KR100213708B1 - Surge current response characteristic inspection apparatus for stator - Google Patents

Abstract

The present invention relates to an apparatus for inspecting surge current response characteristics of a stator, and in particular, by applying a high-pressure impulse to a stator in which a coil is formed on a laminated core, and inspecting an impulse response waveform of the stator, it is possible to inspect whether a manufactured stator is defective. The present invention relates to a device for inspecting surge current response characteristics of a stator.

The apparatus for inspecting the surge current response characteristic of the stator of the present invention stabilizes voltages at both ends of the surge current generating means for generating an impulse signal, the stator bridge means to which the impulse signal generated by the surge current generating means is applied, It characterized in that it comprises a one-to-one transformer, a bridge rectifying means for rectifying the output voltage of the one-to-one transformer and display means connected to both ends of the bridge rectifying means.

Description

Device for checking the surge current response characteristic of the stator

The present invention relates to an apparatus for inspecting surge current response characteristics of a stator, and in particular, by applying a high-pressure impulse to a stator in which a coil is formed on a laminated core, and inspecting an impulse response waveform of the stator, it is possible to inspect whether a manufactured stator is defective. The present invention relates to a device for inspecting surge current response characteristics of a stator.

In general, a motor is equipped with a stator as a means for generating a magnetic field for rotating the rotor, which is shown in FIG.

According to FIG. 1, the stator includes a laminated core 2 having a plurality of magnetic pole pieces 1 formed therein, a coil 3 wound on the magnetic pole piece 1, and the coil 3 and the above. It consists of an insulator 4 which insulates the core 2.

At this time, the coil 3 is composed of a main coil 3a which is wound on the pole piece 1 side, and a sub coil 3b which is wound between each main coil 3a and the main coil 3a.

Therefore, when three phase AC power is applied to a power cable (not shown) connected to the main, sub and common terminals of the coil 3, the main coil 3a and the subcoil of the coil 3 are applied. The rotor (not shown) is rotated by the magnetic field induced at 3b.

However, in the manufacturing process of the stator, a part of the coil 3 is short-circuited to each other, or the coil 3 and the core 2 come into contact with each other due to a failure of the insulator 4. If the bad stator is used for the production of the motor, the motor cannot be used due to the technical defect of the stator. Therefore, before the motor is manufactured, it may be determined whether the stator is already defective. Necessity was required.

Accordingly, according to the necessity of determining whether the stator is defective, the conventional stator surge current response characteristic inspection apparatus as shown in FIG. 2 is used to determine whether the stator is defective. According to FIG. The surge current response characteristic inspection apparatus displays a surge current response means 5 and a surge current response of the stator 7 after the surge current is applied to the stator 7 by the surge current generation means 5. Means (8).

At this time, the surge current generating means 5 and the display means 8 are connected to the stator 7 independently of each other.

The surge current generating means 5 is a high voltage transformer 9 to which a power supply voltage is applied, a high voltage diode 10 to which an output of the high voltage transformer 9 is applied, and A capacitor 12 connected between the high voltage transformer 9 and the high voltage diode 10 and a plurality of silicon controlled rectifiers 11 having one end connected to the high voltage diode 10 and the capacitor 12 ( Hereinafter referred to as SCR).

Therefore, when the power supply voltage is applied to the high voltage transformer 9 of the surge current generating means 5, the high voltage diode 10 connected to the high voltage transformer 9 half-wave rectifies the output voltage of the high voltage transformer 9. This half-wave rectified output voltage is converted into a DC voltage by the peak to peak detection by the capacitor 12 and then applied to the gates of the plurality of SCRs 11. The plurality of SCRs 11 then outputs an impulse signal.

Therefore, when the impulse signal generated from the surge current generating means 5, that is, the surge current is applied to the stator 7, the stator 7 responds to the surge current applied thereto. When displayed by the display means 8 such as an oscilloscope, the inspector of the stator 7 examines the surge current response waveform of the stator 7 displayed by the display means 8 so that the stator 7 is defective. It will be judged.

However, the inspection as to whether or not the stator is defective by the surge current response characteristic inspection apparatus of the conventional stator as described above is made by examining the impulse response waveform of the stator with respect to the surge current displayed by the display means 8 above. In this case, the impulse response waveform may be a ripple generated when a half-wave rectified voltage is detected by the capacitor 12 by the capacitor 12 when the half-wave rectified voltage is included in the surge current generating means 5. Alternatively, since the distortion is severely distorted by the noise as shown in FIG. 5 (b) due to the impedance change according to the connection state of the stator, whether the stator 7 is defective through the highly distorted response waveform. There is a problem that is not easy to determine.

After the inspection of one stator 7 is completed, another test stator is newly connected to the surge current generating means 5 and the display means 8 as described above, and then the response characteristics to the surge current are again displayed. Because of the inspection, a large amount of time was spent to inspect the large amount of stays produced.

Therefore, the present invention is to solve the problem of the conventional stator current response characteristics test device as described above, the stator response to the surge current by removing the noise components included in the response waveform for the surge current of the stator It is an object of the present invention to provide an apparatus for inspecting surge current response characteristics of a stator which can easily make a defect determination of a stator using a waveform and can shorten a time required for determining whether the stator is defective.

1 is a perspective view showing a configuration of a stator mounted on a motor.

2 is a block diagram showing the configuration of a surge current response characteristic inspection apparatus of a conventional stator.

3 is a circuit diagram showing the configuration of an impulse signal generating means used in a surge current response characteristic inspection apparatus of a conventional stator.

Fig. 4 is a block diagram showing the structure of the apparatus for inspecting surge current response characteristics of the stator of the present invention.

Fig. 5 is a circuit diagram showing the configuration of the surge current response characteristic inspection apparatus of the stator of the present invention.

Fig. 6 (a) shows the impulse response waveform of the stator by the conventional surge current response characteristic inspection apparatus.

Fig. 6 (b) shows the impulse response waveform of the stator by the surge current response characteristic inspection apparatus of the stator of the present invention.

* Explanation of symbols for main parts of the drawings

5: Surge current generating means 7: Inspection stator

12: Capacitor 13: Reference Stator

16: 1 to 1 transformer 18: Stator bridge means

19: stator position fixing means 20: stator surge current response inspection means

The apparatus for checking the surge current response characteristic of the stator of the present invention for achieving the above object includes a surge current generating means for generating an impulse signal, a stator surge current response checking means for applying an impulse signal from the surge current generating means; And display means connected to said stator surge current response checking means.

More preferably, the stator surge current response checking means comprises: a stator bridge means to which an impulse signal is applied in the surge current generating means, a one-to-one transformer for stabilizing voltages at both ends of the stator bridge means, and the one-to-one It characterized in that it comprises a bridge rectifying means for rectifying the output voltage of the one transformer.

More preferably, the stator bridge means includes: a stator position fixing means at which an inspection stator is seated at one end, a reference stator connected to the stator position fixing means, a first resistor connected at one end to the reference stator, and the And a second resistor having one end connected to the first resistor.

More preferably, the surge current generating means includes a high voltage transformer to which a power supply voltage is applied, a high voltage diode to which the output of the high voltage transformer is applied, a capacitor connected between the high voltage transformer and the high voltage diode, and the high voltage. And a plurality of SCRs connected to the diode and the capacitor, wherein the ripple period of the output voltage of the capacitor coincides with the period of the SCR.

Therefore, in the surge current generating means, when the high-pressure impulse signal is applied to the node formed by the position fixing means on which the test stator is seated and the reference stator, which is included in the stator surge current response checking means, The high-voltage voltage is generated between the node between the second resistor and the node between the reference stator and the first resistor.

This high-voltage voltage is applied to a one-to-one transformer, stabilized, and then rectified to a DC voltage through bridge rectifying means consisting of a plurality of diodes.

Then, the DC output voltage of the bridge rectifying means is applied to the display means, so that the display means displays the impulse response waveform of the test stator for the impulse signal applied by the surge current generating means.

At this time, the period of the output voltage ripple of the capacitor of the surge current generating means coincides with the period of the SCR to generate a periodic impulse sequence, and the unstable high-voltage voltage generated when applying the impulse sequence is the one-to-one transformer. Since the noise components included in the impulse response are stabilized, the identification of the impulse response waveform is facilitated, so that the operator can respond to the response waveform for the impulse signal of the test stator displayed by the display means. It is possible to easily determine whether the inspection stator of the defect.

Hereinafter, with reference to the accompanying drawings, an embodiment of a surge current response characteristic inspection apparatus of the stator of the present invention will be described in detail.

First, the surge current response characteristic inspection apparatus of the stator according to an embodiment of the present invention is generated in the surge current generating means 5, the surge current generating means 5 as shown in Figs. Stator surge current response checking means 20 to which an impulse signal is applied; and display means 8 connected to the stator surge current response checking means 20, wherein the stator surge current response checking means 20 is provided. Silver rectification means for rectifying the output voltage of the stator bridge means 18, the one-to-one transformer 16 and the one-to-one transformer 16 to stabilize the voltage across the stator bridge means 18 (17).

In addition, the stator bridge means 18 is a stator position fixing means 19 on which the test stator 7 is seated, a reference stator 13 connected to one end of the stator position fixing means 19, and the reference. The first resistor 15 has one end connected to the stator 13 and the second resistor 14 having one end connected to the first resistor 15.

Here, the reference stator 13 is a stator that has been judged good by surge current inspection, and is included in the stator bridge means 18, the reference stator 13, the first resistor 15, and the first agent. The two resistors 14 are fixedly connected to the stator position fixing means 19 described above.

In addition, the surge current generating means 5 includes a high voltage transformer 9 to which a power supply voltage is applied, a high voltage diode 10 to which an output of the high voltage transformer 9 is applied, the high voltage transformer 9 and the above voltage. A capacitor 12 connected between the high voltage diode 10 and a plurality of high voltage diodes 10 and a plurality of SCRs 11 connected to the capacitor 12, that is, as an example, may be configured. The ripple period of the output voltage of the capacitor 12 and the period of the SCR 11 are configured to coincide.

Therefore, when a power supply voltage of AC 220V is applied to the high voltage transformer 9 of the surge current generating means 5, the high voltage diode 10 connected to the high voltage transformer 9 causes the output voltage of the high voltage transformer 9 to be reduced. Half-wave rectified and output, and the half-wave rectified output voltage is converted into a DC voltage containing a ripple component by peak to peak detection by the capacitor 12, and then a plurality of SCRs 11 Is applied to the gate.

The plurality of SCRs 11 then outputs an impulse signal.

At this time, since the period of the ripple included in the DC voltage output from the capacitor 12 and the period of the SCR 11 coincide, the surge current generating means 5 outputs a periodic impulse sequence. In this embodiment, the impulse sequence has a period of about 30 ms.

Therefore, when a high-voltage impulse sequence is applied to the node to which the test stator 7 and the reference stator 13 are connected in the surge current generating means 5, the gap between the test stator 7 and the second resistor 14 is increased. An unstable high voltage is generated between the node and the node between the reference stator 13 and the first resistor 15.

Since the instability of the high-voltage voltage causes noise included in the impulse response of the test stator 7, the high-voltage voltage is applied to the one-to-one transformer 16 and stabilized. It rectifies to DC voltage via the bridge rectification means 17 comprised.

Then, the output voltage of the bridge rectifying means 17 is applied to the display means 8 so that the display means 8 displays the response waveform to the impulse signal applied by the surge current generating means 5. In this case, the response waveform to the impulse signal is a waveform of a sink function type in which noise components are removed as shown in FIG. 6 (a) by stabilization of an unstable high voltage.

On the other hand, the inspection stator 7 which has been inspected is separated from the stator bridge means 18 and another inspection stator (not shown) is connected to the stator bridge means 18 again.

Therefore, the inspection of the surge current response characteristic of the stator includes the stator position fixing means 19 including the test stator 7 in the stator bridge means 18 without a separate fastening for applying an impulse signal to the test stator. This is done quickly by seating on).

By the surge current response characteristic inspection apparatus of the stator of the present invention, the period of the output voltage ripple of the capacitor of the surge current generating means coincides with the period of the SCR to generate a periodic impulse sequence and unstable generated when the impulse sequence is applied. As the high-voltage voltage is stabilized by the one-to-one transformer and the noise components included in the impulse response are removed, the operator inspecting the stator is configured by the response waveform to the impulse signal of the inspection stator displayed by the display means. The effect of being able to easily grasp whether or not the inspection stator is defective is exerted.

In addition, since the impulse signal is applied to the stator bridge means, in order to inspect the impulse response of the test stator, only the test stator needs to be replaced with the stator bridge means including the reference stator. The effect is exerted.

Claims (4)

And a surge current generating means for generating an impulse signal, stator surge current response checking means to which an impulse signal generated by the surge current generating means is applied, and display means connected to the stator surge current response checking means. A surge current response characteristic inspection device for a stator. 2. The stator surge current response checking means according to claim 1, wherein the stator surge current response checking means rectifies the stator bridge means, a one-to-one transformer for stabilizing voltages at both ends of the stator bridge means, and an output voltage of the one-to-one transformer. An apparatus for inspecting surge current response characteristics of a stator, comprising a bridge rectifying means. 3. The stator bridge means according to claim 2, wherein the stator bridge means comprises: a stator position fixing means on which the test stator is seated, a reference stator connected to one end of the test stator, and a first resistance connected to one end of the reference stator. And a second resistor having one end connected to the first resistor. The method of claim 1, wherein the surge current generating means comprises a high voltage transformer to which a power supply voltage is applied, a high voltage diode to which an output of the high voltage transformer is applied, a capacitor connected between the high voltage transformer and the high voltage diode; And a plurality of SCRs connected to the high voltage diode and the capacitor, wherein the ripple period of the output voltage of the capacitor coincides with the period of the SCR.