JP2000131196A - Generator Ripple Spring Looseness Inspection System - Google Patents

Abstract

(57) [Problem] To provide an inspection device capable of accurately and reliably inspecting a looseness of a ripple spring pressing a coil conductor of a generator by a tapping sound. SOLUTION: An external force when a hammer 2 applies an external force to a ripple spring 1 to generate a tapping sound is detected by an exciting force sensor 11 and a ratio calculator 15 calculates a ratio with an external force reference value. Further, a tapping sound generated in the ripple spring 1 is detected by the microphone 3, separated into a time-series signal for each frequency band by the analog BPF 5, further rectified, and instantaneously changed for each frequency band by the peak hold 7. Extract the maximum value.
The maximum value is corrected by the ratio calculated by the ratio calculator 15 and compared with a preset sound pressure reference value in the comparator 9 to output a comparison result signal when the relationship deviates from a predetermined relationship. If the number of comparison result signals is three or more, an alarm is issued. Since the maximum value of the time-series signal for each of a plurality of frequency bands is extracted and compared, the state of looseness can be accurately inspected.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for inspecting the looseness of a ripple spring of a generator, and more particularly to an apparatus for inspecting the looseness of a ripple spring of a generator which can improve the reliability of the inspection.

[0002]

2. Description of the Related Art An iron core of a stator of a generator is provided with an iron core groove, into which a coil conductor is inserted. In order to fix the coil, a coil spring is formed by a ripple spring. Of the stator, that is, outwardly in the radial direction of the stator. At the time of production, even if it is firmly held down, it will loosen due to aging, so it is necessary to regularly check for looseness. Conventionally, inspection for looseness of a ripple spring that holds down a coil in a stator of a generator has relied on a sensory inspection of a skilled person, in which a person hits with a hammer or the like and hears and judges the sound.

A hitting sound inspection apparatus for inspecting the state of an object by hitting sound is disclosed, for example, in Japanese Patent Application Laid-Open No. Hei 6-3336, which inspects peeling of a tile on a wall. In this method, a hitting device hits a wall to which a tile is attached, detects a hitting sound generated, converts the hitting sound into an electric signal, and extracts a component of a predetermined frequency band related to diagnosis through a bandpass filter. It is checked whether the peak value of the extracted AC signal voltage does not exceed a predetermined reference value, and if it does, an alarm is output to the screen display device.

[0004]

As described above, in the case of human judgment, there is a difference in the diagnosis result due to the intuition and skill of the measurer. In addition, in the conventional tapping sound inspection apparatus, since only the sound pressure of the frequency of the maximum level of the frequency band in the sound pressure signal generated by the hitting, that is, the sound pressure of the frequency as the main component, is compared, In the inspection of the hammering sound, if an abnormal feature appears at a frequency other than the main component, the abnormality could not be detected accurately.

[0005] Further, since the maximum level of the frequency band is evaluated, it is not possible to discriminate between a sound pressure that is instantaneously generated greatly and a sound pressure that has a long lingering sound and a low level, which is a characteristic of the tapping sound. was there. For these,
Even if the above-described hammering sound inspection apparatus is applied to the inspection of the looseness of the ripple spring of the generator, it has been difficult to accurately detect the looseness.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and has as its object to obtain the following apparatus for inspecting the looseness of a ripple spring of a generator. a. The reliability of the inspection can be improved by comparing the state of the vibration generated by the impact with the reference state. b. Inexpensive and high-speed processing is possible. c. It can be downsized and can flexibly respond to changes in conditions.

D. The influence of the variation of the external force applied to the object can be prevented. e. Noise from the surroundings and the effects of noise can be prevented.
Further, as further improvements, f. It is possible to know that an external force outside the proper range is applied or that the input has exceeded the proper range. g. The amplification factor of the amplifier can be easily set to an appropriate value. h. The vibration reference value can be set easily and accurately, and the reliability of the inspection can be improved.

[0008]

In order to achieve the above-mentioned object, in the apparatus for inspecting the looseness of a ripple spring of a generator according to the present invention, a vibration generated from a ripple spring to which an external force is applied is subjected to a vibration signal. Signal detecting means for detecting as, a converting means for converting the vibration signal into a time series signal for each of a plurality of predetermined frequency bands, an extracting means for extracting the maximum value of the time series signal for each frequency band, and each maximum value And a comparing means for comparing with a preset vibration reference value for each frequency band. The vibration signal is converted into a time-series signal for each of a plurality of frequency bands, and the maximum value in each of the time-series signals is extracted. Thus, the frequency resolution of the vibration signal is improved, and the maximum value from the time-series signal is improved with high sensitivity. Can be extracted. Therefore, the characteristics of the loud sound or vibration immediately after the occurrence, which is also the characteristic of the impact, can be accurately grasped and compared.

The converting means is a plurality of band filters for passing a frequency component of a predetermined frequency band of the vibration signal. The extracting means rectifies the frequency components passing through each band filter, and converts each of the rectified frequency components. It is characterized in that the largest one of the peak values is extracted as the maximum value. If the conversion means is a bandpass filter, the processing can be performed at a high speed, and the apparatus is simple and inexpensive. In particular, if an analog bandpass filter is used, the processing can be speeded up. If a digital bandpass filter is used, the size can be reduced, and the condition can be flexibly changed. Further, since the extracting means extracts the maximum value from the rectified frequency components, it is possible to detect even when the maximum value is present in the negative sign part of the vibration signal, and to accurately compare even when the vibration signal is rapidly attenuated.

Further, the conversion means is a wavelet conversion means for performing a wavelet conversion of the vibration signal, and the extraction means extracts a maximum value for each frequency band based on a result of the conversion by the wavelet conversion means. If the wavelet transform means is used, the characteristics at the time of separating the signal into time-series signals for each frequency band can be improved, and the reliability of inspection can be improved.

The converting means is a short-time fast Fourier transform means for short-time fast Fourier transform of the vibration signal,
The extracting means extracts the maximum value for each frequency band based on the conversion result by the short-time fast Fourier transform means. The use of the short-time fast Fourier transform means improves the frequency resolution.

Further, an external force detecting means for detecting the magnitude of the applied external force is provided, and at least one of a vibration signal, a time-series signal, a maximum value, and a vibration reference value is corrected according to the magnitude of the external force. A correction means is provided. Correction is made in accordance with the magnitude of the external force to prevent the comparison means from being affected by variations in the magnitude of the external force. Further, for example, by performing different corrections according to the external force for each frequency band, it is possible to perform comparison with high reliability even on an object whose frequency component distribution changes according to the applied external force.

In addition, an external force detecting means for detecting the magnitude of the applied external force is provided, and at least one of a signal detecting means, a converting means, an extracting means, and a comparing means when the magnitude of the external force exceeds a predetermined value. Command means for commanding the start of operation is provided. Since the operation is not started until a command is issued, there is no possibility that noise, vibration, noise, or the like in the surroundings when no command is issued is erroneously processed as a vibration signal. Therefore, the influence of these can be prevented, and the reliability of the inspection is improved.

Further, there is provided external force detecting means for detecting the magnitude of the applied external force as an external force signal, and a ratio calculating means for obtaining a ratio obtained by dividing the external force signal by a preset external force reference value; Correction means for correcting the relationship between the maximum value and the vibration reference value in the comparison means by correcting at least one of the vibration signal, the time-series signal, the maximum value and the vibration reference value based on the ratio; And a ratio inspection means for inspecting whether the value is within the range. The ratio calculation means examines whether the ratio between the external force and the external force reference value is within a predetermined range, that is, whether the external force applied to the object, that is, whether the excitation force is too small or too large, is checked. Make sure that you have applied an inappropriate external force such as If the excitation force is too small or too large, an erroneous inspection can be prevented when the frequency characteristics of the vibration generated by the object are different. If you know that you have applied an inappropriate external force, you can apply the external force again,
It can be operated without using much nerves, and operability is also improved.

Further, there are provided external force signal amplifying means for amplifying the external force signal and outputting it as an amplified external force signal, and vibration signal amplifying means for amplifying the vibration signal and outputting it as an amplified vibration signal. It shall be used as an external force signal, the converting means shall use the amplified vibration signal as a vibration signal, and a range over detecting means for detecting that at least one of the peak values of the amplified external force signal and the amplified vibration signal has exceeded a predetermined value. It is characterized by having been provided. In order to ensure the reliability of the measurement, it is detected that the amplified external force signal or amplified vibration signal has exceeded a predetermined value, that is, that a large signal has been input that saturates the external force signal amplification means or vibration signal amplification means. I do.

Further, the present invention is characterized in that amplification factor automatic setting means for automatically setting the amplification factor of at least one of the external force signal amplification means and the vibration signal amplification means is provided. The amplification factor can be easily set so that the amplified external force signal and the amplified vibration signal are in an appropriate output range, and the operability is improved. Further, a decrease in the S / N ratio can be prevented, and the reliability of the inspection can be improved.

[0017] The comparison means is characterized in that the comparison is performed based on a vibration reference value set based on a vibration signal generated when an external force is applied to the ripple spring in a predetermined state. A vibration reference value according to the state of the ripple spring can be easily set, and the reliability of the inspection increases.

[0018]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiment 1 Hereinafter, an embodiment of the present invention will be described with reference to FIGS. FIG. 1 is a configuration diagram of a looseness inspection device for a ripple spring of a generator, and FIG. 2 is a detailed diagram of a ripple spring portion. The ripple spring portion is configured, for example, as shown in FIG. In FIG. 2, the ripple spring portion 100 is configured as follows. An iron core groove 102 is formed in an iron core 101 of a stator of a generator, and a coil conductor 103 is accommodated in the iron core groove 102.

The ripple spring 1 is provided between the spacer 104 and the wedge 106. The wedge 106 is inserted into a wedge groove 107 provided in the iron core 101 from the axial direction of the stator. The coil conductor 103 is pressed against the bottom of the iron core groove 102 by the elastic force of the ripple spring 1. Even if such a ripple spring 1 is firmly pressed at the time of manufacture, it loosens due to aging, so it is necessary to periodically inspect whether it is loose.

2 strikes the ripple spring 1 via the wedge 106 (hereinafter sometimes referred to as "impacting the ripple spring 1 by omitting" via the wedge 106 "),
It is a hammer that produces a hammering sound. That is, an external force is applied to the ripple spring 1 via the wedge 106, and a loose state of the ripple spring 1 is determined by a tapping sound. Reference numeral 11 denotes a vibrating force sensor as external force detecting means which is attached to the hammer 2 and converts a vibrating force applied to the ripple spring 1 as an external force into an electric signal. Reference numeral 12 denotes an amplifier for amplifying the electric signal converted by the excitation force sensor 11, and reference numeral 13 denotes a rectifier for converting the signal amplified by the amplifier 12 to DC.

Reference numeral 14 denotes a peak hold that holds the maximum value of the DC signal output from the rectifier, and 15 denotes a ratio calculator that determines the ratio between the output of the peak hold and the external force reference value stored in the reference value setting device 16. . Reference numeral 17 denotes a trigger detector that detects a trigger from a DC signal output from the rectifier 13.

Reference numeral 19 denotes a ratio determiner for determining the ratio obtained by the ratio calculator 15. Reference numeral 20 denotes an automatic range setting device that automatically sets the amplification factor of the amplifier 12 from the maximum value output from the peak hold 14. Reference numeral 21 denotes a range over detector that detects range over from the maximum value output from the peak hold 14.

Reference numeral 3 denotes a microphone as signal detection means for converting a tapping sound generated by the hitting ripple spring attached to the hammer 2 into an electric signal. Reference numeral 4 denotes an amplifier for amplifying the electric signal converted by the microphone 3. 5 is an amplifier 4
Is an analog BPF as a converting means for separating a signal obtained from the signal for each frequency band. This analog BPF5
For example, in order to cover almost 20 Hz to 20 kHz, which is a human audible range, for 9 octaves from 31.25 Hz to 16 kHz, a total of 28 bands are provided to provide a resolution of 1/3 octave.

Reference numeral 6 denotes a rectifier for rectifying a signal for each frequency band obtained from the analog BPF 5 and converting the signal into a direct current.
Reference numeral 7 denotes a peak hold as extraction means for holding the maximum value of the output from the rectifier 6, and reference numeral 8 denotes a corrector for correcting the maximum value output from the peak hold 7 based on the ratio obtained from the ratio calculator 15. 9 is the output of the compensator 8 and the reference value setting device 1
The comparator compares the sound pressure reference value as the vibration reference value stored in 0 with a predetermined method, that is, a predetermined comparison reference. Reference numeral 18 denotes an alarm device that performs an overall inspection based on the comparison result from each of the comparators 9 and outputs an alarm when an abnormality is detected.

A rectifier 31 converts a signal amplified by the amplifier 4 into a direct current. Reference numeral 32 denotes a peak hold that holds the maximum value of the output from the rectifier 31, and reference numeral 33 denotes an automatic range setting device that automatically sets the amplification factor of the amplifier 4 based on the maximum value output from the peak hold 32. Numeral 34 is a range over detector for detecting range over from the maximum value output from the peak hold 32.

Next, a reference value setting mode in which an external force reference value and a sound pressure reference value are set by an object serving as a reference, that is, the ripple spring 1 in FIG. I do. The fact that the ripple spring 1 is not loose is confirmed by measuring, for example, the compression allowance of the ripple spring 1.

First, the amplification factors of the amplifiers 4 and 12 are minimized. In this state, the ripple spring 1 which is not loosened is hit by the hammer 2, and the generated hitting sound is converted into an electric signal by the microphone 3, and the amplifier 4, the rectifier 31,
The maximum value of the impact sound signal is obtained by the peak hold 7.

The maximum value is input to the automatic range setting unit 33, and the gain of the amplifier 4 is set so as to have an appropriate measurement range. Similarly, after the vibration generated in the hammer by the impact is converted into an electric signal by the excitation force sensor 11, the maximum value of the vibration signal is obtained by the amplifier 12, the rectifier 13 (not passing through the analog BPF 5), and the peak hold 14. This maximum value Is input to the automatic range setting device 20 to set the gain of the amplifier 12 so as to obtain an appropriate measurement range.

The appropriate measurement range is, for example, corrected by the difference in the excitation force as in this embodiment. If the range is 1/2 to 2 times, the range is at most 2 times larger than the reference value. Since it is necessary to accept twice the input, the signal level input in this reference value setting mode is 5 times the measurement range.
The gain is set to be 0%.

In this manner, the amplification of both vibration and sound is set by the first hit in the reference value setting mode.

Next, the hammer 2 strikes the sound ripple spring 1 as a reference as an object. At this time, the vibration generated in the hammer 2 is converted into an electric signal by the excitation force sensor 11, and the amplifier 12 gives the gain set by the first hit in the reference value setting mode. This amplified signal is converted into a direct current by the rectifier 13. The trigger detector 17 compares the DC signal from the rectifier 13 with a preset reference value, and outputs a trigger when the DC signal exceeds the reference value.

The peak hold 14 records the maximum value of the DC signal input from the rectifier 13. At this time, the operation of the peak hold 14 is started by a trigger signal from the trigger detector 17. The recording of such a maximum value is performed for a fixed time until the vibration generated by the hammer due to the impact is attenuated to some extent, and thereafter the output from the peak hold 14 is stored in the reference value setting device 16 as an external force reference value.

Similarly, the sound wave generated by the impact is converted into an electric signal by the microphone 3, and the gain set by the first impact in the reference value setting mode is given by the amplifier 4. A plurality of amplified sound pressure signals are provided to the analog BPF 5 set to pass different frequency bands, and are separated into time-series signals for each frequency band.

The time series signal separated for each frequency band by the analog BPF 5 is converted into a DC signal by the rectifier 6 and input to the peak hold 7. The maximum value recording operation of the DC signal from the rectifier 6 of the peak hold 7 is performed by the trigger detector 7.
, And is carried out for a certain period of time until the sound pressure of the object is attenuated in the same manner as the peak hold 14 for vibration. In this way, the instantaneous maximum value for each frequency band is recorded.

After the fixed time until the sound pressure decay ends, the maximum value for each frequency band recorded by the peak hold 7 is stored in the reference setting device 10 as a sound pressure reference value. By the operation of the reference value setting mode, the reference value setting device 16 stores the external force reference value, which is information indicating the strength of the impact,
The reference value setting device 10 stores a sound pressure reference value which is information indicating an instantaneous maximum sound pressure in each frequency band of the tapping sound.

Next, an inspection mode for inspecting an object will be described. First, the hammer 2 strikes the ripple spring 1 as an object. At this time, as in the case of the reference value setting mode, the vibration generated in the hammer 2 is converted into an electric signal by the excitation force sensor 11, amplified by the amplifier 12, and
In step 3, it is converted to direct current.

The trigger detector 17 similarly outputs a trigger from the DC signal from the rectifier 13 and
Records the maximum value of the DC signal for a certain period of time from the trigger output to the sound pressure decay. In the case of the inspection mode, the maximum value recorded in the peak hold 14 is input to the ratio calculator 15 after a certain period of time until the hammer vibration damping is completed.
Is the maximum value from the peak hold 14 and the reference value setting device 1
6 to calculate and output the ratio with respect to the external force reference value.

Similarly to the reference value setting mode, the sound wave generated by the impact is converted into an electric signal by the microphone 3, amplified by the amplifier 4, separated into a time series signal for each frequency band by the analog BPF 5, and The signal is converted into a DC signal and input to the peak hold 7. The peak hold 7 records the maximum value of the DC signal for a fixed time from the trigger output to the sound pressure decay.

In the case of the inspection mode, the maximum value recorded by the peak hold 7 is inputted to the compensator 8 after a certain period of time until the sound pressure decay, and the corrector 8 determines an appropriate value from the ratio obtained from the ratio calculator 15. The correction value is calculated, corrected to the maximum value obtained from the peak hold 7, and output.

At this time, for example, when the correction of the vibration level and the sound pressure is performed in proportion, if the ratio twice as large as the reference value is obtained by the calculation, the maximum value recorded in the peak hold 7 is calculated. Divide by two. That is, if the excitation force in the inspection mode is twice as large as the excitation force in the reference value setting mode, the maximum sound pressure obtained assuming that the sound pressure for each frequency band generated is also doubled Divide the value by 2 to convert the value to the excitation force in the reference value setting mode.

The maximum value corrected in this way is compared by the comparator 9 with the sound pressure reference value stored in the reference value setting device 10 based on a predetermined method or a predetermined comparison reference.
In this embodiment, a comparison result signal is output to the alarm 18 when the corrected maximum value deviates from a predetermined relationship set in advance.

At this time, the predetermined relationship is, for example, that a certain band is normal when the corrected maximum value is within a range of, for example, 80% to 120% with respect to the sound pressure reference value of the band. When the value is out of the range, the value is out of the range and a comparison reference is set so as to output a comparison result signal. In another band, the comparison result signal is not output when the sound pressure reference value of the band is within a range of, for example, 70% to 110%, and is output when the sound pressure reference value is out of the range. Set the reference for comparison.

Further, when the sound pressure reference value is smaller than the whole sound pressure, by taking measures such as canceling the lower limit of the range, a comparison result signal is not erroneously output in a frequency band other than the main component. I do.

The alarm device 18 receives the comparison result signal from the comparator 9 in each frequency band, and determines a criterion such that when the number of comparison result signals exceeds a preset number, for example, two, it is determined that there is an abnormality. When an abnormality is determined, an alarm is output to the outside.

The ratio checker 19 outputs an out-of-correction range alarm when the ratio calculated by the ratio calculator 15 exceeds a predetermined relationship. The predetermined relationship at this time is set to, for example, 1/2 to 2 times. Then, if there is an input less than や or more than twice, an out-of-correction-range alarm is output.

When the exciting force changes extremely, the frequency component of the generated sound changes greatly, making correction difficult. When the excitation force is extremely weak or extremely strong, as in the case of this ripple spring, a sound is generated that has nothing to do with the looseness of the ripple spring, which is the purpose of the inspection, and the reliability of the inspection is greatly reduced. Will be done. However, by limiting the range of the correction by the exciting force in this way, it is possible to reliably inspect even an object in which the frequency characteristics of the impact sound generated when the exciting force changes extremely are changed. An erroneous inspection due to an extreme change in the excitation force can be prevented.

In the correction, the relationship between the waveform analysis result and the sound pressure reference value, that is, the sound pressure reference value stored in the reference value setting unit 10 in the comparator 9 is corrected in accordance with the magnitude of the vibration signal. The output of the amplifier 12 and each analog B
One or more of the output of the PF 5, the output of the rectifier 6, or the sound pressure reference value stored in the reference value setting device 10 may be corrected.

When the magnitude of the vibration detected by the excitation force sensor 11 exceeds a predetermined value, the peak hold 1
4. Since the trigger detector 17 for instructing the start of the operation is provided to the peak hold 7 as the extracting means, the influence of noise from the surroundings can be reduced, and the reliability of the inspection can be improved.

Although the trigger signal from the trigger detector 17 is given to the peak hold 7, the microphone 3, the amplifier 4, the analog BPF 5 as the converting means, the rectifier 6, the compensator 8 as the compensating means, and the comparing means The same effect can be obtained by giving the maximum value to the comparator 9 or the like to start the storage operation of the maximum value or the comparison operation.

In each of the reference value setting mode and the inspection mode, the range over detector 21 inputs the maximum value of the vibration signal obtained from the peak hold 14, and when the maximum value exceeds a predetermined relationship, the range over is detected. Output an alarm. The range over detector 34 inputs the maximum value of the sound signal obtained from the peak hold 7, and outputs a range over alarm when the measurement signal exceeds a predetermined relationship.

The predetermined relationship at this time is set, for example, as 99% of the measurement range. In this case, when a signal exceeding 99% is input, an overrange alarm is output.

Further, by setting an appropriate measurement range in the first hit in the reference value setting mode, the trouble of manually setting the measurement range is eliminated, and the operability is improved. Further, when the range is not appropriate when setting manually, the S / N ratio is lowered and the reliability of the inspection is lowered. However, such a problem does not occur because the range is automatically set to an appropriate value. In addition, it is possible to obtain a hammering inspection apparatus with improved inspection reliability.

Further, by outputting a range over alarm immediately before the input of each signal is saturated, an erroneous determination due to the saturation of the amplifier can be prevented, and a tapping sound inspection apparatus with improved inspection reliability can be obtained. Becomes The inspection can be performed at high speed by using the analog BPF.

Embodiment 2 FIG. 3 is a block diagram of a generator for checking looseness of a ripple spring of a generator according to another embodiment of the present invention. In FIG. 3, the following points are different from those shown in FIG. 1, but the other configuration is the same as that shown in FIG. The point at which the maximum value of the sound pressure for each frequency band extracted by the peak hold 7 is corrected by the corrector 8 and then input to the reference setter 10 and the reference setter 1
0 has the function of determining the average value of the input maximum value for each frequency band and using this as the sound pressure reference value, determining the range of variation of the maximum value, and determining the comparison reference based on the range. The points are different.

Prior to the operation, a sound ripple spring 1 is
Select 0 locations. The soundness of the ripple spring 1 is confirmed by measuring the compression allowance of the ripple spring 1. In addition, "healthy"
Strictly speaking, it means that the ripple spring 1 is slightly loosened during use of the generator due to withering of the insulator or the like, but the looseness is within an allowable range.

Next, the operation will be described. First, an arbitrary healthy ripple spring 1 is hit with a hammer 2. At this time, the vibration generated in the hammer 2 is detected as an external force applied to the ripple spring 1 by the excitation force sensor 11, converted into an electric signal, and the maximum value is extracted by the peak hold 14. The maximum value extracted by the peak hold 14 is determined by the reference setter 16
Is stored as an external force reference value. At this time, the ratio calculator 1
5 outputs the ratio 1. These are the same as those shown in the embodiment of FIG.

On the other hand, the maximum value of the sound pressure signal extracted by the peak hold 7 passes through the compensator 8 as it is because the ratio output by the ratio calculator 15 is 1, and is input to the reference setting device 10 and It is stored as a pressure reference value.

Next, the variation in the sound pressure reference value is determined. Hit 50 healthy ripple springs and obtain 50 data. The maximum value of the sound pressure obtained for each impact, that is, the maximum value for each frequency band extracted in the peak hold 7,
The corrector 8 corrects the ratio calculated by the ratio calculator 15 each time and stores the corrected value in the reference value setting device 10. In other words, if the ratio is 1.2, it is assumed that the external force applied this time is 1.2 times the external force when the external force reference value was previously stored in the reference setting device 16 and divided by 1.2. To normalize.
In this way, 50 data are obtained for each frequency band.

Then, the average value is obtained and set as a sound pressure reference value. In addition, a range of variation of the maximum value is obtained for each frequency band. For example, in the frequency band number A1, the sound pressure reference value is set to 100 and 95 to 110, and in the frequency band number A2, 90 to 105. The comparator 9 does not output a comparison result signal within the range of the variation determined as described above, and determines a comparison criterion so as to output the comparison result signal to the alarm device 18 when the comparison result signal is exceeded. Also,
If it is expected that there may be cases where the variation exceeds the normal data obtained in the reference value setting mode, a margin of about ± 10% may be provided to prevent erroneous determination.

In the alarm 18, even if it is normal, there is a possibility that the alarm will be out of the data obtained from the above-mentioned 50 ripple springs. An abnormality is inspected when three or more are detected, and a criterion is set so that an alarm is issued.

As described above, the range of the maximum value variation of the time series signal for each frequency band of the sound pressure signal is obtained from a sufficient number of data by striking a sound ripple spring, and comparison is made based on this. If this is done, if there is a looseness of the ripple spring beyond a predetermined value, an abnormality will appear somewhere in the above-mentioned frequency band and it will be out of the comparison standard, so that the defect can be reliably detected.

The following can also be performed. One hundred ripple springs 1 whose soundness is not completely secured but which seem to be sound are selected, and 100
Take data. If there is data exceeding three times the standard deviation σ, it is determined that the slackness is equal to or larger than the allowable value, and the average value and the range of the variation are obtained by excluding this data. In this way, even if there is a large looseness of the ripple spring, it can be prevented from being included in the sound pressure reference value or the comparison reference.

Data obtained by striking the ripple spring 1 when it is new, that is, within the range when the compression allowance of the ripple spring is within a predetermined range, for example, ± 10% of a reference value. If data on the range of variation in the sound pressure reference value and the maximum value when the ripple spring is hit is stored, the data can be used. It should be noted that the comparison criterion set by each of the above methods can be modified and learned based on data obtained in a later actual test.

Embodiment 3 In the first embodiment, an analog BPF is used to determine the maximum value for each frequency band, but a digital BPF may be used. In this embodiment, a case where a digital BPF is used will be described with reference to the configuration diagram of FIG. In FIG. 4, reference numeral 51 denotes an A / D converter for converting an analog signal from the rectifier 13 into a digital signal, and reference numeral 52 denotes an A / D converter for converting an analog signal from the amplifier 4 into a digital signal. 53 is an A / D converter 5
This is a maximum value calculator for calculating the maximum value of the output of No. 1.

Reference numeral 61 denotes a digital BPF as conversion means for converting a digital signal into a time series signal for each frequency band. The digital BPF 61 is, for example, 9 to 31.25 to 16,000 Hz in order to cover almost 20 to 20,000 Hz which is a human audible range similarly to the embodiment of FIG.
For 28 octaves, a total of 28 bands are provided with a resolution of 1/3 octave. Reference numeral 62 denotes a rectifier for rectifying an AC signal from the digital BPF, and reference numeral 63 denotes a maximum value calculator as extraction means for extracting a maximum value from the rectified digital signal.

A corrector 64 corrects the maximum value output by the maximum value calculator 63 based on the ratio obtained from the ratio calculator 15 and outputs a corrected value. A comparator 65 compares the output of the compensator 64 with the sound pressure reference value stored in the reference value setting device 66 by a predetermined method. The rectifier 62, the peak hold circuit 63, the compensator 64, the comparator 65, and the reference value setter 66 are digital BPs provided for all 28 bands.
28 are provided corresponding to F61, respectively.

A maximum value calculator 41 extracts the maximum value from the digital signal from the A / D converter 52 rectified by the rectifier 31. Other configurations are the same as those shown in FIG. 1, and the corresponding components are denoted by the same reference numerals and description thereof is omitted.

Next, the operation will be described. First, a reference value setting mode for setting each reference value using a reference target object will be described. The A / D converter 51 converts an analog DC signal from the rectifier 13 into a digital signal. At this time, the A / D converter 51 starts operation in response to the trigger signal from the trigger detector 17, and is continuously performed for a certain period of time until the vibration generated by the hammer due to the impact attenuates to a predetermined value or less. The maximum value calculator 53 extracts the maximum value of the digital signal from the A / D converter 51, and the maximum value is stored in the reference value setting device 16 as an external force reference value.

Similarly, the sound wave generated by the impact is converted into an electric signal by the microphone 3, given an appropriate gain by the amplifier 4, and then converted into a digital signal by the A / D converter 52. At this time, the A / D converter 52 starts operating in response to a trigger signal from the trigger detector 17 and operates for a certain period of time until the sound pressure generated by the impact on the target object attenuates below a predetermined value. This converted digital signal is
The signals are input to 28 digital BPFs 61 set so as to pass through different frequency bands, and separated into time-series signals for each frequency band.

The time series signal separated by the digital BPF 61 for each frequency band is converted into a DC signal by the rectifier 62 and input to the maximum value calculator 63. Maximum value calculator 63
Extracts the maximum value of this DC signal,
To be stored. In this way, the instantaneous maximum value of each frequency band is extracted, and the reference value setting unit 66 is used as the sound pressure reference value.
Is stored in

By the operation of the reference value setting mode, the reference value setting device 16 stores the external force reference value which is information indicating the strength of the hitting, and the reference value setting device 66 stores the frequency band of each of the hitting sounds. The sound pressure reference value, which is information indicating the instantaneous maximum sound pressure at the time, is stored.

Next, an inspection mode for inspecting an object will be described. First, the hammer 2 strikes the ripple spring 1 as an object. At this time, as in the case of the reference value setting mode, the vibration generated in the hammer 2 is converted into an electric signal by the excitation force sensor 11, amplified by the amplifier 12, and
In step 3, it is converted to DC. Similarly, the trigger detector 17 outputs a trigger signal from the DC signal from the rectifier 13, and the A / D converter 51 converts the DC signal into a digital signal for a certain period from the trigger output to the sound pressure attenuation. The maximum value calculator 53 extracts and outputs the maximum value of the digital signal.

In the case of the inspection mode, the maximum value extracted by the maximum value calculator 53 is input to the ratio calculator 15, and the ratio calculator 15 calculates the maximum value and the external force reference value stored in the reference value setter 16. Calculates and outputs the ratio.

Similarly to the reference value setting mode, the sound wave generated by the impact is converted into an electric signal by the microphone 3, amplified by the amplifier 4, and converted into a digital signal by the A / D converter 52. At this time, the operation of the A / D converter 52 is started by a trigger signal from the trigger detector 17, and is performed for a certain period of time until sound pressure decay. The digital signal is separated into a time series signal for each frequency band by a digital BPF 61, converted into a DC signal by a rectifier 62, and input to a maximum value calculator 63. The maximum value calculator 63 extracts and outputs the maximum value of the DC signal.

In the case of the inspection mode, the maximum value extracted by the maximum value calculator 63 is input to the corrector 64,
Reference numeral 4 calculates an appropriate correction value based on the ratio obtained from the ratio calculator 15, corrects the maximum value obtained from the maximum value calculator 63, and outputs the corrected value.

The corrected maximum value is compared by a comparator 65 with a sound pressure reference value stored in a reference value setting device 66. If the reference value deviates from a predetermined relationship set in advance, a comparison result signal is output from the alarm 18 Is output to The predetermined relationship to set is
As in the embodiment shown in FIG. 1, for example, in a certain band, when the corrected maximum value is within the range of 80% to 120% with respect to the sound pressure reference value of the band, the comparison result signal is regarded as normal. Is set to output a comparison result signal when the value is out of this range, that is, when it is less than 80% and more than 120%, as an abnormality. Also, other,
In a certain band, it is set so that the comparison result signal is output as out of the range when it deviates from 70% to 110% with respect to the sound pressure reference value of the band.

When the sound pressure reference value is smaller than the overall sound pressure, a comparison result signal is not erroneously output in a frequency band that is not the main component by taking measures such as canceling the comparison on the lower limit side. To When the number of input comparison result signals exceeds a preset number, for example, two, the alarm device 18 sounds a buzzer as a notification need and flashes a lamp to give an alarm.

As described above, by using the digital BPF 61 as a method of obtaining a time series signal for each frequency band, the size of the apparatus can be reduced, and since the processing is performed by software (S / W), the filter characteristic is changed and the frequency band to be diagnosed is changed. It is possible to flexibly cope with the addition of, for example.

Embodiment 4 FIG. 5 is a configuration diagram of a looseness inspection device for a ripple spring of a generator according to still another embodiment of the present invention. Although the digital BPF is used to obtain the maximum value for each frequency band in the embodiment of FIG. 4, wavelet transform (Wavelet Transform) is used.
form) may be used. Hereinafter, the case where the wavelet transform is used will be described with reference to the configuration diagram of FIG.

In this embodiment, a wavelet transform operation unit 71 is provided to obtain a time-series signal for each frequency band.
This is the same as the embodiment. In the wavelet transform, an effective value is calculated by the analysis operation, so that it is not necessary to provide a rectifier.

In the figure, reference numeral 71 denotes a wavelet transform (WaveletTransform) as a transforming means.
An arithmetic unit that separates a digital sound pressure signal into a time series signal for each frequency band by expanding or reducing a basis function (mother wavelet). The wavelet-transformed signal is supplied to a maximum value calculator 6 provided in 28 sets.
3, input to the corrector 64 and the comparator 65.

The comparator 65 is compared with the sound pressure reference value stored in the reference value setting device 66 in the same manner as shown in FIGS. 1 and 4, and when a predetermined relationship is established, The comparison result signal is output to the alarm 18.

At this time, by selecting an appropriate basis function in accordance with the measured waveform and the phenomenon to be observed, the frequency separation characteristics can be improved, and the reliability of the inspection can be improved. In addition, the size of the apparatus can be reduced by using the wavelet transform operation unit.

Embodiment 5 FIG. 6 is a configuration diagram of a looseness inspection device for a ripple spring of a generator according to still another embodiment of the present invention. In the embodiment of FIG. 4, the digital BPF is used to find the maximum value for each frequency band, but a short-time FFT may be used. Below, short-time FFT
The case where is used will be described with reference to FIG. In this embodiment, a short-time FFT calculator 81 is provided,
A time-series signal for each frequency band is obtained.

Other operations are the same as those of the embodiment shown in FIG. In the short-time FFT, an effective value is calculated by the analysis operation, so that it is not necessary to provide a rectifier. In FIG. 6, reference numeral 81 denotes a short-time FF as a conversion unit.
T (STFT: Short-Time Fourier
-Transform) arithmetic unit, which obtains a time-series signal for each frequency band.

As described above, the short-time F which is a Fourier transformer
By providing the FT calculator 81 and obtaining a time-series signal for each frequency band, the frequency resolution can be improved.

Therefore, the reliability of diagnosis can be improved when the characteristic of the change in frequency appears due to the configuration of the ripple spring by utilizing the excellent resolution of the short-time FFT. Further, the size of the apparatus can be reduced by using the short-time FFT operation unit.

Further, in each of the above embodiments, a method in which an external force is applied by a hammer has been described, but a method in which an external force is applied by other means, for example, a method in which an exciting force is applied by an electromagnetic wave, a cylinder, or the like may be used.

In each of the above embodiments, the external force is detected by the excitation force sensor 11 and the striking sound is detected by the microphone 3, but the striking sound is detected by using a vibration detector instead of the microphone. Is also good. In the above embodiments, the audible frequency is referred to as sound, and the frequency range wider than the audible frequency is referred to as vibration. However, in the present invention, the inspection apparatus is not limited to sound, but may be referred to as sound. Are not distinguished, and include those caused by vibration.

Although the alarm device 18 is used to give an alarm, each signal and the calculated value in such an inspection, for example, each sound pressure reference value stored in the setting device 10 in the embodiment of FIG. The normal and abnormal ranges serving as comparison standards set in the comparator 9, the correction value calculated by the ratio calculator 15, the corrected maximum value from each of the correctors 8 in the inspection, and the like are represented as dots or bands. Items that are displayed on the CRT and that are out of the range are color-coded in red or the like, so that they can be easily checked, thereby improving operability.

The maximum value corrected by the corrector 8 may be superimposed on a normal range and displayed so as to be visually grasped. At this time, if the comparison result deviates from the predetermined relationship, the maximum value detected at that time may be displayed in red, or the like.

Further, by pulling the small inspection robot equipped with the looseness inspection device of the present invention into the air gap between the rotor and the stator of the generator, the operation of pulling out the rotor during the periodic inspection can be simplified.

Instead of the sound pressure reference value and the comparison reference shown in the third to fifth embodiments, the sound pressure reference value and the comparison reference obtained in the same manner as in the second embodiment are used. You can also.

[0094]

Since the present invention is configured as described above, it has the following effects.

Signal detecting means for detecting a vibration generated from a ripple spring to which an external force is applied as a vibration signal; converting means for converting the vibration signal into a plurality of time-series signals for each of a plurality of predetermined frequency bands; Extraction means for extracting the maximum value for each frequency band, and comparison means for comparing each maximum value with a preset vibration reference value for each frequency band are provided. The frequency distribution of the pressure can be accurately grasped, and the reliability of comparison can be improved.

The converting means is a plurality of band filters for passing frequency components of a predetermined frequency band of the vibration signal. The extracting means rectifies the frequency components passing through each band filter, and converts each of the rectified frequency components. Since the maximum value among the peak values is extracted as the maximum value, if the converting means is a band-pass filter, the processing can be performed at high speed, and the apparatus is simple and inexpensive.
Further, since the extracting means extracts the maximum value from the rectified frequency components, it is possible to detect even when the maximum value is present in the negative sign part of the vibration signal, and to accurately compare even when the vibration signal is rapidly attenuated.

Further, the transforming means is a wavelet transforming means for wavelet transforming the vibration signal, and the extracting means extracts the maximum value for each frequency band based on the result of the conversion by the wavelet transforming means. It is possible to improve characteristics at the time of separating into time-series signals for each frequency band, and to improve the reliability of comparison and inspection.

Since the converting means is a short-time fast Fourier transform means, and the extracting means extracts the maximum value for each frequency band based on the result of the conversion by the short-time fast Fourier transform means, the frequency resolution is improved. be able to.

Further, an external force detecting means for detecting the magnitude of the applied external force is provided, and at least one of a vibration signal, a time-series signal, a maximum value, and a vibration reference value is corrected according to the magnitude of the external force. Since it is characterized by the provision of a correction means, by correcting according to the magnitude of the external force,
In the comparison by the comparison means, the influence of the variation in the magnitude of the external force can be prevented, and the reliability of the comparison is improved.

Further, an external force detecting means for detecting the magnitude of the applied external force is provided, and at least one of a signal detecting means, a converting means, an extracting means and a comparing means when the magnitude of the external force exceeds a predetermined value. A command means for commanding the start of operation is provided. Since the operation is not started until a command is issued, the surrounding noise, vibration, noise, etc. when there is no command may be erroneously processed as a vibration signal. There is no. Therefore, the influence of these can be prevented, and the reliability of the inspection is improved.

Further, external force detecting means for detecting the magnitude of the applied external force as an external force signal is provided, ratio calculating means for calculating a ratio obtained by dividing the external force signal by a preset external force reference value, Correction means for correcting the relationship between the maximum value and the vibration reference value in the comparison means by correcting at least one of the vibration signal, the time-series signal, the maximum value and the vibration reference value based on the ratio; It is characterized by having a ratio inspection means for inspecting whether or not it is within the range, so that it can be understood that an improper external force that is out of the predetermined range is given, and the reliability of comparison can be improved. it can.

Further, external force signal amplifying means for amplifying the external force signal and outputting it as an amplified external force signal and vibration signal amplifying means for amplifying the vibration signal and outputting it as an amplified vibration signal are provided. It shall be used as an external force signal, the converting means shall use the amplified vibration signal as a vibration signal, and a range over detecting means for detecting that at least one of the peak values of the amplified external force signal and the amplified vibration signal has exceeded a predetermined value. Since it is characterized in that it has been provided, it is detected that the amplified external force signal or the amplified vibration signal exceeds a predetermined value, that is, it is detected that a large signal is input such that the external force signal amplifying means or the vibration signal amplifying means is saturated. As a result, the reliability of the inspection can be ensured.

Also, since the automatic gain setting means for automatically setting the gain of at least one of the external force signal amplifying means and the vibration signal amplifying means is provided, the amplified external force signal and the amplified vibration signal can be obtained. The amplification factor can be easily set so as to be in an appropriate output range, and operability is improved.
Further, a decrease in the S / N ratio can be prevented, and the reliability of the inspection can be improved.

The comparison means is characterized in that the comparison is performed based on a vibration reference value set based on a vibration signal generated when an external force is applied to the ripple spring in a predetermined state. In addition, it is possible to easily set a vibration reference value according to the state of the ripple spring, and it is possible to improve the reliability of the inspection.

[Brief description of the drawings]

FIG. 1 is a configuration diagram of a looseness inspection device for a ripple spring of a generator according to an embodiment of the present invention.

FIG. 2 is a detailed view of a ripple spring portion of the generator.

FIG. 3 is a configuration diagram of a looseness inspection device for a ripple spring of a generator according to another embodiment of the present invention.

FIG. 4 is a configuration diagram of a generator for checking looseness of a ripple spring of a generator according to another embodiment of the present invention.

FIG. 5 is a configuration diagram of a looseness inspection device for a ripple spring of a generator according to another embodiment of the present invention.

FIG. 6 is a configuration diagram of a looseness inspection device for a ripple spring of a generator according to another embodiment of the present invention.

[Explanation of symbols]

1 Ripple spring, 2 hammer, 3 microphone, 4
Amplifier, 5 analog BPF, 6 rectifier, 7 peak hold circuit, 8 corrector, 9 comparator, 10 reference value setting device, 11 excitation force sensor, 12 amplifier, 13
Rectifier, 14 peak hold, 15 ratio calculator, 1
6 Reference value setting device, 17 trigger detector, 18 alarm device, 19 ratio judgment device, 20 range automatic setting device, 21
Range over detector, 31 rectifier, 32 peak hold, 33 range automatic setting device, 34 range over detector, 41 maximum value calculator, 51, 52 A / D converter, 53 maximum value calculator, 61 digital BPF, 62
Rectifier, 63 Maximum value calculator, 64 Corrector, 65
Comparator, 66 Reference value setting unit, 71 Wavelet transform operation unit, 81 Short-time FFT operation unit.

Claims (10)

[Claims] 1. A signal detecting means for detecting a vibration generated from a ripple spring to which an external force is applied as a vibration signal; a converting means for converting the vibration signal into a time series signal for each of a plurality of predetermined frequency bands; Extraction means for extracting the maximum value of the time-series signal for each frequency band, and comparison means for comparing each of the maximum values with a preset vibration reference value for each frequency band. Looseness inspection device. 2. The converting means is a plurality of bandpass filters for passing a frequency component of a predetermined frequency band of the vibration signal,
2. The method according to claim 1, wherein the extracting means rectifies the frequency components passing through the band-pass filters, and extracts a maximum value among peak values of the rectified frequency components as maximum values. An apparatus for inspecting looseness of a ripple spring of a generator as described in the above. 3. The method according to claim 1, wherein the transforming means is a wavelet transforming means for performing a wavelet transform on the vibration signal, and the extracting means extracts a maximum value for each frequency band based on a result of the transformation by the wavelet transforming means. Item 2. An inspection device for a looseness of a ripple spring of a generator according to Item 1. 4. The short-time fast Fourier transform means for short-time fast Fourier transform of the vibration signal, and the extracting means extracts a maximum value for each frequency band based on a result of the conversion by the short-time fast Fourier transform means. The apparatus for inspecting the looseness of a ripple spring of a generator according to claim 1, characterized in that: 5. An external force detecting means for detecting the magnitude of the applied external force, and correcting at least one of a vibration signal, a time-series signal, a maximum value, and a vibration reference value according to the magnitude of the external force. The apparatus for inspecting a looseness of a ripple spring of a generator according to claim 1, further comprising a correcting means. 6. An external force detecting means for detecting the magnitude of the applied external force, and at least one of a signal detecting means, a converting means, an extracting means, and a comparing means when the magnitude of the external force exceeds a predetermined value. 2. A device for inspecting looseness of a ripple spring of a generator according to claim 1, further comprising command means for commanding start of operation. 7. An external force detecting means for detecting the magnitude of the applied external force as an external force signal, and a ratio calculating means for calculating a ratio obtained by dividing the external force signal by a preset external force reference value; Correcting means for correcting at least one of the vibration signal, the time-series signal, the maximum value, and the vibration reference value based on the relationship to change the relationship between the maximum value and the vibration reference value in the comparing means; The apparatus for inspecting looseness of a ripple spring of a generator according to claim 1, further comprising a ratio inspection means for inspecting whether or not the value is within a range. 8. An external force signal amplifying means for amplifying an external force signal and outputting it as an amplified external force signal, and a vibration signal amplifying means for amplifying a vibration signal and outputting the amplified vibration signal as an amplified vibration signal, wherein the ratio calculating means comprises the amplified external force signal. Is used as an external force signal, the converting means uses the amplified vibration signal as a vibration signal, and a range for detecting that the peak value of at least one of the amplified external force signal and the amplified vibration signal exceeds a predetermined value. 8. The apparatus for inspecting looseness of a ripple spring of a generator according to claim 7, further comprising over-detection means. 9. The generator ripple according to claim 8, further comprising automatic amplification factor setting means for automatically setting the amplification factor of at least one of the external force signal amplifying device and the vibration signal amplifying device. Spring looseness inspection device. 10. The comparison means according to claim 1, wherein the comparison is performed based on a vibration reference value set based on a vibration signal generated when an external force is applied to the ripple spring in a predetermined state. The looseness inspection device for a ripple spring of a generator according to any one of claims 1 to 9.