JPS6312539B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to an impact diagnostic device suitable for inspecting the insulation of generator coils, motor coils, etc., for example.

FIG. 1 shows the state of testing a generator coil using a conventional insulation testing method. In FIG. 1, the coil 1 is inserted into the groove 2A of the core 2. In addition, the coil 1 is shown in a second section showing a schematic cross section thereof.
As is clear from the figure, it is composed of a core wire 3 and an insulator 4 surrounding the core wire. in general,
When such a coil 1 is used in a generator, the insulator 4 is initially firmly attached to the core wire 3. Therefore, when the coil 1 is struck by the hammer 5, the coil 1 generates a striking sound such as "kong, kong" or "kang, kang" depending on the cross-sectional size or length of the coil 1. The inspector of the insulator 4 hears this impact sound and uses his years of experience to judge whether each part of the insulator 4 is good or bad.

It is widely known that even if the insulator 4 of the coil 1 is initially determined to be good, the insulation performance of the insulator 4 gradually deteriorates over many years of use.
When the insulation performance of the insulator 4 deteriorates, the insulator 4 covering the core wire 3 swells or the insulator 4 separates from the core wire 3. In this case, hammer 5
When a blow is applied to the insulator 4 using the insulator 4, an impact sound that is duller than when the insulator 4 is in a good condition, such as a "boko, boko" sound, is produced.

Conventionally, an inspector of the insulator 4 has judged by hearing the impact sounds generated when the insulator 4 is good and when it is bad. However, when determining impact sounds at power plants or factories,
If the ambient noise is large, it may become difficult to judge whether the insulator 4 is good or bad, or the judgment may be made incorrectly. Furthermore, if a large impact force is applied to the insulator 4 with the hammer 5 in order to make the impact sound louder in order to avoid misjudgment, even if the insulator 4 is in a good state, there is a problem in that the insulation properties are deteriorated. Therefore, it is necessary to suppress the impact force of the hammer 5. Furthermore, there is a possibility that the criteria for determining the quality of the insulator 4 may vary depending on the physical condition of the person inspecting the insulator 4 on the day of the inspection or the passage of time during the day.

It is an object of the present invention to eliminate such conventional drawbacks and to provide an impact diagnosis device that can accurately judge the insulator 4 regardless of the surrounding environmental conditions and the physical condition of the inspector.

The present invention will be explained below based on illustrated examples.

FIG. 3 is a block diagram showing one embodiment of the impact diagnosis device according to the present invention. In the figure, parts corresponding to those in FIG. 1 are given corresponding symbols. This also applies to the following drawings. In FIG. 3, the pressure sensitive element 6 is fixed to the striking surface of the hammer 5. The amplifier 7 is connected to the pressure sensitive element 6 and amplifies the output of the pressure sensitive element 6. The Schmitt circuit 8 is connected to the amplifier 7 and generates an output voltage only when the magnitude of the output signal of the amplifier 7 exceeds a certain level. The integrator 9 is connected to the Schmitt circuit 8 and integrates the output signal of the Schmitt circuit 8.
The peak value holding circuit 10 is connected to the amplifier 7 together with the Schmitt circuit 8, and is configured to continuously hold the maximum value of the output signal of the amplifier 7 and extract the output of the maximum value. The divider 11 is connected to the integrator 9 and the peak value holding circuit 10, and divides the respective output signals. The judge 12 is connected to the divider 11, and compares the magnitude of the output of the divider 11 with a reference value to judge whether the insulator 4 shown in FIG. 2 is good or bad. 12a and a lamp 12b that lights up when a failure occurs. Furthermore, the output signal of the Schmitt circuit 8 is applied to the determiner 12 through a negative pulse generating circuit 13. The pushbutton switch 14 is connected to a reset command generator 15, and operates the reset command generator 15 when it is pressed and closed. The command signal from the reset command generator 15 is applied to the integrator 9, peak value holding circuit 10, divider 11, and determiner 12 to reset their respective operations.

Next, the operation of this impact diagnosis device will be explained.
In this explanation, application to the coil 1 shown in FIG. 4 will be taken as an example. In FIG. 4, 4A indicates a location with good insulation, and 4B indicates a location with poor insulation. When the hammer 5 is used to strike the well-insulated area 4A and the other poor-insulated area 4B of the coil 1, the shock applied to the hammer 5 as a reaction is caused by the difference in softness and hardness of each surface as described above. Power is different. Therefore, the pressure-sensitive element 6, which is fixed to the hammer 5 and converts the magnitude of the striking force into an electric signal, includes, for example, a fifth
Different output signals result, as shown by the solid and dashed lines in Figure a. In FIG. 5a, the solid line indicates the signal at the good insulation location 4A, and the broken line indicates the signal at the poor insulation location 4B. Generally, in the case of the well-insulated part 4A where the surface of the insulator 4 that receives the blow is hard, the output signal of the pressure-sensitive element 6 has a waveform with a large peak value and a short time width, as shown by the solid line. On the other hand, in the case of the poor insulation spot 4B where the surface receiving the blow is soft, the output signal of the pressure sensitive element 6 has a waveform with a small peak value and a long time width, as shown by the broken line. Since the output signal of the pressure sensitive element 6 is amplified by the amplifier 7, the output signal of the amplifier 7 has a similar waveform to the input signal, and has a waveform as shown in FIG. 5a, although the magnitude is different. The output signal of the amplifier 7 is applied to a Schmitt circuit 8 and a peak value holding circuit 9. The Schmitt circuit 8 generates the voltage Vs only when the magnitude of the input signal exceeds _A0 shown in FIG. 5a. Hereinafter, a signal corresponding to the good insulation location 4A will be discussed first, followed by a signal corresponding to the poor insulation location 4B. When the solid line waveform with the maximum value _A1 shown in FIG. 5a is applied to the Schmitt circuit 8, the time point as shown in FIG.
Since the voltage becomes _A0 at _T1 , the output voltage of the Schmitt circuit 8 becomes Vs as shown in FIG. This state continues until the time _T3 when the input voltage of the Schmitt circuit 8 becomes less than _A0 , that is, for the time _t1 , and the output voltage of the Schmitt circuit 8 becomes Vs. When the output voltage Vs of the Schmitt circuit 8 is applied to the integrator 9, the integrator 9 outputs a time signal as shown in FIG.
Starting the integration from T ₁ and ending the integration at time T ₃ ,
The output voltage of the integrator 9 becomes _B1 . This output voltage
B ₁ is applied to the divisor side of the divider 11. on the other hand,
The output signal of the amplifier 7 is also applied to the peak value holding circuit 10, and the output voltage of the peak value holding circuit 10 is continuously held at the maximum voltage _A1 as shown by the solid line in FIG. 5d. This maximum voltage A ₁ is applied to the dividend side of the divider 11. As a result, the divider 11
The output becomes a voltage proportional to A ₁ /B ₁ or A ₁ /t ₁ , and this output voltage is applied to the determiner 12 .

Next, a case will be described in which a signal corresponding to the insulation failure location 4B is applied to the Schmitt circuit 8 and the peak value holding circuit 10. As shown in FIG. 5a, when a broken line signal with a maximum value _A2 is applied to the Schmitt circuit 8, this signal becomes _A0 or more between time _T2 and time _T4 , so that during this period time t ₂
At this point, the output voltage of the Schmitt circuit 8 becomes Vs. When this output voltage Vs is applied to the integrator 9,
The output voltage of the integrator 9 becomes as shown by the broken line in FIG. 5c, and the final value becomes _B2 . This final value B ₂ is applied to the divider 11 . On the other hand, the peak value holding circuit 10
Since the maximum voltage A ₂ is continuously maintained as shown by the dotted line in FIG. 5d, this maximum voltage A ₂ is applied to the dividend side of the divider 11. As a result, the output of the divider 11 becomes a voltage proportional to A ₂ /B ₂ or A ₂ /t ₂ , and this output voltage is applied to the determiner 12 .

As shown in FIG. 5e, the negative pulse generating circuit 13 is configured to generate a negative pulse at the moment when the output signal of the Schmitt circuit 8 goes from Vs to zero (time T ₃ or time T ₄ ). ing. Judgment device 1
2, after this negative pulse is input, the output voltage separately applied from the divider 11 is compared with a reference voltage arbitrarily set inside the determiner 12.
As a result of this comparison, if the output voltage of the divider 11 is higher than the reference voltage, the good lamp 12a lights up.
If the output voltage of the divider 11 is lower than the reference voltage, the defective lamp 12b is lit.

When determining the state of the insulator 4 with the determiner 12,
It is better to compare the ratio of the maximum value of the input signal to the time width of the input signal (A ₁ /t ₁ , A ₂ /t ₂ ) than to simply compare the maximum value of the input signal to the judgment unit 12. It is good to see a clear difference. As a specific example, see Figure 5a.
In the case where A ₁ :A ₂ =3:2 and t ₁ :t ₂ =1:3, A ₁ /t ₁ and A ₂ /t ₂ are compared. Simply comparing the maximum value of the input waveform gives A ₁ /A ₂ = 1.5, but comparing A ₁ /t ₁ and A ₂ /t ₂ gives A ₁ /t ₁ /A ₂ /t ₂ = 4.5. . Furthermore, when comparing the maximum values of the input waveforms, if the impact force of the hammer 5 that strikes the coil 1 varies, it becomes difficult to determine whether the input waveform is a good insulation location 4A or a poor insulation location 4B. However, in the embodiment of the present invention, since the maximum amplitude is divided by the time width, it is not affected by the impact force of the hammer 5.

As described above, compared to the comparison of the maximum values of the input waveforms, according to the embodiment of the present invention, there is a clear difference between the good insulation location 4A and the poor insulation location 4B.

In this way, when performing a second determination after the first determination has been completed, the inspector presses the push button switch 14, and the reset command generator 15, integrator 9, peak value holding circuit 10, A reset command is applied to the divider 11 and the determiner 12 to restore the initial state in which they can be determined.

FIG. 6 is a block diagram showing a portion of another embodiment of the impact diagnosis device according to the present invention. In FIG. 6, a level detector 16 generates an output when the output of the amplifier 7 is saturated. The overload lamp 17 is attached to the hammer 5 via a cushion 18 and is turned on by the output of the level detector 16. That is, in the embodiment of FIG.
The push-button switch 14 is installed in the main part of the impact diagnosis device away from the hammer 5, but the push-button switch 14 is installed in the embodiment shown in FIG.
is installed near the hammer 5 or attached to the hammer 5. Therefore, in the embodiment shown in FIG. 3, it was necessary for the inspector to walk up to the main part of the impact diagnosis device and press the push button switch 14 every time he or she made a judgment, but on the other hand, in the embodiment shown in FIG. In the embodiment shown, pushbutton switch 1
4 is attached near the hammer 5 or on the handle of the hammer 5, so that the push button switch 14 closes every time the hammer 5 hits, thereby allowing smooth repetition of hitting, judgment, and resetting. be. In this case, the reset signal generating circuit 15 is provided with a delay circuit and is configured to generate a reset signal after determining whether the insulator 4 is good or bad.

Further, in the embodiment shown in FIG. 3, saturation of the output signal of the amplifier 7 is not considered. That is,
When the amplifier 7 becomes saturated, the reliability of the determination result obviously decreases. Therefore, in the embodiment shown in FIG. 6, the level detector 16 is connected to the output side of the amplifier 7,
The overload lamp 17, which is lit by the output of the level detector 16, is connected to the hammer 5 through the cushion 18.
It is designed to be attached to the end of the handle.
Further, the level detector 16 is configured to output a constant voltage when the amplifier 7 is saturated.
Therefore, if the impact force of the hammer 5 is excessive and the amplifier 7 is saturated, the overload lamp 17 will be lit, indicating that the impact force of the hammer 5 is excessive. In this case, saturation of the amplifier 7 can be avoided by reducing the striking force of the hammer 5 or by lowering the amplification factor of the amplifier 7.

In the above embodiment, the judgment result is displayed using lamp 1.
Although this is done by lighting up the lights 2a and 12b, the same effect can be obtained by displaying with a meter or numerical values.

Although the above embodiment describes the case where the insulator 4 of the coil 1 is diagnosed, the object to be inspected is not limited to the coil 1. It goes without saying that the present invention can also be applied to investigating the softness and hardness of.

This invention is constructed as described above, and a pressure-sensitive element is fixed to the striking surface of the hammer that strikes the coil, and the quality of the insulator is determined and displayed based on the output signal of this pressure-sensitive element. This has the effect of making insulation diagnosis easier.

[Brief explanation of the drawing]

FIG. 1 is a diagram showing the inspection status of a generator coil using a conventional insulation testing method, FIG. 2 is a schematic cross-sectional view of the coil shown in FIG. 1, and FIG. Figure 4 is a perspective view showing a coil with poor insulation, Figure 5 is a block diagram showing the
Figure a is the percussion waveform or the output waveform of the amplifier, Figure 5b is the output waveform of the Schmidts circuit, Figure 5c is the output waveform of the integrator, Figure 5d is the output waveform of the peak value holding circuit, and Figure 5e. 6 is a block diagram showing a portion of another embodiment of the impact diagnosis device according to the present invention. In the figure, 1 is a coil, 5 is a hammer, 6 is a pressure sensitive element, 7 is an amplifier, 8 is a Schmitt circuit, 9
10 is an integrator, 10 is a peak value holding circuit, 11 is a divider, 12 is a determiner, 16 is a level detector, and 17 is an overload lamp. In each figure, the same reference numerals indicate the same or corresponding parts.

Claims (1)

[Scope of Claims] 1. A pressure-sensitive element attached to the striking surface of an object that strikes the object, an amplifier that amplifies the output of the pressure-sensitive element, and produces an output when the output of the amplifier exceeds a certain level. a Schmitt circuit, an integrator that integrates the output of the Schmitt circuit, a peak value holding circuit that holds the maximum output of the amplifier, a divider that divides the maximum output of the peak value holding circuit by the output of the integrator, and the division A blow diagnosis device characterized by comprising a determining device that determines the magnitude of the output of the device. 2. The impact diagnosis device according to claim 1, wherein the contents of the integrator, peak value holding circuit, divider, and determiner are reset by a reset signal. 3. The impact diagnosis device according to claim 2, wherein the reset signal is automatically generated each time the impact of the object to be hit is completed. 4. The impact diagnosis device according to claim 2, wherein the reset signal is generated by pressing a push button switch. 5. The impact diagnosis device according to claim 4, wherein the push button switch is installed at or near the hitting object. 6. The impact diagnosis device according to claim 1, further comprising a display device that displays the saturated state of the output of the amplifier. 7. The display device includes a level detector that detects the level of the output of the amplifier and produces an output when the level exceeds a predetermined value, and an overload lamp that is energized by the output of the level detector. The impact diagnosis device according to claim 6. 8. The impact diagnosis device according to claim 7, wherein the overload lamp is installed at or near the hitting object.