KR20060039593A - Sag monitoring apparatus for overhead transmission line - Google Patents

Abstract

The present invention relates to an apparatus for monitoring the ear canal of overhead transmission lines.

According to the present invention, the electromagnetic wave and ultrasonic wave generating means which is installed at the islands of the overhead transmission line for generating electromagnetic waves and ultrasonic waves at the same time; Detecting means provided on the ground to detect electromagnetic waves and ultrasonic waves emitted from the electromagnetic wave and ultrasonic wave generating means, respectively; And data processing means for calculating the height and degree of the electromagnetic wave and ultrasonic wave generating means corresponding to the detection time difference after measuring the detection time difference between the electromagnetic wave and the ultrasonic wave.

Overhead transmission line, ear canal, corona discharge, electromagnetic wave, ultrasonic wave

Description

SAG MONITORING APPARATUS FOR OVERHEAD TRANSMISSION LINE}

The following drawings attached to this specification are illustrative of preferred embodiments of the present invention, and together with the detailed description of the invention to serve to further understand the technical spirit of the present invention, the present invention is a matter described in such drawings It should not be construed as limited to

1 is a block diagram of a tension measuring method ear canal monitoring system according to the prior art.

2 is a conceptual diagram to help understand the ear canal conversion principle used in the system of FIG.

3 is a block diagram of a temperature measuring method ear canal monitoring system according to the prior art.

4 is a conceptual diagram to help understand the ear canal conversion principle used in the system of FIG.

5 is a block diagram of an ear canal monitoring apparatus according to a preferred embodiment of the present invention.

Figure 6 is a conceptual diagram to help understand the ear canal measurement principle used in the ear canal monitoring apparatus of the present invention.

7 is a waveform diagram showing a difference in detection time between an electromagnetic signal and an ultrasonic signal.

8 is a block diagram showing a functional configuration of an ear canal monitoring apparatus according to a preferred embodiment of the present invention.

9 is a flowchart showing the operation of the ear canal monitoring apparatus according to the preferred embodiment of the present invention.

<Description of main reference numerals in the drawings>

100 Protruding member 101 Detecting means

101a ... electromagnetic wave receiving antenna 101b ... ultrasound receiving antenna

102 Data Processing Means

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for monitoring change in the ear canal of a overhead transmission line, and more particularly, to an apparatus for monitoring a change in ear canal of a overhead transmission line.

Overhead transmission lines are installed to have proper separation, taking into account the tension with the steel tower supporting the wires and the electrical separation distance from the ground. Such overhead transmission line changes its temperature due to the external environment such as air temperature, wind, solar light, and current flowing through the wire, and its ear canal due to contraction or expansion of the wire due to temperature change.

On the other hand, the maximum allowable current of the overhead transmission line is limited by the ear canal of the wire, so monitoring the change of the ear can be seen the maximum allowable current of the wire.

In general, overhead transmission lines are subjected to high voltages of hundreds of kV, so real-time ear canal monitoring is not possible due to electrical insulation problems with conventional displacement sensors. Therefore, conventionally, an indirect measurement method for monitoring the temperature of the wire or monitoring the tension between the wire and the steel tower and converting the ear canal using a predetermined calculation formula has been used.

1 shows a configuration for monitoring the ear canal by measuring the tension of the wire. As shown in the figure, the conventional tension measuring method ear canal monitoring system is a tension and wire inclination measuring sensor 11 installed between the built-in insulator 10 and the overhead transmission line 1 of the steel tower, and the measuring sensors 11 And a terrestrial data collection device 12 for receiving measurement data from the apparatus. The change in tension and wire inclination measured in real time through this configuration is converted into ear canal D by Equation 1 below.

Referring to FIG. 2, the relationship between the wire tension load T _A and the wire inclination angle θ in the pylon A with respect to the wire horizontal load T at the maximum ear canal point in Equation 1 is shown in Equation 2 below, and w is the The load, S denotes the distance between two pylons A and B.

3 shows a configuration for monitoring the ear canal by measuring the temperature of the wire. As shown in the figure, a conventional temperature measuring method ear canal monitoring system includes a measurement module 20 for measuring the temperature on the wire and wirelessly transmitting data, and a ground data collection device 21 for receiving the measurement data. The temperature change of the wire measured in real time through such a configuration is converted into the ear canal D by Equation 3 below.

Referring to FIG. 4, in Equation 3, D ₁ and t _c1 each represent an uninterrupted degree and temperature of the overhead transmission line, and D ₂ and t _c2 each represent a changed degree and temperature. In addition, α denotes the linear expansion coefficient of the electric wire, and S denotes the distance between two steel towers A and B.

However, the conventional ear canal monitoring system described above uses an indirect method of measuring the tension or temperature of a wire and converting it into an ear canal without directly monitoring the ear canal of the overhead transmission line. There is a vulnerability.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and an object thereof is to provide an ear canal monitoring apparatus for detecting ear canal displacement of a overhead transmission line by using a difference in traveling speed between electromagnetic waves and ultrasonic waves.

In order to achieve the above object, the ear canal monitoring apparatus according to the present invention includes: electromagnetic wave and ultrasonic wave generating means installed at the ear canal of the overhead transmission line to simultaneously generate electromagnetic waves and ultrasonic waves; Detecting means provided on the ground to detect electromagnetic waves and ultrasonic waves emitted from the electromagnetic wave and ultrasonic wave generating means, respectively; And data processing means for measuring the height and degree of the electromagnetic wave and ultrasonic wave generating means corresponding to the detection time difference after measuring the detection time difference between the electromagnetic wave and the ultrasonic wave.

The electromagnetic wave and ultrasonic wave generating means is preferably a protrusion member for generating corona discharge.

Preferably, the protruding member may be made of a sharp metal body that is electrically connected to the overhead transmission line.

The detecting means may be located vertically downward from the protruding member.

Preferably the data processing means, the amplifier for amplifying the electromagnetic signal and the ultrasonic signal output from the detection means; A level detector for generating a pulse signal when the level of the detection signal passed through the amplification unit is greater than or equal to a set voltage level; A signal counter for calculating a time difference between the pulse signal corresponding to the electromagnetic wave detection signal and the pulse signal corresponding to the ultrasonic wave detection signal generated by the level detector; And calculating a height of the electromagnetic wave and the ultrasonic wave generating means by multiplying the detected time difference calculated by the signal counter with an ultrasonic speed, and then calculating the difference by calculating a difference from the height of the overhead transmission line in the absence of the ear canal. It can be provided.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms or words used in the specification and claims should not be construed as having a conventional or dictionary meaning, and the inventors should properly explain the concept of terms in order to best explain their own invention. Based on the principle that can be defined, it should be interpreted as meaning and concept corresponding to the technical idea of the present invention. Therefore, the embodiments described in the specification and the drawings shown in the drawings are only the most preferred embodiment of the present invention and do not represent all of the technical idea of the present invention, various modifications that can be replaced at the time of the present application It should be understood that there may be equivalents and variations.

5 shows the configuration of the ear canal monitoring apparatus according to the preferred embodiment of the present invention.

Referring to FIG. 5, the ear canal monitoring apparatus according to a preferred embodiment of the present invention detects the corona discharge generating protruding member 100 installed in the overhead transmission line 1, and detects electromagnetic waves and ultrasonic waves emitted during corona discharge, respectively. Means 101 and data processing means 102 for calculating the ear canal by using the detected time difference between electromagnetic waves and ultrasonic waves.

Although the protruding member 100 is employed as a means for simultaneously generating electromagnetic waves and ultrasonic waves in this embodiment, the present invention is not limited thereto, and various other electromagnetic wave and ultrasonic wave generating means capable of simultaneously generating electromagnetic waves and ultrasonic waves are provided. Of course, it can be employed.

The protruding member 100 is installed at the maximum ear canal of the overhead transmission line 1, preferably facing the ground to generate the electromagnetic wave and the ultrasonic wave simultaneously by generating a corona discharge. Preferably, the protruding member 100 is made of a pointed metal body, and is installed to be electrically connected to the inner core of the overhead transmission line 1. Here, the shape or mounting jig of the protruding member 100 is not limited to those shown in the drawings can be variously modified. When a high voltage is applied to the overhead transmission line 1, an electric field is concentrated at the end of the protruding member 100 to generate a corona discharge in which the adjacent air is partially destroyed.

The detecting means 101 includes an electromagnetic wave receiving antenna 101a and an ultrasonic wave receiving antenna 101b to detect electromagnetic waves and ultrasonic waves emitted during corona discharge from the protruding member 100, respectively. Here, a known dipole antenna or the like may be employed as the electromagnetic wave receiving antenna 101a, and a known dish type acoustic wave antenna or the like may be employed as the ultrasonic receiving antenna 101b. The detecting means 101 is installed on the ground vertically downward with respect to the protruding member 100 where the corona discharge occurs so as to calculate the vertical height (see L in FIG. 6) of the protruding member 100 as described later. It is preferable to be.

The data processing means 102 calculates the degree of declination of the overhead transmission line 1 using the electromagnetic wave signal and the ultrasonic signal detected by the detection means 101. 6 schematically shows the principle in which the ear canal is calculated. Referring to the drawing, since the electromagnetic wave radiated during the corona discharge proceeds at the speed of light, the electromagnetic wave reaches the electromagnetic wave receiving antenna 101a of the detecting means 101 at the same time as the generation of the corona discharge, and the ultrasonic wave at a speed of about 340 m / s. Since it reaches the ultrasonic receiving antenna 101b of the detecting means 101, the detection time difference Δt as shown in FIG. 7 occurs. Therefore, if the detection time difference is multiplied by the traveling speed of the ultrasonic waves, the distance L from the detection means 101 to the protruding member 100 can be calculated, and subtracting the L value from the height H of the overhead transmission line 1 in the absence of an ear canal. This degree D is calculated.

8 shows the configuration of the data processing means 102 provided in the present invention in more detail. Referring to the drawings, the data processing means 102 generates pulses for the first amplifying part 103 and the second amplifying part 104 connected to the output terminal of the detecting means 101 and the detection signal of a predetermined level or more. And a level detector 105, a signal counter 106 for calculating a detection time difference, and an arithmetic processing unit 107 for calculating the height and degree of the projecting member 100 corresponding to the detection time difference.

The first amplifier 103 and the second amplifier 104 are for amplifying the electromagnetic wave detection signal and the ultrasonic wave detection signal, respectively. The first amplifier 103 and the second amplifier 104 may be configured by employing a conventional amplifier for amplifying a weak electric signal with a constant amplification. .

The level detector 105 generates a pulse signal when the voltage level of the detection signal passed through the first amplifier 103 and the second amplifier 104 is greater than a preset voltage level. The level detector 105 may be configured by employing a conventional comparator using an operational amplifier or the like.

The signal counter 106 counts the time from the pulse generation time corresponding to the electromagnetic wave detection signal to the pulse generation time corresponding to the ultrasonic wave detection signal generated by the level detector 105 to calculate the detection time difference Δt between the electromagnetic wave and the ultrasonic wave. do.

The calculation processing unit 107 calculates the height L of the protruding member 100 by multiplying the detection time difference calculated by the signal counter 106 with the ultrasonic speed, and then the height H of the overhead transmission line 1 when there is no ear canal. The ear canal D is calculated by calculating the difference between the height L of the protruding member 100. The arithmetic processing unit 107 may be configured using software such as a general basic, C-language, or Fortran.

Next, an operation of the ear canal monitoring apparatus according to the preferred embodiment of the present invention will be described with reference to FIG. 9.

At the maximum ear canal of the overhead transmission line 1, a protruding member 100 having a sharp tip is installed to generate a corona discharge when a high voltage is applied for power transmission (step S100).

Since the propagation speeds of the electromagnetic waves and the ultrasonic waves radiated according to the corona discharge are different from each other, the electromagnetic wave and the ultrasonic waves are detected with a time difference in the detection means 101 installed on the ground (step S110).

The data processing unit 102 receives and amplifies the electromagnetic wave and ultrasonic detection signals detected by the detection unit 101, generates a pulse signal corresponding to the detection time point, and calculates a detection time difference Δt by counting the time between pulses. (Step S120).

Next, in the data processing means 102, the height L of the protruding member 100 is obtained by multiplying the detection time difference Δt by the speed of the ultrasonic wave to calculate the traveling distance of the ultrasonic wave. The ear canal D is calculated by performing the operation of subtracting the L value (step S130).

Although the present invention has been described above by means of limited embodiments and drawings, the present invention is not limited thereto and will be described below by the person skilled in the art to which the present invention pertains. Of course, various modifications and variations are possible within the scope of the claims.

Since the present invention uses a method of measuring the ear canal displacement of the overhead transmission line, there is an advantage that the measurement accuracy is higher than the prior art using an indirect conversion method.

In addition, according to the present invention, since only a protruding member having a degree capable of generating corona discharge is provided on the overhead transmission line, the construction is simple and does not adversely affect the operation of the overhead transmission line unlike the conventional tension measurement method or temperature measurement method. .

Claims (5)

Electromagnetic wave and ultrasonic wave generating means installed at the islands of the overhead transmission line for generating electromagnetic waves and ultrasonic waves at the same time; Detecting means provided on the ground to detect electromagnetic waves and ultrasonic waves emitted from the electromagnetic wave and ultrasonic wave generating means, respectively; And And data processing means for calculating the height and degree of the electromagnetic wave and ultrasonic wave generating means corresponding to the detection time difference after measuring the detection time difference between the electromagnetic wave and the ultrasonic wave. The method of claim 1, The electromagnetic wave and ultrasonic wave generating means is an ear canal monitoring device, characterized in that the protrusion member for generating corona discharge. The method of claim 2, The protruding member is an ear canal monitoring device, characterized in that the pointed metal body electrically connected to the overhead transmission line. The method of claim 1, The ear canal monitoring apparatus, characterized in that the detecting means is located vertically downward from the electromagnetic wave and ultrasonic wave generating means. The data processing means according to any one of claims 1 to 4, wherein An amplifier for amplifying the electromagnetic signal and the ultrasonic signal output from the detection means; A level detector for generating a pulse signal when the level of the detection signal passed through the amplification unit is greater than or equal to a set voltage level; A signal counter for calculating a time difference between the pulse signal corresponding to the electromagnetic wave detection signal and the pulse signal corresponding to the ultrasonic wave detection signal generated by the level detector; And And a calculation processor for calculating the height of the electromagnetic wave and the ultrasonic wave generating means by multiplying the detected time difference calculated by the signal counter with the ultrasonic speed, and calculating the difference with the height of the overhead transmission line in the absence of the ear canal. Ear canal monitoring device characterized in that.

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