KR20030004510A - Apparatus and method for multi-testing insulation of power cables - Google Patents

Abstract

PURPOSE: An apparatus for analyzing the multi-insulation of a power cable and a method for the same are provided to reduce an interruption time of electrical power and to increase the reliability of the apparatus through the selection of various diagnostic modes. CONSTITUTION: An apparatus for analyzing the multi-insulation of a power cable includes a power supply(100) for supplying a power to charge the power cable, a high voltage switching module block(200) provided with a switching module block for performing a power input and power interruption to supply from the power supply(100) to the cable and a switching module for discharging the charged voltage to the cable, a resistor module block(400) connected to the cable, a signal measuring block(500) for detecting the current and the voltage selectively flowing into the resistor module block(400) in response to the high voltage switching module block(200), an input block(900) for selecting a plurality of insulation diagnostic modes to diagnose the deterioration status of the cable and a control block(600) provided with an operation control block(610) for selectively operating the high voltage switching module(200) and the resistor module block(400) in response to the insulation diagnostic modes set through the input block(900), a signal process block(620) for appropriately fabricating the data detected at the signal measuring block(500) and a deterioration determination block(630) for determining the deterioration status of the cable based on the fabricated data.

Description

Apparatus and method for multi-testing insulation of power cables

The present invention relates to a multi-insulation diagnosis apparatus and method thereof for a power cable, and more particularly, to a multi-diagnosis insulation diagnosis apparatus and a method for increasing reliability of deterioration determination of a power cable.

In general, the power cable embedded in the ground can not directly determine the deterioration state of the cable, so the deterioration state of the cable was determined by applying a high DC voltage to the cable and then measuring the amount of minute leakage current flowing into the outer layer of the cable.

However, this method cannot obtain accurate measured value because the guideline of measuring instrument is shaken, and the error of measured value becomes very large according to the length of the embedded power cable. There is a disadvantage that destruction is likely to occur.

In order to remedy these shortcomings, a voltage attenuation method is used to calculate the attenuation of the discharge voltage by measuring the current flowing through the high resistance by temporarily applying a high voltage to the cable and then charging and disabling the cable. Degradation determination of the cable was made.

However, the conventional unilateral diagnostic method based on a single diagnostic technique has a problem in that there is a possibility of determination error, and the live diagnosis method is not applicable to the multi-grounding system in Korea, and only the oblique diagnosis is possible. As a result, losses due to power outages have to be considered.

In addition, in order to efficiently manage the underground cable embedded there is a need for a device that can increase the field applicability by improving the stability of the device, portability, operability, and the like.

Therefore, the technical problem to be achieved by the present invention is to increase the reliability of the insulation diagnosis for the determination of degradation of underground cables and to improve the field applicability of the device.

1 is a structural diagram of a multiple insulation diagnostic apparatus according to an embodiment of the present invention.

2 is a block diagram showing a detailed structure of a multiple insulation diagnostic apparatus according to an embodiment of the present invention and a connection state with a cable database management and diagnostic analysis unit.

3 is a view showing the structure of a battery module of the power supply unit according to an embodiment of the present invention.

4 is a diagram illustrating a structure of an ultrahigh resistance module unit of a resistance module unit according to an exemplary embodiment of the present invention.

5 is an exemplary view showing a detailed structure of a control unit and a memory unit of a multiple insulation diagnostic apparatus according to an embodiment of the present invention.

6 is an operational flowchart of a multiple insulation diagnostic method according to an embodiment of the present invention.

7 is a graph showing deterioration determination criteria according to an embodiment of the present invention.

Multi-insulation diagnostic apparatus according to a feature of the present invention for achieving the technical problem, a device for diagnosing the insulation state of the power cable, a power supply for supplying a voltage for charging the power cable; A high voltage switching module unit including a switching module unit for supplying a voltage from the power supply unit to a cable and turning off a power supply; and a switching module unit for discharging the voltage charged in the cable; Ultra high resistance module part for measuring deterioration time constant, charging series resistance part for all diagnostic methods, current resistance input resistance part for measuring polarity index, absorption current and relaxation current, and discharge resistance for discharging the remaining charge in the cable A resistor module unit including a unit; A signal measuring unit measuring a current and a voltage selectively flowing through the resistance module unit according to the operation of the high voltage switching module unit after the cable is charged; An input unit for selecting a plurality of insulation diagnostic modes for diagnosing a degradation state of the cable; And an operation control unit for selectively operating each unit of the high voltage switching module unit and the resistance module unit according to the insulation diagnosis mode set through the input unit, a signal processing unit processing the data measured by the signal measuring unit into an appropriate form, and the processing And a control unit including a deterioration determination unit for determining a deterioration state of the cable based on the data.

The high voltage switching module unit includes a plurality of switching units for supplying power to the first phase, the second phase, and the third phase of the cable, and shutting off and discharging the power, respectively.

In this case, when the three-phase multiple simultaneous insulation diagnosis mode is set through the input unit, the control unit operates all the plurality of switching units of the switching module unit for turning on and off the power so that the voltage is predetermined as the first to third phases of the cable. After supplying during the boost and pressurization time, the switching module unit for turning on and off the power was again cut off, and a signal flowing during the discharge of the cable through the ultra high resistance module unit of the resistance module unit was measured to determine the degradation time constant of the first to third phases. Simultaneous measurements are made to determine the deterioration of the cable based on these measured data.

In addition, when the single-phase multiple insulation diagnostic mode is set through the data input unit, the control unit operates only one phase switching unit among the plurality of switching units of the power supply and interruption switching module unit, so that the predetermined step-up of only one phase of the cable, After the power is supplied during the pressurized time, immediately after the power is turned on, the signal measuring unit measures a signal flowing through the charging series resistance unit and the current measuring input resistance unit of the resistance module unit to measure the current change over time and the voltage change over time. Measure and de-energize the cable by switching off only one phase switching part of the switching module part for power on and off, and measure the deterioration time constant through the ultra high resistance module part of the resistance module part, and measure the remaining two phases through the test procedure in turn. The deterioration state of the cable is determined based on the data.

In the multiple insulation diagnostic apparatus of a power cable according to a feature of the present invention, the control unit operates the discharge switching module unit before the power is turned on and after each test to measure the deterioration state of the cable, and the charge remaining in the cable Is discharged through the discharge resistor part of the resistance module to remove the effect of the pressurized state and the preceding test before the test.

On the other hand, the power supply unit includes a battery cell, a charging unit for charging and discharging the battery cell, a blocking switch for blocking the over-current due to the overcharge of the battery cell, and a battery module including a voltage detector for detecting the charge voltage of the battery cell The battery module unit may be selectively used according to the degradation condition of the cable.

In addition, the multi-insulation diagnosis method according to another aspect of the present invention, a method for diagnosing the insulation state of the power cable, a plurality of phases including a three-phase simultaneous diagnosis mode of the cable or a single-phase multi-diagnosis mode for sequentially measuring the cable single phase Selecting one of the diagnostic modes of the diagnostic mode; Setting a measurement variable including a test voltage and a number of measurements according to the selected diagnostic mode; Charging the cable; Cutting off the power supply to the cable after a predetermined time and measuring a signal flowing through the resistor module connected to the cable according to the selected diagnostic mode; Discharging the remaining charge in the cable by operating the switching module for discharging when the signal measurement is completed; And processing the measured data into deterioration determination data, and determining whether the cable is deteriorated based on the processed deterioration determination data.

When the three-phase multiple simultaneous insulation diagnostic mode is set in the diagnostic mode selection step, the power is supplied to all three phases of the cable, and then the first to third phases are connected through the ultra-high resistance module part of the resistance module part connected to the cable. The degradation time constant is simultaneously measured and the degradation state of the cable is determined based on the measured data.

On the other hand, when the single-phase multi-insulation diagnostic mode is set in the diagnostic mode selection step, the power is supplied to only one of three phases of the cable, and then the charging series resistance part and the current of the resistance module part connected to the cable immediately after the power is supplied. Measure the current change with time and voltage change with time through the input resistance part for measurement, and measure the diagnostic variables of the polarity index, absorption current, and current characteristics for each voltage step. The degradation time constant is measured through the unit to determine the degradation state of the cable based on the measured data.

In addition, the electrical diagnostic results according to the diagnostic mode is managed by the database through the cable database management and diagnostic result analysis unit to derive the final degradation determination results according to the track history and environmental data.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The multi-insulation diagnosis method according to the embodiment of the present invention can select the multi-diagnosis, single-phase diagnosis or three-phase simultaneous diagnosis, etc. without depending on the single insulation method, which is a conventional insulation grounding method. The final diagnosis results should be derived by parameterizing and weighting the track history and environmental data such as the environment.

Specifically, the principle of multiple or simultaneous diagnosis is largely divided into DC current measurement and voltage measurement, so that various diagnostic variables can be measured for each measurement variable, the polarization method and the step voltage test for each voltage step ), The insulation diagnosis method of absorption current method and cable time constant method is applied simultaneously or selectively to increase the reliability of insulation diagnosis.

In addition, it is possible to select single-phase or three-phase simultaneous diagnosis according to the environmental and economic conditions of the measuring place.In addition, various data are variable and weighted by the cable DB management and diagnosis result analysis program, and the electrical diagnosis result is given. And the final diagnosis results.

Among the insulation diagnostic techniques, the polarity index method is a method of exponentially expressing the change in the amount of current over time (e.g., the change in the amount of current at 1 minute after turning on the power and the amount of current at 10 minutes after turning on the power) is exponential. It is judged that the insulation state is deteriorated.

The step voltage test for each voltage step increases the test voltage step by step to measure the current value at a predetermined time point for each voltage step to determine the deterioration degree of the non-linearity of the current-voltage characteristic. I think the condition has worsened.

Absorption current method removes charging current and leakage current and deteriorates by signal processing of absorption current. As the current component with long polarization time increases, insulation state deteriorates.

The measurement method of the cable degradation time constant is to measure and determine the degradation time constant by measuring the voltage signal after the equivalent opening of the cable RC equivalent circuit after removing the power supply. The insulation degradation deteriorates as the degradation time constant increases.

The user can select several modes such as three-phase simultaneous diagnosis mode and single-phase multiple diagnosis mode by applying these isolation diagnostics simultaneously or cross-apply or by selectively applying specific diagnostic techniques and determining whether three-phase simultaneous diagnosis or single-phase diagnosis is applied. have.

In addition, test conditions, such as test voltage and pressurization conditions, need to be changed to optimal conditions according to the accumulation of diagnostic results according to site conditions, and in the present invention, such test conditions can be changed.

In addition, in order to determine whether the cable is replaced and the range, in addition to the insulation diagnosis and deterioration determination by the various electrical insulation diagnosis techniques described above, the weighting is made by varying the line history and environmental data such as accident history, years of use, and line environment. Since it is necessary to derive the final diagnosis result by combining it with the electrical diagnosis result, in the present invention, the diagnosis result of the cable is database-managed and managed together with the track history and environmental data such as accident history, years of use, and track environment. It is possible to reliably determine whether to replace the cable.

A detailed apparatus and method for implementing multiple insulation diagnostics according to an embodiment of the present invention having these characteristics will be described.

1 shows a structure of a multiple insulation diagnostic apparatus of a power cable according to an embodiment of the present invention, and FIG. 2 shows a detailed structure of each part constituting the device of FIG. 1.

As shown in FIG. 1, the multi-insulation diagnosis apparatus according to the embodiment of the present invention includes: a power supply unit 100, a high voltage switching module unit 200, a terminal leakage removing unit 300, a resistance module unit 400, Signal measuring unit 500, control unit 600, memory unit 700, input and output communication unit 800, data input unit 900, display device unit 1000, and the cable database management through the input and output communication unit 800 And it is connected to the diagnostic result analysis unit 1100.

The power supply unit 100 converts an AC voltage into a DC voltage, and supplies the AC-DC power supply 110 to convert the DC voltage into a predetermined DC voltage, and supplies the DC-DC power supply 120 and a separate DC voltage. It includes a battery module 130 for supplying, and a power control unit 140 to control the operation of each unit to selectively supply the voltage of each unit. The battery module 130 is used to exclude the noise due to the AC input power is particularly serious in the case of power supply and current measurement in the field difficult to secure power.

3 shows a detailed structure of the battery module unit. As shown in FIG. 3, the battery module unit 130 controls the operation of the battery cell 131, the FET device 132 and the FET device 132 that perform charge / discharge of the battery cell 131. A control IC 133 that controls charging and discharging of the battery cell 131, a blocking switch 134 for blocking an overcurrent caused by overcharging of the battery cell 131, and a voltage for detecting the charging voltage of the battery cell 131. Detector 135. Here, the battery cell 131 is a lithium-ion battery cell, and the control IC 133 controls charging and discharging of the battery cell 131 based on the voltage output from the voltage detector 135 to charge an appropriate voltage to each circuit. To be supplied.

On the other hand, the high-voltage switching module unit 200 is a switching module unit (211, 212, 213) for power supply and cut off, and the discharge switching module unit (221, 222, 223) for ensuring the stability of the device and improving the measurement reliability Include.

The terminal leakage removing unit 300 is made of synthetic resin such as Teflon to prevent external noise caused by terminal leakage or the like during signal measurement.

The resistance module unit 400 includes an ultra high resistance module unit 410 for measuring attenuation voltage or deterioration time constant, a charge series resistor unit 420 applied to all diagnostic methods, and a current measurement for measuring a polarity index, an absorption current, and a relaxation current. And a discharge resistor 440 for discharging the remaining charge in the cable after the start of the mode test or the end of each test.

4 shows the structure of the ultrahigh resistance module unit. In an embodiment of the present invention, the ultrahigh resistance module unit 410 is formed of a structure in which ultrahigh resistance of 1TΩ-10TΩ or more is installed inside a Teflon cell. The ultra-high resistance module unit 410 ensures that the final equivalent resistance value is at least 10 ² times the line equivalent resistance to ensure the reliability of the measurement. The charging series resistor unit 420 functions to limit the charging current in response to the change in the capacitance component according to the length of the line. The current resistance input resistance unit 430 has a structure for excluding an influence such as noise during the micro current measurement.

The signal measuring unit 500 measures the leakage current measured through the resistance module unit 400 to determine the degradation state of the cable. For example, the current voltage converter converts the measured leakage current into a corresponding voltage. Amplifier to amplify voltage, sample hold to sample amplified voltage, clock generator to generate clock signal, divider to divide output of clock generator, controller to control signal conversion operation according to clock signal, output of divider And an A / D converter for converting the sampled signal provided from the sample hold device into digital data and outputting the digital data to the controller under the control of the controller. do.

The controller 600 may determine a deterioration state of the cable based on the data output from the signal measuring unit 500. For example, the controller 600 may include a microprocessor in which a program for diagnosing the state of the cable is embedded. In particular, the control unit 600 sets a mode for diagnosing a deterioration state of the cable according to a user's selection, and selectively operates each unit of each of the resistance module 400 or the high voltage switching module 200 according to the set mode. An operation control unit 610 for measuring the deterioration state of the cable, a signal processing unit 620 for processing the data measured by the signal measuring unit 500 into an appropriate form, and a deterioration state of the cable based on the processed data. The deterioration determination unit 630 to determine the. Such a controller may be implemented as shown in FIG. 5.

The memory unit 700 stores the degradation measurement result of the cable, in addition to the degradation diagnostic program according to the present invention is stored, and may include a ROM RAM, FLASH MEMORY.

The data input unit 900 is formed of a keypad, and the display device 1000 is formed of an LCD. In the present embodiment, the cable deterioration state can be more conveniently diagnosed through the data input unit or the display device unit having a simple structure without using a personal computer, and the size can be reduced. It provides a site for diagnosing.

The input / output communication unit 800 communicates with a cable database management and diagnostic result analysis unit 1100 that manages and analyzes a database in which various types of information of a cable are stored. Send and receive necessary data to each other.

Meanwhile, the cable database management and diagnosis result analysis unit 1100 (hereinafter referred to as management and diagnosis result analysis unit) is a communication interface unit communicating with the multiple insulation diagnostic apparatus according to the embodiment of the present invention, as shown in FIG. 1110, a cable database 1120 storing deterioration state information of a cable diagnosed by a multi-insulation diagnosis device, a database manager 1130 managing data input / output to the cable database 1120, and a cable database 1120. It includes a data analysis unit 1140 for analyzing the cable degradation diagnostic results based on various data. The management and diagnosis result analysis unit 1100 may be installed in a personal computer or the like.

Next, a multi-insulation diagnosis method according to an embodiment of the present invention will be described in more detail based on the device having such a structure.

6 is an operation flowchart of a multiple insulation diagnostic method according to an embodiment of the present invention.

As shown in FIG. 6, first, each part of the multiple deterioration diagnosis apparatus is connected to the cable (measurement cable) to diagnose the deterioration state as shown in FIG. That is, the high voltage switching module unit 200 and the resistance module unit 400 are connected to both ends of the measuring point of the measuring cable to input a high voltage for the diagnostic test and to signal the resistance module unit 400 capable of measuring various diagnostic variables. To flow (S100).

Through the data input unit 900, one of three-phase simultaneous diagnosis, single-phase multiple diagnosis, or one of several modes in which the various diagnostic techniques are selectively and alternately applied is received, and test variables such as pressure, boost, and repetition frequency are input. S110).

The operation control unit 610 controls the operation of the high voltage switching module unit 200 and the power supply unit 100 according to the selection of the mode inputted to the data input unit 900 and the test variable (pressure, boost, repetition frequency, etc.). Charge (S120).

After a predetermined time, the switching module unit 211, 212, 213 for turning on and off the high voltage switching module unit 200 is cut off and the resistance module unit 400 according to the insulation diagnostic mode selected by the data input unit 900. The signal flowing through the ultra-high resistance module unit 410, the serial charging unit 420, or the current measurement input resistance unit 430 is measured by the signal measuring unit 500 (S130).

When the measurement is made for a predetermined time, the operation controller 610 immediately operates the switching module modules 221, 222, and 223 for discharging, and discharges the charge remaining in the three-phase cable to the discharge resistor 440 of the resistor module 400. Discharge for a predetermined time through (S140).

The data measured for a predetermined time is processed by the signal processing unit 610 into an appropriate form according to the deterioration determination data (S150). The deterioration determination unit 630 determines an insulation state according to a predetermined data processing procedure and standard based on the processed data, and displays the result through the display device unit 1000 (S160).

Finally, when all the diagnostic tests are completed, the diagnostic result data is stored in the memory unit 700 in the apparatus, and if necessary, the transmission and storage of the diagnostic result data to an external PC through the input / output communication unit 800 is possible. The analysis unit 1100 makes a variable and weights the track history and environmental data of the measurement cable to derive the final diagnosis result (S170).

The multiple degradation diagnostic method of the cable will be described in detail for each mode to be set.

In step S110, when the user selects the three-phase simultaneous diagnosis mode for simultaneously measuring three phases to reduce the power failure time during the oblique diagnosis, the operation controller 610 performs the three-phase simultaneous diagnosis mode through the data input unit 900. Input test variables such as pressurization, boost, and repetition frequency for execution. Then, the voltage supplied by driving the power supply unit 100 is boosted for a predetermined time according to the length of the cable to be measured to reach a predetermined test voltage.

When the voltage reaches a predetermined test voltage, the switching module unit 211, 212, 213 for turning on and off the power is operated so that the boosted voltage is simultaneously supplied to three phases for a predetermined time. The switching switching module parts 211, 212, 213 are operated to cut off the voltage supply to the three phases. Next, the signal measuring unit 500 measures the current flowing through the ultra-high resistance module unit 410 of the resistance module unit 400 to perform three-phase simultaneous measurement of the degradation time constant. At this time, the results of powering on and measuring are displayed on the screen through the display device 1000 in real time.

After the deterioration time constant measurement of the signal measuring unit 500 is completed for a predetermined time, the switching switching module units 221, 222, and 223 for discharge are operated immediately to discharge the charge remaining in the three-phase cable to the discharge resistance of the resistance module unit 400. Through the unit 440 is discharged for a predetermined time.

The operation controller 610 repeats the above-described cable charging and signal measurement according to the number of repetitions selected by the data input unit 900. When the signal measurement is performed according to the set number of repetitions, the signal processor 620 transmits the measurement data. The processed form is processed and the processed data is processed by the deterioration determining unit 630 according to a predetermined data processing procedure and standard to determine the insulation state of the cable and display the determination result on the display device unit 1000.

On the other hand, when a single-phase multi-diagnosis mode is set to maximize the reliability by applying multiple insulation diagnostic techniques in multiple steps (S110) and sequentially measuring the three-phase cable single-phase, single-phase multiple diagnosis through the data input unit 900 The test variables such as pressurization, boosting, and repetition frequency are input.

Next, the voltage supplied from the power supply unit 100 is boosted for a predetermined time to reach a predetermined test voltage. For repeated tests, the voltage is stepped up from 0kV to 5kV in steps of 1kV, and the test power is repeatedly turned on, off, and discharged.

In addition, the B and C phase power supply and cutoff switching module parts 212 and 213 of the switching module parts 211, 212 and 213 for power supply and interruption are opened to prevent power from being supplied to the B and C phases of the cable. It separates and controls the switching module part 211 for A phase power supply and interruption, and inputs the voltage of the power supply part 100 controlled by the predetermined | prescribed primary test voltage to phase A of a cable. The signal measuring unit 500 measures the current and voltage according to the passage of time for each predetermined voltage step during the predetermined pressing time, and provides the signal to the controller 600, and the controller 600 controls the current-time and the voltage-time for the predetermined time. Calculate the characteristic data. Upon completion of the measurement, immediately open the switching module part 211 for turning on and off the phase A power and cut off the power and measure the degradation time constant.

The current-time and voltage-time characteristic data measured immediately after the power is applied are applied to the dielectric diagnosis method, the polarity index method, the absorption current method, and the current characteristic method for each voltage step. At this time, the results of power on, current-time, voltage-time characteristics, and deterioration time constant measurement are displayed on the screen through the display device 1000 in real time.

On the other hand, when the measurement is finished, the operation control unit 610 immediately operates the A phase discharge switching module unit 221 to discharge the charge remaining in the cable through the discharge resistor unit 440 of the resistance module unit 400 for a predetermined time. Discharge.

In this embodiment, the above-described diagnostic procedure is repeatedly performed for each voltage step input according to the single-phase multiple insulation diagnostic mode setting, and the data measured by the signal measuring unit 500 according to the repetition is performed through the signal processing unit 620. The deterioration determination unit 630 determines the insulation state of the cable based on the processed data according to a predetermined data processing procedure and standard, and displays the result through the display device unit 1000.

The B-phase and C-phase cables are also performed sequentially according to the method described above. At this time, the state of the high-voltage switching module 200 on the remaining phase other than the cable to be diagnosed is an open state.

On the other hand, the deterioration judging unit determines the deterioration state of the cable based on the data measured according to the insulation diagnostic mode set as described above, and FIG. 7 shows a graph showing deterioration determination criteria in the embodiment of the present invention.

As shown in Fig. 7, the deterioration index is determined to determine the deterioration state of the cable into three categories: good, attention, and bad.

In the three-phase simultaneous diagnosis mode, the deterioration status of the cable is judged into three categories of good, caution, and poor according to predetermined criteria of each phase. Determine whether or not. Since it is a three-phase simultaneous measurement, the deterioration of the cable is judged as good, caution, or bad only when the three phases match.

In the case of single-phase multiple diagnosis mode, each diagnosis technique (polarity index method, absorption current method, current characteristic method for each voltage step) is weighted and the result is summed to determine the final result. Determine the final result. That is, when three or more results of each diagnostic technique are the same, the deterioration state of a cable is determined as a good state, a caution state, or a bad state.

The deterioration determination method is performed through an algorithm embedded in the controller 600, and the determination result is provided to the tester through the display apparatus 1000. In addition, the determination results and data are stored in the memory unit 700 inside the device, and later transferred to the cable database management and diagnosis result analysis unit 1100 installed in the PC through the input / output communication unit 800, if necessary, to be databaseized and managed. . And the cable database management and diagnostic result analysis unit 1100 is the electrical diagnostics measured by the device of the present invention the results of the parameterized track history and environmental data, such as accident history, years of use, track environment according to the needs of the field tester Combined with the results, the final diagnostic results can be derived.

In the embodiment of the present invention, as described above, a single method of applying only one insulation diagnostic technique for determining the deterioration state of the cable or a multiple method of applying two or more insulation diagnostic techniques, and single-phase or three-phase simultaneous diagnosis of the cable Depending on whether or not the insulation diagnostic mode according to an embodiment of the present invention can be selected from several modes.

In addition, the voltage for determining the deterioration state of the cable for each mode may be set step by step, and the number of times for repeatedly performing the measurement operation for each voltage may be set.

Therefore, the investigator can diagnose the deterioration of the cable by selectively applying a plurality of modes according to the diagnosis request or the environment, and the reliability of the insulation diagnosis by selectively applying the measurement variables (voltage for each step, the number of measurement repetitions, etc.) of each mode. Can improve.

The invention is susceptible to various modifications and implementations without departing from the scope of the following claims.

According to the multiple insulation diagnostic apparatus and the method according to the embodiment of the present invention as described above, it is possible to reduce the power failure time and to increase the reliability of the insulation diagnosis by selecting the various diagnostic modes.

In addition, depending on the environmental conditions of the cable to be measured, it is possible to improve the stability, portability, and operability of the device by integrating the device components to improve the field, by removing the terminal leakage, by installing the battery module, by automating the whole test, and by reducing the weight of the device. Can be.

Claims (10)

In the device for diagnosing the insulation state of the power cable, A power supply unit supplying a voltage for charging the power cable; A high voltage switching module unit including a switching module unit for supplying a voltage from the power supply unit to a cable and turning off a power supply; and a switching module unit for discharging the voltage charged in the cable; A resistance module unit connected to the cable, including an ultra-high resistance module unit for measuring a deterioration time constant, a discharge resistor unit for discharging residual charge in the cable, a charge series resistor unit, and an input resistance unit for current measurement; A signal measuring unit measuring a current and a voltage selectively flowing through the resistance module unit according to the operation of the high voltage switching module unit after the cable is charged; An input unit for selecting a plurality of insulation diagnostic modes for diagnosing a degradation state of the cable; And An operation control unit for selectively operating each unit of the high voltage switching module unit and the resistance module unit according to the insulation diagnosis mode set through the input unit, a signal processing unit processing the data measured by the signal measuring unit into an appropriate form; Control unit including a deterioration determination unit for determining the deterioration state of the cable based on the data Multiple insulation diagnostic device of a power cable comprising a. The method of claim 1, The high voltage switching module unit is a multiple insulation diagnostic device of the power cable, characterized in that the power supply to the first phase, the second phase, and the third phase of the cable, and a plurality of switching unit for performing power off and discharge, respectively. The method of claim 2, When the three-phase multiple simultaneous insulation diagnosis mode is set through the data input unit, the control unit operates all of the plurality of switching units of the switching module unit for turning on and off the power so that voltage is boosted or pressed to the first to third phases of the cable. After supplying for a period of time, the switching on and off of the switching module for the power supply and cut-off again simultaneously measured the degradation time constant of the first to third phases based on the signal flowing through the ultra-high resistance module unit of the measured data such measured data Multiple insulation diagnostic apparatus for a power cable, characterized in that for determining the degradation state of the cable based on. The method of claim 2, When the single-phase multiple insulation diagnostic mode is set through the input unit, the controller operates only one switching unit among the plurality of switching units of the power supply and disconnection switching module unit for a predetermined boost and pressurization time for only one phase of the cable. After the power is supplied, measure the current flowing over time and the voltage change over time by measuring the signal flowing through the charging series resistance part of the resistance module part and the input resistance part for current measurement, and blocking the switching part. The deterioration time constant is measured on the basis of the discharge current of the cable flowing through the negative ultra-high resistance module, and the remaining two phases are sequentially determined based on the data measured through the test procedure. Insulation diagnostic device. The method according to any one of claims 1 to 4, The control unit is characterized in that before the power is turned on to measure the deterioration state of the cable and after each diagnosis is finished, the discharge switching module unit is operated so that the charge remaining in the cable is discharged through the discharge resistor unit of the resistance module unit. Cable multiple insulation diagnostics. The method of claim 1, The power supply unit includes a battery module including a battery cell, a charging unit performing charging and discharging of the battery cell, a blocking switch for blocking an overcurrent due to overcharging of the battery cell, and a voltage detector detecting a charging voltage of the battery cell. Multiple insulation diagnostic apparatus of a power cable, characterized in that. In the method for diagnosing the insulation of the power cable, Selecting one of a plurality of diagnostic modes including a three-phase simultaneous diagnosis mode of the cable or a single-phase multiple diagnosis mode for sequentially measuring the cables one by one; Setting a measurement variable including a test voltage and a number of measurements according to the selected diagnostic mode; Charging the cable; Cutting off the power supply to the cable after a predetermined time and measuring a signal flowing through the resistor module connected to the cable according to the selected diagnostic mode; Discharging the remaining charge in the cable by operating the switching module for discharging when the signal measurement is completed; And Processing the measured data into deterioration determination data, and determining whether the cable is deteriorated based on the processed deterioration determination data. Multiple insulation diagnostic method of a power cable comprising a. The method of claim 7, wherein When the three-phase multiple simultaneous insulation diagnostic mode is set in the diagnostic mode selection step, the power is supplied to all three phases of the cable, and then based on a signal flowing through the ultra-high resistance module part connected to the cable. And degrading time constants of the third to third phases simultaneously and determining the deterioration state of the cable based on the measured deterioration time constants. The method of claim 7, wherein When the single-phase multiple insulation diagnostic mode is set in the diagnosis mode selection step, the power is supplied to only one of three phases of the cable, and then the current change over time and the voltage change over time are measured. Calculate the diagnostic variables representing the polarity index, the absorption current, and the current characteristics for each voltage step, cut off the power supply of the cable, measure the degradation time constant based on the signal flowing along the cable discharge, and measure the diagnostic variable and degradation time constant. Multiple insulation diagnostic method of a power cable, characterized in that for determining the degradation state of the cable based on. The method according to claim 8 and 9, Managing a database of the deterioration state determination result of the cable according to the diagnosis mode; And Finally determining the deterioration state of the cable based on the data stored in the database and the additional data including the line history of the cable. Multiple insulation diagnostic method of the power cable further comprising.