KR101150503B1 - Device and method of shorted-turn diagnosis for generator rotor windings - Google Patents

Abstract

The present invention relates to a device for diagnosing a rotor winding short circuit.
The apparatus for short-circuiting a rotor winding according to the present invention comprises a test voltage setting means for setting a test voltage to be applied to a rotor winding of a generator, a first measurement region and a second measurement region according to the direction of the winding wound on the rotor An impedance voltage measuring means for measuring an impedance voltage by a test voltage from each of the windings included in the first measurement region and the second measurement region, A winding short-circuit diagnosing means for diagnosing whether or not the rotor winding is short-circuited from a difference value of an impedance voltage between an n-th winding of the first measuring region and an n-th winding of the second measuring region on the basis of the slip ring of the former and n is a natural number.

Description

TECHNICAL FIELD [0001] The present invention relates to a short-circuit fault diagnosis apparatus and a method for diagnosing a short-

The present invention relates to a device for short-circuiting a rotor winding and a method for diagnosing a rotor winding short-circuit.

As power demand increases, generators that supply electric power have become more important, diagnostics for prevention of generator malfunctions become more important as they become larger, higher voltage and smaller and lighter. Most of the electrical failures of generators occur in stator and rotor windings. It takes a long time to recover from such a failure.

Among the failure types of rotor windings, interlayer short circuit, short circuit between windings, grounding, etc. occur. Among these, it is important to detect the interlayer short-circuit phenomenon which is the initial process of fault occurrence and to establish countermeasures.

Diagnosis technique to detect interlayer short-circuit phenomenon in advance is largely an off-line diagnosis method and an on-line diagnosis method. Currently, the most commonly used method in Korea is the stopping diagnosis method. During stoppage, the generator stops and the low voltage is applied to each rotor winding while the rotor is drawn out, and the sharing voltage of each winding is measured. The values of the windings and the windings are compared with each other by the measured sharing voltage to diagnose whether or not an interlayer short circuit occurs.

However, when performing the interlaminar short-circuit test of rotor windings using this method, more than two people are required. It also takes a lot of time to prepare the pre-measurement equipment, connect the measurement circuit, and analyze the measurement results.

The present invention is to provide a device and method for diagnosing a short-circuit of a rotor winding that can reduce the time consuming time in diagnosing rotor winding shortage.

The present invention is directed to a device and method for diagnosing a short-circuit of a rotor winding that can reduce the time to wait for a diagnostic result when diagnosing a rotor winding short.

The present invention seeks to provide a device and method for diagnosing a short-circuit of a rotor winding that can perform a rotor winding short-circuit diagnosis test alone.

According to an aspect of the present invention, there is provided an apparatus for diagnosing a rotor winding short circuit.

The apparatus for short-circuiting a rotor winding according to an embodiment of the present invention includes a test voltage setting means for setting a test voltage to be applied to a rotor winding of a generator, a first measurement region and a second measurement region according to the direction of a winding wound on the rotor, A measurement region selection means for selecting a measurement region to which a test voltage is to be applied among the measurement regions divided by the first measurement region and an impedance voltage measurement for measuring an impedance voltage by the test voltage from each of the windings included in the first measurement region and the second measurement region A winding short-circuited to diagnose whether the rotor winding is short-circuited from the difference value of the impedance voltage between the nth winding of the first measuring area and the nth winding of the second measuring area based on the slip ring of the means and the rotor Means - where n is a natural number.

According to another aspect of the present invention, there is provided a method of diagnosing a rotor winding short circuit.

A method for diagnosing a rotor winding shortage according to an embodiment of the present invention includes applying a preset test voltage to a first measurement area or a second measurement area of a rotor winding, And the second measurement region is a region including a winding wound by rotating in a direction opposite to the first direction to the rotor and including a winding wound around the slip ring of the rotor, Th winding of the first measuring region or the second impedance voltage of the nth winding of the second measuring region, calculating a difference between the first impedance voltage and the second impedance voltage, calculating the calculated first impedance voltage and the first impedance voltage, Comparing the difference value between the first and second impedance voltages with a reference value that is a reference of whether or not the winding is short-circuited to diagnose whether the winding is short-circuited, and outputting the diagnosis result.

According to the embodiment of the present invention, there is an advantage that the preparation time and the diagnosis time for the rotor winding short-circuit test can be reduced.

According to the embodiment of the present invention, there is an advantage that the result of the rotor winding short-circuit test can be immediately known.

According to the embodiment of the present invention, there is an advantage that the rotor winding shorting test can be performed alone.

1 is a block diagram showing a device for diagnosing a short circuit of a rotor winding according to an embodiment of the present invention.
2 is an exemplary view showing an impedance voltage measuring means.
FIG. 3 is a diagram illustrating a method of measuring an impedance voltage of each winding according to an embodiment of the present invention. FIG.
4 is a block diagram illustrating a device for diagnosing a short circuit of a rotor winding according to another embodiment of the present invention.
5 is a flowchart illustrating a method of diagnosing a rotor winding shortage according to an embodiment of the present invention.

While the present invention has been described in connection with certain exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and similarities. It should be understood, however, that the invention is not intended to be limited to the particular embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT Hereinafter, an apparatus and method for diagnosing a rotor winding shortage of a generator according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram showing a device for diagnosing a short circuit of a rotor winding according to an embodiment of the present invention.

1, the apparatus for short-circuiting a rotor winding includes a test voltage setting means 110, a measurement region selection means 120, a test voltage output means 130, an impedance voltage measurement means 140, 150) and a first display means (160).

The test voltage setting means 110 sets a test voltage to be applied to the rotor windings of the generator. The test voltage setting means 110 may receive a constant power supply and generate a test voltage having a predetermined value. For example, the test voltage setting means 110 may generate a plurality of test voltages having different values. Therefore, the test voltage setting means 110 can select a test voltage to be applied to the rotor winding among the plurality of generated test voltages.

The measurement region selection means 120 selects the measurement region which is the region of the rotor winding to which the test voltage is to be applied. Here, the measurement region can be divided into one measurement region and another measurement region according to the direction in which the winding is wound on the rotor. For example, one measurement area may include windings wound in one direction on the rotor. In addition, the other measurement area may include a winding wound on the rotor in a direction opposite to the one direction. Since the rotor windings exhibit different polarities depending on the direction in which the windings are wound on the rotor, in the embodiment of the present invention, one measurement region of the measurement region is referred to as an N pole region, another measurement region of the measurement region is referred to as an S pole region .

When the measurement region selection means 120 receives the N pole region selection signal, the measurement region selection means 120 can connect the winding corresponding to the N pole region to the winding shortage diagnosis means 150. That is, the voltage at one end of the N pole region is transferred to the winding shortage diagnosis means 150. Also, when the measurement region selection means 120 receives the S pole region selection signal, it is possible to connect the winding corresponding to the S pole region to the winding shortage diagnosis means 150. [ That is, the voltage at one end of the S pole region is transmitted to the winding shortage diagnosis means 150.

The test voltage output means 130 applies the test voltage to the selected measurement region.

Impedance voltage measuring means 140 measures the impedance voltage of the winding. Impedance voltage measuring means 140 measures the impedance voltage of each winding according to the test voltage applied to the measurement region.

The winding short-circuit diagnosis means 150 can diagnose a short-circuit of the rotor windings from the impedance voltages of the windings or the gaps measured in the measurement region, respectively.

The winding short-circuit diagnosis means 150 receives the voltage at one end or the other end of each measurement region. Further, the winding short-circuit diagnosis means 150 receives the impedance voltage between windings or gaps included in each measurement area. Therefore, the winding short-circuit diagnosis means 150 can calculate the individual impedance values of the windings using the voltage of the received measurement region and the impedance values of the windings included in the measurement region.

The winding shortage diagnosis means 150 can calculate the difference value between the impedance voltages between the windings of the same order in the N pole region and the S pole region. Here, the windings of the same order in the N pole region and the S pole region are the nth corresponding windings in the N pole region and the S pole region with respect to the slip ring of the rotor. Where n is a natural number. That is, the winding short-circuit diagnosis means measures the impedance of the n-th winding wound around the rotor when the test voltage is applied to the N-pole region and the impedance of the n-th winding wound on the rotor when the test voltage is applied to the S- The difference value of the voltage can be calculated. Then, the n-th winding winding in each area is called an n-th winding. Where n is a natural number.

Further, the winding short-circuit diagnosis means 150 can calculate the difference value of the impedance voltage at the inter-pole contact point where the N pole region and the S pole region are connected. That is, when the test voltage is applied to the N pole region, the winding short-circuit diagnosis means 150 calculates the difference between the impedance voltage measured at the inter-pole contact and the impedance voltage measured at the inter-pole contact when the test voltage is applied to the S pole region Can be calculated.

The winding short-circuit diagnosis means 150 can diagnose the rotor winding to be in a steady state if the difference value between the calculated impedance voltages and the impedance voltage difference between the gaps are less than a predetermined reference value. Or the winding short-circuit diagnosis means 150 can diagnose the rotor winding to be in a short-circuit state if the difference value between the calculated impedance voltages and the difference value between the inter-pole impedance voltages are equal to or less than a preset reference value. Here, the predetermined reference value is the impedance voltage difference value between the N pole region and the S pole region which is diagnosed as a short-circuit state of the rotor winding. For example, the reference value may be ± 5 [%] in the case of the difference value between the impedance voltages between the nth windings of the N pole region and the S pole region. Also, the reference value can be ± 2 [%] for the difference value between the gaps. However, the reference value is not limited thereto but may be changed by a person skilled in the art.

The first display means 160 outputs a diagnosis result of whether or not the winding short circuit diagnosis means 150 short-circuits the rotor winding. The first display means 160 can output not only whether the rotor winding is short-circuited, but also an impedance voltage corresponding to each region measured for each winding. At this time, the first display means 160 may output the measured impedance voltage as a graph or a numerical value.

2 is an exemplary view showing an impedance voltage measuring means.

2, the impedance voltage measuring unit 140 may include a probe 141, an operation unit 142, and a second display unit 143. [

The probe 141 is a device that measures the impedance voltage by contacting the rotor winding. The second display means 143 displays the magnitude of the impedance voltage measured by the probe 141. The second display means 143 can display the magnitude of the impedance voltage measured by the probe 141 as a scale or a numerical value. The operating section 142 transmits the impedance voltage measured by the probe 141 to the winding shortage diagnosis means 150. When the probe 141 receives the signal for measuring the impedance voltage when measuring the impedance voltage, the operating section 142 controls the magnitude of the impedance voltage displayed on the second display means 143 to the winding shortage diagnosis means 150 Lt; / RTI > Impedance voltage measurement means 140 may be included in the rotor winding shorting diagnostic device, but may be externally connected via a cable or the like to a separately configured device with a rotor winding shorting diagnostic device. Impedance voltage measuring means 140 measures the winding-to-pole or inter-pole impedance voltage corresponding to each measurement area.

FIG. 3 is a diagram illustrating a method of measuring an impedance voltage of each winding according to an embodiment of the present invention. FIG.

Referring to FIG. 3, a test voltage, which is a low voltage alternating voltage or a direct current voltage, can be applied to both ends of the rotor winding for diagnosis of the rotor winding short circuit. The rotor winding short-circuit diagnostics device measures the impedance voltage per winding generated by the test voltage applied to both ends (10, 20) of the winding. That is, the device for short circuit diagnosis of the rotor winding measures the impedance voltage of each winding included in the N pole region and the S pole region. Further, the rotor winding shorting device can calculate the difference value of the impedance voltage of the n-th winding in the N-pole region and the S-pole region based on the slip ring of the rotor. Further, the device for diagnosing short-circuit in the rotor winding can calculate the difference between the impedance voltages at the inter-terminal contact 30, which is a portion where the N pole region and the S pole region are connected to each other. For example, the rotor winding shorting device may have a first impedance voltage, which is the impedance voltage 12 measured at the first winding 11 of the N pole region, and a second impedance, which is the impedance measured at the first winding 21 of the S pole region And the second impedance voltage, which is the voltage 22, can be calculated. In addition, the device for short-circuiting the rotor winding detects the impedance between the impedance voltage at the inter-pole contact 30 generated when the test voltage is applied to the N-pole region and the impedance voltage at the inter-pole contact generated when the test voltage is applied at the S- The difference can be calculated.

The short circuit diagnosis device of the rotor winding can diagnose whether the rotor winding is short-circuited by calculating the difference value between the measured impedance or the impedance voltage between the windings and comparing it with a reference value capable of diagnosing whether or not the winding is disconnected.

4 is a block diagram illustrating a device for diagnosing a short circuit of a rotor winding according to another embodiment of the present invention.

4, the rotor winding short-circuit diagnosis apparatus includes a test voltage setting means 110, a measurement region selection means 120, a test voltage output means 130, an impedance voltage measurement means 140 and a winding short- 150). Here, FIG. 4 shows a constituent part that can be included in the rotor winding short-circuit diagnosis apparatus, and the second display means 143 is excluded.

The test voltage setting means 110 sets a test voltage to be applied to the rotor windings.

The test voltage setting means 110 may include a voltage supply transformer 111 and a test voltage selection means 112.

The voltage supply transformer 111 can change the input voltage 113 to the magnitude of the test voltage to be applied to the rotor winding. The input voltage 113 may be a voltage supplied from an external power source. The voltage supply transformer 111 can set a plurality of test voltages having different sizes by using the input voltage 113. [

The test voltage selecting means 112 selects a test voltage to be applied to the rotor windings. The test voltage selecting means 112 can select one of the test voltages set by the voltage supplying transformer 111. [ For example, the test voltage selection means 112 may be configured as a changeover switch. That is, if the voltage supply transformer 111 outputs three test voltages, the test voltage selecting means 112 can be a three-stage switch.

The measurement region selection means 120 selects an area for measuring the impedance voltage of the winding with respect to the applied test voltage.

The measurement region selection means 120 can select either the N pole region or the S pole region. The measurement region selection means 120 can transmit the voltage flowing to one end of the N pole region or one end of the S pole region to the winding shortage diagnosis means 150. [

For example, the measurement area selection means 120 may be a two-stage toggle switch.

The test voltage output means 130 applies the test voltage to the rotor windings. For example, the test voltage output means 130 can apply the test voltage to one end of the rotor winding corresponding to the N pole region or the S pole region through the cable.

The impedance voltage measuring means 140 can measure the impedance voltage generated in the winding in the N pole region and the impedance voltage generated in the winding in the S pole by using the probe. The impedance voltage measuring means 140 may be included inside or outside the rotor winding shorting diagnostic apparatus.

The impedance voltage measuring means 140 may be located outside the rotor winding short-circuit diagnosis device. At this time, the rotor winding short-circuit diagnosis apparatus may further include connecting means 180.

The winding short-circuit diagnosis means 150 receives the voltage at one end or the other end of each measurement region. Further, the winding short-circuit diagnosis means 150 receives the impedance voltage between windings or gaps included in each measurement area. The winding short-circuit diagnosis means 150 can calculate the impedance voltage difference between the windings corresponding to the same order by using the impedance of the windings or the gaps included in the measurement region and the measurement region received. The winding short-circuit diagnosis means 150 can diagnose whether or not the corresponding winding is short-circuited based on the calculated impedance voltage difference between the calculated turns.

The connecting means 180 may be composed of an impedance voltage measuring means 140 located externally and a connecting jack connecting the rotor winding short-circuit diagnosis device.

5 is a flowchart illustrating a method of diagnosing a rotor winding shortage according to an embodiment of the present invention.

Referring to Fig. 5, first in step S400, the rotor winding short-circuit diagnosis device sets a test voltage. The rotor winding short-circuit diagnosis device can set the test voltage by changing the magnitude of the voltage supplied from the power source. The rotor winding short-circuit diagnosis device can set one or more test voltages of different sizes using the voltage supplied from the power source. At this time, the rotor winding short-circuit diagnosis device can select the test voltage to be applied to the rotor winding among the plurality of test voltages set.

In step S410, the rotor winding short-circuit diagnosis device applies a test voltage to one measurement area. Here, one measurement area is an area including a winding wound in one direction by rotating the rotor, and the other measurement area is an area including a winding wound around the rotor by rotating in a direction opposite to the one direction. At this time, the polarities of the windings are different from each other depending on the direction of rotation of the windings on the rotor. For example, one measurement region may be an N pole region, and another measurement region may be an S pole region. That is, the device for shorting the rotor winding can apply the test voltage to the N pole region of the rotor winding.

In step S420, the rotor winding short-circuit diagnosis device measures the first impedance voltage. The rotor winding short-circuit diagnosis device can measure the first impedance voltage which is the impedance voltage of a measurement area generated by the test voltage applied to one measurement area. For example, the rotor winding shorting device can measure each of the windings corresponding to the N pole region, and the first impedance voltage, which is the impedance voltage at the contact point between the N pole region and the S pole region.

In step S430, the rotor winding short-circuit diagnosis device measures the second impedance voltage. The rotor winding short-circuit diagnosis device can measure the second impedance voltage which is the impedance voltage of the other measurement area. For example, the rotor winding shorting device can measure each of the windings corresponding to the S-pole region and the second impedance voltage, which is the impedance voltage at the contact point between the N-pole region and the S-pole region.

According to the embodiment of the present invention, the rotor winding short-circuit diagnosis apparatus sequentially performs steps S410 to S430, but is not limited thereto. That is, the rotor winding short-circuit diagnosis apparatus can perform steps S410 and S430 at the same time. Therefore, if the rotor winding short-circuit diagnosis apparatus performs the steps S410 and S430 at the same time, the steps S420 and S440 can be performed simultaneously.

In step S440, the rotor-winding short-circuit diagnosis apparatus may calculate the difference between the first impedance voltage and the second impedance voltage. The short circuit diagnosis device of the rotor winding can calculate the difference value between the first impedance voltage of the nth winding of one measurement area and the second impedance voltage of the nth winding of the other measurement area based on the slip ring of the rotor. In addition, the device for short-circuiting the rotor winding can calculate the difference value between the impedance voltages measured at the inter-pole contacts.

In step S450, the rotor winding short-circuit diagnosis device can compare the difference between the impedance voltages for each winding with a predetermined reference value. Here, the preset reference value is a reference value for diagnosing whether or not the rotor winding is short-circuited. If the difference value between the impedance voltages of the windings is equal to or greater than the reference value, the short circuit diagnosis device for the rotor winding performs step S460. If the difference between the impedance voltages of the windings is less than the reference value, the short circuit diagnosis device for the rotor winding performs step S470.

In step S460, if the difference value between the impedance voltages is larger than the reference value, the short-circuit diagnosis device diagnoses the n-th rotor winding of one measurement area or other measurement area as a short-circuit state.

In step S470, when the difference value between the impedance voltages is smaller than the reference value, the short-circuit diagnosis apparatus diagnoses the n-th rotor winding of one measurement area and the other measurement area as a normal state.

In step S480, the rotor winding short-circuit diagnosis device outputs the diagnosis result. The short circuit diagnosis device of the rotor winding can output the diagnosis result of whether the corresponding winding of the rotor is short-circuited or steady-state so that the user can visually or audibly confirm the result. The rotor winding short-circuit diagnosis device outputs the result of diagnosing the condition of the rotor winding and terminates the diagnosis of the rotor winding short-circuit.

In the embodiment of the present invention, the winding short-circuit diagnosis apparatus is constituted by one apparatus including each constituent unit. However, the present invention is not limited to the winding short-circuit diagnosis device as means for performing the winding short-circuit diagnosis method according to the embodiment of the present invention. For example, each component that performs winding shorting diagnostics can be interconnected to a separate device. That is, the present invention can be constituted by a winding short-circuit diagnosis system in which each component is interconnected with a single individual device, thereby performing diagnosis of winding short-circuit.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined in the appended claims. It will be understood that the invention may be varied and varied without departing from the scope of the invention.

110: test voltage setting means 111: voltage supply transformer
112: Test voltage selection means 113: External power supply
120: measurement area selection means 130: test voltage output means
140: Impedance voltage measuring means 141: Probe
142: operating section 143: second display means
150: winding shortage diagnosis means 160: first display means

Claims (9)

Test voltage setting means for setting a test voltage to be applied to the rotor winding of the generator;
Measuring area selecting means for selecting a measuring area to which the test voltage is to be applied, among the measuring areas divided into the first measuring area and the second measuring area according to the direction of the winding wound on the rotor;
An impedance voltage measurement means for measuring an impedance voltage by the test voltage from each winding included in the first measurement region and the second measurement region; And
Wherein a winding short is diagnosed based on a slip ring of the rotor from a difference value of an impedance voltage between an nth winding of the first measuring area and an nth winding of the second measuring area, Diagnostic means, wherein n is a natural number.
The method according to claim 1,
Wherein the measurement area selection unit includes a first measurement area that is an area including a winding wound in one direction and wound around the rotor and a second measurement area that is an area including a winding wound in a direction opposite to the first direction to the rotor, Wherein the region of the rotor winding is short-circuited.
3. The method of claim 2,
If the difference value of the impedance voltage between the nth winding of the first measuring area and the nth winding of the second measuring area is less than a reference value which is a criterion of shorting of the winding, nth winding of the second measuring region and the nth winding of the second measuring region to a steady state.
3. The method of claim 2,
If the difference value of the impedance voltage between the nth winding of the first measuring area and the nth winding of the second measuring area is equal to or greater than a reference value which is a reference for shorting the winding, And diagnoses the winding or the n-th winding of the second measuring area to a short-circuited state.
The method according to claim 1,
A test voltage output means for outputting a test voltage to the first measurement region or the second measurement region; And
And first display means for outputting to the screen whether or not the diagnosed rotor winding is short-circuited.
6. The method of claim 5,
Wherein the first display means outputs a result of comparing the impedance voltage of each of the n-th winding of the first measurement region and the n-th winding of the second measurement region in a numerical value or a graph. Device.
A method of diagnosing rotor winding shorting of a generator,
Applying a predetermined test voltage to the first measurement area or the second measurement area of the rotor winding, wherein the first measurement area is a region including a winding wound on the rotor by rotating in one direction, 2 measuring area is a region of the rotor containing a winding wound in a direction opposite to the one direction;
Measuring a first impedance voltage of an nth winding of the first measurement region or a second impedance voltage of an nth winding of the second measurement region with reference to a slip ring of the rotor;
Calculating a difference value between the first impedance voltage and the second impedance voltage;
Comparing the difference between the calculated first impedance voltage and the second impedance voltage with a reference value which is a reference of whether or not the winding is short-circuited to diagnose whether the winding is short-circuited; And
And outputting the diagnosed winding short circuit.
8. The method of claim 7,
The step of diagnosing whether the rotor winding is short-
And diagnoses the n-th winding of the first measurement region and the n-th winding of the second measurement region as a normal state when the difference between the first impedance voltage and the second impedance voltage is less than the reference value Rotor winding shorting diagnostic method.
8. The method of claim 7,
The step of diagnosing whether the rotor winding is short-
And diagnoses the nth winding of the first measurement region and the nth winding of the second measurement region as a short-circuit state when the difference between the first impedance voltage and the second impedance voltage is equal to or greater than the reference value Rotor winding shorting diagnostic method.

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