceleration signal and a noise signal are measured for the pump 1, and a signal related to a variable on the operation output side of the pump 1 is:
The pump discharge flow rate signal and the pump discharge pressure signal are measured. In addition, a suction liquid level signal and a suction pressure signal are measured as signals relating to a variable on the operation input side of the pump 1.

The vibration acceleration signal, the noise signal, the pump discharge flow rate signal, and the pump discharge pressure signal are all absolute signals for each signal by the first absolute value comparison and evaluation means 41 and the first relative value comparison and evaluation means 51. A value comparison and a relative value comparison judgment are performed, and each judgment result is given to the OR circuit 61. Both the suction liquid level signal and the suction pressure signal are subjected to absolute value comparison and relative value comparison judgment for each signal by the second absolute value comparison and evaluation means 42 and the second relative value comparison and evaluation means 52. The result of each judgment is given to the OR circuit 62.

The signals from the respective OR circuits 61 and 62 are subjected to logical product processing by a logical product circuit 63, and the processing results are output to the display means 7. The operation of the device configured as described above will be described below. FIG. 3 is an explanatory diagram of the judgment operation performed by each absolute value comparison and evaluation means 41. The absolute value comparing / evaluating means 41 converts the absolute value of the measurement data given thereto into various standards such as JIS, ISO, VDI, etc.
The determination is made based on whether or not a predetermined value (threshold) based on a reference value presented by the manufacturer is exceeded.

That is, regarding the measured value of the noise of the pump 1, for example, if the flow rate flowing through the pipeline is Q1, if the absolute value of both amplitudes of the noise signal is A1 or less, the state becomes excellent (Very Smooth). It is determined that there is, and if it is A2 or less, it is determined that it is in a good state (Good).
(air), and if it exceeds A4, it is determined that it is a cautionary state. If it exceeds A5, it is determined that it is dangerous. A1 <A2 <A3 <A4 <
A5 is assumed. Similarly, for example, when the flow rate is Q2, the absolute value of both amplitudes is determined to be in the excellent state when the absolute value of both amplitudes is equal to or less than B1, and when the absolute value of both amplitudes is equal to or less than B2, it is determined to be in the good state. If it is less than or equal, it is determined that it is possible, and B
If it exceeds 4, it is determined that the user is in a caution state, and B
If it exceeds 5, it is determined to be in danger.

FIG. 4 is an explanatory diagram of the judgment operation performed by the relative value comparison and evaluation means 51. The relative value comparison / evaluation means 51 reads out the normal specification data for the vibration acceleration signal unique to the pump 1 and sets the normal data as an initial value,
On the other hand, a relative value evaluation is performed as to how much the measurement data is (in what ratio). That is, the pump 1
If the vibration acceleration signal value output from is more than twice the normal data, it is determined to be good, if it is 2 to 4 times or less, it is determined to be cautionary, and if it exceeds 4 times Is determined to be in a dangerous state. When the object to be diagnosed is a rolling bearing, if the value of the vibration acceleration signal output therefrom is three times or less with respect to the normal data, it is determined to be good. Judge as the state,
If it exceeds six times, it is determined that the vehicle is in a dangerous state.

The pump to be diagnosed is stored as normal data (initial value data) for each discharge flow rate (minimum, middle, maximum) of the pump, and the corresponding initial value is set according to the discharge flow rate. By using the value data and making a relative evaluation of the state of the measurement data with respect to the value data, more accurate abnormality detection can be performed. The logical product processing means 6 includes signals from the first absolute value comparison / evaluation means 41 and the first relative value comparison / evaluation means 51 and the second absolute value comparison / evaluation means 42 and the second relative value comparison / evaluation means. A logical AND operation with each signal from the means 52 is performed, and when signals are output from both, it is determined that the cavitation phenomenon has occurred, and the detection signal is output to the display means 7. That is,
If the diagnosis result based on the input-side variable of the pump 1 and the diagnosis result based on the output-side variable indicate an abnormality at the same timing, a detection signal of the occurrence of the cavitation phenomenon is generated based on the fact that the cavitation phenomenon has occurred. This is to output.

The display of the occurrence of the cavitation phenomenon on the display means 7 may be, for example, a message or a window automatically displayed. Further, it may be output by an audio signal or the like. In the embodiment of FIG. 2, the OR circuit 61 is used.
Is a vibration acceleration signal and a noise signal obtained from the pump 1,
For each of the discharge flow rate signal and the discharge pressure signal, an absolute value comparison evaluation and a relative value comparison evaluation are performed, and the results of those evaluations are input. However, the signal obtained from the pump 1 is a vibration acceleration signal, A configuration may be adopted in which any one of the noise signal, the discharge flow rate signal, and the discharge pressure signal is input.

[0021]

As described above in detail, according to the present invention, the logical product of the diagnosis result based on the input variable of the pump 1 and the diagnosis result based on the output variable is performed. This makes it possible to accurately detect the cavitation phenomenon of the pump, which has conventionally been difficult to detect accurately.

[Brief description of the drawings]

FIG. 1 is a basic configuration block diagram of the present invention.

FIG. 2 is a configuration block diagram showing one embodiment of the present invention.

FIG. 3 is an explanatory diagram of a judgment operation performed by each absolute value comparison and evaluation means.

FIG. 4 is an explanatory diagram of a judgment operation performed by a relative value comparison and evaluation unit.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Pump 2 Pipeline 3 Various sensors 41, 42 Absolute value comparison and evaluation means 51, 52 Relative value comparison and evaluation means 6 Logical product processing means 7 Display means

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Claims (1)

(57) [Claims] A first method for comparing and evaluating a measured signal and a prescribed reference value with respect to at least one of a measured signal related to a vibration acceleration of a pump, a measured signal related to a noise of the pump, and a measured signal related to a variable on an operation output side of the pump. An absolute value comparison and evaluation means, and a first value for evaluating a relative value of how much the measurement signal is in relation to one of the measurement signals and a signal in a normal state specific to the pump as an initial value. Relative value comparing and evaluating means; and a second comparing and evaluating the measured signal and a prescribed reference value for a measured signal relating to a variable on the operation input side of the pump.
Means for comparing the absolute value of the measurement signal with respect to the variable on the operation input side of the pump and the normal signal unique to the pump as an initial value, and evaluating the relative value of the state of the measurement signal with respect to this. Second relative value comparing and evaluating means, first absolute value comparing and evaluating means, signals from the first relative value comparing and evaluating means, second absolute value comparing and evaluating means, second relative value comparing and evaluating means Performs a logical AND operation with each signal from the means,
A cavitation detection device comprising: a logical product processing means for outputting a cavitation detection signal.