KR102361166B1 - Breakage diagnosis device of steel reinforcement for electric pole and diagnosis method using the same - Google Patents

Abstract

The present invention provides a steel wire breakage diagnosis apparatus for electric poles that is inserted into the inner space of the electric pole through a hole formed on one side of the electric pole and detects the magnetic field of the steel wire buried in the electric pole, the apparatus comprising: a body; a cable coupled to the body and inserted through the hole; a sensor unit coupled to one end of the cable and in contact with the inner surface of the electric pole to detect the magnetic field of the steel wire; a support portion provided at one end of the sensor unit to support one end of the sensor unit; and a rotating part coupled to one end of the support part and rotatable about a plurality of axes; It provides an electric pole steel wire breakage diagnostic apparatus and a diagnostic method using the same, including a. Thereby, durability and usability are improved, and it is possible to effectively diagnose whether the steel wire is broken in the underground part of the pole.

Description

Electric pole steel wire breakage diagnosis device and diagnosis method using the same

The present invention relates to an apparatus for diagnosing steel wire breakage for electric poles and a diagnostic method using the same, and more particularly, to a device capable of diagnosing whether an underground steel wire is broken in a structure in which a steel wire is embedded, such as a concrete electric pole, and a steel wire using the same It relates to a fracture diagnosis method.

Inside the concrete pole, a prestressed steel wire (tension reinforcing bar) and a prestressed steel wire (reinforcement reinforcing bar) are installed to support the load received by the pole. That is, a plurality of steel wires are installed inside the electric pole.

In general, a pole should be able to resist bending load, that is, a moment. However, if the steel wire is cut, it cannot resist the bending load and there is a risk of the pole collapsing.

Figure 1 shows the breaking phenomenon of the steel wire inside the concrete pole above and below the ground. As such, the breaking phenomenon of the steel wire may occur not only above the ground but also in the underground part, and in particular, when the steel wire breaks in the underground part, the possibility of the collapse of the electric pole is high.

Since the steel wire is inside the concrete pole, it cannot be visually confirmed, so a method for diagnosing steel wire breakage using a magnetic field sensor or the like is used on the outer surface of the electric pole. However, since it is not possible to diagnose whether the steel wire corresponding to the underground part of the pole buried in the ground is broken by diagnosis from the outer surface of the pole, a method of inserting a sensor into the inner space of the pole has been developed to diagnose whether the steel wire in the underground part is broken. has been

2 to 4 show a conventional electric pole breakage diagnosis apparatus. As shown in FIG. 4 , in the prior art, a distal end provided with a hinge 12 and a spring 13 was used at the distal end of the electric pole breakage diagnosis device. After the roller 11 touches the inner surface of the electric pole, it rotates around the hinge and goes down in the direction of gravity along the inner surface of the electric pole. phenomenon was prevented.

However, the distal end of this structure must be inserted with the top and bottom of the distal end aligned (so that the spring is located below) when the first insertion of the electric pole steel wire breakage diagnosis device, and the top and bottom of the distal end must be maintained until the roller touches the inner surface of the pole. do. If the top and bottom of the distal end were changed during insertion, the device for diagnosing the breakage of the steel wire for electric poles had to be removed again, and the distal end had to be properly aligned and inserted again.

In addition, the conventional steel wire breakage diagnosis apparatus for electric poles has a problem in that the pole in contact with the inner surface of the electric pole is bent in the opposite direction, not in the direction toward the inner surface of the electric pole, so that the diagnosis of the corresponding part is impossible. In this case, for accurate diagnosis, the work process was cumbersome and inconvenient, and the work convenience was low because the work process was cumbersome and inconvenient because it was necessary to straighten the stem and bend it again to bend it in the correct direction, or to remove the steel wire breakage diagnosis device for electric poles and clean the stem and insert it again.

In addition, as shown in FIG. 13 , the conventional steel wire breakage diagnosis device for electric poles has a structure in which the stem is unfolded when holding the handle 501 ′ provided on the body 500 ′ and pulling it, but a fairly large force is required to unfold the stem. Therefore, there was a problem of high work fatigue.

An object of the present invention is to provide an apparatus for diagnosing steel wire breakage for electric poles capable of diagnosing whether a steel wire is broken in an underground part of an electric pole, and a diagnostic method using the same.

In order to achieve the above object, the present invention is a steel wire breakage diagnosis apparatus for electric poles that is inserted into the inner space of the electric pole through a hole formed on one side of the electric pole and detects the magnetic field of the steel wire buried in the electric pole, the body part ; a cable coupled to the body and inserted through the hole; a sensor unit coupled to one end of the cable and in contact with the inner surface of the electric pole to detect the magnetic field of the steel wire; a support portion provided at one end of the sensor unit to support one end of the sensor unit; and a rotating part coupled to one end of the support part and rotatable about a plurality of axes.

The sensor unit may include a plurality of spokes formed of an elastic material, and a sensor may be provided in the spokes.

The spokes may be made of a stainless steel material.

In the center of the sensor unit, a spoke manipulator coupled to the support is located, and the plurality of spokes may be arranged to be symmetrical about the spoke manipulator.

The support portion may include an inclined portion surrounded by the plurality of spokes; and a fixing part for supporting the end of the rib; may include

The fixing unit may be coupled to the rotating unit with a pin, and the rotating unit may be rotatable around the pin.

The rotating part may include: a first part positioned on the support side; a second part hingedly coupled to the first part; and a roller coupled to the second part.

The second part is rotatable about the hinge with respect to the first part, and a plurality of rollers are provided, and at least one roller is located at an end of the second part and is larger than the width of the second part. can have a diameter.

The rotation angle of the second part may be limited to a predetermined range by interference with the first part.

The body portion is provided with a handle to protrude from the rotating plate and the rotating plate to which one end of the stem manipulation unit is coupled,

When the rotating plate is rotated by manipulating the handle, the support part may be moved by winding or unwinding the spoke manipulator to the rotating plate.

In addition, the present invention provides a method for diagnosing a steel wire for electric pole using a steel wire breakage diagnosis apparatus for electric pole, comprising: a first step of selecting an electric pole to be diagnosed; a second step of drilling a hole on one side of the electric pole; a third step of setting the electric pole breakage diagnosis device; By inserting the steel wire breakage diagnosis device for the electric pole into the inner space of the electric pole. a fourth step of measuring the magnetic field of the steel wire of the electric pole; a fifth step of analyzing the measured magnetic field data; and a sixth step of examining the safety of the electric pole using the analysis result of the magnetic field data;

In the fourth step, the electric pole steel wire breakage diagnosis apparatus may be located in the basement of the electric pole, and a part of the electric pole steel wire breakage diagnosis apparatus may contact the inner surface of the electric pole.

In the fourth step, the magnetic field of the steel wire of the electric pole may be measured by moving the steel wire breakage diagnosis apparatus for the electric pole in the direction of gravity or the direction opposite to the gravity.

The hole to be punched in the second step may be a footrest fixing groove position into which a footrest provided on the electric pole is inserted.

The steel wire breakage diagnosis apparatus for an electric pole and a diagnostic method using the same according to the present invention can effectively diagnose whether the steel wire is broken in the underground part of the electric pole by improving durability and work convenience.

1 is a cross-sectional view showing the breaking phenomenon of the steel wire inside the ground and underground concrete poles;
2 is a view showing a conventional steel wire breakage diagnosis apparatus for electric poles;
Figure 3 is a view showing the operating state of Figure 2;
4 is a front view showing the distal end of the conventional electric pole steel wire breakage diagnosis apparatus;
5 is a perspective view showing a support part of a steel wire breakage diagnosis apparatus for electric poles according to an embodiment of the present invention;
Figure 6 is a front view of Figure 5;
7 is a front view showing the distal end of the steel wire breakage diagnosis apparatus for electric poles according to an embodiment of the present invention;
Fig. 8 is a plan view of Fig. 7;
9 is a front view showing a state in which FIG. 7 is bent;
Figure 10a is a view showing a diagnostic signal characteristic graph of a pole in which the steel wire is not damaged;
Figure 10b is a diagram showing a diagnostic signal characteristic graph of a pole in which the steel wire is damaged;
11 is a view showing a state of using the steel wire breakage diagnosis apparatus for electric poles according to an embodiment of the present invention;
12 is an enlarged view of part A of FIG. 11;
13 is a perspective view showing a conventional steel wire breakage diagnosis device for electric poles;
14 is a view schematically showing the inside of a body part of a steel wire breakage diagnosis apparatus for electric poles according to an embodiment of the present invention;
15 is a view showing a state in which the steel wire breakage diagnosis device for electric pole according to an embodiment of the present invention is inserted into the electric pole inner space;
16 is a view showing a state in which the steel wire breakage diagnosis apparatus for electric pole according to an embodiment of the present invention is bent in the direction of gravity in the inner space of the electric pole;
17 is a flowchart illustrating a method for diagnosing a breakage of a steel wire for an electric pole using the apparatus for diagnosing a breakage of a breakage of a steel wire for an electric pole according to an embodiment of the present invention.

Hereinafter, an apparatus for diagnosing a steel wire breakage for electric poles according to an embodiment of the present invention will be described with reference to the accompanying drawings.

5 is a perspective view illustrating a support part of a steel wire breakage diagnosis apparatus for electric poles according to an embodiment of the present invention, FIG. 6 is a front view of FIG. A front view showing the distal end of the , FIG. 8 is a plan view of FIG. 7 , FIG. 9 is a front view showing the bent state of FIG. 7 , and FIG. 10b is a diagram showing a diagnostic signal characteristic graph of an electric pole with a damaged steel wire, FIG. 11 is a view showing a state of using the steel wire breakage diagnosis apparatus for electric pole according to an embodiment of the present invention, and FIG. 12 is part A of FIG. 13 is a perspective view of a conventional steel wire breakage diagnosis apparatus for electric poles, and FIG. 14 is a view schematically showing the inside of the body of the steel wire breakage diagnosis apparatus for electric poles according to an embodiment of the present invention; 15 is a view showing a state in which the steel wire breakage diagnosis apparatus for electric poles according to an embodiment of the present invention is inserted into the electric pole inner space, and FIG. 17 is a flowchart illustrating a method for diagnosing a breakage of a steel wire for an electric pole using the apparatus for diagnosing a breakage of a steel wire for an electric pole according to an embodiment of the present invention.

The steel wire breakage diagnosis apparatus for electric poles according to this embodiment includes a cable 300 , a distal end 200 , a sensor unit 400 , a support unit 100 , and a body unit 500 .

The body part 500 is located on one side of the pole breakage diagnosis device, is not inserted into the inner space of the pole, is located outside, so that the operator can operate it while holding it. The cable 300 is connected to the body 500 , and a rotatable rotating plate 510 is provided inside the body 500 , and the rotating plate 510 protrudes to the outside of the body 500 . A handle 520 is provided. The operation of the handle 520 and the rotating plate 510 will be described later.

The cable 300 is inserted into the inner space of the electric pole with one side coupled to the sensor unit 400, and the other end is connected to analysis equipment located outside the electric pole. That is, during the diagnosis operation, the cable 300 is positioned over the inner space and the outside of the electric pole, and the data measured by the sensor unit 400 is analyzed by connecting the sensor unit 400 and the analysis equipment. serves to transmit The cable 300 is formed of a bendable material, and is bent by a load such as the sensor unit 400 in the inner space of the electric pole.

7 to 9 , the distal end 200 includes a first portion 202 , a hinge 206 , a roller 204 , and a second portion 210 . And, the first part 202 is coupled to the support part 100 and the pin 220 . The first part 202 is freely rotatable about the pin 220 with respect to the support part 100 . The second part 210 supports the roller 204 to rotate, and one side of the second part 210 is hinge-coupled to the first part 202 . That is, the second part 210 is freely rotatable with respect to the first part 202 about the hinge 206 .

9 shows a state in which the second part 210 is rotated about 45 degrees with respect to the first part 202 with the hinge 206 as the center. However, the second part 210 may rotate up to 90 degrees with respect to the first part 202 .

At this time, since the second part 210 and the roller 204 are freely rotatable about two axes around the hinge 206 and the pin 220, the distal end is in contact with the inner surface of the electric pole. After that, the roller 204 may descend in the direction of gravity along the inner surface of the electric pole. That is, even if the upper and lower ends of the distal end 200 are not aligned at the time of initial insertion, the hinge 206 and the pin 220 rotate and the roller 204 is positioned in a direction in which it can descend in the direction of gravity.

The sensor unit 400 includes a plurality of spokes 110 to which a sensor 410 is attached to an intermediate portion. The sensor 410 is a means for measuring a magnetic field signal. As the spoke 110 is bent, the sensor 410 comes into contact with the inner surface of the electric pole. In addition, by measuring the magnetic field while moving the sensor unit 400 up and down, it is possible to diagnose whether or not the steel wire embedded in the electric pole is broken and the location of the break.

The spoke 110 is formed of a stainless steel material. Stainless steel is durable and does not break easily even when subjected to stress due to repeated bending. In addition, since the sensor 410 uses a magnetic field, a magnetic material cannot be used as the material of the stem 110 , but stainless steel is a non-magnetic material and has a characteristic that the magnetic field is transmitted without loss. Since the spoke 110 is bent and has to come into contact with the inner surface of the electric pole, it is advantageous in this respect when using a stainless steel material in consideration of usability and durability.

The support part 100 is coupled to the sensor part 400 . The support part 100 supports the plurality of ribs 110 in a fixed manner, and the poles 110 are convexly bent in the direction of the inner surface of the electric pole to induce the sensor 410 to contact the inner surface of the electric pole. . That is, the support part 100 can prevent the reverse bending of the spokes 110 . Referring to FIGS. 5 and 6 , the support part 100 is provided with a fixing part 102 that is in contact with the end of the rib and an inclined part 104 coupled to the fixing part 102 . The inclined portion 104 has a shape of a truncated cone with an inclined side surface, and the spokes 110 contacting the side surface are formed in a shape consistent with the inclined portion 104 . In addition, a groove 112 is formed at the end of the spoke 110 along the circumferential direction. Although not shown, a ring is fastened to the groove 112 so that the end of the spoke 110 may not be separated from the support 100 .

11 and 12 , a spoke manipulator 420 is coupled to the inclined portion 104 . When the spoke operating part 420 is pulled in the opposite direction to gravity, the support part 100 rises, and as a result, the end of the spoke 110 comes into contact with the fixing part 102 and receives a force to be compressed as a result of the spoke ( 110) is bent. At this time, the spokes 110 are convexly bent toward the inner surface of the electric pole while moving along the inclined portion 104 in the direction in which they open from each other.

In the conventional equipment, there was no means for preventing the rib 110 from being bent in the opposite direction as intended, and when the rib 110 is bent in the opposite direction, the sensor 410 provided in the rib 110 cannot contact the inner surface of the pole. Therefore, it was not possible to diagnose whether the steel wire was broken in the relevant part. However, in this embodiment, because the inclined portion 104 is provided, the spokes 110 can always be convexly bent toward the inner surface of the electric pole.

On the other hand, in any one of the sensor unit 400 , the support unit 100 , and the distal end 200 , an endoscope for improving work convenience by photographing the inner space of the electric pole may be provided. The operator can work while looking at the screen photographed with the endoscope while appropriately adjusting the position or angle of the sensor unit 400 .

In this embodiment, the operation to bend the spoke 110 is made by applying a compressive force to the spoke 110 by pulling the spoke operating part 420 . As described above, one end of the spoke manipulation unit 420 is coupled to the inclined unit 104 . And the other end of the spoke manipulator 420 is coupled to the rotating plate 510 provided inside the body portion (500). That is, the spoke manipulator 420 is positioned inside the cable 300 or positioned in parallel with the cable 300 to extend from the body part 500 to the support part 100 . As shown in FIG. 14 , the rotating plate 510 is rotatable by manipulating the handle 520 , and when the rotating plate 510 rotates, the spoke manipulation unit 420 is wound around the outer peripheral surface of the rotating plate 510 or will be released Therefore, when the handle 520 is turned in one direction, the spoke manipulator 420 is pulled, and the spoke 110 is bent.

At this time, in order to maintain the spoke 110 in a bent state even when the handle 520 is released, a fixing means for fixing the rotating plate 510 at a specific angle may be provided.

Although not shown, a reverse movement prevention device known as a ratchet may be applied as the fixing means. The ratchet is a type of toothed wheel with teeth formed on the outer circumferential surface, and is rotatable in the forward direction, but is formed with teeth of a structure in which pawls in contact with the outer circumferential surface of the ratchet are caught when trying to rotate in the reverse direction. impossible.

By coupling the ratchet to rotate together with the central axis of the rotating plate 510 , the rotating plate 510 is fixed even if the operator releases the handle 520 , thereby maintaining the spokes bent. However, since the rotation plate 510 is rotated in the reverse direction to unfold the spokes 110 after the diagnosis operation is completed, a switch for separating the poles from the ratchet may be provided.

When the electric pole steel wire breakage diagnosis apparatus according to an embodiment of the present invention described above is used, the sensor unit 400 always descends in the direction of gravity even if the upper and lower ends of the distal end 200 are not aligned at the time of initial insertion, and the Since the rib 110 of the sensor unit 400 is not bent in reverse, work convenience is high, and since the rib 110 is made of a stainless steel material, durability is high. Therefore, according to the present embodiment, it is possible to more effectively diagnose the breakage of the steel wire.

Hereinafter, a diagnosis method using the steel wire breakage diagnosis apparatus for electric poles according to an embodiment of the present invention will be described.

In the first step (S100), a diagnosis target Jeonju is selected. At this time, matters that can be considered include the appearance of abnormalities such as tilting or cracking of the pole, and the year of manufacture and inspection of the pole.

In the second step (S200), one side of the pole is perforated. In this case, the footrest fixing groove formed on the electric pole is generally used. That is, the footrest is removed from the electric pole, and the footrest fixing groove formed to fix the footrest is drilled. The footrest fixing groove is located at a height (L1) spaced apart from the ground surface as shown in FIG. 11, and generally the height (L1) is about 1.8 m. If the footrest fixing groove is large enough to allow the diagnosis device to be inserted, a separate hole may be unnecessary. However, in the case of an electric pole in which the size of the footrest fixing groove is not sufficient or the footrest fixing groove is not formed, a perforation is required at this stage.

In the third step (S300), the electric pole steel wire breakage diagnosis device is set. In particular, since the sensor unit 400 must be in a fully folded state in order to pass through the hole punched in the second step, the spokes 110 are folded in the sensor unit 400 to be in close contact with each other. In addition, in this step, it is also checked whether various equipments inserted into the inner space of the electric pole, such as the sensor 410 and the endoscope, operate normally.

In the fourth step (S400), by inserting the electric pole breakage diagnosis device into the electric pole inner space. Measure the magnetic field of the steel wire of the electric pole. In the steel wire breakage diagnosis apparatus for electric poles according to the present invention, as described above, in the electric pole inner space, the sensor unit 400 is oriented in the direction of gravity by its own load. And, when the sensor 410 is in contact with the inner surface of the electric pole by extending the spoke 110, the magnetic field is measured while moving the sensor unit 400 up and down. In this case, the depth L2 of the part to be measured may be set to about 2.5 m.

In the fifth step (S500), the magnetic field data measured in the fourth step is analyzed through analysis equipment. As shown in FIGS. 10A and 10B , an electric pole with a damaged steel wire and an undamaged electric pole can be distinguished through magnetic field data. Specifically, an electric pole in which the steel wire is broken shows an “S”-shaped graph in which the N and S poles change rapidly, and the electric pole in which the steel wire is not broken does not appear in this form.

In the sixth step (S600), safety is reviewed using the results analyzed in the fifth step. In this case, the safety is judged by comprehensively considering the degree of breakage of the steel wire and the location of the breakage. If it is diagnosed as a serious risk, follow-up work such as replacing the pole may be required.

According to the diagnostic method using the steel wire breakage diagnosis apparatus for electric poles according to the present invention described above, it is possible to effectively diagnose whether the steel wire located in the underground part of the electric pole is broken.

Claims (14)

In the electric pole steel wire breakage diagnosis apparatus which is inserted into the inner space of the electric pole through a hole formed on one side of the electric pole and detects the magnetic field of the steel wire buried in the electric pole,
body part;
a cable coupled to the body and inserted through the hole;
a sensor unit coupled to one end of the cable and in contact with the inner surface of the electric pole to detect the magnetic field of the steel wire;
a support portion provided at one end of the sensor unit to support one end of the sensor unit; and
a rotating part coupled to one end of the support part and rotatable about a plurality of axes;
including,
The sensor unit,
It includes a plurality of spokes formed of an elastic material,
A sensor is provided on the spoke,
The support part,
an inclined portion surrounded by the plurality of spokes; and
a fixing part for supporting the end of the rib;
including,
The steel wire breakage diagnosis device for electric poles is formed in a shape coincident with the inclined portion, wherein the inclined portion is in the shape of a truncated cone with an inclined side, and the spokes contacting the side of the inclined portion are formed in a shape consistent with the inclined portion. delete According to claim 1,
The pole is a steel wire breakage diagnosis device for electric poles, characterized in that made of a stainless steel material. According to claim 1,
At the center of the sensor unit, a shank operation unit coupled to the support unit is located,
The plurality of ribs is a steel wire breakage diagnosis device for electric poles, characterized in that it is arranged to be symmetrical about the rib operation part. delete According to claim 1,
The fixing unit is coupled to the rotating unit with a pin,
The rotating part, a steel wire breakage diagnosis apparatus for electric poles, characterized in that rotatable around the pin. According to claim 1,
The rotating part,
a first portion located on the side of the support;
a second portion hingedly coupled to the first portion; and
Steel wire breakage diagnosis apparatus for electric poles, characterized in that it includes a roller coupled to the second part. 8. The method of claim 7,
The second part is rotatable about the hinge with respect to the first part,
A plurality of rollers are provided, and at least one roller is located at an end of the second part and has a diameter greater than a width of the second part. 8. The method of claim 7,
The second part is a steel wire breakage diagnosis apparatus for electric poles, characterized in that the rotation angle is limited to a predetermined range by the interference with the first part. 5. The method of claim 4,
The body portion is provided with a handle to protrude from the rotating plate and the rotating plate to which one end of the stem manipulation unit is coupled,
When the rotating plate is rotated by manipulating the handle, the steel wire breakage diagnosis apparatus for electric poles, characterized in that the support part moves by winding or unwinding the shank manipulation part to the rotating plate. A method for diagnosing a steel wire for electric poles using the steel wire breakage diagnosis apparatus for electric poles according to any one of claims 1, 3 to 4, and 6 to 10,
A first step of selecting a diagnosis target Jeonju;
a second step of drilling a hole on one side of the electric pole;
a third step of setting the electric pole breakage diagnosis device;
By inserting the steel wire breakage diagnosis device for the electric pole into the inner space of the electric pole. a fourth step of measuring the magnetic field of the steel wire of the electric pole;
a fifth step of analyzing the measured magnetic field data; and
A sixth step of examining the safety of the electric pole by using the analysis result of the magnetic field data; Containing, a method for diagnosing breakage of the steel wire for electric poles. 12. The method of claim 11,
In the fourth step,
The electric pole steel wire breakage diagnosis apparatus is located in the basement of the electric pole, and a part of the electric pole steel wire breakage diagnosis apparatus contacts the inner surface of the electric pole steel wire breakage diagnosis method. 13. The method of claim 12,
In the fourth step, the steel wire breakage diagnosis method for electric poles, characterized in that the electric pole steel wire breakage diagnosis apparatus is moved in the direction of gravity or the opposite direction to gravity and the magnetic field of the steel wire of the electric pole is measured. 12. The method of claim 11,
The hole to be drilled in the second step is a steel wire breakage diagnosis method for electric poles, characterized in that the position of the footrest fixing groove into which the footrest provided on the electric pole is inserted.

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