JP6379370B1 - Cable breakage detection device and cable breakage detection method - Google Patents

Abstract

A breakage detection apparatus and a breakage detection method for accurately detecting a breakage point of a cable even under various breakage conditions.
SOLUTION: Signals 25 and 27 having different frequencies are oscillated from both ends of a cable 1 having a damaged portion 6 from a transmitter connected to both ends, and signals having different frequencies propagating through the cable are in a non-contact state. A cable breakage detection device that identifies a breakage point based on the identification result, and the transmission device has a combined resistance of a switch that forms a closed circuit and a resistance corresponding to the capacitance of the cable. And a termination resistor having a small resistance value provided on a closed circuit for increasing the voltage drop at the damaged portion by increasing the ratio of the resistance at the damaged portion to a value smaller than the resistance DR. And a receiving device that receives a change in a signal transmitted from the transmitting device in a non-contact manner and identifies a damaged portion.
[Selection] Figure 2

Description

  The present invention relates to a cable breakage detection apparatus and a breakage detection method, and more particularly, to a breakage detection apparatus and a breakage detection method capable of detecting breakage with high accuracy from a low resistance to a high resistance.

Conventionally, high-voltage cables have been laid at various places in facilities such as production lines and power plants that manufacture various products from home appliances to automobiles. Some of these high-voltage cables have a shielding copper tape wrapped around the structure in order to prevent an electric shock accident or an induction failure.
This shielded copper tape expands and contracts due to stress caused by expansion and contraction due to temperature changes due to outside air temperature and load current, or when the outer layer of the high voltage cable deteriorates and breaks due to corrosion due to moisture intrusion There is.
When this shielding copper tape is disconnected, the induced current does not flow smoothly, and a minute discharge phenomenon occurs, resulting in destruction of the insulating layer and a cause of a ground fault blackout. In order to prevent a power outage accident, it is necessary to inspect the high voltage cable, to quickly find the part where the resistance value of the shielding layer is abnormal, and to repair the broken part.

Conventionally, an environment in which a high voltage cable is laid is easily affected by noise from a commercial power supply, communication equipment, and the like, and it has been extremely difficult to detect a disconnection portion of the cable.
For this reason, conventionally, an invention has been proposed in which a disconnection location is accurately pinpointed without being affected by noise or the like.
For example, Patent Document 1 includes a first oscillator that outputs a signal X having a specific frequency, and a second oscillator that outputs a signal Y having a specific frequency different from the signal X. In addition, a detector is provided for identifying the signals X and Y oscillated on the cable by the first and second oscillators in a non-contact manner. Then, using the fact that the signals X and Y are propagated from both ends of the cable to the breakage point, the change point of the signal on the cable is detected to identify the change point as the breakage point. The signals X and Y have non-sinusoidal waveforms, so that the signal X, Y can be detected even in an environment where the location where cable breakage detection is affected by commercial frequency 50 Hz and 60 Hz noise sources. An invention capable of accurately detecting Y has been proposed.

  For example, in Patent Document 2, an alternating voltage is generated by two piezoelectric oscillators having different frequencies, and each voltage is alternately switched in a certain cycle to be an intermittent voltage. Each intermittent voltage is amplified and passed through an output transformer. The voltage applied to the buried electric wire is applied between both ends of the buried electric wire and the ground, and the electrode is in contact with two points on the ground surface on the buried electric wire and the ground surface laterally separated from the buried electric wire. The voltage between the two points generated from the voltage distribution on the ground surface generated by is amplified and the received voltage is amplified, and the output voltage is passed through the two piezoelectric filters having the same frequency as the two piezoelectric oscillators, respectively. The filter output voltage is amplified by two amplifiers each, a lamp or buzzer is connected to the output side, and the two electrodes are moved along the buried electric wire. At the point before and after the boundary, the lamp or buzzer that has been operating until then stops and the lamp or buzzer of another frequency starts to operate, thereby detecting the presence of a break in the buried electric wire under the front and rear boundary ground. There has been proposed a device for detecting a broken portion of an embedded electric wire, which is characterized by this.

Japanese Patent Laid-Open No. 10-2927 Japanese Utility Model Publication No. 03-46873

  However, the degree of disconnection varies depending on the situation, and appears in various situations such as complete disconnection or minor damage. For example, in the case of complete disconnection, the resistance is 20 KΩ, but in the case of minor damage that does not lead to disconnection, the disconnection point resistance DR is 400Ω. FIG. 11A shows the state of the damaged part, and is an equivalent circuit composed of conventional transmitters 100a and 100b and a high-voltage cable. Since the termination is in an open state, the input resistance of the transmitter 100b is large (∞Ω), and the capacitance resistance Z corresponding to the capacitance of the high-voltage cable is also as large as 5 kΩ to 10 kΩ. When the value is small, particularly 1000Ω or less, as shown in FIG. 11B, the voltage drop at the damaged portion is small, and it is difficult to detect signal attenuation in the conventional receiver. . In addition, there is a problem that signals having different frequencies transmitted from the transmitting devices 100a and 100b on both sides interfere with each other, and the receiving device cannot read the signals well.

  The present invention has been made in view of the above problems, and it is an object of the present invention to provide a breakage detection apparatus and a breakage detection method for accurately detecting a breakage point of a cable even under various breakage conditions.

A first transmitter connected to one end of a cable including a conductor having a damaged portion and a conductor not having a damaged portion; and a second transmitter connected to the other end of the cable,
The first transmission device and the second transmission device each include a wiring connected to a conductive body having the damaged portion, and a wiring connected to a conductive body not having the damaged portion,
The first transmission device transmits a first signal having a first frequency, and the second transmission device has a second frequency different from the frequency output from the first transmission device. Send a second signal ,
A cable breakage detection device that identifies the first signal and the second signal of different frequencies propagating through the cable in a non-contact state, and identifies the breakage point from the identification result,
The first transmission device includes:
A first termination resistor connected in series with a breakage point resistance that is an assumed resistance at the breakage point of the cable ;
A first changeover switch that allows the second signal to pass through the conductor having no damaged part resistance, the first terminal resistor, and the damaged part by closing a circuit;
The second transmitter is
A second termination resistor connected in series with the breakage point resistor;
A second changeover switch for passing the first signal to the conductor having no damaged part resistance, the second terminal resistor and the damaged part by closing a circuit;
The first termination resistor or the second resistor connected in parallel with a resistance corresponding to a capacitance made of an insulator of the cable between the conductor having the damaged portion and the conductor not having the damaged portion. By increasing the ratio of the combined resistance of the terminal resistor and the damaged portion resistance to 40: 1 or more, a value obtained by increasing the voltage drop at the damaged portion is detected, and the first transmitter and the first And a receiving device that receives the change of the first signal and the second signal transmitted from the second transmitting device in a non-contact manner and identifies the damaged portion.

  Due to the above features, the cable breakage detection device of the present invention has a large voltage drop at the breakage point, and can detect the breakage point with high accuracy even when the breakage point has a small resistance value regardless of the breakage state. is there.

It is the schematic which showed the damaged location of the high voltage | pressure cable of embodiment. It is explanatory drawing which shows a mode that the broken location of the high voltage | pressure cable of embodiment is detected. It is the schematic which shows the equivalent circuit which detects the broken location of the high voltage | pressure cable of embodiment. It is explanatory drawing which shows a mode that the broken location of the high voltage | pressure cable of embodiment is detected. It is the schematic which showed the voltage drop of the broken part of the high voltage | pressure cable of embodiment. It is a block diagram which shows the structure of the transmitter in the damage detection apparatus which detects the damage location of the high voltage | pressure cable of embodiment. It is a block diagram which shows the structure of the transmitter in the damage detection apparatus which detects the damage location of the high voltage | pressure cable of embodiment. It is a block diagram which shows the structure of the receiver in the damage detection apparatus which detects the damage location of the high voltage | pressure cable of embodiment. It is a front view which shows the external appearance of the receiver in the damage detection apparatus which detects the broken location of the high voltage | pressure cable of embodiment. It is a time chart which shows the timing which outputs the signal in the damage detection apparatus which detects the damage location of the high voltage | pressure cable of embodiment. It is explanatory drawing which shows the mode of the voltage drop of the equivalent circuit which detects the broken location of the conventional high voltage cable, and a broken location.

  A cable breakage detection apparatus and a breakage detection method according to the present invention will be described in detail with reference to the drawings. It should be noted that the embodiments and drawings described below exemplify a part of the embodiments of the present invention, and are not used for the purpose of limiting to these configurations, and do not depart from the gist of the present invention. Can be changed as appropriate.

FIG. 1 shows a state where a general high-voltage cable 1 is broken. The high-voltage cable 1 includes a three-core high-voltage cable in addition to a single core, and is applied depending on the application. In this embodiment, the structure of the single-core high-voltage cable 1 will be described. The structure of the high-voltage cable 1 is composed of a conductor 5, an insulator 4, a shielding layer 3, and an anticorrosion layer 2.
As the conductor 5, a circular stranded wire, a circular compression stranded wire, or a divided compression stranded wire formed of a material such as copper or aluminum is used. The insulator 4 is covered with a crosslinked polyethylene material. Further, an internal semiconductor layer (not shown) is formed between the conductor 5 and the insulator 4, and the internal semiconductor layer fills the gap between the conductor 5 and the insulator 4 in order to reduce the surface potential gradient, and corona discharge is generated. It is provided to prevent it from occurring.

The shielding layer 3 is covered around the insulator 4 by a copper, stainless steel, or iron material in the form of a copper strip exterior, a stainless tape exterior, or an iron wire exterior. The anticorrosion layer 2 is covered with an outermost shell in order to protect the insulator 4 and isolate it from moisture and the like. As the material of the anticorrosion layer 2, vinyl, polyethylene or polypropylene is adopted. FIG. 1 shows a state in which the shielding layer 3 is broken, and shows a state in which a broken portion 6 of the shielding layer that cannot be recognized from the outside is formed. In the present embodiment, the broken portion resistance DR in which the shielding layer 3 is broken is shown, and it is assumed that there is a resistance value of about 400Ω.

<Damage detection device and damage detection method>
The damage detection apparatus and damage detection method will be described with reference to FIGS. The breakage detection device is composed of a transmission device 10 and a reception device 50, and is a device that detects breakage of a wiring provided with a shielding layer 3 typified by a high voltage cable 1 or the like. The breakage detection device includes a pair of transmission devices 10a and 10b and a reception device 50. FIG. 2A is an explanatory diagram illustrating a state in which the transmission device 10 is connected to the high-voltage cable 1 when a damaged portion is detected. FIG. 2B is an explanatory diagram showing signals transmitted by the transmission apparatuses 10a and 10b in terms of time and voltage. FIG. 3 shows an equivalent circuit composed of a pair of transmitters 10 a and 10 b and the high-voltage cable 1 when detecting breakage of the high-voltage cable 1. Drawing 4 is an explanatory view showing signs that a broken part of high voltage cable 1 of an embodiment is detected. FIG. 5 is a schematic diagram illustrating a voltage drop at a damaged portion of the high-voltage cable 1 according to the embodiment. FIG. 6 is a block diagram illustrating a configuration of the transmission device 10a in the damage detection device that detects a damaged portion of the high-voltage cable 1 according to the embodiment. FIG. 7 is a block diagram illustrating a configuration of the transmission device 10b in the damage detection device that detects a damaged portion of the high-voltage cable 1 according to the embodiment. FIG. 8 is a block diagram illustrating a configuration of the receiving device 50 in the damage detection device that detects a damaged portion of the high-voltage cable 1 according to the embodiment. FIG. 9 is a front view illustrating an appearance of the receiving device 50 in the breakage detection device that detects a breakage point of the high-voltage cable 1 according to the embodiment. FIG. 10A is a time chart showing the timing of signal output in the case of complete damage. FIG. 10B is a time chart showing signal output timing when the shielding layer 3 is damaged.

As shown in FIG. 2A, the transmission device 10 is connected to both ends of the high-voltage cable 1 that is a target of damage detection. The transmission device 10 is set to transmit a voltage of about 15 V as a pulse signal. Positive wirings 22 a and 22 b are provided as positive wirings of the transmission device 10, and the positive wirings 22 a and 22 b are connected to the shielding layer 3 of the high-voltage cable 1. Further, minus wires 21 a and 21 b are provided as minus wires of the transmission device 10, and the minus wires 21 a and 21 b are connected to the conductor 5 of the high-voltage cable 1.
Further, the high-voltage cable 1 can stabilize the potential by connecting the grounds 7 a and 7 b connected to the ground to both ends of the conductor 5. Therefore, the signal from the transmission device 10 is stable, and the detection sensitivity of the reception device 50 is stable. Therefore, the receiving device 50 can accurately read the signal from the transmitting device 10.

FIG. 3A shows an equivalent circuit composed of the transmission devices 10a and 10b and the high-voltage cable 1 when an A signal (25 in FIG. 2) is transmitted from the transmission device 10a. FIG. 3B shows an equivalent circuit including the transmission devices 10a and 10b and the high-voltage cable 1 when a B signal (27 in FIG. 2) is transmitted from the transmission device 10b.
As shown in FIGS. 2 and 3A, the transmission device 10a transmits a 35 kHz rectangular wave A signal (25). At that time, the transmission device 10b forms a closed circuit that closes the changeover switch 13b and passes through the termination resistor 11b. Here, the cable capacitance component resistor 12b, which is a resistor corresponding to the capacitance of the high-voltage cable 1, is as large as 5 kΩ to 10 kΩ, but the termination resistor 11b uses a very small resistor of 10Ω.

Therefore, the combined resistance GRb cable capacitance partial resistor 12b and the terminating resistor 11b becomes 10Ω or less, breach resistance DR of the shielding layer breach 6 assuming a 400 [Omega, the voltage drop is larger in the shielding layer breach 6 Become. As shown in FIG. 5, when a voltage of 15 V is applied, a significant voltage drop is obtained up to a value close to 0 volts. As described above, even if the damaged portion resistance DR of the shielding layer breakage portion 6 is 1000Ω or less, the voltage drop at the shielding layer breakage portion 6 becomes large and is noticeable. improves.

  Similarly to the above, as shown in FIGS. 2 and 3B, the transmitting apparatus 10b transmits a B signal (27) of a rectangular wave of 50 kHz. At that time, the transmitting device 10a forms a closed circuit that closes the changeover switch 13a and passes through the terminating resistor 11a. Here, the cable capacitance component resistor 12a, which is a resistor corresponding to the capacitance of the high-voltage cable 1, is as large as 5 kΩ to 10 kΩ, but the termination resistor 11a uses a very small resistor of 10Ω. Although the ideal termination resistance is 0Ω, 10Ω is adopted in consideration of safety.

Therefore, the combined resistance GRa cable capacitance component resistor 12a and the terminating resistor 11a becomes 10Ω or less, breach resistance DR of the shielding layer breach 6 assuming a 400 [Omega, the voltage drop is larger in the shielding layer breach 6 Become. As shown in FIG. 5, when a voltage of 15 V is applied, a significant voltage drop is obtained up to a value close to 0 volts. As described above, even if the damaged portion resistance DR of the shielding layer breakage portion 6 is 1000Ω or less, the voltage drop at the shielding layer breakage portion 6 becomes large and is noticeable. improves. In addition, the ratio of the damage part resistance DR assumed to the synthetic | combination resistance is set to about 40: 1.

Next, the circuit configuration of the transmission apparatuses 10a and 10b will be described with reference to the block diagrams of FIGS.
First, the transmission device 10a will be described with reference to FIG. The transmitter 10a employs a battery for the power source 31a in consideration of carrying. These batteries may be dry batteries or rechargeable lithium batteries. The power source 31a is not limited to a battery, and an AC 100V, DC power source may be used as the power source 31a. The power supply 31a is connected to the power supply stabilization circuit 32a. The power stabilization circuit 32a monitors the power supply voltage, and if there is an abnormality in the power supply 31a, a control circuit 37a such as an LSI displays an abnormality notification of the power supply 31a, a remaining battery level, etc. on the LCD display 62a.

The power supply circuit 33a connected to the power supply stabilization circuit 32a varies the voltage from 5V to 20V so that the output voltage is instructed from the control circuit 37a. It is possible to increase the voltage output when the reception sensitivity is weak by changing the output voltage, and it is possible to cope with various environments.
Further, the A signal output circuit 34a connected to the plus wiring 22a controls the output of the A signal 25 according to a command from the control circuit 37a, and switches a photocoupler or the like to ON / OFF so that a 35 kHz rectangular wave is obtained. A signal 25 is output.

  The transmitting device 10a is provided with a B signal receiving circuit 36a connected to the plus wiring 22a and the control circuit 37a. When receiving the B signal 27 from the B signal receiving circuit 36a, the control circuit 37a opens the A signal output circuit 34a and stops the transmission of the A signal 25. Then, the control circuit 37a closes the changeover switch 13a such as a photocoupler provided in the termination resistor and switching circuit 35a, and forms a closed circuit that passes through the plus wiring 22a, the termination resistor 11a, the changeover switch 13a, and the minus wiring 21a. . In this way, the control circuit 37a of the transmission device 10a forms a synchronization timing with the transmission device 10b and performs control so that signals do not interfere with each other.

  In addition, the control circuit 37a equipped with an LSI or the like can perform various settings such as an output voltage output from the plus wiring 22a, a screen display of the LCD display 62a, and a sound output from the speaker 38a by an input operation using the operation key 61a. Is possible. The speaker 38a connected to the control circuit 37a can output an operation sound or a synchronization sound when synchronization is achieved.

  Next, the transmission device 10b will be described with reference to FIG. The transmitter 10b employs a battery for the power source 31b in consideration of carrying. These batteries may be dry batteries or rechargeable lithium batteries. The power source 31b is not limited to a battery, and an AC 100V, DC power source may be used as the power source 31b. The power supply 31b is connected to the power supply stabilization circuit 32b. The power stabilization circuit 32b monitors the power supply voltage, and if there is an abnormality in the power supply 31b, a control circuit 37b such as an LSI displays an abnormality notification of the power supply 31b, a remaining battery level, etc. on the LCD display 62b.

The power supply circuit 33b connected to the power supply stabilization circuit 32b varies the voltage from 5V to 20V so that the output voltage is instructed from the control circuit 37b. It is possible to increase the voltage output when the reception sensitivity is weak by changing the output voltage, and it is possible to cope with various environments.
Further, the A signal output circuit 34b connected to the plus wiring 22b controls the output of the B signal 27 according to a command from the control circuit 37b, and switches a photocoupler or the like to ON / OFF, thereby causing a 50 kHz rectangular wave. B signal 27 is output.

  The transmitting device 10b is provided with an A signal receiving circuit 36b connected to the plus wiring 22b and the control circuit 37b. When receiving the A signal 25 from the A signal receiving circuit 36b, the control circuit 37b opens the B signal output circuit 34b and stops the transmission of the B signal 27. Then, the control circuit 37b closes the changeover switch 13b such as a photocoupler provided in the termination resistor and switching circuit 35b, and forms a closed circuit that passes through the plus wiring 22b, the termination resistor 11b, the changeover switch 13b, and the minus wiring 21b. To do. In this way, the control circuit 37b of the transmission device 10b forms a synchronization timing with the transmission device 10a and performs control so that signals do not interfere with each other.

  In addition, the control circuit 37b equipped with an LSI or the like can perform various settings such as an output voltage output from the plus wiring 22b, a screen display of the LCD display 62b, and a sound output from the speaker 38b by an input operation using the operation key 61b. Is possible. The speaker 38b connected to the control circuit 37b can output an operation sound or a synchronization sound when synchronization is achieved.

Next, the circuit configuration of the receiving device 50 will be described with reference to the block diagram of FIG. The receiving device 50 can receive two types of A signal 25 (35 kHz) and B signal 27 (50 kHz) with one device.
The receiving device 50 employs a battery for the power source 51 in consideration of carrying. These batteries may be dry batteries or rechargeable lithium batteries. The power source 51 is not limited to a battery, and may be an AC 100V, DC power source. The power supply 51 is connected to the power supply stabilization circuit 52. The power supply stabilization circuit 52 monitors the power supply voltage, and if there is an abnormality in the power supply 51, a control circuit 55 such as an LSI displays an abnormality notification of the power supply 51 and a remaining battery level on the LCD display 62.

The A signal receiving circuit 53 is mounted with a coil element whose inductance or core shape is changed with the best sensitivity for receiving the A signal 25 (35 kHz). Similarly, the B signal receiving circuit 54 is equipped with a coil element in which the inductance and the core shape have the best sensitivity for receiving the B signal 27 (50 kHz). The large amplitude waveforms obtained from the A signal receiving circuit 53 and the B signal receiving circuit 54 are respectively extracted by the mounted window comparator, and the reception intensity is determined by the control circuit 55. In this way, by configuring the receiving circuit (53, 54) according to the frequencies of the A signal 25 and the B signal 27, it is possible to receive with high accuracy.
The A signal receiving circuit 36b and the B signal receiving circuit 36a described above take out a signal with a coupling capacitor without using a coil, and receive it with the control circuits 37a and 37b through a bias circuit.

  The control circuit 53 equipped with an LSI or the like displays the strength of the signal A25 or the signal B27 received by, for example, a ratio display such as “XX%” on the LCD display 62 or a level display by an arrow “>>>>”. It can also be displayed. Further, the speaker 38 can output the difference between the A signal 25 and the B signal 27 while changing the pitch of the sound or the sound transmission interval.

  Next, the external structure used for the transmission device 10 and the reception device 50 will be described with reference to FIG. Since the transmitting apparatus 10 has the same structure as the receiving apparatus 50, the receiving apparatus 50 will be described as an example. The casing 63 of the receiving device 50 adopts a waterproof and dustproof structure of the IP67 standard so that it can be used even in rainy weather. An LCD display 62 is provided inside the receiving device 50. The LCD display 62 has a structure in which a backlight is lit so that settings and display contents can be confirmed even at night or in a dark place. An operation key 61 having a plurality of keys is disposed below the LCD display 62. Various settings can be made with the operation keys 61 and the LCD display 62.

A method for detecting the shielding layer breakage point 6 by the transmission device 10 and the reception device 50 configured as described above will be described with reference to FIGS.
The transmission device 10 can apply a voltage of 5V to 20V, and the transmission device 10a continues to transmit the rectangular wave A signal 25 for a predetermined time as shown in FIG. To do.
Since the transmission apparatus 10a can be synchronized with the transmission apparatus 10b by the B signal reception circuit 36a connected to the control circuit 37a, the transmission of the A signal 25 is performed while the transmission apparatus 10b is transmitting the B signal 27. Has stopped. Conversely, as shown in FIG. 2B, the transmission device 10b continues to transmit a rectangular wave B signal 27 for a predetermined time, and then stops transmission.
Since the transmitting apparatus 10b can be synchronized with the transmitting apparatus 10a by the A signal receiving circuit 36b connected to the control circuit 37b, the transmitting apparatus 10b transmits the B signal 27 while the transmitting apparatus 10a transmits the A signal 25. Has stopped. In this way, interference between signals transmitted by the transmission apparatuses 10 being synchronized with each other is prevented. Therefore, the receiving device 50 can accurately receive various signals transmitted from the transmitting device 10.

In more detail, the manner in which the transmission apparatus 10 outputs signals while synchronizing will be described with reference to the timing chart shown in FIG.
FIG. 10A shows a state in which the breakage of the shielding layer 3 is not a slight breakage and the high-voltage cable 1 is completely disconnected. In the case of complete disconnection, the transmitting devices 10a and 10b cannot receive the signal on the other side by the A signal receiving circuit 34b or the B signal receiving circuit 34a, so the changeover switches 13a and 13b do not perform switching. The transmitter 10 continues to output signals without synchronizing. The A signal 25 outputs a signal of a frequency of 35 kHz from the A signal output circuit 34a during the output period T, which is a fixed period, and then stops outputting the A signal 25 during the interval period Xs, which is a fixed period. To do. The A signal 25 is output at such a period of T + Xs. The B signal 27 is output from the B signal output circuit 34b during the same period T as the output period A signal, which is a fixed period, after the signal having a frequency of 50 kHz, and then during the interval period Ys, which is a fixed period, Stop the output of. Then, the B signal 27 is output at such a period of T + Ys.

  Next, FIG. 10B illustrates the case where the shielding layer 3 is slightly damaged. The transmission apparatus 10a outputs the A signal 25 from the A signal output circuit 34a during the output period T, and then the B signal reception circuit 34a receives the B signal 27 during the interval period Xs that is a fixed period. In response to reception of the B signal 27, the changeover switch 13a (shown by a broken line in the drawing) is turned ON for a period of T + α, which is a fixed time. In response to reception of the B signal 27 (indicated by a broken line in the drawing), the A signal output circuit 34a continues to stop outputting the A signal 25 for a period of T + α. After the elapse of the period T + α, the A signal output circuit 34a starts outputting the A signal 25 again.

  Similarly, the transmitting apparatus 10b synchronized with the transmitting apparatus 10a outputs the B signal 27 from the B signal output circuit 34b during the output period T, and then outputs the A signal receiving circuit 34b during the interval period Ys that is a fixed period. When the A signal 25 is received, the changeover switch 13b (indicated by a broken line in the drawing) is turned on for a period of T + α that is a fixed time when the A signal 25 is received. In response to reception of the A signal 25 (indicated by a broken line in the drawing), the B signal output circuit 34a continues to stop outputting the B signal 27 for a period of T + α. After the elapse of the period T + α, the B signal output circuit 34a starts outputting the B signal 27.

  As described above, signals are output simultaneously by providing an operation period of the changeover switch 13a or an output stop period of the A signal 25 and the B signal 27 longer than the period in which the A signal 25 and the B signal 27 are output. The A signal 25 and the B signal 27 do not interfere with each other.

Next, with reference to FIG.4 and FIG.5, the method to detect the shielding layer breakage location 6 is demonstrated.
The A and B signals are transmitted from the transmitters 10a and 10b. However, as shown in FIG. 5, the shielding layer breakage point 6 has a high voltage resistance with respect to 10Ω of the termination resistors 11a and 11b as described above. Since the signal is attenuated and the signal is attenuated, detection by the receiving device 50 is enabled by the change in the strength of the reception level of the A signal 25 or the B signal 27 received by the receiving device 50.
As shown in FIG. 4, the area from the transmitting device 10a to the shielding layer breakage point 6 becomes an A signal receiving area 23a that is an area where the A signal 25 is strongly received, and the transmission device 10b to the shielding layer breakage point 6 It is a B signal reception area 23b, which is an area where the B signal 27 is strongly received.

For example, the high-voltage cable 1 often has a long distance of 1 km or more, and the two receiving devices 50 are used to detect the broken portion 6 of the shielding layer in order to find a broken point from both ends. Between A signal receiving area 23a or B signal receiving area 23b uses the receiving apparatus 50, will explore directed from both sides transmitting apparatus 10 of the center, the reception apparatus 50 enters the shielding layer breach 6, the received signal The strength changes. At that time, for example, the receiver 50 receives the signal A25 or the signal B27 received by the ratio display such as “XX%” or the level display by the arrow “>>>>” on the LCD display 61 shown in FIG. It is also possible to display strength. Further, the A signal 25 and the B signal 27 can be notified by changing the pitch of the sound or the sound transmission interval by the speaker 38 shown in FIG.

When the high-voltage cable 1 is completely disconnected, as described above, the A signal receiving area 23a receives only the A signal 25, and conversely, the B signal receiving area 23b receives only the B signal 27. There is no.
In the present embodiment, the high-voltage cable 1 has been described. However, not only a high-voltage cable but also normal electric wiring such as an emergency bell can be detected.
In the present embodiment, not only a complete disconnection but also a state such as a slight breakage of a conducting wire, that is, a state such as poor contact can be detected. For example, a communication cable such as a LAN cable can communicate without being completely disconnected. However, even if there is a communication error, a data error may be avoided by an operation such as retry. However, depending on the degree of breakage, the communication speed decreases and the frequency of data errors increases, and the cable state may be deteriorated. In the present invention, it is possible to inspect such a lightly damaged portion. Therefore, the present invention can be used to detect various cable abnormalities.

(Technical features)
An example of technical features of the present embodiment is shown in parentheses in the following, but is not particularly limited but illustrated, and effects that can be considered from these features are also described.

<First feature point>
Transmitting devices (for example, mainly transmitting devices 10a and 10b) connected to both ends of a cable (for example, mainly high voltage cable 1) having a damaged portion (for example, mainly shielding layer damaged portion 6). , Signals of different frequencies (for example, mainly A signal 25 and B signal 27) are transmitted , the signals of different frequencies propagating through the cable are identified in a non-contact state, and the damaged portion is identified from the identification result. A cable breakage detection device, wherein the transmission device includes a switch forming a closed circuit (for example, mainly changeover switches 13a and 13b) and a resistance corresponding to the capacitance of the cable (for example, mainly cable electrostatics). The combined resistance (for example, the combined resistances GRa and GRb) with the capacitive resistor 12a) is set to a value smaller than the resistance at the damaged portion (for example, mainly the damaged portion resistance DR), and the damage A terminating resistor having a small resistance value (for example, mainly terminating resistors 11a and 11b) provided on the closed circuit for increasing the voltage drop at the damaged portion by increasing the ratio of the resistance at the location; And a receiving device (for example, mainly receiving devices 50a and 50b) that receives the change of the signal transmitted from the transmitting device in a non-contact manner and identifies the damaged portion. And

  With the above features, the cable breakage detection device of the present invention has a large voltage drop at the breakage point, and can detect the breakage point with high accuracy even when the breakage point has a small resistance value regardless of the breakage state. is there.

<Second feature>
The termination resistor has a resistance value of 10Ω or less.
With the above features, the cable breakage detection device of the present invention has a large voltage drop at the breakage point, and can detect the breakage point with high accuracy even when the breakage point has a small resistance value regardless of the breakage state. is there.

<Third feature point>
An earth (for example, mainly earth 7a, 7b) connected to the conductor of the cable is provided.
With the above features, the cable breakage detection apparatus of the present invention stabilizes the potential due to the ground connected to the conducting wire, so that the voltage of the output signal is stable and the breakage point can be detected with high accuracy.

<Fourth feature point>
When the transmitting device receives a signal having a frequency different from the signal transmitted from itself, the transmitting device stops transmitting the signal of its own and operates the switch to perform control to form the closed circuit (for example, , Mainly comprising control circuits 37a, 37b).
With the above features, the cable breakage detection apparatus of the present invention prevents interference of transmitted signals. For this reason, the receiving device can detect a damaged portion with high accuracy.

<Fifth feature point>
The receiving apparatus is characterized in that a receiving circuit (for example, mainly an A signal receiving circuit 53 and a B signal receiving circuit 54) is provided for each different frequency at which the signal is received.
With the above features, the cable breakage detection apparatus of the present invention can receive the transmitted signal without interference, so the reception apparatus can detect the breakage point with high accuracy.

<Sixth feature point>
The receiving circuit includes a coil element (for example, mainly a coil element) that matches the frequency of the signal to be received.
With the above features, the cable breakage detection apparatus of the present invention can receive the transmitted signal without interference, so the reception apparatus can detect the breakage point with high accuracy.

<Seventh feature point>
The transmission device is characterized in that voltage adjusting means (for example, mainly power supply circuits 33a and 33b) for adjusting the output voltage of the signal is provided.
Due to the above characteristics, the cable breakage detection device of the present invention can detect a broken portion with high accuracy by adjusting the voltage value of the signal to be transmitted when the reception sensitivity is poor due to the surrounding environment such as noise. Is possible.

<Eighth feature point>
It transmits each different frequency of a signal from a transmitting device connected to both ends of the cable having a damaged section, to identify the signals of different frequencies propagating through the cable in a non-contact state, identifying the damaged part from the identification result Cable breakage detection method,
The value of the resistance provided on the closed circuit formed by closing the switch is reduced, the combined resistance of the resistance of the cable and the resistance of the cable is made smaller than the resistance of the damaged part, Increase the voltage drop of the damaged part by increasing the ratio of the resistance of the part,
The receiving device is characterized in that the damaged portion is identified by a change in a signal generated by the voltage drop.

  Due to the above characteristics, the cable breakage detection method of the present invention increases the voltage drop at the breakage point, and can accurately detect the breakage point regardless of the breakage state even if the breakage point has a small resistance value. is there.

<Ninth feature point>
When the transmitting device receives a signal of a frequency different from the signal transmitted from itself, it stops transmitting its own signal, operates the switch to form the closed circuit in the transmitting device, Control is performed so that timings of transmitting signals having different frequencies are not the same.

  With the above features, the cable breakage detection method of the present invention receives other signals to stop the transmission of itself and prevent interference of the transmitted signals. For this reason, the receiving device can detect a damaged portion with high accuracy.

<Tenth feature point>
10. The cable breakage detection method according to claim 9, wherein a stop period of its own signal after receiving another signal is longer than a signal output period.
With the above features, the cable breakage detection method of the present invention prevents interference of transmitted signals by making the period for stopping the transmission of itself longer than the period for outputting. For this reason, the receiving device can detect a damaged portion with high accuracy.

It can be used for an inspection device and inspection method for a high-voltage electric wire laid in a power plant, or an inspection device and inspection method for a transformer cable, a communication cable, etc. with a built-in inverter. Further, even in electric wiring such as a commercial 100V it is possible to detect the damaged section, is available to the breakage detection device and damage detection method of electrical wiring.

DESCRIPTION OF SYMBOLS 1 ... High voltage cable, 3 ... Shielding layer, 5 ... Conductor, 6 ... Shielding layer breakage place, 7a, 7b ... Ground,
10, 10a, 10b ... transmitting device, 11a, 11b ... termination resistor,
12a, 12b, Z ... resistance of cable capacitance, 13a, 13b ... changeover switch,
25 ... A signal, 27 ... B signal, 33a, 33b ... power supply circuit,
34a ... A signal output circuit, 34b ... B signal output circuit, 36b, 53 ... A signal reception circuit,
36a, 54 ... B signal receiving circuit, 37a, 37b, 55 ... control circuit,
50 ... Receiving device, 61 ... Operation keys, 62 ... LCD display, 63 ... Case,
DR: Damaged part resistance, GRa, GRb: Composite resistance.

Claims (8)

A first transmitter connected to one end of a cable including a conductor having a damaged portion and a conductor not having a damaged portion; and a second transmitter connected to the other end of the cable,
The first transmission device and the second transmission device each include a wiring connected to a conductive body having the damaged portion, and a wiring connected to a conductive body not having the damaged portion,
The first transmission device transmits a first signal having a first frequency, and the second transmission device has a second frequency different from the frequency output from the first transmission device. Send a second signal ,
A cable breakage detection device that identifies the first signal and the second signal of different frequencies propagating through the cable in a non-contact state, and identifies the breakage point from the identification result,
The first transmission device includes:
A first termination resistor connected in series with a breakage point resistance that is an assumed resistance at the breakage point of the cable ;
A first changeover switch that allows the second signal to pass through the conductor having no damaged part resistance, the first terminal resistor, and the damaged part by closing a circuit;
The second transmitter is
A second termination resistor connected in series with the breakage point resistor;
A second changeover switch for passing the first signal to the conductor having no damaged part resistance, the second terminal resistor and the damaged part by closing a circuit;
The first termination resistor or the second resistor connected in parallel with a resistance corresponding to a capacitance made of an insulator of the cable between the conductor having the damaged portion and the conductor not having the damaged portion. By increasing the ratio of the combined resistance of the terminal resistor and the damaged portion resistance to 40: 1 or more, a value obtained by increasing the voltage drop at the damaged portion is detected, and the first transmitter and the first A receiving device that receives the change of the first signal and the second signal transmitted from two transmitting devices in a contactless manner and identifies the damaged portion;
A breakage detecting device for a cable, comprising: The cable breakage detection device according to claim 1, wherein the first termination resistor and the second termination resistor have resistance values of 10Ω or less. The cable breakage detection device according to claim 1, further comprising a ground connected to a conductor that does not have a breakage point of the cable. The cable breakage detection apparatus according to claim 1, wherein the reception apparatus is provided with a reception circuit for each different frequency at which the first signal and the second signal are received. 5. The cable breakage detection apparatus according to claim 4, wherein the reception circuit includes a coil element that matches a frequency of the first signal and the second signal to be received. 2. The cable according to claim 1, wherein the first transmission device and the second transmission device are provided with voltage adjusting means for adjusting output voltages of the first signal and the second signal. Damage detection device. Wiring connected to a conductor having a damaged portion;
Wiring connected to a conductor that does not have a breakage point;
A first termination resistor connected in series with a damaged portion resistance which is an assumed resistance at the damaged portion of the cable including the conductive body having the damaged portion and the conductive body not having the damaged portion;
A first transmission device comprising: a first changeover switch that causes a second signal to pass through the conductor having no damaged portion, the first terminal resistor, and the damaged portion by closing a circuit; To one end of the cable,
Wiring connected to the conductor having the damaged portion;
Wiring connected to the conductor without the damaged portion;
A second termination resistor connected in series with the breakage point resistor;
A second transmission device comprising: a second changeover switch that passes the first signal to the conductor having no damaged portion, the second terminal resistor, and the damaged portion by closing the circuit; To the other end of the cable,
The first transmission device performs control to transmit the first signal different from the frequency output from the second transmission device,
The second transmission device performs control to transmit the second signal different from the frequency output from the first transmission device,
The first transmission device and the second transmission device are:
In order to synchronize the timing of alternately outputting the first signal and the second signal, the first stop period and the second stop period after the first signal and the second signal are output. By controlling the output timing of the first signal and the second signal not to be the same,
The first transmission device includes:
After stopping the transmission of the first signal, the second signal is received from no reception during the first stop period, and the transmission of the first signal is stopped. 1 is closed, and after the second fixed period, the first signal is transmitted during the first fixed period.
The second transmitter is
After the transmission of the second signal is stopped, the first signal is received from no reception during the second stop period, and the transmission of the second signal is stopped. 2 is closed, and after the second fixed period, the second signal is transmitted during the first fixed period.
Changes in the first signal and the second signal transmitted from the first transmission device and the second transmission device are received in a contactless manner by a reception device, and the damaged portion is identified. Cable breakage detection method. The first transmission device includes:
In response to receiving the second signal from no reception during the first stop period,
With the transmission of the first signal stopped, the first changeover switch is closed, and after the second fixed period has elapsed, the first changeover switch is opened, and during the first fixed period, Send the first signal,
Controlling to stop the transmission of the first signal during the first stop period;
The second transmitter is
In response to receiving the first signal from no reception during the second stop period,
While the transmission of the second signal is stopped, the second changeover switch is closed, and after the second fixed period, the second changeover switch is opened, and during the first fixed period, the Send a second signal,
By performing control to stop transmission of the second signal during the second stop period,
8. The cable breakage detection method according to claim 7, wherein control for synchronization is performed .

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