RU2035744C1 - Method and device for checking turn insulation of windings of electrical machines and apparatuses - Google Patents

Abstract

FIELD: checking-and-measuring equipment. SUBSTANCE: preliminary charged reservoir capacitor discharges into tested winding and a response is compared with the response of a serviceable coil. The response begins to be measured at 1-2 periods of oscillation, i.e. after switching off the reservoir capacitor. The device has one controlled voltage source, one reservoir capacitor, one power switch, one unit for controlling power switch, terminals for connecting the tested object, one voltage divider, one rectifier, one generator for shaping pulse of duration of 1/2 of semi-period of response voltage, one switch, and one meter for measuring average value of voltage. EFFECT: enhanced reliability of checking. 3 cl, 4 dwg

Description

 The invention relates to instrumentation and is intended for quality control of coil insulation of the windings of electrical machines and apparatuses.

A known method for controlling the winding insulation of windings, in which a pre-charged storage capacitor is discharged to the test winding or the winding of the inductively coupled inductance connected to it, and by the nature of the oscillatory damping process that occurs in this case, make a conclusion about the state of the winding insulation of this winding, and the most characteristic response different magnitudes amplitude, decay time, ratio or difference of amplitudes of two voltage maxima, number of achievements is intense em response setpoint etc. [1,2]
The disadvantage of this method is that when the storage capacitor is discharged, it remains connected to the tested winding until the switching device disconnects it, remaining the main factor determining the nature of the process during this time, and thereby reducing the sensitivity to the controlled parameter. This drawback is due to the natural property of all known switching elements used for this purpose (thyratrons, arresters, thyristors, saturation chokes) to break the circuit only after the current flowing through this element decreases to zero or close to zero. This process is shown in FIG. 1, where U is the voltage across the test winding; I current flowing through the switching device; τ response oscillation period; T is the pulse repetition period of the test voltage.

 A device is known for evaluating the quality of coil insulation [3] The device comprises a high-voltage rectifier for charging a storage capacitor, a spark gap acting as a power switch, a surge arrester control device that generates a pulse that initiates breakdown of a spark gap, a measuring part that allows you to optionally measure the ratio of the amplitude value on a working coil to the amplitude value of the voltage on the test coil, the ratio of the numbers reaching the voltage on this coil and on the working set value damping decrements for these coils.

This device allows you to evaluate the quality of the nature of the whole process together with the part of this process in which the storage capacitor remains connected to the tested winding, which significantly reduces the sensitivity to defects, since in this part the capacitor impedance noticeably changes the parameters of the system, and the energy of this part response is a significant fraction of the total response energy. In the method implemented in the known [4] device, comprising an autotransformer voltage regulator 1, a voltage boosting transformer 2, a storage capacitor 3, a ball gap 4, a measuring winding 5 connected inductively with the tested winding, a diode 6, an arrow magnetoelectric device 7 with additional resistance 8 (Fig. 3), the quality assessment of insulation is as follows. When the voltage at the storage capacitor reaches the set value, the latter is discharged through the arrester to the tested winding L _x , in which damped oscillations occur, the average voltage of which is measured by the average response voltage meter.

u(t)

dx (1) где U среднее напряжение отклика; l u(t) l- модуль мгновенного значения напряжения отклика; Т период следования импульсов разряда накопительного конденсатора.U

u (t)

dx (1) where U is the average response voltage; lu (t) l is the modulus of the instantaneous value of the response voltage; T is the period following the discharge pulses of the storage capacitor.

 This value is compared with the same value for the model coil and the deviation from it is judged on the presence of a defect. The test object remains connected to the storage capacitor until the current through the arrester ceases, i.e. approximately 1/2 period τ of the response voltage. During this time, the process of generating the response voltage is determined by the equivalent impedance of the object and the pulse voltage generator, the impedance of the generator being the determining factor at this time, since it is usually much less than the impedance of the object and the state of the latter has little effect on the nature of the process and, accordingly, on the average response voltage , since the first half-cycle with the maximum amplitude plays a noticeable role in the formation of the average voltage.

 The prototype of the device is the device described in [5] and shown in FIG. 4. A constant voltage source 1 is connected to the test object 2 through a current-limiting resistor 3 and a dividing switching device 4. A pulse voltage source 5 is connected to the test object 2 through a spark gap 6, which prevents the direct voltage from being transmitted to the pulse voltage source 5. An additional switching device 8 is connected to the output 7 of the apparatus 4, which ensures the connection of this point with the ground at least for the duration of the application of the pulse voltage. The device also contains a capacitive voltage divider 9, a capacitor 10, a blocking device 11 that provides electrical, mechanical or otherwise made connection of the wires of the devices 4 and 8 with the device 12, designed to start the source 5 of the pulse voltage.

 The device operates as follows. At the beginning of the test cycle, the apparatus 4 is turned on, the apparatus 8 is turned off, a constant voltage from the source 1 through the resistor 3 and the apparatus 4 is applied to the test object 2, the divider 9 and the capacitor 10. At the end of the charge of the pulse voltage source 5 using the device 12, it is launched and at the same time or preemptively, a command is sent to turn off the apparatus 4 and turn on the apparatus 8 so that the shutdown of the apparatus 4 precedes the turn on of the apparatus 8. After performing these operations, the DC voltage source turns out to be locked to the ground through resistor 3, and at object 2, a constant voltage is maintained due to the presence of capacitors.

 After starting the source 5, the pulse ignites the gap 6 and, being applied to the object 2 of the test, recharges the capacitance to the value of the pulse voltage. After the cessation of the pulse, the apparatus 8 is first turned off, and then the apparatus 4 is turned on, while supplying a constant voltage to the test object 2.

 In the formation of voltage at the test object, the main role is determined by the period during which the spark gap 6 is open, which reduces the sensitivity to defects.

 The purpose of the invention is to increase the sensitivity to insulation defects.

 In the method for controlling the coil insulation of the windings of electric machines and apparatuses, in which a pre-charged capacitor is discharged to the test winding or the winding of an inductively coupled inductor and, according to the values characterizing the damped oscillatory process that arises, they make a conclusion about the state of the coil insulation, measuring the value chosen to assess the nature of the damped oscillatory process, produce with a delay relative to the beginning of the process for 1/2 period of oscillation. The sensitivity to defects also depends on the choice of the value characterizing the response.

 As a value characterizing a damped oscillatory process, use the average voltage value of this process.

 In a device for monitoring coil insulation containing a voltage source, a storage capacitor, a power switch, a power switch control circuit, a voltage divider, a pulse voltage source, a switch, two terminals for connecting a test object, in which the first output of the voltage source is connected to the first output of the storage capacitor , with the first terminal for connecting the monitoring object, with the first output of the voltage divider, the output of the power switch control circuit is connected to the control input of the power switch, the first output q the power switch is connected to the second terminal for connecting the monitoring object, the task of increasing the sensitivity to defects is solved by introducing a rectifier, a meter into the device, using a pulse shaper as a source of pulse voltage for a duration of 1/2 period of oscillation of the response voltage with a restart delay of at least a duration attenuation of the response and not more than the period following the discharge of the storage capacitor, the input and output of which are connected respectively with the third output divides For voltage, with the input of the rectifier, with the control input of the key, the first and second conclusions of which are connected respectively to the output of the rectifier, with the first input of the meter and with the first output of the voltage source, with the second input of the meter, the second output of the power switch is connected to the second output of the storage capacitor and with the second output of the voltage source.

 Calculation of transients in the test coil with and without defects shows that, if there is a short circuit or breakdown, the oscillation period and the decay time are reduced, it is easy to make sure that the average voltage value differs greatly from the same value in the working coil, since it in a first approximation, it is proportional to the product of changes in the period and decay time multiplied by the change in amplitude. These findings are confirmed by experiments.

 The task of increasing the sensitivity of the device is additionally solved by the fact that the average voltage meter is used as a meter.

 The task of ensuring control of coils with different levels of normalized test voltage is solved by the fact that the voltage source is adjustable.

 In the sources of information available to us, no descriptions of both the proposed method and the devices that implement it, i.e. the proposed solution is novel.

 The introduction of a delay in assessing the state for 1/2 of the response period (for the duration of the current flowing through the test coil from the storage capacitor), together with an estimate of the average value of the response voltage, can increase the sensitivity to insulation defects, since it cuts off that part of the test process in which the nature of the process is determined mainly by the parameters of the test voltage generator, and not by the parameters of the tested winding, which gives reason to believe that the proposed solution meets the criterion of "Engineering level".

u(t)

dt (2) где U среднее значение напряжения; lu(t) l- модуль мгновенного значения напряжения; Т период следования разрядов конденсатора; τ период колебаний напряжения отклика.The test of the winding insulation in accordance with the proposed method is carried out by discharging a pre-charged voltage of the required capacitor value to the tested winding or winding of an inductor connected to the latter. The measurement of the value chosen to assess the nature of the decaying process that occurs in this case begins with a delay of 1/2 the oscillation period of this process. In relation to the average value of the response voltage, the meter readings will be proportional
U

u (t)

dt (2) where U is the average voltage value; lu (t) l is the module of the instantaneous voltage value; T the period of the discharge of the capacitor; τ period of fluctuations in the response voltage.

 The state of coil insulation is evaluated by the deviation of the magnitude of this voltage in the presence of a defect from the magnitude of this voltage, measured on a winding with normal insulation.

 An insulation monitoring device is shown in FIG. 2.

 The device contains a voltage source 1, a storage capacitor 2, a power switch 3, a power switch control circuit 4, two terminals 5 for connecting a test object, a voltage divider 6, a rectifier 7, a pulse voltage source 8, a switch 9, a meter 10, a first output of a source 1 voltage is connected to the first output of the storage capacitor 2, with the first terminal 5 for connecting the control object, with the first output of the voltage divider 6, the output of the power switch control circuit 4 is connected to the control input of the power switch 3. the first output with the sludge switch 3 is connected to the second terminal 5 for connecting the monitoring object, the second output of the voltage divider 6, the input and output of the pulse voltage source 8, respectively, with the third output of the voltage divider 6 and the input of the rectifier 7, which controls the input of the switch 9, the first and second conclusions of which are connected to the output of the rectifier 7, with the first input of the meter 10 and with the first output of the voltage source 1, with the second input of the meter 10, the second output of the power switch 3 is connected to the second output of the storage capacitor 2 and the second output of the source ka 1 voltage and a source voltage pulse generator pulses used 1/2 of the period of response to voltage fluctuations.

 An additional increase in sensitivity to defects is ensured by the fact that the average voltage response meter is used as a meter. The voltage source 1 is adjustable.

 The device operates as follows. The regulated voltage source 1 charges the storage capacitor 2 to the desired level. The power switch 3 is closed by the signal supplied by the control device 4, and discharges the storage capacitor to the test coil connected to the terminals 5. The response voltage is divided into the required number of times by the voltage divider 6 and is supplied to the pulse former for 1/2 period. At the same time, the voltage from the output of the divider 6 is rectified by the rectifier 7 and fed to the input of the meter 10. The pulse generated by the divider 6 is fed to the input of the switch 9 and holds it in the closed state 1/2 of the oscillation period, blocking the meter 10. The delay of the former from repeated start-up is necessary to protect the meter from blocking by subsequent response half-periods and random interference.

 In a prototype of the described device that implements the proposed method, the functions of the power switch were performed by a magneto-thyristor pulse generator, a bipolar transistor was used as the key blocking the medium voltage meter, the control pulse of this switch was formed by a transistor amplifier-limiter, the input of which was blocked by a one-shot signal triggered by a trailing edge pulse shaper.

 When testing an unplaced stator coil of a 4AZM-2000 asynchronous motor (2000 kW, 6.3 kV) containing 6 turns of 9 kV, the results are shown in the table.

 The results shown in the table were obtained on the same coils with the same defects. The value ΔU, which characterizes the state of coil insulation for a short circuit, increased 4 times, for breakdown 4.7 times, i.e. sensitivity has increased markedly.

 The proposed method and device for its implementation have a significantly higher sensitivity to insulation defects compared to prototypes. This makes it possible to more reliably distinguish between insulation defects and deviations of the coil parameters, which do not lead to loss of performance (variations in the dielectric constant of the insulation material, the difference in steel losses when testing coils placed in the stator, etc.), but affecting the response. All units of the device are easily implemented on widespread components.

 The proposed device is implemented in the form of a prototype aimed at testing the coil insulation of the coil windings of powerful high-voltage motors, and has been tested in the shops of A / O "ELSIB".

Claims (5)

 1. A method for monitoring the coil insulation of the windings of electric machines and apparatuses, in which a pre-charged capacitor is discharged to the tested winding and, in magnitude characterizing the damped oscillatory process that occurs in this case, make a conclusion about the state of the coil insulation, characterized in that the measurement of the value chosen for evaluation the nature of the damped oscillatory process, produced with a delay relative to the beginning of the process for 1/2 period of oscillation.  2. The method according to claim 1, characterized in that the average voltage value of this process is used as a value characterizing a damped oscillatory process.  3. A device for controlling the coil insulation of the windings of electrical machines and apparatuses, containing a voltage source, a storage capacitor, a power switch, a power switch control circuit, a voltage divider, a pulse voltage source, a switch, two terminals for connecting the monitoring object, the first output of the voltage source is connected to the first output of the storage capacitor, with the first terminal for connecting the monitoring object, with the first output of the voltage divider, the output of the power switch control circuit is connected to the control input power switch house, the first output of the power switch with a second terminal for connecting the monitoring object, with the second output of the voltage divider, characterized in that a rectifier, a meter are introduced into the device, a pulse shaper of 1/2 duration of the response voltage fluctuation period with delayed restart for a period of at least the duration of the attenuation of the response and no more than the period following the discharges of the storage capacitor, the input and output of which are connected respectively to t etim terminal of the voltage divider, to an input of the rectifier to the first input meter, a first terminal of a voltage source and a second meter input, a second terminal coupled to the power key second terminals of the storage capacitor and the voltage source.  4. The device according to claim 3, characterized in that the average voltage meter is used as a meter.  5. The device according to claim 3, characterized in that the voltage source is adjustable.

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