KR101391146B1 - On-Line Cable Status Monitoring Apparatus and Method thereof - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus and a method for monitoring a cable state in a live state.
In the present invention, an insulation measurement unit measures a leakage current flowing through the cable shielded ground wire; An insulation calculation unit for calculating a deviation between an insulation resistance value and a leakage current of the insulation layer and the method layer using the leakage current measured by the insulation measurement unit; A data storage unit for storing data of an insulation resistance value of the insulation layer and the method layer and a deviation value of the leakage current calculated by the insulation calculation unit; A score is calculated for each item of the insulation layer insulation resistance value or the insulation layer resistance value of the insulation layer or the deviation value of the leakage current stored in the data storage section or a score of the insulation layer resistance value and the leakage current deviation value A score calculation unit for calculating a sum; A score is used for each item of the insulation layer insulation resistance value, the method layer insulation resistance value, or the leakage current deviation value calculated by the above-described score calculation unit, or a score is calculated for each item of insulation layer insulation resistance value and method layer insulation resistance value and leakage current deviation value And a state judging section for judging the state of insulation of the cable by using the state judging section.

Description

Technical Field [0001] The present invention relates to an on-line cable status monitoring apparatus and method,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus and a method for monitoring a cable state in a live state. More particularly, the present invention relates to a method of superimposing a signal voltage on a bus line of a commercial AC voltage system in a live state, that is, in a live state, or by superimposing a signal voltage of a component other than a commercial frequency (including a direct current) And more particularly, to a device and method for monitoring an insulation state and a partial discharge state of a cable by measuring a leakage current of a component corresponding to an overlapped applied signal voltage flowing between a ground wire and a ground. More specifically, the leakage current is measured for each day of measurement, and is calculated as the value of the insulation layer insulation resistance value, the method layer insulation resistance value, and the leakage current value, and the stored data is measured for a long period of time to read the stored data, The insulation resistance value and the leakage current deviation value are calculated for each item and the measurement day, and a cumulative total score is calculated again for a certain period of time, and a long term measurement And more particularly, to a cable state monitoring apparatus and method in a live-line state that enables an administrator to determine an insulation state of a cable with data, thereby allowing a manager to easily make a determination of the state of the cable.

As the industry develops today, the increase in electric power demand and the advancement of information technology demands high reliability for electric power demand, and the most important factor in this supply reliability is power failure time. Especially, the cable system (including the connection material) used for supplying electric power has various characteristics spatially varying according to the use condition since it must be directly connected to the load through the breaker in the transformer.

Although transformers and circuit breakers are installed in a certain space, cable systems vary from a few meters to a few meters, and there are many conditions such as the installation conditions of underground, pipelines, and trays, The conditions are different compared to the equipment. In order to prevent the accident of the electric power equipment including the cable system, there is a method of monitoring the state of the electric power facility. It can be roughly divided into live cable insulation condition monitoring method which diagnoses the state of insulation equipment in live state without power failure.

Since the method of monitoring the insulation state of the electrostatic cable has a limitation in use due to the problem of stopping the supply of electricity, many methods for monitoring the insulation state of the live cable have been developed. For monitoring the live cable insulation state, see Korean Patent Registration No. 10-0789339 (Registered Date: December 20, 2007).

FIG. 1 is a view for understanding and explaining a live cable insulation monitoring apparatus used in the prior art and the present invention, and corresponds to a live cable insulation monitoring method by a voltage superposition method among various live cable insulation monitoring methods . The main components in the figure are a transformer 1, a copper conductor 2, a signal voltage 3, an AC grounding system 4, an insulating layer 5, an insulating layer insulating resistor 6, a copper tape 7, Type insulated layer insulation resistance 8, a sheath 9, a shielded ground wire 10 and a ground ground 11 and measuring the leakage current by the signal voltage 3 to monitor insulation ). ≪ / RTI >

1 (a) shows a state in which a signal voltage 3 different from the commercial AC voltage component is applied to the cable copper conductor 2 through the transformer 1 and the copper tape 2 is superposed on the copper tape 7 through the insulating layer 5 of the cable. 1 (b) shows a leakage current component corresponding to the signal voltage (3) component flowing to the shielded ground wire 10 connected to the cable 3, A leakage current component corresponding to the component of the signal voltage (3) flowing in the shielded ground wire (10) of the cable is measured by superimposing a component of the signal voltage (3) different from the commercial AC voltage component on the cable through the shielded ground wire . The AC grounding system 4 connected between the neutral point of the transformer 1 and the earth ground 11 and between the cable shielded ground wire 10 and the earth ground 11 is to be alternately grounded. In this case, the frequency component of the signal voltage 3 includes a DC having a frequency of 0, and is generally used from 0.1 Hz to several hundred Hz, and the voltage is used from several hundreds of mV to several tens of volts. A conventional live cable insulation state monitoring apparatus will be described with reference to Figs. 2 to 6 and Fig. 14. Fig.

2 is a block diagram of a conventional insulation monitoring apparatus. The leakage current flowing from the cable shielding ground wire 10 to the earth ground 11 includes a leakage current component corresponding to the signal voltage (3) And the insulation measuring unit 510 has a function of amplifying the leakage current component and filtering and converting only the leakage current component corresponding to the signal voltage (3) component into a digital component . An I / O input / output unit 540 having a function of inputting various data or inputting and outputting various data through the control processing unit 530 to the leakage current of the digital component output from the insulation measuring unit 510, A data display unit 550 for displaying various data and an insulation calculation unit 555 having a function of calculating an insulation resistance value using the leakage current measured by the insulation measurement unit 510 ).

FIG. 3 shows a schematic overall flow chart of the insulation monitoring apparatus of FIG. 2, and FIG. 4 shows an embodiment showing the insulation resistance after measurement of the insulation monitoring apparatus of FIG. Fig. 5 is a diagram illustrating an example in which measured data is measured and stored for a long period of time as shown in Fig. 4, and data measured for one cable FIG. 6 is a view showing an example of displaying data when the flow of FIG. 5 is executed

When the measurement start step S100 is performed in FIG. 3, various setting values stored in the data storage unit 545 of FIG. 2, not shown in the drawing, are read or the I / O input / output unit 540 of FIG. And then selects a shielded ground wire of the cable to be insulated. Then, when the insulation measurement step S110 of FIG. 3 is executed, the leakage current flowing through the cable shielded ground wire 10 of FIG. The current component is amplified, filtered, and A / D-converted by the insulation measuring unit 510, the leakage current value of the insulation measuring unit 510 is read by the control processor 530, And the display step S120 are performed, the insulation layer insulation resistance value, the insulation layer resistance value and the leakage current deviation value of the insulation layer using the leakage current value read by the control processing unit 530 Is calculated by the calculation unit 555, The insulation layer insulation resistance value, the insulation layer resistance value and the leakage current deviation value calculated in the insulation calculation section 555 of the insulation layer 555 are stored in the data storage section 545 of FIG. 2, And the leakage current deviation value are displayed on the data display unit 550 of FIG. 2 as in the embodiment of FIG.

FIG. 5 shows an example of a flow in which data such as the above-described embodiment of FIG. 4 described above is displayed for a long time, a history of measured data for a specific cable, FIG. 6 shows an example of the flow of the embodiment of FIG. A data reading step S200 for reading the insulation layer insulation value, the insulation layer resistance value, the leakage current deviation value, and the determination criterion, which is the measurement date stored in Fig. 5, is executed as an example of displaying the measurement data for one month in the F15 cable A measurement date display step S210 for displaying the measurement date, an insulation layer value display step S220 for displaying the insulation layer insulation resistance value, an insulation layer determination display step S230 for determining the insulation layer insulation resistance value, A method layer display step S240 for displaying a method layer insulation resistance value, a method layer determination display step S250 for determining a method layer insulation resistance value, a leakage current deviation value indicating a leakage current deviation value When the leading-end system (S260), and repeatedly executed in an order measuring the leakage current deviation determining a display step (S270) for determining a deviation value of the leakage current embodiment, data as shown in FIG 6 is displayed on the screen.

Conventionally, according to the embodiment of the insulation measurement data display for one month of the F15 cable shown in Fig. 6, the insulated layer insulation resistance for one month in June 2012 is good and the condition for racing is repeated, Repeating the defective state and repeating the good and the bad of the leakage current deviation. Since both of the insulation state of the insulation layer, the method layer and the leakage current deviation are both good and the attention area is repeated, Have experienced difficulty in determining whether the insulation layer insulation resistance in the F15 cable is in a good state, in a race state or in a certain state, and when the method layer insulation resistance is judged as being good or bad And the leakage current deviations that can detect the partial discharge state of the cable are also in a good state or in a certain state It has experienced difficulties in having judgments.

In addition, there is a need for an invention relating to a cable state monitoring apparatus and method for monitoring a cable state in a live state using data capable of judging which insulation state or partial discharge state among three kinds of insulation states should be checked first, .

Korean Patent Registration No. 10-0789339 (Registered Date: December 20, 2007)

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems of the prior art, and it is an object of the present invention to provide a method and apparatus for calculating a sum of scores of items of insulation resistance value, To thereby determine an insulation state and a partial discharge state of the cable, and a method thereof.

As a technical solution for achieving the object of the present invention, as a first aspect of the present invention, there is provided a method of superimposing a signal voltage of a component (including DC) different from a commercial frequency on a commercial AC voltage system bus line in a live- It monitors the cable condition by measuring the leakage current of the component corresponding to the superimposed applied signal voltage flowing between the cable shielded ground wire and the earth ground by superimposing the signal voltage of the commercial frequency and other components (including the direct current) on the shielded ground wire An insulating measuring unit for measuring a leakage current flowing through the cable shielded ground line; and an insulation measuring unit for calculating a deviation between the insulation resistance value and the leakage current of the insulation layer and the method layer using the leakage current measured by the insulation measurement unit. And the data of the insulation resistance value of the insulation layer and the method layer and the deviation value of the leakage current calculated by the insulation calculation unit Or the difference between the values of the insulation layer resistance value of the insulation layer, the insulation layer resistance value of the building layer or the deviation value of the leakage current stored in the data storage section, A score calculating section for calculating the sum of the scores for each item of the leakage current deviation value and a score for each item of the insulation layer insulation resistance value or the method layer insulation resistance value or the leakage current deviation value calculated by the score calculation section, And a state determination section for determining an insulation state of the cable by using a score for each item of the insulation layer insulation resistance value, the insulation layer resistance value for the insulation layer and the leakage current deviation value.

According to a second aspect of the present invention, in the invention of the first aspect, a point calculating section for calculating a point sum of an insulation layer insulation resistance value stored in the data storage section, And a state judging section for judging the insulation state of the cable by using the score of the insulation resistance value.

According to a third aspect of the present invention, in the invention of the first aspect, a point calculating section for calculating a point sum of the insulation layer resistance value stored in the data storage section, And a state judging section for judging an insulation state of the cable by using the number of insulation resistance values.

According to a fourth aspect of the present invention, there is provided a data processing apparatus comprising: a score calculating unit for calculating a sum of points of a deviation value of a leakage current stored in the data storage unit; and a score calculating unit for calculating a score of a deviation value of the leakage current calculated by the score calculating unit And judging an insulation state of the cable based on the detected state of the cable.

According to a fifth aspect of the present invention, there is provided a point calculation apparatus comprising: a score calculation unit for calculating a sum of points by items such as an insulation layer insulation resistance value, a method layer insulation resistance value, and a leakage current deviation value stored in the data storage unit; And a state determination section for determining an insulation state as a largest item having a large total of points among the total of points for each item of the insulation layer insulation resistance value calculated by the insulation layer resistance value and the method layer insulation resistance value and the leakage current deviation value. A cable condition monitoring device is presented.

According to a sixth aspect of the present invention, there is provided a method of applying a signal voltage of a component (including DC) different from a commercial frequency to a commercial AC voltage system bus line in a live state, The method includes the steps of: (a) monitoring a state of a cable by measuring a leakage current of a component corresponding to a superposed applied signal voltage flowing between a cable shielded ground line and a ground ground, Calculating and storing a dielectric layer insulation resistance value, a dielectric layer insulation resistance value and a leakage current deviation value by measuring a leakage current flowing through the dielectric layer; (b) calculating a cumulative score by calculating a score for each item and each measurement day using the calculated and stored insulation layer insulation resistance value, the insulation layer resistance value for the insulation layer, and the leakage current deviation value using preset reference values; (c) a step of judging the insulation state of the cable using the sum of the insulation resistance value of the insulation layer, the insulation layer resistance value of the insulation layer and the leakage current deviation value, .

According to a seventh aspect of the present invention, there is provided a computer-readable recording medium containing a computer program for performing the cable state monitoring method in the live state of the sixth aspect.

According to the present invention, by calculating the sum of the scores of the insulation layer insulation resistance value, the method layer insulation resistance value, and the deviation value of the leakage current, the cable insulation state is determined using the calculated score of each item, Layer and the leakage current deviation can be accurately and quickly judged.

1 is a schematic measurement circuit diagram for explaining a signal voltage superposition method, which is one of methods for monitoring the insulation state of a cable.
2 is a schematic block diagram of a conventional insulation monitoring apparatus.
3 is a flowchart for explaining a method of measuring using a conventional insulation monitoring apparatus.
4 is a diagram showing a measured insulation resistance value of a conventional insulation monitoring apparatus.
5 is a flowchart for explaining a method of displaying measured data for one cable of a conventional insulation monitoring apparatus.
6 is a diagram showing data measured for one cable of a conventional insulation monitoring apparatus.
7 is a schematic block diagram of an embodiment of a cable state monitoring apparatus in a live state according to the present invention.
FIG. 8 is a flowchart for explaining a first embodiment of a cable state monitoring method in the live state of the present invention.
9 is a flowchart for explaining a second embodiment of the cable state monitoring method in the live state of the present invention.
10 is a flowchart for explaining a third embodiment of the cable state monitoring method in the live state of the present invention.
11 is a flowchart for explaining a fourth embodiment of the cable state monitoring method in the live state of the present invention.
12 is a flowchart for explaining a fifth embodiment of the cable state monitoring method in the live state of the present invention.
FIG. 13 is a diagram showing a score calculated by the cable state monitoring apparatus in the live state of the present invention. FIG.
FIG. 14 is a diagram showing a determination criterion for each measurement item of the conventional and the monitoring apparatus of the present invention. FIG.
Fig. 15 is a diagram showing the unit score of each measurement item used in calculating the score of the cable state monitoring apparatus in the live state of the present invention. Fig.
16 is a diagram showing a constant (K) value according to a cumulative total score of the cable state monitoring apparatus in the live state of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. 7 is a schematic block diagram of an embodiment of the insulation state monitoring apparatus in the live state according to the present invention. It is to be understood that the terminology used herein is for the purpose of describing the present invention only and is not used to limit the scope of the present invention as defined in the claims or the claims, It may be omitted. In describing the embodiments of the present invention, the description of the above-described prior art may be omitted.

7, in the insulation state monitoring apparatus in the live wire state of the present invention, the leakage current flowing from the shielded ground wire 10 to the earth ground 11 is connected to the system bus or the cable shielded ground wire The leakage current component corresponding to the component of the signal voltage (3) of the component (including the direct current) different from the commercial frequency to be superimposed on the reference current source 10 flows together with the leakage current component of the common frequency component. Amplifies the leakage current component and has a function of filtering only the leakage current component corresponding to the signal voltage (3) component and converting it into a digital component.

An I / O input / output unit 540 having a function of inputting various data through the control processor 530 and inputting / outputting various signals, a leakage current of the digital component output from the insulation measurement unit 510, A data display unit 550 for displaying various data, and a data storage unit 545 for storing the data of the insulation layer resistance value and the insulation layer resistance value of the method layer using the leakage current measured by the insulation measurement unit 510 And a leakage current deviation value calculating unit 555 for calculating a leakage current deviation value based on the measured values of the insulation layer insulation resistance value stored in the data storage unit 545 or the insulation layer resistance value or the leakage current deviation value A cumulative score of the insulation layer insulation resistance value calculated by the score calculation unit 560 or a cumulative score of the insulation layer resistance value or a leakage current deviation value of the leakage current deviation value It is composed of the sum or the state determining section 570 for determining the status of the cable by using the cumulative total score of the three kinds of the above.

8 is a flowchart for explaining a first embodiment of the insulation state monitoring method in the live state of the present invention. FIG. 7 is a flow chart for determining the insulation state for each item of the insulating layer insulation resistance value of the cable, the insulation layer resistance value of the method layer, and the leakage current deviation value in the insulation state monitoring device in the live wire state of the present invention. For example, an insulation layer insulation resistance value or a method layer insulation resistance value or a leakage current deviation value stored in the data storage unit 545, or an insulation layer insulation resistance value, a method layer insulation resistance value, a leakage current deviation value, A data reading step (S300) of reading data such as data; A score calculating step (S310) of calculating a score using the read data and calculating a cumulative score sum; The calculated values are used to determine a state for the insulation layer insulation resistance, a state determination for the method layer insulation resistance, a state determination for the leakage current deviation, and a comprehensive status for the insulation resistance and leakage current deviation of the insulation layer and the method layer And a state determination step (S320) for performing determination.

In the score calculation step S310, as shown in FIG. 13, from one data item or three items of measurement items for each measurement item read in the data reading step S300, Month and 1 month for each month, and the cumulative score is calculated by calculating the score using data such as item-specific unit scores as shown in FIG. 15 for each item.

In the state determination step S320, the state determination for the insulation layer insulation resistance is performed as shown in FIG. 9, which will be described later, and the state determination for the insulation layer resistance is performed as shown in FIG. 10 11, and the comprehensive state determination on the insulation resistance and the leakage current deviation of the insulating layer and the method layer is performed in the same manner as in the first embodiment, Is performed in a step as shown in FIG. 12 which will be described later.

9 is a flowchart for explaining a second embodiment of the insulation state monitoring method in the live state of the present invention. A second embodiment of the present invention relates to a method of determining an insulation state using an insulation layer insulation resistance value.

For reference, the values of the constant K in the embodiments of Figs. 9 to 11 use the same values as those in the embodiment of Fig. 16 is a constant K value in the case of using 30 data, but in the case of using data of 10 days, that is, 10 data, the value of the constant K is a value calculated proportionally by 1/3 Except for a value less than a decimal point) can be used in the present embodiment.

An insulating layer data reading step (S610) of reading data of an insulating layer insulating resistance value stored in the data storage unit, as shown in FIG. 9; An insulation layer score calculation step (S620) of calculating the total number of points of the insulation layer data read by using the unit score per item, and calculating a total score; And a state determination step (S630) to (S660) of judging the insulation state of the insulating layer by using the calculated total number of insulation layer sliver (SRI).

The step of calculating the insulation layer score (S620) may be performed by using a unit-specific unit score as shown in Fig. 15, which will be described later, in the insulation layer insulation resistance measurement value read in the insulation layer data reading step (S610) The score is calculated and the score of the insulating layer is calculated on the day of measurement as shown in Fig. 13 to be described later, and then the total score is calculated. For example, in FIG. 6, the insulation layer measurement value of 30 June 2012 is 3,050 Mohm, and in FIG. 15, the unit score of 3,000 Mohm or more in the insulation layer is 0, The measured value of the insulation layer on June 29, 2012, which is the previous measurement date, is 2,850Mohm, and in FIG. 15, the unit score is 1 when the insulation layer is less than 300Mohm to 3,000Mohm, The score of the insulation layer of the insulation layer is 1, and the score of the insulation layer is calculated from June 28 to June 1 of the previous measurement day. Next, as shown in FIG. 13, As shown in Fig. 13, eleven points are calculated for the total score (SRI) of the insulating layer of the period from March 30 to June 1, 2012. Although the data of one month (30 days) is used in the embodiment of the present invention, the data of various periods such as 10 days, 20 days, and 60 days can be used instead of the one month.

The state determination steps (S630) to (S660) determine the insulation state of the insulation layer according to the total score of the insulation layers using the total score (SRI) of the insulation layers calculated in the insulation layer score calculation step (S620) . Examples of values for the constants KI1, KI2 and KI3 in S630 to S650 in Fig. 9 are shown in Fig. A first comparison step (S630) of comparing the total score (SRI) of the insulating layer and the magnitude of the constant KI1; (S635) of determining that the insulation state of the insulation layer is seriously degraded if the total score (SRI) of the insulation layer as a result of the first comparison step (S630) is greater than the constant KI1; A second comparing step (S640) of comparing the sum of the total number of the insulating layers (SRI) and the size of the constant KI2 when the total number of the insulating layer (SRI) of the insulating layer is less than the constant (KI1) ; (S645) of determining that the insulation state of the insulation layer is deteriorated if the total score (SRI) of the insulation layer as a result of the second comparison step (S640) is greater than the constant KI2; A third comparing step (S650) of comparing the sum of the total number of the insulating layers (SRI) and the size of the constant KI3 when the sum of the total number of the insulating layers (SRI) of the insulating layer is smaller than the constant (KI2) ; (S655) of judging that the insulation state of the insulation layer is hardened if the total score (SRI) of the insulation layer as a result of the third comparison step (S650) is larger than the constant KI3; And a step S660 of determining the insulation state of the insulation layer as good if the total number SRI of the insulation layer as a result of the third comparison step S650 is smaller than the constant KI3.

In the first comparison step, the constant KI1, which is compared with the total score (SRI) of the insulating layer, is 120 when 30 pieces of data are used in the embodiment of the present invention.

Also, in the second comparison step, the constant KI2, which is compared with the total score (SRI) of the insulating layer, is 60 when 30 pieces of data are used in the embodiment of the present invention.

In addition, the constant KI3, which is compared with the total score (SRI) of the insulating layer in the third comparison step, is 15 when 30 pieces of data are used in the embodiment of the present invention.

10 is a flowchart for explaining a third embodiment of the insulation state monitoring method in the live state of the present invention. A third embodiment of the present invention relates to a method of determining an insulation state using a method layer insulation resistance value. 10, a method layer data reading step (S710) of reading data of a layer insulation resistance value stored in a data storage unit; A method of calculating the score of the method layer data by using the unit score per item and calculating the total score by the measurement day (S720); And a state determination step (S730) to (S760) of judging the insulation state of the method layer by using the calculated total sum (SRS) of the method layers.

The method of calculating the method layer score (S720) may be performed by using the unit-specific unit score as shown in Fig. 15, which will be described later, in the measurement daytime mode layer insulation resistance measurement read in the method layer data reading step (S710) The score is calculated and the score of the method layer is calculated on the day of measurement as shown in Fig. 13 to be described later, and the total score is calculated.

For example, in FIG. 6, the method layer measurement of June 30, 2012 is 890 Kohm, and in FIG. 15, the unit score of 100 Kohm to less than 1,000 Kohm is 1 in FIG. 15, , The score of the method layer is 1, and the unit score of the method layer is 0 from June 29, 2012 to June 26, 2012, and the measurement value of the method layer of June 25, 2012 is 1,010 Kohm, In FIG. 15, since the unit score of 1,000 Kohm or more is 0 in the case of FIG. 15, in the example of FIG. 13, the score of the method layer on June 25, 2012 is 1 and the score of the method layer is calculated by June 1 13, the total score (SRS) of the method layers from June 30, 2012 to June 1, 2012 is calculated as 13 points in the example of Fig.

Although the data of one month (30 days) is used in the embodiment of the present invention, the data of various periods such as 10 days, 20 days, and 60 days can be used instead of the one month.

The state determination steps (S730) to (S760) determine the insulation state of the method layer according to the total score of the method layer using the total score (SRS) of the method layers calculated in the method layer score calculation step (S720) . An example of the values for the constants KS1, KS2 and KS3 of S730 to S750 in Fig. 10 is shown in Fig. A first comparison step (S730) of comparing the total score (SRS) of the method layer and the size of the constant KS1; (S735) if the sum of the resultant SRS of the resultant layer of the first comparison step (S730) is greater than a constant KS1; A second comparison step (S740) of comparing the total score (SRS) of the method layer and the size of the constant KS2 if the total score (SRS) of the resultant method layer of the first comparison step (S730) is smaller than the constant KS1 ; (S745) if the sum of the resultant SRS of the resultant layer of the second comparison step (S740) is greater than the constant KS2; A third comparison step (S750) of comparing the total score (SRS) of the method layer and the size of the constant KS3 if the total score (SRS) of the resultant method layer of the second comparison step (S740) is smaller than the constant KS2 ; If the total score SRS of the resultant method layer of the third comparison step S750 is larger than the constant KS3, the step S755 judges that the insulation state of the method layer is poor; (S760), when the total score (SRS) of the resultant method layer of the third comparison step (S750) is smaller than the constant KS3, the insulation state of the method layer is determined to be good.

In the first comparison step, the constant KS1, which is compared with the total score (SRS) of the method layer, is 120 when 30 pieces of data are used in the embodiment of the present invention.

Also, in the second comparison step, the constant KS2, which is compared with the total score (SRS) of the method layer, is 60 when 30 pieces of data are used in the embodiment of the present invention.

Also, in the third comparison step, the constant KS3, which is compared with the total score (SRS) of the method layer, is 15 when 30 pieces of data are used in the embodiment of the present invention.

11 is a flowchart for explaining a fourth embodiment of the insulation state monitoring method in the live state of the present invention. A fourth embodiment of the present invention relates to a method of determining an insulation state using a leakage current deviation value. 11, a leakage current deviation data reading step (S810) of reading data of a leakage current deviation value stored in the data storage unit; A leakage current deviation score calculation step (S820) of calculating leakage current deviation data read by using the unit score for each item and calculating a score for each measurement day and calculating a total score; And a state determination step (S830) to (S860) of determining an insulation state with respect to the partial discharge state of the cable by using the sum of the calculated leakage current deviations (SRD).

The leakage current deviation score calculation step S820 calculates the leakage current deviation score using the leakage current deviation data read from the leakage current deviation data reading step S810 using the unit score for each item as shown in FIG. , And the score of the leakage current deviation is calculated for each day of measurement as shown in Fig. 13 to be described later, and then the total score is calculated. For example, in FIG. 6, the leakage current deviation measurement of June 30, 2012 is 7.6, and the unit score of leakage current deviation of 5.0 in FIG. 15 is 10. Therefore, in the example of FIG. 13, The deviation score is 10, and the leakage current deviation measurement of June 29, 2012, which is the previous measurement date, is 4.9, and the unit score of leakage current deviation of more than 1.0 to less than 5.0 in FIG. 15 is 3 in the example of FIG. The leakage current deviation score on June 29 is 3, and the leakage current deviation score is calculated by June 1, and then the score is calculated on the measurement day as in the example of FIG. 13, The total sum of the leakage current deviations (SRD) of days 1 to June 1, 2012 is calculated as 108 points as in the example of FIG.

Although the data of one month (30 days) is used in the embodiment of the present invention, the data of various periods such as 10 days, 20 days, and 60 days can be used instead of the one month. In addition, in the example of FIG. 15 described above, the range of the measurement value by item and the number of the points and the range of the measurement value can be changed. The value of the constant (K) for each item in the embodiment of FIG. 16 can also be different for each measurement item, and the value of the constant K can also be different.

The state determination steps S830 to S860 may be performed in the cable system according to the sum of the leakage current deviations using the sum of the leakage current deviation sums SRD calculated in the leakage current deviation score calculation step S820 And a linear connection material.

An example of the values for constants KD1, KD2 and KD3 of S830, S840 and S850 in Fig. 11 is shown in Fig.

A first comparison step (S830) of comparing the sum of the leakage current deviation points (SRS) and the size of the constant KSD; If the total sum SRD of the leakage current deviations as a result of the first comparison step S830 is greater than the constant KD1, it is determined that the partial discharge is strictly observed (S835); A second comparing step (S840) of comparing the sum of the leakage current deviations (SRD) and the magnitude of the constant KD2 when the sum total score (SRD) of the resultant smoothing layer of the first comparing step (S830) is smaller than the constant KD1; Wow; If the total sum SRD of the leakage current deviations as a result of the second comparison step S840 is greater than a constant KD2, A third comparing step (S850) of comparing the sum of the leakage current deviations (SRD) and the magnitude of the constant KD3 when the sum of the leakage current deviations (SRD) of the leakage current deviations resulting from the second comparison step (S840) is smaller than the constant KD2 )Wow; If the total sum SRD of the leakage current deviations as a result of the third comparison step S850 is greater than the constant KD3, the step S855 may determine that the partial discharge is cautious; And determining (S860) that the partial discharge is good if the sum of the leakage current deviations (SRD) as a result of the third comparison (S850) is smaller than the constant KD3.

In the first comparison step, the constant KD1, which is compared with the total number of points SRD of the method layer, is 120 when 30 pieces of data are used in the embodiment of the present invention.

Also, in the second comparison step, the constant KD2, which is compared with the total score (SRD) of the method layer, is 60 when 30 pieces of data are used in the embodiment of the present invention.

Also, in the third comparison step, the constant KD3, which is compared with the total score (SRD) of the method layer, is 15 when 30 pieces of data are used in the embodiment of the present invention.

12 is a flowchart for explaining a fifth embodiment of the insulation state monitoring method in the live state of the present invention. A fifth embodiment of the present invention is a configuration for comprehensively determining the insulation state of a cable by using an insulation layer insulation resistance, a method layer insulation resistance, and a leakage current deviation value.

As shown in FIG. 12, a data reading step (S400) of reading the data of the insulating layer insulation resistance, the method layer insulation resistance and the leakage current deviation stored in the data storage unit as shown in FIG. 6; An insulation layer score calculation step (S410) of calculating a total score by calculating a score for the insulation layer insulation resistance measurement on the measurement day by the read data; An insulating layer state determination step (S420) of temporarily determining the determination of the insulation state with respect to the insulation layer using the calculated total number SRI of the insulation layers; A method of calculating a total score by calculating a score for the measurement value of the insulation layer resistance of the method layer by the measurement date in the read data (S430); A method state determination step (S440) of temporarily determining the determination of the insulation state with respect to the method layer using the calculated total number of method layers (SRS); A leakage current deviation score calculation step (S450) of calculating a total score by calculating a score with respect to a leakage current deviation measurement value by the measurement date in the read data; A leakage current deviation determination step (S460) of temporarily determining the determination of the partial discharge state with respect to the leakage current deviation using the sum of the calculated leakage current deviations (SRD); (S470) of judging the insulation state of the measurement item having the largest one of the total score (SRI) of the insulation layer, the total score (SRS) of the method layer and the sum of the leakage current deviation score (SRD) Configuration,

FIG. 13 is a diagram showing an example of the score and the score of each of the embodiments of FIG. 12; FIG. As shown in Fig. 13, the total score (SRI) of the insulating layers is 11 and the insulation state of the insulating layer is in a good state. In addition, the total score (SRS) of the method layer is 13 and the determination of the insulation state of the method layer is in a good state. Further, the sum of the leakage current deviations (SRD) is 108, and the leakage current deviation is determined to be the state of the partial discharge middle winding.

Since the largest value among SRI, SRS, and SRD is the sum of the leakage current deviation (SRD), if the insulation state of the F15 cable of the embodiment of the present invention is comprehensively judged, And tell the cable manager that the insulation status of the F15 cable is partially discharged. In addition, the cable manager can give an additional message to the terminal to check for end-of-line or straight-through connections, where the partial discharge is likely to occur. Thus, the cable manager can collectively determine the insulation status of the cable and can easily check the cable for inspection or action.

12, a determination step (S420), a method layer state determination step (S440), and a leakage current deviation state determination step (S460) are performed for each measurement item, for example, in accordance with another embodiment of the present invention (S410), a method layer score calculation step (S430), and a leakage current deviation score calculation step (S410) are performed for each measurement item without performing the determination for each measurement item as described above S450), the insulation state corresponding to the score of the largest item among the scores calculated for each measurement item in the comprehensive state determination step (S470) can be comprehensively determined.

Although the embodiments of the present invention are described by way of example, they are not necessarily limited to the values of the above embodiments.

The embodiments of the present invention described above are only a few of the various embodiments of the present invention. (For example, may be included in the insulation calculation section) for each of the insulation layer insulation resistance value, the mode insulation resistance value and the leakage current deviation value of the cable of the present invention, It is obvious that various embodiments included in the technical idea to be determined are included in the protection scope of the present invention.

1: Transformer ???????????????? 2: copper conductor
3: Signal voltage ??????????????? 4: AC grounding system
5: Insulation layer ????????????????? 6: Insulation layer Insulation resistance (RI)
7: Dong Tape ????????????????????????? 8: Method layer insulation resistance (RS)
9: Sheath ??????????? 10: Shielding ground wire
500: Isolation monitoring device
510: Insulation measuring part. 530:
540: I / O I / O part 545: Data storage unit
550: Data display ???

Claims (10)

In the live state, the signal voltage of the commercial frequency and the other component (including the direct current) is superimposed on the commercial AC voltage system bus line, or the signal voltage of the component other than the commercial frequency (including the direct current) An apparatus for monitoring a state of a cable by measuring a leakage current of a component corresponding to an overlapped applied signal voltage flowing between a ground line and a ground,
An insulation measuring unit for measuring a leakage current flowing through the cable shielded ground line; An insulation calculation unit for calculating a deviation between an insulation resistance value and a leakage current of the insulation layer and the method layer using the leakage current measured by the insulation measurement unit; A data storage unit for storing data of an insulation resistance value of the insulation layer and the method layer and a deviation value of the leakage current calculated by the insulation calculation unit; A score is calculated for each item of the insulation layer insulation resistance value or the insulation layer resistance value of the insulation layer or the deviation value of the leakage current stored in the data storage section or a score of the insulation layer resistance value and the leakage current deviation value A score calculation unit for calculating a sum; A score is used for each item of the insulation layer insulation resistance value, the method layer insulation resistance value, or the leakage current deviation value calculated by the above-described score calculation unit, or a score is calculated for each item of insulation layer insulation resistance value and method layer insulation resistance value and leakage current deviation value And a state judging section for judging an insulation state of the cable by using the state of the cable. In the live state, the signal voltage of the commercial frequency and the other component (including the direct current) is superimposed on the commercial AC voltage system bus line, or the signal voltage of the component other than the commercial frequency (including the direct current) An apparatus for monitoring a state of a cable by measuring a leakage current of a component corresponding to an overlapped applied signal voltage flowing between a ground line and a ground,
An insulation measuring unit for measuring a leakage current flowing through the cable shielded ground line; An insulation calculation unit for calculating a deviation between an insulation resistance value and a leakage current of the insulation layer and the method layer using the leakage current measured by the insulation measurement unit; A data storage unit for storing data of an insulation resistance value of the insulation layer and the method layer and a deviation value of the leakage current calculated by the insulation calculation unit; A score calculation unit for calculating a total score of the insulation layer insulation resistance value stored in the data storage unit; And a state determination section for determining an insulation state of the cable by using the score of the insulation layer insulation resistance value calculated by the score calculation section. In the live state, the signal voltage of the commercial frequency and the other component (including the direct current) is superimposed on the commercial AC voltage system bus line, or the signal voltage of the component other than the commercial frequency (including the direct current) An apparatus for monitoring a state of a cable by measuring a leakage current of a component corresponding to an overlapped applied signal voltage flowing between a ground line and a ground,
An insulation measuring unit for measuring a leakage current flowing through the cable shielded ground line; An insulation calculation unit for calculating a deviation between an insulation resistance value and a leakage current of the insulation layer and the method layer using the leakage current measured by the insulation measurement unit; A data storage unit for storing data of an insulation resistance value of the insulation layer and the method layer and a deviation value of the leakage current calculated by the insulation calculation unit; A score calculation unit for calculating a sum of scores of the layer insulation resistance values stored in the data storage unit; And a state judging section for judging an insulation state of the cable using the score of the insulation layer resistance value calculated by the score calculation section. In the live state, the signal voltage of the commercial frequency and the other component (including the direct current) is superimposed on the commercial AC voltage system bus line, or the signal voltage of the component other than the commercial frequency (including the direct current) An apparatus for monitoring a state of a cable by measuring a leakage current of a component corresponding to an overlapped applied signal voltage flowing between a ground line and a ground,
An insulation measuring unit for measuring a leakage current flowing through the cable shielded ground line; An insulation calculation unit for calculating a deviation between an insulation resistance value and a leakage current of the insulation layer and the method layer using the leakage current measured by the insulation measurement unit; A data storage unit for storing data of an insulation resistance value of the insulation layer and the method layer and a deviation value of the leakage current calculated by the insulation calculation unit; A score calculation unit for calculating a sum of scores of deviation values of leakage currents stored in the data storage unit; And a state judging section for judging an insulation state of the cable by using the score of the deviation value of the leakage current calculated by the score calculating section. In the live state, the signal voltage of the commercial frequency and the other component (including the direct current) is superimposed on the commercial AC voltage system bus line, or the signal voltage of the component other than the commercial frequency (including the direct current) An apparatus for monitoring a state of a cable by measuring a leakage current of a component corresponding to an overlapped applied signal voltage flowing between a ground line and a ground,
An insulation measuring unit for measuring a leakage current flowing through the cable shielded ground line; An insulation calculation unit for calculating a deviation between an insulation resistance value and a leakage current of the insulation layer and the method layer using the leakage current measured by the insulation measurement unit; A data storage unit for storing data of an insulation resistance value of the insulation layer and the method layer and a deviation value of the leakage current calculated by the insulation calculation unit; A score calculation unit for calculating a sum of scores for each item of the insulation layer insulation resistance value, the insulation layer resistance value and the leakage current deviation value stored in the data storage unit; And a state judging section for judging an insulation state as a largest item having a large total of points among the total of points for each item of the insulation layer insulation resistance value calculated by the score calculation section, the method layer insulation resistance value and the leakage current deviation value Cable status monitoring device. In the live state, the signal voltage of the commercial frequency and the other component (including the direct current) is superimposed on the commercial AC voltage system bus line, or the signal voltage of the component other than the commercial frequency (including the direct current) A method of monitoring a state of a cable by measuring a leakage current of a component corresponding to an overlapped applied signal voltage flowing between a ground line and a ground,
(a) calculating a leakage current flowing through the cable-shielded ground wire and calculating and storing the insulation layer insulation resistance value, the insulation layer resistance value and the leakage current deviation value;
(b) calculating a cumulative score by calculating a score for each item and each measurement day using the calculated and stored insulation layer insulation resistance value, the insulation layer resistance value for the insulation layer, and the leakage current deviation value using preset reference values;
(c) collectively determining the insulation state of the cable using the insulation resistance value of the insulation layer, the total insulation resistance value of the insulation layer, and the cumulative score of the leakage current deviation value. The method of claim 6,
The step (c)
Wherein the insulation state is judged as an item having a largest value among cumulative total points of the insulation layer insulation resistance value, the method layer insulation resistance value and the leakage current deviation value. A data reading step of reading insulation layer data, method layer data or leakage current deviation data stored in a data storage unit;
A point calculating step of calculating a total number of points by using a unit score for each item on the basis of the read insulation layer data, the method layer data, or the leakage current deviation data;
(The first constant> the second constant> the third constant) of the insulating layer or the corrosion layer and the total sum of the leakage current deviations of the insulating layer or the corrosion layer, And a state determining step of determining a state of the cable or a partial discharge state of the cable. The method of claim 8,
The method according to claim 1,
And if the total score is larger than the first constant, the warning is determined; and if the total score is greater than the second constant, the warning is determined respectively. If the total score is greater than the third constant, And judging that the total score is smaller than the third constant, respectively, and judging that the total score is satisfactory when the total score is smaller than the third constant. A computer-readable recording medium storing a computer program for performing a cable state monitoring method according to any of claims 6 to 9 in a live state.

Images