KR100911841B1 - Detector for connectors of overhead conductors - Google Patents

Abstract

Disclosed is a flaw detector capable of grasping the internal structure of a connection point so as to enable accurate construction and stable operation management of the connection point installed on the power transmission line. The Hall probe sensor continuously detects the magnetic field strength in the stranded aluminum wire, the magnetic field strength in the exposed area of high carbon steel wire, and the magnetic field strength in the steel sleeve while moving along the length of the connection point of the overhead transmission line and the metal fitting in the aluminum sleeve. The first, second, and third detection signals are output. Gauss meta is based on the first, second, and third detection signals from the Hall probe sensor, the magnetic field strength in the aluminum stranded wire, the magnetic field strength in the exposed area of the high carbon steel wire, and the steel sleeve. Obtain the magnetic field strength respectively. The control unit may determine that the steel sleeve is centered on the aluminum sleeve depending on whether the magnetic field strength at the exposed portion of the high carbon steel wire obtained by the Gaussian meta is greater than the magnetic field strength at the aluminum stranded wire and the magnetic field strength at the steel sleeve. Determine if it is located in.

Overhead transmission line, bracket

Description

Detecting device for overhead transmission line {Detector for connectors of overhead conductors}

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a block diagram showing the configuration of a overhead line connecting point flaw detector according to an embodiment of the present invention.

Figure 2 is a schematic view of the overhead transmission line in the straight sleeve according to an embodiment of the present invention.

3 is a graph showing a change in magnetic field strength according to the length of the straight sleeve according to an embodiment of the present invention.

              Explanation of Reference Numbers

100: Hall probe sensor 200: Gaussian meta

300: control unit 400: induction device for applying a magnetic field

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a flaw detection technique, and more particularly to a flaw detection apparatus capable of grasping the internal structure of a connection location in order to detect an eccentric construction at a connection location of a overhead transmission line.

Overhead transmission lines are always used in transmission lines in combination with fixtures such as sleeves and clamps. However, it is pointed out that there are many cases in which installation of the bracket is applied to the overhead transmission line in violation of the standard work regulations due to the negligence or ignorance of the worker. In the case of construction defects that have been identified so far, when constructing a straight sleeve, ① the eccentric construction where the steel sleeve is not located at the center of the aluminum sleeve, ② the construction is performed under the specified compressive force when crimping, or does not uniformly crimp the entire joint. Cases, etc. In other words, the types of poor construction at the connection points can be divided into two types, where each component is not installed at the prescribed position inside the connection point, and when the components are not installed at the specified compression force, and when the compression is not carried out over the specified range. Can be.

On the other hand, in the case of construction failure cases ②, it is possible to check the construction status by grasping the construction status even by visual inspection from the outside, but in the case of ① such as construction, the construction status cannot be checked by visual inspection. There is an urgent need for the development of a technology capable of detecting structures.

The poorly installed connection point is always a potential cause of track accident due to the rapid decrease in tensile load at the joining site and the increase of heat generated by the increase in contact resistance at the joining site. It is becoming. However, if the construction of the connection point is completed by the worker at the time of construction, there is no way to confirm later that the construction was properly performed in accordance with the standard work rules in the case of (1). This is because the connection point is connected to the bracket by inserting the overhead power transmission line, and then pressurized and finished with a high-pressure press, so that the working situation inside the connection point cannot be grasped from the outside.

Since the reliability of a transmission line can depend largely on the stability of the connection point, proper construction and continuous management of the connection point are very important in terms of line operation.

Until now, there is no technique which can grasp | ascertain the internal structure in the connection point of a overhead transmission line and a bracket.

An object of the present invention is based on the magnetic field strength of the stranded aluminum wire, the magnetic field strength of the exposed portion of the high carbon steel wire, and the magnetic field strength of the steel sleeve, to enable accurate construction and stable operation management of the connection points installed on the transmission line, The present invention provides a flaw detector capable of grasping the internal structure of a connection location by determining whether the steel sleeve is located at the center of the aluminum sleeve.

In order to achieve the above object, the present invention provides a magnetic field strength in the stranded aluminum wire, magnetic field strength in the high-carbon steel wire exposed portion, magnetic field in the steel sleeve while moving along the length of the connection point portion of the overhead power transmission line and the bracket in the aluminum sleeve A hall probe sensor for continuously detecting the intensity and outputting first, second, and third detection signals; Based on the first, second, and third detection signals from the Hall probe sensor, the magnetic field strength in the aluminum stranded wire, the magnetic field strength in the exposed area of the high carbon steel wire, and the magnetic field strength in the steel sleeve are determined. Gaussian meta each obtained; And determining whether there is a change in the magnetic field strength in the aluminum stranded wire obtained by the Gaussian meta, the magnetic field strength in the exposed portion of the high carbon steel wire, and the magnetic field strength in the steel sleeve, and based on the determination result. An overhead transmission line connecting point flaw detection apparatus including a control unit for predicting an internal structure of the overhead transmission line and the bracket apparatus is provided.

Preferably, the overhead transmission line connecting point flaw detection apparatus further includes an induction device for applying a magnetic field connected to the overhead transmission line to increase the magnetic field strength of the high carbon steel wire of the overhead transmission line.

Hereinafter, the overhead line inspection device according to an embodiment of the present invention based on the accompanying example drawings will be described in detail.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a block diagram showing the configuration of a overhead line connecting point flaw detector according to an embodiment of the present invention.

The overhead line connecting device flaw detector according to the embodiment of the present invention includes a hall probe sensor 100, a Gaussian meta 200, a control unit 300, and a magnetic field applying induction apparatus 400.

The hall probe sensor 100 continuously moves along the length of the connection point between the overhead transmission line and the metal fitting in the aluminum sleeve and continuously increases the magnetic field strength in the stranded aluminum, the magnetic field strength in the exposed area of the high carbon steel wire, and the magnetic field strength in the steel sleeve. Is detected to output the first, second, and third detection signals.

Gaussian meta 200 is based on the first, second, and third detection signal from the Hall probe sensor 100, the magnetic field strength in the aluminum stranded wire, the magnetic field strength in the exposed area of the high carbon steel wire, And magnetic field strengths in the steel sleeve, respectively.

The control unit 300 determines whether there is a change in the magnetic field strength in the aluminum stranded wire and the magnetic field strength in the steel sleeve obtained by the Gaussian meta 200, and based on the determination result, the overhead power transmission line And predict the internal structure of the bracket.

The magnetic field applying induction apparatus 400 is connected to the overhead transmission line to increase the magnetic field strength of the carbon steel wire of the overhead transmission line.

When the Gaussian meta 200 fails to obtain the magnetic field strength of the carbon steel wire of the overhead transmission line, the control unit 300 operates the induction device for applying the magnetic field, so that the induction device for applying the magnetic field is applied to the overhead transmission line. By increasing the magnetic field strength of the carbon steel wire, the detection capability of the Gaussian meta 200 is improved.

This is used when the strength of the magnetic field of the high carbon wire is too small or the number of wires in the wire is difficult to detect. The horizontal hall probe sensor is useful as a device for detecting a change in the magnetic field while moving the hall probe sensor 100 to a connection site. The Gauss meta is an instrument for measuring the magnetic field strength of the constituent material, and it is advantageous to be able to measure the strength as low as possible.

The technique of grasping the internal structure of a connection point uses the thing from which magnetic property and magnetic intensity differ from one material to another.

Overhead transmission lines consist of aluminum wire and high carbon steel wire. Aluminum is basically a paramagnetic material that is not magnetic, but high carbon steel is a ferromagnetic material that is magnetic. On the other hand, the bracket or sleeve is made of aluminum and steel (steel), also in this case aluminum is paramagnetic, steel is ferromagnetic.

   And even if the material is the same material, the magnetic strength is different depending on the manufacturing process. The aluminum sleeves, aluminum clamps, steel sleeves and steel clamps of the bracket are all manufactured by casting. However, since the high carbon steel wire of the overhead transmission line is wired by wire drawing after casting, the strength of the magnetic field is much higher than that of the cast product.

   Therefore, by tracking the change of the magnetic strength from the outside using Gaussian meta-base of the relative magnetic strength of the components, it is possible to grasp the arrangement structure of various metal fittings such as overhead transmission line, steel sleeve, etc. .

The relative magnetic intensities of the connection components made of ferromagnetic ferroalloy are large in the order of overhead transmission high carbon steel> steel clamp> steel sleeve. Particularly, since high carbon steel wire is manufactured by drawing, magnetic strength is very large, ranging from several to several tens of Gauss, while steel clamps or steel sleeves made of casting material have a weak magnetic field of less than 1 gauss. Indicates strength. Clamps, sleeves, etc. made of aluminum show little magnetic field because they are paramagnetic.

It is thought that the magnetic field of the high carbon steel wire is a large magnetic field that can be measured sufficiently from the outside with a Gaussian of several to several tens of Gauss, but if the magnetic field strength is insufficient to measure, the magnetic field can be applied externally. Increasing the magnetic field strength of high-carbon steel wires by improving the accuracy of Gaussian meta can increase the accuracy.

Figure 2 is a schematic view of the overhead transmission line in the straight sleeve according to an embodiment of the present invention. Part names and dimensions of FIG. 2 are as follows. Reference numeral 1 is an aluminum sleeve, reference 2 is a steel sleeve, reference 3 is a high carbon steel wire, reference 4 is an aluminum stranded wire, reference 5 is an exposed portion of the high carbon steel wire (3), the steel sleeve (2) and aluminum 50 mm at the distance between the strands 4, 6 is 200 mm as the length of the steel sleeve 2, 7 is 150 mm as the insertion length of the wire, 10 is 600 mm as the total length of the straight sleeve , And 400 denote magnetic induction devices.

As shown in FIG. 2, the internal structure was detected using the flaw detection method which concerns on this invention using the straight sleeve connection part clamped. At this time, the left end of the straight aluminum sleeve 1 was set as a starting point 0, and the hole probe sensor 100, which is a measuring sensor, was measured while moving from left to right. The magnetic field generated by the straight sleeve is measured by Gaussian meta 200 while applying a magnetic field by applying a suitable current to the induction device 400 for applying the magnetic field. It is.

Since the magnetic field strength of the overhead transmission line high carbon steel wire is the largest, the magnetic field detected by the Gaussian meta 200 is the magnetic field thereby. The internal structure shown in Table 1 can be predicted from the strength of the magnetic field that varies with the length of the straight sleeve.

 Straight sleeve length (mm) Hazard Century (G) Internal structure  0 to 150 0 Aluminum stranded wire  150 to 200 10 High carbon wire exposed area  200 to 400 3 Strong sleeve area  400 to 450 10 High carbon wire exposed area  450 to 600 0 Aluminum stranded wire

And the internal structure shown in Table 1 is estimated to be due to the change in the magnetic field shown in Table 2.

   As can be seen from the examples, it can be seen that the internal structure of the connection point can be grasped by tracking the change in the magnetic strength of the overhead transmission high carbon steel wire.

Straight sleeve length (mm) Hazard Century (G) Factors of change in magnetic field strength 0 to 150 0 The magnetic field of the high carbon steel wire is almost shielded by the aluminum wire of the wire and the aluminum of the sleeve 150 to 200 10 The magnetic field of high carbon steel remains unshielded 200 to 400 3 The magnetic field of high carbon steel wire is shielded by the steel sleeve and the aluminum of the sleeve, but the weak magnetic field is detected as a whole due to the weak magnetic field of the steel sleeve. 400 to 450 10 The magnetic field of high carbon steel remains unshielded 450 to 600 0 The magnetic field of the high carbon steel wire is almost shielded by the aluminum wire of the wire and the aluminum of the sleeve

According to the present invention, by confirming that the steel sleeve is located in the center of the aluminum sleeve, various information about the state of the insertion of the overhead transmission line, the steel sleeve or the steel clamp arrangement state, etc. in the connection location can be obtained.

Claims (4)

The magnetic field strength in the stranded aluminum, the magnetic field strength in the exposed area of the high carbon steel wire, and the magnetic field strength in the steel sleeve are continuously detected while moving along the length of the connection point between the overhead transmission line and the bracket in the aluminum sleeve. A hall probe sensor for outputting a second detection signal; Based on the first, second, and third detection signals from the Hall probe sensor, the magnetic field strength in the aluminum stranded wire, the magnetic field strength in the exposed area of the high carbon steel wire, and the magnetic field strength in the steel sleeve are determined. Gaussian meta each obtained; And It is determined whether or not there is a change in the magnetic field strength in the aluminum stranded wire obtained by the Gaussian meta, the magnetic field strength in the exposed area of the high carbon steel wire, and the magnetic field strength in the steel sleeve, and based on the determination result. And a control unit for predicting an internal structure of the overhead transmission line and the bracket. According to claim 1, Wherein the Gaussian meta failed to obtain the magnetic field strength of the high-carbon steel wire of the overhead transmission line, The control unit is to detect the overhead transmission line connection point control to increase the magnetic field strength of the high-carbon steel wire of the overhead transmission line Device. 3. The overhead transmission line connecting part flaw detector according to claim 1 or 2, further comprising a magnetic field application induction device connected to the overhead transmission line to increase the magnetic field strength of the high carbon steel wire of the overhead transmission line. delete

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