JPH09236557A - Method for observing water tree in electric insulator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To efficiently observe a water tree in an electric insulator by acting to the electric insulator a high frequency magnetic field bringing about a nuclear magnetic resonance to hydrogen atoms in the presence of a static magnetic field and an inclined magnetic field. SOLUTION: A static magnetic field magnet 6 is connected to a static magnetic field power source 3, and an inclined magnetic field coil 7 generating inclined magnetic fields in X, Y, Z directions is connected to an inclined magnetic field power source 4. High frequency pulses output from a high frequency unit 5 are amplified at an amplifier 8 and then input to a high frequency coil 9. Pulse signals from the high frequency coil 9 are projected to an electric insulator placed at the center of the static magnetic field magnet 6, whereby a nuclear magnetic resonance is brought about to hydrogen atoms. A relaxation signal of the nuclear magnetic resonance(NMR) is detected by a detecting part of the high frequency coil 9, input as an NMR signal to the high frequency unit 5 and processed as required at a controlling/image-processing device 2. An image of the signal is displayed on a screen of a monitor 10 and also stored in an image memory device 11 such as an HDD or the like.

Description

Detailed Description of the Invention

[0001]

FIELD OF THE INVENTION The present invention relates to a method for observing a water tree in an electrical insulator in a rubber / plastic insulated power cable or the like.

[0002]

2. Description of the Related Art As a power cable, a CV cable having a cross-linked polyethylene as an insulating layer is often used. In this CV cable, an inner semiconductive layer, a polyethylene layer containing a cross-linking agent and an outer semi-conductive layer are sequentially extruded and coated on a cable conductor, which is heated under pressure in a cross-linking tube to add the cross-linking agent added to the polyethylene layer. It is made by reacting and cross-linking polyethylene, and then coating the outer periphery with a metal shielding layer, cable sheath, etc.The polyethylene insulating layer has a low dielectric constant and dielectric loss rate, and the cross-linking also improves heat resistance. Therefore, it is widely used as a high voltage or ultra high voltage power cable. By the way, the CV cable having such excellent performance also has a low insulation performance during a long-term use, or a relatively short period depending on its manufacturing conditions or use conditions, leading to dielectric breakdown. Sometimes. One of the causes of this dielectric breakdown is
It is considered that this is due to the water tree generated in the polyethylene insulating layer. The cause of the water tree is that the water is decomposed by minute discharge into hydrogen gas and oxygen gas, and that the increase in the pressure destroys the insulator, and water gathers in the area where the electric field concentrates. The theory that the insulator is physically destroyed by the volume expansion due to the aggregation of water,
There is a theory that water that has condensed in the area where the electric field is concentrated becomes a jet jet and physically destroys the insulator.
None of them is a dogma, and intensive research is underway.

In the actual cable, when observing or measuring the state of water tree generation, the cable is disassembled, the cable insulating layer is sliced into slices, and the obtained slice pieces having a thickness of about 1 mm are seen through. Although the number, size, shape, etc. of water trees are observed, it is not easy to create a large number of slice pieces or visually observe them. In addition, the pre-break test method may be used to investigate the state of deterioration of cables and the mechanism of destruction. This test method preserves the state of the starting point of partial discharge by applying a voltage to the test cable to cause partial discharge, and interrupting the applied voltage before it develops a dielectric breakdown. By observing the vicinity of, we will try to find a clue to clarify the state of deterioration of the cable and the relationship between the mechanism of destruction and the water tree. In this test method as well, when observing the vicinity of the starting point of breakage, the test cable is disassembled and the cable insulating layer is sliced into slices. If the cutting edge of the cutting blade hits the position of the starting point of the partial discharge when cutting into pieces, necessary information cannot be obtained. When locating this partial discharge location, when gradually narrowing down the section containing the partial discharge location, the precursor cutoff test method is repeatedly applied, so the cutting edge of the cutting blade is the starting point of the partial discharge. The probability of hitting a position is high, about 1/2.

[0004]

As described above, when observing the generation state of a water tree or observing the vicinity of the starting point of partial discharge by the precursor interruption test method, the work of slicing an actual cable is troublesome. Not only that, there is a risk that the information source will be destroyed, and the work of seeing through a large number of slices and collecting data is a manual work, which is not easy. An object of the present invention is to provide a method for efficiently observing a water tree in an electrical insulator by using a magnetic resonance imaging apparatus utilizing a nuclear magnetic resonance phenomenon. The magnetic resonance imaging apparatus utilizing this nuclear magnetic resonance phenomenon has been widely used in the field of medicine from the past, but it is considered to be used for observing a water tree in an insulator such as an electric wire / cable according to the present invention. Is presumed to have not existed in the past.

[0005]

A method of observing a water tree in an electric insulator according to the present invention is a high frequency wave which causes a nuclear magnetic resonance phenomenon in hydrogen atoms in the electric insulator in the presence of a static magnetic field and a gradient magnetic field. A relaxation time of the nuclear magnetic resonance phenomenon is measured by applying a magnetic field, the measured value is image-processed based on the signal related to the magnetic field, and a water tree image on a tomographic plane in the electrical insulator is displayed on a monitor screen. Then, the state of the water tree is observed based on this image.

[0006]

BEST MODE FOR CARRYING OUT THE INVENTION As described above, in the present invention, a magnetic resonance imaging apparatus utilizing the nuclear magnetic resonance phenomenon is used, and hydrogen atoms are nucleated in an electric insulator in the presence of a static magnetic field and a gradient magnetic field. A high-frequency magnetic field that causes a magnetic resonance phenomenon is acted on, the relaxation time of the nuclear magnetic resonance phenomenon is measured, the measured value is image-processed based on a signal related to the magnetic field, and a water tree on a fault plane in the electrical insulator is measured. An image is displayed on the monitor screen and the state of the water tree is observed based on this image. Since water is collected in the water tree in the electrical insulator, a clear water tree image can be obtained by applying a high-frequency magnetic field that causes a nuclear magnetic resonance phenomenon to the hydrogen atoms. In the present invention, the electrical insulator is a cable insulating layer in a rubber / plastic insulated power cable, for example, a CV cable, and a static magnetic field, a gradient magnetic field, and a high frequency wave are generated with the cable semiconductive layer being applied to the inner and outer layers thereof. A water tree image can be obtained by applying a magnetic field, and a static magnetic field, a gradient magnetic field, and a high-frequency magnetic field can be applied while the cable conductor is inserted inside the cable insulating layer via the cable semiconductive layer. You can also get a water tree statue.

[0007]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 shows a schematic configuration of a magnetic resonance imaging apparatus (MRI) utilizing the nuclear magnetic resonance phenomenon used in the present invention. A control / image processing apparatus 2 operated by an operation console 1 includes a static magnetic field. A power source 3, a gradient magnetic field power source 4 in three directions of X, Y and Z, and a high frequency unit 5 for transmitting and receiving high frequency signals are connected. The static magnetic field power source 3 is connected to a static magnetic field magnet 6 including an air-core coil and having a magnetic shield layer on the outer surface thereof.
A gradient magnetic field coil 7 for generating a gradient magnetic field having an arbitrary direction and magnitude in the Z direction is connected. The high frequency pulse output from the high frequency unit 5 is input to the high frequency coil 9 after being amplified by the high frequency amplifier 8. The high-frequency coil 9 is composed of a transmitter and a receiver, and a pulse signal sent from the transmitter is applied to an electric insulator (not shown) placed at the center of the static magnetic field magnet 6 so that its hydrogen atoms are removed. Nuclear magnetic resonance. The relaxation signal of the magnetic resonance is detected by the receiving unit of the high frequency coil 9 and is input to the high frequency unit 5 as an NMR signal, and the control / image processing device 2
After being subjected to the necessary processing in, the image is displayed on the screen of the monitor 10 and stored in the image storage device 11 such as an HDD device.

FIG. 2 shows an outline of the water tree measurement of the cable insulating layer of the CV cable 20 as an object to be inspected. In the figure, a gradient magnetic field coil 7 for three directions of X, Y and Z directions is arranged inside the static magnetic field magnet 6, and a high frequency coil (not shown in FIG. 2) is further arranged inside thereof. It is arranged. The CV cable 20 is formed by sequentially extruding an inner semiconductive layer 22, a crosslinked polyethylene insulating layer 23, and an outer semiconductive layer 24 on the outer side of a cable conductor 21 and removing the outer cable sheath and the metal shielding layer. Therefore, the static magnetic field magnet 6 is positioned and arranged at the center thereof. In this state, the console 1 is operated to excite the static magnetic field magnet 6 and its axial direction (the length direction of the cable)
To generate a static magnetic field of a predetermined intensity, and also apply a gradient magnetic field pulse to the gradient magnetic field coil 7 to generate a gradient magnetic field of a predetermined magnitude in predetermined directions of X, Y, and Z directions. A high frequency pulse of a predetermined frequency is emitted from the transmitting unit of 9. The frequency of this high-frequency pulse is about 100 MHz when the magnetic field generated by the static magnetic field magnet 6 and the gradient magnetic field coil 7 is 2.35 Tesla, for example. In this way, the hydrogen atom (proton ¹ H) in the cross-linked polyethylene insulating layer 23 to be inspected causes a nuclear magnetic resonance phenomenon,
While absorbing and exciting the irradiated high frequency pulse,
Relax after a predetermined time. The relaxation signal of the magnetic resonance is detected by the receiver of the high frequency coil 9 and is input to the high frequency unit 5 as an NMR signal. Therefore, in the control / image processing apparatus 2, if the relaxation time of the nuclear magnetic resonance is measured while changing the gradient magnetic field in the XY direction on an arbitrary tomographic plane in the Z direction, the density distribution of hydrogen atoms on the tomographic plane is measured. As a result, information about the water content is obtained, and by performing image processing on this information, it is possible to display the distribution state of the water tree, which has a larger water content than other portions, on the screen.

FIG. 3 shows the CV thus obtained.
The distribution state of the water tree image 25 on the tomographic plane with the cable is schematically shown on the screen of the monitor 10 as an image. After observing the distribution state of the water tree on a specific fault plane, the position of the cable to be inspected is moved slightly in the lengthwise direction, and the combination of gradient magnetic field pulses is changed to change the water on the next fault plane. The distribution state of trees can be displayed as an image. Therefore, by repeating this, it is possible to easily observe the distribution state of the water tree in the length direction in the cable to be inspected having an arbitrary length. As described above, the present invention is to observe the water tree in the cable insulating layer by using the magnetic resonance imaging apparatus utilizing the nuclear magnetic resonance phenomenon.
Even if a conductor exists in the center like a cable, a tomographic image of a water tree can be obtained without removing it. Also, when the metal shield layer of the cable is a wire shield, there is a slight gap between each wire and the magnetic field can be transmitted inside. Therefore, without removing this metal shield layer or cable sheath, the actual cable The water tree at can be observed nondestructively. Further, if the static magnetic field coil is a superconducting magnet, the magnitude and stability of the magnetic field can be increased, so that the detection sensitivity of the water tree can be greatly improved.

As described above, according to the present invention, the distribution state of the water tree can be accurately grasped without slicing the cable insulating layer, and the reliability of the data can be improved by the online observation of the water tree deterioration phenomenon. Because it will improve
It is possible to accurately estimate the degree of cable insulation deterioration, and it can be expected to make a great contribution to the investigation of water tree deterioration phenomena and the study of the relationship between water trees and insulation performance.
In the above description, an example in which the present invention is applied to the observation of a water tree in the cable insulating layer of a CV cable has been described, but the present invention is not limited to this, and other electric wires and cables can be used. It can also be widely applied to the observation of water trees in insulating layers or electrical insulators other than cables. In addition to observing the water tree, it can also be used for crushing the outer shape of the cable and inspecting the internal structure, or for investigating voids, foreign matter, or protrusions in the cable.

[0011]

According to the present invention, since the water tree can be observed without slicing the electrical insulator, the time and labor required for its preparation can be saved, and the data can be handled easily and its reliability can be improved. The property is also improved.

[Brief description of drawings]

FIG. 1 is a schematic configuration diagram of a magnetic resonance imaging apparatus used in the present invention.

FIG. 2 is a perspective view showing an example in which the present invention is applied to detection of a water tree of a CV cable.

FIG. 3 is an explanatory diagram schematically showing an image on the screen of the monitor in FIG.

[Explanation of symbols]

 1 ... Operation console 6 ... Static magnetic field magnet 7 ... Gradient magnetic field coil 9 ... High frequency coil 10 ... Monitor 11 ... Image storage device 20 ... CV cable 21 ... Cable conductor 22 ... Internal semi-conductive layer 23 ...... Cable insulation layer 24 …… External semiconductive layer 25 …… Water tree image

Claims (3)

[Claims] 1. A relaxation time of the nuclear magnetic resonance phenomenon is measured by causing a high-frequency magnetic field that causes a nuclear magnetic resonance phenomenon in hydrogen atoms to act on the electrical insulator in the presence of a static magnetic field and a gradient magnetic field. The value is image-processed based on the signal relating to the magnetic field, a water tree image on a tomographic plane in the electric insulator is displayed on a monitor screen, and the state of the water tree is observed based on this image. A method for observing water trees in electrical insulators. 2. A static magnetic field, wherein the electrical insulator is a cable insulating layer in a rubber / plastic insulated power cable, and a semiconductive layer of the cable is attached to the inner and outer layers thereof.
The method for observing a water tree in an electrical insulator according to claim 1, wherein a gradient magnetic field and a high frequency magnetic field are applied. 3. The static magnetic field, the gradient magnetic field and the high frequency magnetic field are applied while the cable conductor is still inserted inside the cable insulating layer via the cable semiconductive layer. A method for observing water trees in electrical insulators.