KR101291595B1 - Insulation status monitoring Apparatus of power equipments - Google Patents

Abstract

The present invention relates to an insulation state monitoring apparatus for a power device and a method thereof.
In the present invention, the sensor unit for detecting the partial discharge for one period and two periods set from the power device, and the signal of the partial discharge of the frequency band set in the signal of the partial discharge detected in the one period and two periods in the sensor unit An analog-to-digital converter for converting components into digital data for each sensing day, and calculating standard deviation values from the digital data of each of the first and second periods, and comparing the standard deviation threshold values with preset standard deviation threshold values. The number of standard deviation values da1 and da2 for each of the sensing days of the first and second cycles, which are not less than one, is calculated, respectively, and the number of standard deviation values da1 of the one period is the number of the standard deviation values of the two periods. An apparatus for monitoring insulation state of a power device and a method thereof, including a calculating unit for determining that the insulation state of the power device is poor when it is greater than (da2).

Description

Insulation status monitoring Apparatus of power equipment and its method

The present invention relates to an insulation state monitoring apparatus for a power device and a method thereof. More particularly, the present invention relates to an insulation state monitoring device and a method for measuring an electrical discharge in a power device such as an ultra high voltage and large-scaled electric power facility to determine the risk of the insulation state of the power device. .

In recent years, as the industry develops rapidly, as power facilities become ultra-high pressure and large capacity, the possibility of various types of accidents that can occur in various facilities continues to increase. Therefore, there is an urgent need for an always-on preventive diagnosis system for preventing accidents and improving reliability of electric power facilities. In order to develop a preventive diagnosis system for such a permanent facility, the most researched and applied part among the various diagnostic methods that can predict the danger of power equipment without being influenced by external noise is measured by PD. Risk diagnosis technology.

In order to diagnose the insulation state of power equipment, the measurement method using partial discharge among various measurement / diagnosis methods has much information about insulation state. In the straight detection test according to the standard of IEC270, for the partial discharge test, a small partial discharge current generated in the test object is measured at the ground terminal by using a coupling capacitor to the coupling capacitor. Partial discharge is very easy to introduce external noise because the signal is very small, ranging from several mV to several hundred mV. Therefore, in order to increase the signal-to-noise ratio (S / N) by measuring in the high frequency band where external noise is less introduced, research on high frequency partial discharge is being actively conducted. In addition, partial discharge is measured using a current transformer (CT) sensor and a shunt type sensor. In addition, the measurement of the partial discharge of the power device is generally made by collecting and analyzing data on the PD (Partial Discharge) pulse.

Patent No. 10-0954665 (Registration date April 16, 2010) discloses a risk analysis system and method of power equipment.

The patent invention, PD sensor for detecting the electromagnetic wave generated due to partial discharge (PD) generated in the power device; And counting the number of PD pulses detected during a predetermined measurement time and the average size of the pulses received for a predetermined time with respect to the PD pulses detected by the PD sensor, and mapping them to a QN (Quantity / Number) matrix. And a risk diagnosis device for comparing the mapped position with a predetermined risk determination criterion to determine a risk of the power device.

The patent invention uses a single measurement or short term data to determine the risk of a power device. In general, however, deterioration of power equipment tends to repeat good and caution until it reaches a very dangerous stage. Therefore, there is a problem in that the state of the power device may be misjudged because the patent invention is judged to be good every time it is judged, but it is determined to be careful and may cause confusion to the insulation monitor of the power device.

Therefore, there is a need for an invention in which the partial discharge of a power device is measured at regular intervals, so that the insulation state of the power device can be accurately determined even when the insulation state of the power device is good and the surroundings are repeated during the predetermined period.

Patent Registration No. 10-0954665 (Registration date April 16, 2010)

The present invention is to solve the problems of the prior art, an object of the present invention is to monitor the insulation state of the power device, even if the measured value of the partial discharge of the power device changes for a certain period of time of the power device An object of the present invention is to provide an insulation state monitoring device for a power device and a method thereof capable of accurately determining the risk of the insulation state.

As a technical solution for achieving the object of the present invention, as a first aspect of the present invention, a PD sensor for detecting a partial discharge by a set period, a set time and a set number of times in the power device to be measured; A filter and amplifying unit for extracting and amplifying a signal having a predetermined frequency band from the partial discharge signal detected by the PD sensor; An analog / digital converter for converting analog values of the partial discharge signal components output from the filter and the amplifier into digital values; A standard deviation calculator for calculating a standard deviation of digital values of the partial discharge signal components output from the analog / digital converter; A first period calculation for receiving the standard deviation values during the first period of the set number of times from the standard deviation value calculated by the standard deviation calculator and calculating the number of standard deviation values having a standard deviation value larger than the set value Wealth; A second period calculation for calculating the number of standard deviation values having a standard deviation value larger than a set value by receiving standard deviation values for a second period of the set number of times from the standard deviation value calculated by the standard deviation calculator; Wealth; A first periodic average value calculation unit for obtaining an average value of the standard deviation values during the first period; A second period average value calculation unit for obtaining an average value of standard deviation values for the second period; A first multiplier for multiplying the calculated value of the first period calculator and the calculated value of the first period average value calculator; A second multiplier for multiplying the calculated value of the second period calculator and the calculated value of the second period average value calculator; Monitoring the insulation state of a power device including an insulation state determination unit for comparing the calculated value of the first multiplier and the calculated value of the second multiplier to determine that the insulation state of the power device is poor if the calculated value of the first multiplier is large. The device is presented.

In addition, as a second aspect of the present invention, the PD sensor and the partial discharge detection step of detecting the partial discharge by the set period, the set time and the set number of times in the power target device; A filtering and amplifying step of extracting and amplifying a signal of a predetermined frequency band from the partial discharge signal detected by the PD sensor by the filter and the amplifier; An analog / digital conversion step of converting an analog value of the partial discharge signal component output from the filter and amplification unit into a digital value by an analog / digital conversion unit; A standard deviation calculation step of calculating a standard deviation of a digital value of the partial discharge signal component outputted from the analog / digital converter by a standard deviation calculator; A first period calculator receives standard deviation values for the first period of the set number of times from the standard deviation value calculated by the standard deviation calculator to calculate the number of standard deviation values having a standard deviation value larger than the set value. A first period calculating step; A second period calculator receives standard deviation values for a second period of the set number of times from the standard deviation value calculated by the standard deviation calculator to calculate the number of standard deviation values having a standard deviation value larger than the set value. A second period calculating step; A first period average value calculating step of a first period average value calculating unit obtaining an average value of standard deviation values during the first period; A second period average value calculating step of a second period average value calculating unit obtaining an average value of the standard deviation values during the second period; A first multiplication step of multiplying, by a first multiplier, the calculated value of the first period calculator and the calculated value of the first period average value calculator; A second multiplication step of multiplying, by a second multiplier, the calculated value of the second period calculator and the calculated value of the second period average value calculator; And an insulation state judging unit comparing the calculated value of the first multiplier with the calculated value of the second multiplier to determine that the insulation state of the power device is poor if the calculated value of the first multiplier is large. Insulation condition monitoring method is presented.

According to the present invention, in monitoring the insulation state of a power device, there is an effect that can accurately determine the risk of the insulation state of the power device even in a state where the measurement value of the partial discharge of the power device changes frequently from time to time.

1 is a schematic configuration diagram of an embodiment of an insulation state monitoring apparatus of a power device of the present invention.
2 is a schematic configuration diagram of an embodiment of an operation unit which is a main part of an insulation state monitoring apparatus of a power device of the present invention.
FIG. 3 is a table for setting the period to 30 days in the PD sensor unit 20 and showing values such as partial discharge values and standard deviations measured for each day of one cycle, two cycles, and three cycles.
4 is a flowchart illustrating a first embodiment of an insulation state monitoring method of a power device according to the present invention.
5 is a flowchart illustrating a second embodiment of an insulation state monitoring method of a power device according to the present invention.
6 is a flowchart for explaining a third embodiment of the insulation state monitoring method of the power device of the present invention.
7 is a flowchart illustrating a fourth embodiment of an insulation state monitoring method of a power device according to the present invention.
8 is a flowchart for describing a fifth embodiment of the insulation state monitoring method of the power device according to the present invention.
9 is a flowchart for explaining a sixth embodiment of the insulation state monitoring method of the power device of the present invention.

Hereinafter, the configuration of the invention of the embodiments of the present invention will be described in detail with reference to the accompanying drawings. 1 is a schematic configuration diagram of an embodiment of an insulation state monitoring apparatus of a power device of the present invention. As shown in FIG. 1, an insulation state monitoring apparatus of a power device of the present invention includes a PD sensor 20 for detecting partial discharge by a set period, a set time, and a set number of times in a measurement target power device 10; A filter and amplifying unit 30 for extracting and amplifying a signal of a predetermined frequency band from the partial discharge signal detected by the PD sensor 20; An analog / digital converter 40 for converting the analog value of the partial discharge signal component output from the filter and amplification unit into a digital value; A standard deviation calculator (50) for calculating a standard deviation of digital values of the partial discharge signal components output from the analog / digital converter (40); A number of standard deviation values da1 having a standard deviation value larger than a set value by receiving standard deviation values for a first period of the set number of times from the standard deviation value calculated by the standard deviation calculator 50; The standard deviation value calculated by the standard deviation calculator 50 receives the standard deviation values for the second period of the set number of times and calculates the number of standard deviation values da2 having a standard deviation value larger than the set value. A comparison calculation unit 60 for performing; An average value calculator (70) for obtaining an average value (db1) of standard deviation values during the first period, and calculating an average value (db2) of standard deviation values for the second period; The calculated value da1 of the first period of the comparison calculation unit 60 and the average value db1 of the first period of the average value calculation unit 70 are multiplied, and the value of the comparison calculation unit 60 is increased. A multiplier (80) for multiplying a calculated value (da2) relating to a second period and an average value (db2) relating to said second period of said average value calculator (70); The calculated value dc1 of the first period is compared with the calculated value dc2 of the second period of the multiplier 80, and the calculated value dc1 of the first period is calculated from the second period. If greater than (dc2) is configured to include an insulation state determination unit 90 for determining that the insulation state of the power device is poor.

In addition, the insulation state monitoring device of the power device of the present invention may be configured by the calculation unit 200 including the configuration of the standard deviation calculation unit 50 to the insulation state determination unit 90. The apparatus may further include a storage unit 100 for storing the calculated value calculated in the configuration of the standard deviation calculator 50 or the multiplier 80 or calculated by the calculator. The apparatus may further include a data input unit 120 for inputting the set value to be referred to by the standard deviation calculation unit 50 to the insulation state determination unit 90. In addition, the calculated value calculated in the configuration of the standard deviation calculation unit 50 to the multiplication unit 80 or the calculation unit 200 is visually displayed, or the determination result of the insulation state determination unit 90 It may further include a display unit 110 for visually displaying the. In addition, according to the determination result of the insulation state determination unit 90 may further include an alarm output unit 130 for outputting the alarm visually or audibly. The apparatus may further include a remote communication means for communicating with an administrator computer capable of remotely checking or controlling the insulation state monitoring device and the wired / wireless communication means of the power device.

The PD sensor unit 20 may include a configuration including a coupling capacitor, a CT type sensor, a current sensor, or a shunt type sensor. The PD sensor unit 20 may be installed on the ground line of the power device to detect partial discharge. 2 is a schematic configuration diagram of an embodiment of a calculation unit 200 which is a main part of an insulation state monitoring apparatus of a power device of the present invention. As shown in FIG. 2, the comparison calculation unit 60 included in the calculation unit 200 of the present invention reads the standard deviation calculation value calculated by the standard deviation calculation unit 50 and performs the standard for the first period. A first period calculator 62 for calculating the number da1 of standard deviation values having standard deviation values larger than a set value by receiving deviation values, and the standard deviation calculated by the standard deviation calculator 50 A second period calculation unit 64 for reading the calculated value and receiving the standard deviation values during the second period to calculate the number of standard deviation values da2 having a standard deviation value larger than the set value. have.

Further, the average value calculator 70 includes a first period average value calculator 72 for calculating an average value db1 of the standard deviation values for the first period, and an average value of the standard deviation values for the second period. and a second period average value calculator 74 to obtain db2.

In addition, the multiplication unit 80 includes a calculated value da1 of the first period of the comparison calculation unit 60 or the first period calculation unit 62, the average value calculation unit 70, or the A first multiplier 82 for multiplying an average value db1 of the first period average value calculating unit 72 and the first period average value calculating unit 72 and the comparison calculation unit 60 or the second period calculating unit 64; The second multiplier 84 for multiplying the calculated value da2 of the two periods with the average value db2 of the second period of the average value calculating part 70 or the second period average value calculating part 74 is It may include.

The first period or the second period of the present invention may be set on a weekly, monthly or quarterly basis. Preferably it is set in units of months (30 days). The first period may be before January (30 days) from today, and the second period may be set to January (30 days) before the first period. In addition, the present invention may further include a third period, and the comparison calculation unit 60 may further include a third period calculation unit 66 and a third period average value calculation unit 76. In addition, the multiplier 80 may further include a third multiplier 86. In this case, the third period may be set to, for example, January 30 before the second period.

3 shows the standard deviation value calculated by the standard deviation calculator 50 from the partial discharge value measured for each day of 1 cycle, 2 cycles and 3 cycles by setting the period to 30 days in the PD sensor unit 20. , The values da1, da2, da3 of each period calculated from the comparison calculation unit 60 or the first period calculation unit 62 to the third period calculation unit 66, and the average value calculation unit 70 or The average value db1, db2, db3 of each period calculated by the first period average value calculation unit 72 to the third period average value calculation unit 76, and the multiplication unit 80 or the first multiplication unit 82; It is a table regarding data regarding multiplication values dc1, dc2, dc3 of each period calculated from the third multiplication section 86. FIG.

In addition, the set time for measuring the partial discharge of the power device may be set to 10 minutes or less or more.

As shown in FIG. 3, each cycle is set to 30 days, and one cycle is set to 10 minutes every day, for example, the measurement time until June 1, 2011, 30 days before June 30, 2011. In this case, when the partial discharge is measured by the PD sensor unit 20 for 10 minutes every day, the filter and amplification unit 30 extracts a signal of a frequency band set from the signals of the partial discharge detected by the PD sensor unit 20. And amplify it, convert the analog value of the partial discharge signal component outputted from the filter and the amplification unit 30 to the digital value from the analog / digital conversion unit 40, and the standard deviation calculator 50 The standard deviation of the digital value of the partial discharge signal component output from the analog / digital conversion unit 40 is calculated, and the comparison calculation unit 60 or the first period calculation unit 62 to the third period calculation unit 66 are performed. ), The standard deviation threshold for each period is set to 5. The case, the standard deviation value for each period stored in the storage unit 100 counts the number (= 17 da1, da2 = 7, da3 = 4) of big standard deviation value than the threshold value. In addition, the average value calculating unit 70 or the first period average value calculating unit 72 to the third period average value calculating unit 76 calculates the standard deviation average values (db1 = 5.16, db2 = 2.06, db3 = 1.84) of each period. It is calculated and stored in the storage unit 100. In addition, the multiplication unit 80 or the first multiplication unit 82 to the third multiplication unit 86 is the number of standard deviation values (da1, da2, da3) larger than the boundary value of each cycle and the standard of each cycle. The multiplication deviation values (db1, db2, db3) are multiplied, respectively, and the multiplication values (da1 × db1 = dc1 = 87.78, da2 × db2 = dc2 = 14.42, da3 × db3 = dc3 = 7.36) are stored.

The insulation state determination unit 90 of the present invention retrieves each stored data to determine the insulation state of the power device to be monitored.

4 is a flowchart illustrating a first embodiment of an insulation state monitoring method of a power device according to the present invention. As shown in Figure 4, the insulation state monitoring method of the power device of the present invention, the set measurement period (period) of the partial discharge with respect to the power device, the set measurement time per day, the number of measurements (in the present invention can calculate the standard deviation) In order to calculate the data, 100 times, 100 times or less or more than 100 embodiments can be configured.) And insulation state monitoring of power equipment using insulation state monitoring device that stores the set standard deviation threshold. In the method, the step of measuring the partial discharge of the power device in the PD sensor unit (S100), the filter and amplification unit extracts a signal of the frequency band set from the signal of the partial discharge detected by the PD sensor unit and amplifies it (S102), converting the analog signal amplified by the analog-digital conversion unit into digital data (S104), and the digital unit in the operation unit Computing the standard deviation for each day of the data (S106) and the value of the standard deviation for each day from the initial date to the end date of the measurement period by comparing the standard deviation boundary value stored in the calculation unit and the value of the standard deviation for each day Determining whether the value of the standard deviation that is greater than or equal to the standard deviation boundary is increased (S108), and when the value of the standard deviation that is greater than or equal to the standard deviation threshold is increased by the calculator, the insulation of the power device is increased. The configuration includes the step (S110) of determining the state of attention.

The first embodiment of the method for monitoring the insulation state of a power device of the present invention obtains a standard deviation value for each period from one past period, for example, 30 days ago to the present, and compares it with a set standard deviation threshold value. It is a method of determining that the insulation state of the said power equipment requires attention if the daily standard deviation value higher than a deviation threshold becomes high gradually.

5 is a flowchart illustrating a second embodiment of an insulation state monitoring method of a power device according to the present invention. As shown in FIG. 5, the insulation state monitoring method of a power device of the present invention includes a set measurement period (one cycle and two cycles), a set measurement time per day, a measurement frequency, and a set standard deviation boundary of the partial discharge of the power device. A method of monitoring an insulation state of a power device using an insulation state monitoring device storing a value, the method comprising: measuring a partial discharge of the power device during each of the first period and the second period in a PD sensor unit (S200), a filter and Extracting, filtering, and amplifying a signal component of a predetermined frequency band from the partial discharge signal detected by the PD sensor in the amplifier (S202), and converting the analog signal amplified by the analog-digital converter into digital data (S204), and calculating a standard deviation for each day of the digital data of the first period and the second period by the operation unit (S206), respectively. The calculation unit compares the standard deviation boundary value stored for the one cycle and the second cycle with the standard deviation value for each day, and calculates the number of standard deviation values for which the standard deviation value for each day becomes equal to or greater than the standard deviation boundary value. Counting each step (S208), comparing the count number of one cycle with the count number of two cycles in the operation unit, and determining whether the number of first period counts is large (S210), and counting the one cycle in the operation unit If the number is greater than the number of counts of two cycles, it is determined that the insulation state of the power device is bad (S212).

6 is a flowchart for explaining a third embodiment of the insulation state monitoring method of the power device of the present invention. As shown in Figure 6, the insulation state monitoring method of the power device of the present invention, the set measurement period (1 cycle, 2 cycles and 3 cycles) of the partial discharge with respect to the power device, the set measurement time per day, the number of measurements and the set In the insulation state monitoring method of a power device using an insulation state monitoring device that stores a standard deviation threshold value, the PD sensor unit measures the partial discharge of the power device for each of the 1 cycle, 2 cycles and 3 cycles (S300) Extracting and amplifying a signal component of a predetermined frequency band from the partial discharge signal detected by the PD sensor unit in the filter and amplifying unit (S302), and converting the analog signal amplified by the analog-to-digital converter unit into a digital signal. Converting to data (S304), converting an analog signal amplified by the analog-digital converting unit into digital data (S304), and calculating unit 1 Calculating daily standard deviations of the digital data of periods, periods two, and periods three (S206), and the standard deviation boundary values stored for the periods one, two, and three by the calculation unit Comparing the values of the standard deviations and counting the number of values of the standard deviations such that the standard deviation value of each day becomes equal to or greater than the standard deviation boundary value (S308); Comparing the number of counts and the number of counts of three cycles to determine whether the number of counts of the third period is greater than the number of counts of the second period and whether the number of counts of the first period is greater than the number of counts of the second period (S310). And the power device when the count of the third period is greater than the count of the second period and the count of the first period is greater than the count of the second period in the operation unit. The insulation is a configuration including a step (S312) determines that poor.

7 is a flowchart illustrating a fourth embodiment of an insulation state monitoring method of a power device according to the present invention. As shown in FIG. 7, the insulation state monitoring method of a power device of the present invention includes a set measurement period (one cycle and two cycles), a set measurement time per day, a measurement frequency, and a set standard deviation boundary of a partial discharge of the power device. A method for monitoring an insulation state of a power device using an insulation state monitoring device storing a value, the method comprising: measuring partial discharge of the power device during each of the one period and the second period in a PD sensor unit (S400); Extracting and amplifying a signal component of a set frequency band from the partial discharge signal detected by the PD sensor in the amplification unit (S402), and converting the analog signal amplified by the analog-digital converter into digital data; (S404), and calculating a standard deviation for each day of the digital data of the first cycle and the second cycle by the calculation unit (S406), and by the calculation unit The number of standard deviation values for which the standard deviation value for each day is equal to or greater than the standard deviation boundary value by comparing the standard deviation boundary value stored for the first period and the second period with the standard deviation boundary value (da1, da2) respectively counting (S408), and calculating the average value (db1, db2) of the standard deviation value of the one cycle and two cycles in the operation unit (S410), and the standard of one cycle in the operation unit The number of deviation values da1 is multiplied by the average value db1 of the standard deviation values of one cycle, and the number of standard deviation values da2 of the two cycles is multiplied by the average value db2 of the standard deviation values of the two cycles. Obtaining the calculated values dc1 and dc2, respectively (S412); comparing the calculated value dc1 of the one period with the calculated value dc2 of the two periods by the operation unit (S414); In the operation unit, the calculated value dc1 of the one period is set to the two periods. If greater than the calculated value (dc2) is configured to include a step (S416) for determining that the insulation state of the power device is poor.

8 is a flowchart for describing a fifth embodiment of the insulation state monitoring method of the power device according to the present invention. As shown in Figure 8, the insulation state monitoring method of the power device of the present invention, the set measurement period (1 cycle, 2 cycles and 3 cycles) of the partial discharge with respect to the power device, the set measurement time per day, the number of measurements and the set In the insulation state monitoring method of a power device using an insulation state monitoring device that stores a standard deviation threshold value, the PD sensor unit measures the partial discharge of the power device for each of the 1 cycle, 2 cycles and 3 cycles (S500) Extracting and amplifying a signal component of a predetermined frequency band from the partial discharge signal detected by the PD sensor in the filter and amplifying unit (S502), and converting the analog signal amplified by the analog-digital converting unit into a digital signal. Converting the data into data (S504), calculating a daily standard deviation of the digital data of the 1 cycle, 2 cycle, and 3 cycle by the calculation unit (S506), The standard deviation value of the standard deviation for each day is greater than or equal to the standard deviation boundary value by comparing the standard deviation boundary value stored for the 1, 2, and 3 cycles with the value of the standard deviation for each day. Counting the number of values da1, da2, and da3, respectively (S508), and calculating the average values db1, db2, and db3 of the standard deviation values of the one, two, and three cycles, respectively, by the calculator. (S510) and multiply the number da1 of the standard deviation values in one cycle by the average value db1 of the standard deviation values in one cycle in the calculation unit, and the number da2 of the standard deviation values in the two cycles. Multiply the average value (db2) of the standard deviation values of two cycles, multiply the number of standard deviation values (da3) of the three periods by the average value (db3) of the standard deviation values of the three cycles, and calculate the calculated values (dc1, dc2, acquiring dc3) (S512), and the calculated value (1) in the period 1 dc1), comparing the calculated value (dc2) of the two cycles and the calculated value (dc3) of the three cycles (S514), and the calculated value (dc2) of the two cycles in the calculation unit is the three cycles Determining that the insulation state of the power device is poor when the calculated value dc1 of the one period is greater than the calculated value dc2 of the two periods (S514). It is a constitution.

9 is a flowchart for explaining a sixth embodiment of the insulation state monitoring method of the power device of the present invention. As shown in FIG. 9, the insulation state monitoring method of a power device of the present invention includes a set measurement period (one cycle and two cycles), a set measurement time per day, a measurement frequency, and a set standard deviation boundary of the partial discharge of the power device. A method of monitoring an insulation state of a power device using an insulation state monitoring device storing a value, the method comprising: measuring partial discharge of the power device during each of the one period and the second period in a PD sensor unit (S600), a filter and Extracting and amplifying a signal component of a set frequency band from the partial discharge signal detected by the PD sensor in the amplification unit (S602), and converting the analog signal amplified by the analog-digital converter into digital data; (S604), and calculating a standard deviation for each day of the digital data of the first period and the second period by the calculation unit (S606), and by the calculation unit The number of standard deviation values for which the standard deviation value for each day is greater than or equal to the standard deviation boundary value by comparing the standard deviation boundary value stored for the first and second cycles with the standard deviation value for each day for each period. counting (da1, da2), respectively (S608), calculating, by the calculation unit, an average value (db1, db2) of the standard deviation values for each of the first and second cycles (S610), and in the calculation unit, respectively. A value (dc1) obtained by multiplying the number of standard deviations (da1) at which the value of the standard deviation per day of the one cycle is equal to or greater than the standard deviation boundary value and the average value (db1) of the standard deviation per day of the one period A value obtained by multiplying the number da2 of standard deviations, wherein the value of the standard deviation for each day of the two periods is equal to or greater than the standard deviation boundary value, and the average value db2 of the standard deviation for each day of the two periods ( to calculate dc2) (S612), and the number (da1) of standard deviations for which the value of the standard deviation for each day of the one cycle is equal to or greater than the standard deviation boundary in the calculation unit is equal to the standard deviation for each day of the two cycles. Determining whether it is greater than the number da2 of standard deviations that are equal to or greater than the deviation boundary value (S614), and the number of standard deviations that are equal to or greater than the standard deviation boundary value of the one period by the calculation unit (da1) Is equal to or less than the number of standard deviation values (da2) of the two cycles, is the average value db1 of the standard deviation values for each day of the first cycle greater than the average value db2 of the standard deviation values for the two cycles? If the step (S616) and the average value (db1) of the standard deviation of the day of the one cycle in the cycle is less than or equal to the average value (db2) of the standard deviation of the day of the two cycles, the operation unit The standard deviation value for each day is The value of the standard deviation for each day of the two periods is equal to the value (dc1) obtained by multiplying the number da1 of standard deviations that are equal to or more than the standard deviation threshold by the average value db1 of the standard deviation for each day of the period. Determining whether the value is greater than a value (dc2) obtained by multiplying the number of standard deviation values da2 equal to or more than a standard deviation boundary value by the average value db2 of the daily standard deviation values of the two cycles (S618), and the operation unit If the value of the first period (dc1) is less than or equal to the value of the two periods (dc2) in the step of determining that the insulation state of the power device is good (S620), and the calculation unit in the step S614 The number da1 of the standard deviation values of the periods is greater than the number da2 of the standard deviation values of the two periods, or the average value db1 of the standard deviation values for each day of the one period in the step S616 is the second period. Is greater than or equal to the mean value (db2) of the standard deviation value for each day of The value of the first period in step S618, if (dc1) is greater than the value (dc2) of the second period is a configuration including a step (S622) for determining that the insulation of the electrical equipment poor.

In the first to sixth embodiments of the insulation state monitoring method of the power device of the present invention, one cycle is a period from a certain period (for example, 30 days) to the present, and two cycles are a period (for example, For example, 30 days) up to the day before the first cycle, and the three cycles may be determined from a certain period (for example, 30 days) up to the day before the two cycles. In this case, for example, one cycle may be August, two cycles July, and three cycles June.

Embodiments of the insulation state monitoring apparatus and method of the power device of the present invention described above are only a part of various embodiments of the present invention. In the technical idea of measuring the partial discharge of a power device for a period of time of the present invention, extracting digital data on signal components of a set frequency band, calculating standard deviation values, and monitoring the insulation state of the power device. As far as it is included, embodiments other than the above-described embodiments also fall within the protection scope of the present invention.

10: power equipment
20: PD sensor unit
30: filter and amplifier
40: A / D converter
50: standard deviation calculation unit
60: comparison calculation unit
70: average value calculation unit
80: multiplication part
90: insulation state determination part
200: calculation unit

Claims (15)

delete delete A sensor unit for detecting partial discharge during one period and two periods set from the power device;
An analog-to-digital converter for converting signal components of a frequency band set among the signals of the partial discharge sensed by the first and second cycles into digital data for each sensing day;
The standard deviation value is calculated from the digital data of each of the first and second cycles, and the number of standard deviation values for each detection day of the first and second cycles that is greater than or equal to a standard deviation boundary value (da1) , da2) are respectively calculated, and the average values (db1, db2) of the standard deviation values of the first and second cycles are respectively calculated, and the number of standard deviation values (da1) of the standard deviation of the one cycle and the average of the standard deviations of the first cycle, respectively. If the value (dc1) multiplied by (db1) is greater than the value (dc2) multiplied by the number of standard deviation values (da2) of the two cycles and the average value (db2) of the standard deviation values of the two cycles, the insulation state of the power device is Insulation state monitoring device for power equipment including a calculating unit for determining that it is bad. delete A sensor unit for detecting partial discharge for one period, two periods, and three periods set by the power device, respectively;
An analog-digital converter for extracting a component of a signal of a frequency band set from the detected partial discharge signals and converting the signal into digital data;
Computing the standard deviation value of the digital data for each period by the detection date, and compared with the set standard deviation threshold value, the number of standard deviation values (da1, da2, da3) that is greater than the standard deviation threshold value for each period, respectively Calculate the average values (db1, db2, db3) of the standard deviation values for each cycle, and calculate the number of standard deviation values (da1, da2, da3) and the standard for each cycle that are equal to or greater than the standard deviation boundary value for each cycle. The average value (db1, db2, db3) of the deviation value is multiplied for each period to calculate the value of one cycle (dc1), the value of two cycles (dc2) and the value of three cycles (dc3), and the value of the two cycles ( a power unit including a computing unit that determines that the insulation state of the power device is poor when dc2) is greater than the value of the three periods (dc3) and the value of the first period (dc1) is greater than the value of the two periods (dc2). Insulation condition monitoring device. delete delete Detecting a partial discharge of the power device for a set time and a set number of times during the one cycle and the second cycle set by the sensor unit;
Extracting and amplifying a component of a signal of a predetermined frequency band from the signal of the partial discharge detected by the filter and the amplifier;
Converting the signal component of the partial discharge amplified by the analog-digital conversion unit into digital data;
Calculating a standard deviation value for each detection date of one period and two periods in the digital data by an operation unit;
Calculating the number of standard deviation values da1 and da2 by the calculation unit, respectively, wherein the standard deviation values of the first period and the second period are equal to or greater than a set standard deviation boundary value;
Calculating average values (db1, db2) of the standard deviation values of the one period and the second period by the operation unit,
The calculation unit calculates a value (dc1) obtained by multiplying the number da1 of the standard deviation values of the one period by the average value db1 of the standard deviation values of the one period, and the
The value (dc1) obtained by multiplying the number da1 of the standard deviation values of the one period by the average value db1 of the standard deviation values of the one period by the operation unit is equal to the number da1 of the standard deviation values of the two periods. And determining that the insulation state of the power device is inferior when it is larger than the value (dc2) multiplied by the average value db2 of the standard deviation values of the two cycles. delete Detecting a partial discharge of the power device by a set time and a set number of times for one cycle, two cycles, and three cycles set by the sensor unit;
Extracting and amplifying a component of a signal of a predetermined frequency band from the signal of the partial discharge detected by the filter and the amplifier;
Converting the signal component of the partial discharge amplified by the analog-digital conversion unit into digital data;
Calculating a standard deviation value for each detection date of one period, two periods, and three periods in the digital data by the operation unit;
Calculating the number of standard deviation values da1, da2, da3, respectively, by the operation unit, at which the standard deviation values of the 1, 2, and 3 cycles are equal to or greater than a set standard deviation boundary value;
Calculating an average value (db1, db2, db3) of the standard deviation values of the one period, the second period, and the third period by the operation unit;
The calculating unit calculates a value (dc1, dc2, dc3) obtained by multiplying the number of standard deviation values of the first, second, and three periods by the average value of the standard deviation values, respectively, and the multiplied value (dc2). Is greater than the multiplied value of the three periods (dc3), and if the multiplied value of the one period (dc1) is greater than the multiplied value of the two periods (dc2) comprising the step of determining that the insulation state of the power device is poor How to monitor insulation status of power equipment. In the insulation state monitoring method of a power device using an insulation state monitoring device that stores the set 1 cycle and 2 cycles of the partial discharge, the set measurement time per day, the number of measurements and the set standard deviation threshold for the power equipment,
Measuring a partial discharge of the power device during the first period and the second period by a sensor unit;
Extracting and amplifying a component of a signal of a predetermined frequency band from the signal of the partial discharge measured by the filter and the amplifier;
Converting the signal component of the partial discharge amplified by the analog-digital conversion unit into digital data;
Calculating a standard deviation for each day of the digital data of the first period and the second period by the operation unit;
The calculation unit compares the standard deviation boundary value stored for the one cycle and the second period with the standard deviation value for each day, and the number of standard deviation values for which the standard deviation value for each day becomes equal to or greater than the standard deviation boundary value. counting (da1, da2) respectively,
Calculating average values (db1, db2) of the standard deviation values for each of the one period and the second period by the operation unit;
A value obtained by multiplying the number da1 of standard deviations by which the value of the standard deviation for each day of the one period is equal to or greater than the standard deviation boundary by the calculation unit and the average value db1 of the standard deviation for each day of the one period ( dc1) is calculated, and the number of values of standard deviation (da2) at which the value of the standard deviation per day of the two cycles is equal to or greater than the standard deviation boundary value, and the average value (db2) of the standard deviation value of the daily deviation of the two periods is calculated. Calculating the multiplied value (dc2),
In the calculation unit, the number da1 of standard deviations such that the value of the standard deviation for each day of the one cycle is equal to or greater than the standard deviation threshold, and the value of the standard deviation for each day of the two cycles is equal to or greater than the standard deviation threshold. Determining whether the value of the standard deviation is greater than the number da2;
If the number da1 of standard deviations equal to or greater than the standard deviation boundary value of the one period in the calculation unit is equal to or less than the number da2 of the standard deviation values of the two periods, the daily standard of the one period Determining whether the average value db1 of the deviation value is larger than the average value db2 of the standard deviation values for each of the two periods;
If the average value db1 of the daily standard deviation values of the one cycle is less than or equal to the average value db2 of the daily standard deviation values of the two cycles, the value of the daily standard deviation of the one cycle is the standard in the calculation unit. The value of the standard deviation for each day of the two periods is the value (dc1) obtained by multiplying the number da1 of standard deviations that is equal to or larger than the deviation threshold by the average value db1 of the standard deviation for each day of the period. Judging whether the number da2 of the standard deviation that is greater than or equal to the deviation boundary value is greater than the value dc2 multiplied by the average value db2 of the standard deviation values for each of the two periods, and the operation unit determines If the value of dc1 is less than or equal to the value of the two periods dc2, determining that the insulation state of the power device is good;
In the operation unit, the number da1 of the standard deviation values of the one period is greater than the number da2 of the standard deviation values of the two periods, or the average value db1 of the standard deviation values for each day of the one period is the second period. Determining that the insulation state of the power device is poor when the average value of the standard deviation value of each day is greater than db2 or the value of one period (dc1) is greater than the value of the two periods (dc2). How to monitor insulation status of power equipment. The method according to claim 3,
Wherein said one period is a certain period in the past from the current state of the insulation state monitoring of said power device, and said two periods are a predetermined period before said one period. The method according to claim 5,
Wherein the one period is a predetermined period in the past from the current state of the insulation state monitoring of the power device, the two periods are a predetermined period before the one period, and the three periods are a predetermined period before the two periods Insulation condition monitoring device. The method according to claim 8 or 11,
Wherein said one period is a certain period in the past from the present day of the insulation state monitoring date of said power device, and said two periods are a predetermined period before said one period. The method of claim 10,
Wherein the one period is a predetermined period in the past from the current state of the insulation state monitoring of the power device, the two periods are a predetermined period before the one period, and the three periods are a predetermined period before the two periods How to monitor insulation status.

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