JPH08122387A - Method and apparatus for testing polarity of current transformer - Google Patents

Abstract

PURPOSE: To perform the polarity test of an air core current transformer easily and reliably even after the current transformer is assembled without modifying the structure thereof by providing a polarity test winding, a step voltage generating means and a pulse voltage detecting means. CONSTITUTION: With regard to a formula e2 =M12 (di1 /dt), where d/dt is a differential operator, an air core current transformer 11 has low mutual inductance M12 between a secondary winding 3 and a polarity test winding 6 but since the rising rate (di1 /dt) of a current i1 is high, the voltage e2 induced in the secondary winding has a detectable peak value. Furthermore, the voltage e2 induced in the secondary winding 3 is the derivative of the current i1 flowing through the winding 6, which means a pulse voltage having very short pulse width. The pulse voltage is detected by means of a pulse voltage detector 14 comprising an electronic circuit for detecting even a pulse voltage having very short pulse width thus testing the polarity of the current transformer 11 easily and reliably.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention uses a secondary winding that is magnetically coupled to a primary conductor through which a current to be detected flows and is wound around an annular core made of a nonmagnetic material. The present invention relates to a method and an apparatus for performing a polarity test of an air-core current transformer that is detected by transforming into the air-core current transformer. The present invention relates to a current transformer polarity test method and device which can be easily and reliably performed.

[0002]

2. Description of the Related Art Conventionally, in the field of power systems, for example, various current transformers have been widely used for the purpose of extracting the current of the system. FIG. 5 is a schematic diagram showing a configuration example of a through-type current transformer having a magnetic material as a winding core (hereinafter, referred to as an iron core current transformer).

In FIG. 5, an iron core type current transformer 1 comprises an annular (ring-shaped in the figure) winding core 2 made of a magnetic material, and a secondary winding 3 wound around the winding core 2. ing. Then, the iron core type current transformer 1 is magnetically coupled to a primary conductor (not shown) through which the current to be detected flows (that is, so as to interlink with the magnetic flux generated in the primary conductor) and transforms the current to be detected into a voltage. Is detected.

In FIG. 5, reference numeral 4 indicates a terminal of the secondary winding 3. By the way, conventionally, a method called a DC kick method has been generally and often used as a method for performing the polarity test of the iron core type current transformer 1.

FIG. 6 is a schematic diagram showing an example of a polarity test of an iron core type current transformer by the DC kick method of this type. In FIG. 6, the iron core type current transformer 1 is used by being fixed to a structure (for example, a switchgear, a tank such as a transformer) due to its structure. When the iron core type current transformer 1 is incorporated in an actually used state, it may be difficult to perform a polarity test using the primary conductor 5. Therefore, in such a case, the one-turn polarity test winding 6 is provided in advance so as to interlink with the magnetic path formed by the secondary winding 3 of the iron core type current transformer 1.

A step voltage generator 9 consisting of a manual opening / closing switch 7 and a dry battery 8 is connected to the terminal of the polarity test winding 6 (when the polarity test winding 6 is not provided,
Connect to primary conductor 5).

Further, the secondary winding terminal 4 of the iron core type current transformer 1
The tester 10 is connected to. Next, iron core type current transformer 1
In the polarity test method, when the manual open / close switch 7 is closed and a voltage is applied, a current i ₁ flows through the polarity test winding 6, and a voltage as shown by the equation (1) is applied between the secondary winding terminals 4. e ₂ is induced.

E ₂ = M ₁₂ (di ₁ / dt) (1) M ₁₂ : Mutual inductance between the secondary winding 3 and the polarity test winding 6 d / dt: Differential operator This causes the induced voltage. Current i caused by e _2
2 flows into the secondary winding 3 (see FIG. 7).

The polarity of the iron core type current transformer 1 is determined by the DC kick method by determining the polarity of the voltage applied to the polarity test winding 6 and the polarity of the current i ₂ of the secondary winding 3 that instantaneously flows. , By measuring the deflection of the needle of the tester 10 and comparing them.

On the other hand, as the current transformer, in addition to such an iron core type current transformer, there is one called an air core current transformer. That is, as shown in the configuration example in FIG. 8, the air-core current transformer 11
The structure is almost the same as that of the iron core type current transformer 1 except that the winding core 12 is made of a non-magnetic material. Therefore, as the polarity test method, the DC kick method may be adopted as in the case of the iron core current transformer 1.

However, in the case of the air-core current transformer 11, since the winding core 12 is a winding core made of a non-magnetic material, the mutual inductance M ₁₂ between the polarity test winding 6 and the secondary winding 3 is the iron core. The size of the current transformer 1 is about several thousandths. Therefore, the voltage e ₂ (see the above equation (1)) induced in the secondary winding 3 by the voltage applied to the polarity test winding 6 is small, and the pulse width of the generated pulse voltage is short. , It is not possible to obtain a sufficient current to drive the needle of the tester 10. Therefore, in the case of the air-core current transformer 11, the polarity test cannot be performed by the DC kick method using the manual open / close switch 7 and the tester 10.

Therefore, when the polarity of the air-core current transformer 11 is tested by the DC kick method, as can be seen from the equation (1), the polarity test winding 6 and the secondary winding 3 are mutually connected. If the inductance M ₁₂ is small, there is a problem that the induced voltage of the secondary winding 3 becomes small. Therefore, as a method for increasing the induced voltage of the secondary winding 3, the number of turns of the polarity test winding 6 is set. It may be increased, but the air-core current transformer 11
Is not desirable because the structure is complicated and the external dimensions are increased.

[0013]

As described above, in the conventional air-core current transformer polarity test method, it is difficult to perform a test by the DC kick method unless the structure of the air-core current transformer is changed. There was a problem.

An object of the present invention is to make it possible to easily and surely perform a polarity test of an air-core current transformer without changing the structure of the air-core current transformer, even if it is incorporated in an actual use state. To provide a polarity test method and device.

[0015]

In order to achieve the above object, first, in the invention according to claim 1, an annular winding made of a non-magnetic material is magnetically coupled to a primary conductor through which a current to be detected flows. In the method of performing the polarity test of the air-core current transformer that transforms the current to be detected into voltage by the secondary winding wound around the core to detect the polarity, the magnetic path formed by the secondary winding may be changed as necessary. A polarity test winding is provided so as to interlink, and a stepwise voltage with a steep rise is applied to the polarity test winding or the primary conductor to flow a stepwise current with a steep rise, The polarity test of the air-core current transformer is carried out by detecting the pulse voltage induced in the secondary winding by the current.

According to the second aspect of the invention, the detected current is provided by the secondary winding that is magnetically coupled to the primary conductor through which the detected current flows and is wound around the annular core made of a non-magnetic material. In a device for performing a polarity test of an air-core current transformer that detects by converting the voltage into a voltage, a polarity test winding provided so as to interlink with the magnetic path formed by the secondary winding, if necessary,
Polarity test A step voltage generator that applies a stepwise voltage with a steep rise to the winding or the primary conductor to flow a stepwise current with a steep rise, and a stepwise current induces it in the secondary winding. And a pulse voltage detecting means for detecting the pulse voltage.

Here, in particular, the step voltage generating means is a switch for forming a voltage, which constitutes a part of the step voltage generating means.
A switch having a high switching speed such as a semiconductor switch is used.

Further, the pulse voltage detecting means is composed of a comparator circuit which is composed of an operational amplifier having a hysteresis characteristic strong against noise and detects a pulse, and a light emitting diode which is turned on by an output from the comparator circuit. There is.

[0019]

Therefore, in the current transformer polarity testing method and apparatus of the present invention, the step-like voltage having a steep rise generated by the step voltage generating means such as a semiconductor switch is the polarity test winding or the primary conductor. Applied to. Then, due to this voltage having a steep rise, a current having a steep rise flows through the polarity test winding or the primary conductor. Then, due to the current having the steep rise, a voltage is induced in the secondary winding according to the equation (1).

In this case, in the equation (1), in the air-core current transformer, the mutual inductance M between the secondary winding and the polarity test winding is M.
₁₂ is small, but the current rise is large (ie d
Since i ₁ / dt is large), the voltage induced in the secondary winding has a detectable peak voltage value.

The voltage induced in this secondary winding is
Since it is a differential value of the current i ₁ flowing in the polarity test winding, the pulse voltage is a very short pulse voltage. However, the pulse voltage detection means configured by an electronic circuit can detect even a very short pulse voltage. By detecting this pulse voltage, the polarity test of the air-core current transformer can be performed easily and surely.

[0022]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described in detail below with reference to the drawings. FIG. 1 is a schematic diagram showing a basic configuration example of a polarity test device for an iron core current transformer according to the present invention. The same elements as those in FIGS. 6 and 8 are designated by the same reference numerals and the description thereof will be omitted. , Here, only different parts will be described.

That is, as shown in FIG. 1, the iron core type current transformer polarity testing apparatus of the present embodiment has a step of generating a step voltage instead of the step voltage generating apparatus 9 shown in FIG. The device 13 is connected (it is connected to the primary conductor 5 when there is no polarity test winding 6), and the secondary winding terminal 4 of the iron core type current transformer 1 is replaced with the pulse voltage instead of the tester 10 in FIG. The detection device 14 is connected.

Here, the step voltage generator 13 applies a stepwise voltage having a steep rise to the polarity test winding 6 (the primary conductor 5 in the case where the polarity test winding 6 is not provided) to make the voltage steep. Stepwise current with rising edge (di
This is for passing a current having a large / dt).

That is, as described above, the air-core current transformer 1
In the case of 1, the mutual inductance M ₁₂ between the polarity test winding 6 and the secondary winding 3 is small. Therefore, if a step voltage having a steep rise is applied to the polarity test winding 6, the polarity test winding 6 having a rise proportional to the rise of the voltage.
The current i ₁ is obtained. If the rising of the current i ₁ is steep, the voltage e ₂ induced in the secondary winding 3 increases even if the mutual inductance M ₁₂ between the polarity test winding 6 and the secondary winding 3 is small. For this reason, a switch having a high switching speed such as a semiconductor switch will be used as a switch for opening and closing the voltage which constitutes a part of the step voltage generator 13.

The pulse voltage detector 14 is for detecting the pulse voltage induced in the secondary winding 3 by the stepwise current. That is, when a voltage having a steep rise is applied to the polarity test winding 6, the pulse width of the voltage e ₂ induced in the secondary winding 3 becomes very short. Test becomes difficult. Therefore, instead of the tester 10, as the pulse voltage detection device 14, a device configured by an electronic circuit that can detect even a pulse having a short pulse width is used.

Next, a method of testing the polarity of the iron core type current transformer of the present embodiment constructed as described above will be described with reference to FIG. The principle of the polarity test method is the same as that of the DC kick method described above, but the polarity test of the air-core current transformer 11 can be easily and surely performed by configuring the polarity test apparatus as shown in FIG. You can

That is, in FIG. 1, the step-like voltage e ₁ having a steep rise generated by the step voltage generator 13 including a semiconductor switch is the polarity test winding 6 (when the polarity test winding 6 is not present, Is the primary conductor 5)
Is applied to Then, the voltage e ₁ having the steep rise causes the current i ₁ having the steep rise to flow in the polarity test winding 6 (the primary conductor 5 when the polarity test winding 6 is not provided). Then, due to the current i ₁ having the steep rise, the voltage e ₂ is induced in the secondary winding 3 in accordance with the equation (1).

In this case, in the equation (1), in the air-core current transformer 11, the mutual inductance M ₁₂ between the secondary winding 3 and the polarity test winding 6 is small, but the rise of the current i ₁ is large (that is, di ₁ / Dt is large), the voltage e ₂ induced in the secondary winding 3 has a detectable voltage peak value.

Further, the voltage e induced in the secondary winding 3
_{Since 2} is a differential value of the current i ₁ flowing in the polarity test winding 6, the pulse voltage is a pulse voltage having a very short pulse width, but a pulse voltage configured by an electronic circuit and having a very short pulse width can be detected. By detecting this pulse voltage with the voltage detection device 14, the polarity test of the air-core current transformer 11 can be performed easily and reliably.

Next, a more specific configuration example of the polarity testing device for the iron core type current transformer of the present embodiment and its polarity testing method will be described. FIG. 3 is a schematic diagram showing a more specific configuration example of the polarity test device for the iron core type current transformer according to the present embodiment, and the same elements as those in FIG. 1 are designated by the same reference numerals.

That is, as shown in FIG. 3, the step voltage generator 13 uses a thyristor 15 which is a semiconductor switch as a switch for opening and closing a voltage which constitutes a part of the step voltage generator 13 having a steep rise. are doing.

The turn-on signal to the gate of the thyristor 15 is given by closing the manual open / close switch 7 provided between the gate of the thyristor 15 and the anode. Further, the thyristor 15 is turned off by opening the manual open / close switch 16 connected in series with the dry battery 8.

On the other hand, as shown in FIG. 3, the pulse voltage detector 14 is composed of, for example, an operational amplifier having a hysteresis input / output characteristic resistant to noise as shown in FIG. 4, and a comparison circuit for detecting a pulse. 17, a reset switch 18 for resetting the output from the comparison circuit 17 before the polarity test, an inverting amplifier 19 having the output from the comparison circuit 17 as an input, and an output from the inverting amplifier 19
And a light emitting diode drive circuit 20 for driving a light emitting diode displaying pulse detection.

Next, a method of testing the polarity of the iron core type current transformer 11 having the above-described structure will be described. In FIG.
When the manual open / close switch 4 of the step voltage generator 13 is closed, the thyristor 15 is turned on, so that the current i ₁ having a steep rise close to the step wave shape flows through the polarity test winding 6. The rise of the current i ₁ can be obtained up to several 100 A / μs in a general semiconductor switch (about several A / μs in a mechanical switch). When the current i ₁ having this steep rise flows through the polarity test winding 6, the voltage e ₂ according to the above equation (1) is induced in the secondary winding 3. The induced voltage e ₂ is input to the pulse voltage detection device 14 as a pulse voltage waveform having a short pulse width because the current i ₁ of the polarity test winding 6 has a steep rise.

In this case, pay attention to the output of the comparison circuit 17 of the pulse voltage detection device 14. That is, the input voltage V _in to the comparison circuit 17 is 0 V until the pulse voltage e ₂ is induced in the secondary winding 3 by the current i ₁ having a sharp rise.
Is. Then, as can be seen from the hysteresis input / output characteristics shown in FIG. 4, when the input voltage V _in is 0 V, the output voltage V _out from the comparison circuit 17 is + V _sat . Therefore, the output from the inverting amplifier 19 becomes a negative voltage, and the transistor of the light emitting diode drive circuit 20 does not conduct, so that the light emitting diode does not light.

Next, the current i having a steep rise now
It is assumed that ₁ flows in the polarity test winding 6 and the pulse voltage e ₂ is induced in the secondary winding 3. When this pulse voltage e ₂ is induced, the input voltage V _in to the comparison circuit 17 exceeds V _H shown in FIG. When the input voltage V _in exceeds V _H , the output voltage V _out of the comparison circuit 17 is inverted from + V _sat → −V _sat . Then, due to the voltage polarity inversion of the output voltage V _out from the comparison circuit 17, the output voltage from the inverting amplifier 19 becomes a positive voltage, so the light emitting diode drive circuit 2
The 0 transistor becomes conductive and the light emitting diode lights up, indicating the detection of the pulse voltage.

In the above description, the input / output characteristic of the comparison circuit 17 is made to have the hysteresis input / output characteristic as shown in FIG. This is to keep the light emitting diode lighting even after the voltage disappears and to prevent malfunction due to noise.

As described above, in the present embodiment, the secondary winding 3 magnetically coupled to the primary conductor 5 through which the current to be detected flows and wound around the ring-shaped winding core 12 made of a non-magnetic material. In the method and the device for performing the polarity test of the air-core current transformer 11 for converting the current to be detected into a voltage and detecting the voltage, the method is provided so as to interlink with the magnetic path formed by the secondary winding 3 if necessary. The polarity test winding 6 and the polarity test winding 6 (or the primary conductor 5 when the polarity test winding 6 is not present) are applied with a stepwise voltage having a steep rising edge so as to have a steep rising edge. Voltage generator 13 for passing a current (current having a large di / dt) and a pulse voltage detector 14 for detecting a pulse voltage induced in the secondary winding 3 by the step current. And a steep rise The stepped voltage that it has is applied to the polarity test winding 6 (or the primary conductor 5 when there is no polarity test winding 6), and a stepped current having a steep rise is made to flow. The polarity test of the air-core current transformer 11 is performed by detecting the pulse voltage induced in the next winding 3.

Therefore, the following operational effects can be obtained. (A) Only with a small and lightweight device, a stepwise current having a sharp rise can be surely passed through the polarity test winding 6. Therefore, a voltage that can sufficiently confirm the polarity of the air-core current transformer 11 can be easily and reliably induced in the secondary winding 3.

That is, when the polarity test of the air-core current transformer 11 is tested by the DC kick method, the mutual inductance M between the polarity test winding 6 and the secondary winding 3 is clear from the equation (1). _{Since 12} is small, the induced voltage in the secondary winding 3 is small. Therefore, as a method for increasing the induced voltage in the secondary winding 3, the number of turns of the polarity test winding 6 is increased, and the air-core current transformer is used. Is not desirable because the structure is complicated and the external dimensions are increased.

In this respect, in this embodiment, in order to surely increase the rise of the current flowing through the polarity test winding 6 (di ₁ / dt in the equation (1)), a switch having a high switching speed such as the thyristor 15 is used. Step voltage generator 1 used
Since 3 is used, the current rises sharply compared to the case where the current was manually turned on, and a current with a sharp rise is surely generated regardless of the skill of the operator. It can be applied to the polarity test winding 6.

(B) Only a small and lightweight device can reliably detect a pulse voltage with a short pulse width induced in the secondary winding 3 without malfunction, and let the tester know the result of the pulse voltage lighting of the light emitting diode. Therefore, the voltage can be detected easily and accurately.

That is, when the rising of the current of the polarity test winding 6 becomes steep, the pulse width of the pulse voltage induced in the secondary winding 3 becomes short, and the polarity test is performed by the deflection of the needle of the tester 10 as in the prior art. Becomes impossible.

In this respect, in the present embodiment, the pulse voltage detecting device 14 constituted by a simple electronic circuit for surely detecting the pulse voltage induced in the secondary winding 3, that is, a hysteresis characteristic mainly resistant to noise. A pulse voltage detection device 14 comprising a comparison circuit 17 with an operational amplifier having a light emitting diode and a light emitting diode drive circuit 20 for notifying a tester of pulse detection.
Since the comparison circuit 17 detects a pulse, the comparison circuit 17 outputs a current to the light emitting diode drive circuit 20 to turn on the light emitting diode so that the voltage can be detected easily and accurately. .

As described above, the polarity test of the air-core current transformer 11 can be performed easily and reliably without changing the structure of the air-core current transformer 11. Further, since the step voltage generator 13 and the light emitting diode drive circuit 20 of the pulse voltage detector 14 do not require large electric power, it is possible to easily reduce the size and weight of the entire device. .

The present invention is not limited to the above embodiment, but can be implemented in the same manner as described below. (A) In the above embodiment, the case where the thyristor 15 is used as the voltage opening / closing switch of the step voltage generator 13 has been described, but the invention is not limited to this. Even if other fast switches are used, it is possible to obtain the same effect as the above case.

(B) In the above embodiment, the pulse voltage detecting device 14 for detecting the pulse voltage induced in the secondary winding 3 is a pulse detecting device composed of an electronic circuit. Not limited thereto, other detection devices (for example, as long as the device can detect the pulse voltage)
Even if an oscilloscope or the like) is used, the same effect as the above case can be obtained.

[0049]

As described above, according to the present invention, the secondary winding, which is magnetically coupled to the primary conductor through which the current to be detected flows and is wound around the annular core made of a nonmagnetic material, In a method and apparatus for performing a polarity test of an air-core current transformer that detects a current to be detected by converting it into a voltage, a polarity test provided so as to interlink with a magnetic path formed by a secondary winding, if necessary. A step voltage generator that applies a step voltage with a steep rise to the winding and the polarity test winding or the primary conductor to flow a step current with a steep rise, and a secondary with the step current. A pulse voltage detection means for detecting a pulse voltage induced in the winding is provided, and a step-shaped voltage having a steep rise is applied to the polarity test winding or the primary conductor to obtain a step-shaped voltage having a steep rise. The polarity test of the air-core current transformer is carried out by detecting the pulse voltage induced in the secondary winding by the stepped current, so the structure of the air-core current transformer should be changed. Therefore, a polarity test method and device for a current transformer capable of easily and surely performing a polarity test of an air-core current transformer even when incorporated in an actual use state can be provided.

[Brief description of drawings]

FIG. 1 is a schematic diagram showing an embodiment of a polarity test apparatus for an air-core current transformer according to the present invention.

FIG. 2 is a diagram showing an example of waveforms of respective parts during a polarity test of the air-core current transformer in the same embodiment.

FIG. 3 is a schematic diagram showing a more specific configuration example of a polarity test device for an air-core current transformer according to the present invention.

4 is a diagram showing an example of hysteresis input / output characteristics of a comparison circuit in the polarity test apparatus of FIG.

FIG. 5 is a schematic diagram showing a configuration example of an iron core type current transformer.

FIG. 6 is a schematic diagram for explaining a conventional polarity test method for the iron core type current transformer.

FIG. 7 is a diagram showing an example of a waveform of each part in a polarity test of the iron core current transformer.

FIG. 8 is a schematic diagram showing a configuration example of an air-core current transformer.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 ... Iron core type current transformer, 2 ... Core, 3 ... Secondary winding, 4 ... Secondary winding terminal, 5 ... Primary conductor, 6 ... Polarity test winding, 7 ... Manual opening / closing switch, 8 ... Dry battery, 9 ... Step voltage generator, 10 ... Tester, 11 ... Air core current transformer, 12 ... Winding core, 13 ... Step voltage generator, 14 ... Pulse voltage detector, 15 ... Thyristor, 16 ... Manual open / close switch, 17 ... Comparison Circuit, 18 ... Reset switch, 19 ... Inversion amplifier, 20 ... Light emitting diode drive circuit.

Claims (4)

[Claims] 1. A secondary winding, which is magnetically coupled to a primary conductor through which a current to be detected flows and is wound around an annular core made of a non-magnetic material, converts the current to be detected into a voltage and detects the voltage. In the method of conducting the polarity test of the air-core current transformer, the polarity test winding is provided as necessary so as to interlink with the magnetic path formed by the secondary winding, and a step voltage with a steep rise is formed. By applying a stepwise current having a steep rise to the polarity test winding or the primary conductor and detecting a pulse voltage induced in the secondary winding by the stepwise current, A polarity test method for a current transformer, characterized in that a polarity test for an air-core current transformer is performed. 2. The detected current is converted into a voltage and detected by a secondary winding that is magnetically coupled to a primary conductor through which the detected current flows and is wound around an annular core made of a non-magnetic material. In the device for performing the polarity test of the air-core current transformer, the polarity test winding provided so as to interlink with the magnetic path formed by the secondary winding, and the polarity test winding or the primary winding, if necessary. Step voltage generation means for applying a stepwise voltage having a steep rise to a conductor to flow a stepwise current having a steep rise, and a pulse voltage induced in the secondary winding by the stepwise current A polarity tester for current transformer, comprising: a pulse voltage detecting means for detecting 3. The step voltage generating means uses a switch having a high switching speed, such as a semiconductor switch, as a voltage opening / closing switch forming a part of the step voltage generating means. Current transformer polarity tester. 4. The pulse voltage detection means comprises a comparison circuit configured by an operational amplifier having a hysteresis characteristic that is strong against noise to detect a pulse, and a light emitting diode which is turned on by an output from the comparison circuit. The polarity testing device for a current transformer according to claim 2.