JPH01222614A - Supervision of protective device of anti-corrosion layor on single core cable line - Google Patents

Abstract

PURPOSE:To carry out continuous supervision, by detecting the current generated in a protective device of an anti-corrosion layor at the insulated junction box where each single line of the 3 phase AC is connected and the current generated in the cable sheath and by suppling them to a control center and by comparing them. CONSTITUTION:Three of single core cable 1a-1c are connected through the insulated junction boxes 10a-10c. On the insulated junction boxes 10a-10c, the left and the right cable sheathes 13a-13c of the insulators 11a-11c are connected and construct the protective devices 7a-7c of the anti-corrosion layor. Cross bonding wires 5a-5c are cross-connected in order among the cable 11a-11c from phase (a) to (b), (c) and phase (a) again. The current of the protective device of anti-corrosion layor 7a-7c are detected by ampere meter 20a-20c and the detected value are supplied to the detected data processing unit 30 and compared with the settings. By this reason, continuous supervision are carried out without power down.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a part C metal sheath for cross-bonding in a single-core couple line, for example, a center-of-gravity OF kegur line or a single-core Cv kegur line. , concerning a device that detects abnormal current flowing through a corrosion protection layer protection device and covers it so that the history of dielectric breakdown of the corrosion protection layer protection device due to the abnormal current can be easily detected, particularly for detecting breaks in single-core cable lines. In order to easily centrally control the occurrence of abnormal current at a location far from the anti-corrosion layer protection device,
This invention relates to a method for monitoring a corrosion protection layer protection device installed in a single-core cable line.

(Prior art) Conventionally, in the underground power transmission route J3 where a single-core cable line is laid, the sheaths 1a, 1b, and 1G of each phase of three-phase AC are connected in parallel, as shown in Figure 6. At the same time, the sheaths of each phase are connected using insulating connection boxes 10a, 10b, and 10c for each bond section.

Then, in the insulated junction box portion of each phase, the metal sheath of each insulated junction box (hereinafter abbreviated as cable sheath) connected to both sides of the insulator is connected to the cross bond connection wires 5a to 5C. niJ: ーCri ``1 Suzuruyo 7
Means is used to connect the metal sheath to the phase I in the j state and to cover the abnormal current flowing through the metal sheath so that it matches W'jL.

. In addition, in the conventional example shown in FIG.
Place and cover a to 6G, and each! 11 core now - anti-corrosion layer protection device i' between pull and ground? (Arrestor) 7
By installing a to 7G, even if an abnormal current flows through the cable sheath of a single-core cable, the sheath current suppressing device 71 and other anti-corrosion layer protection devices will prevent it from occurring in the anti-corrosion layer. This is designed to prevent destruction of the anti-corrosion layer due to abnormal current.

In other words, J3 is added to the conventional corrosion protection layer protection device.
In the cable sheath, a semiconductor element (Arrestor element) such as sintered zinc oxide or silicon carbide particles is used, and if an abnormal voltage occurs in the cable sheath, the high voltage Discharge F1- to other adjacent sheaths or to the ground to mutually 71 il! JL, it is made possible to fit.

(Problems to be Solved by the Invention) However, in the single-core cable line as described above, the abnormal voltage generated in the cable sheath is J-.
When insulation breakdown occurs and small holes are formed in the anti-corrosion layer, water will enter through those holes and corrode the cable sheath made of aluminum, etc., and foreign matter will enter the couple itself, damaging the cable. Problems such as destruction may occur.

In addition, during the use of single-core cable lines, inconvenient conditions such as deterioration of the arrester element installed in the anti-corrosion layer protection device and moisture build-up occur, making it difficult to use as a cross-bonding means. Problems such as not being able to fully demonstrate the effect may occur, and the safety of the power transmission line may not be ensured.

For this reason, it is necessary to periodically inspect the condition of the anti-corrosion layer protection device, but for this inspection, it is necessary to check the anti-corrosion layer for all insulated junction boxes installed on the single-core cable line after power transmission is stopped. 4' if you have to carry out inspection work on the protective equipment.
When the single-core cable line is very long, there are many problems such as requiring a large amount of manpower and equipment for inspection.

In response to this, a protection device for an electric cable sheath was proposed as shown in Japanese Utility Model Publication No. 13231/1983.
There is C. In this conventional example, detection terminals are installed to inspect the anti-corrosion layer protection device, and by measuring the insulation resistance between the detection terminals and the ground, the arrester element of the anti-corrosion layer protection device is detected. The structure is designed to allow easy inspection.

However, even when using such a four-wire method, it is often difficult to measure the insulation resistance of a 111-core cable line, such as a 275kV transmission line, on a platform where the cable line is a high-voltage transmission line during power transmission. In addition, there is a further problem that it is extremely difficult to individually inspect each insulated connection box.

(Object of the Invention) The present invention is directed to the above-mentioned J, the lack of conventionally used devices, and the I/a-solution i11. By installing a means for detecting abnormal high voltage flowing through the insulated junction box (the triple sheath) and centrally monitoring the detected value from the detection means at the control center,
The purpose of this invention is to provide monitoring of anti-corrosion layer protection equipment installed on single-core cable lines to facilitate inspection work.

(Means and effects for solving the problem) The present invention connects each three-phase AC single-core cable through an insulated connection box, and cross-bonds the sheaths of adjacent single-core cables at each connection part. A detection means for detecting the voltage flowing through the anti-corrosion layer protection device installed in the insulated connection box is attached to the single-core cable line connected by the connection method. The voltage flowing through the detection circuit is inputted into the detection data processing device of Renter for each single-core cable, so that 719 hour monitoring can be performed. This is a method for monitoring an anti-corrosion layer protection device in a single-core cable line configured as described above, which can remotely monitor the flow of abnormal voltage in the couple sheath of the single-core coupler line.

In addition, in the monitoring method of the anti-corrosion layer protection device installed on the center-of-gravity couple track according to the present invention, a means is provided to send the detected value from the detection means to the rental vehicle. In both cases, it is possible to electrically connect the detection means to the sensors 1 to 1, and in addition, an optical fiber cable is used to transmit the detection data. By installing photoelectric conversion devices at both ends of the pull and converting the output from the detection means into light, it is possible to achieve
It is also possible to use a device that can transmit signals.

By configuring as described above, in the single-core cable line of the present invention, the voltage flowing through the cable sheath is constantly monitored for the cross-bond section of each single-core cable constituting the 111-core cable line. It becomes possible.

In the device &' of the present invention, the voltage flowing through the detection means 13 is constantly detected and the set values are calibrated.
Therefore, it is possible to easily judge whether or not the anti-corrosion layer protection device is operating normally, and if an abnormality occurs in the anti-corrosion layer protection device, it can be easily identified. This allows countermeasures to be taken quickly.

(Example) A method for monitoring a corrosion protection layer protection device in a tli-core group line according to the present invention will be described according to an illustrated example.

In the embodiment shown in FIG.
For example, three small-core cables 1a to 1 that cover a single-core OF cable line, single-core CV Kegur line, etc.
C has an insulated junction box 1 in its connection section, respectively.
The single-core cables on both sides are connected via 0a to 10C, and the insulated connection box has a structure as shown in FIG. 3.

The insulated junction box 10 shown in FIG. 3 is used to connect the conductors 16.
6E1 through the connecting sleeve 17, ? The ends of the outer cable sheaths (metal sheaths) 18.18a of the conductors 16 are connected to the jacket connection pipes 12.12a by means such as lead connections. Connecting.

An insulating tube 11 is disposed in the middle of the jacket connecting tube 12.12a, and the cable sheaths of the single-core cables on both sides are also insulated by the insulating tube 11, and the cable sheaths of the single-core cables on both sides are also insulated. If the insulation is well-performed, it will cause problems.

Further, in the insulating junction box 10 of the present invention, the insulating tube 11
Connecting terminals 13, 13 are formed to protrude from the jacket connecting tubes 12, 12a on both sides of the connector, and these terminals 13 are used for 11 spond connections and anti-corrosion connections. The layer protection device 7 can be connected, etc. In the case of this embodiment, the anti-corrosion layer protection device 7 is attached using a pair of inner terminals, and the outer terminals are used for cross-bonding.

In the insulating junction box 10 of the present invention described in ``2'', the outer jacket connecting pipe 12.12a is surrounded by a vinyl resin coating layer 14.
A protective layer 14 is formed with a cover 1) of E1, an insulating tube 14b, etc., and a connecting terminal 13 protrudes from the protective layer 14. 1. A reinforcing insulator 15 is provided in the space formed between the connecting parts of the conductor 16 inside the jacket connecting pipe.
is filled with.

In the embodiment shown in FIG. 1, an insulating junction box as shown in FIG. 3 described above is used. It is provided at each connection portion of each single-core cable 1a to 1C of the cable line 1.

Each of the above-mentioned insulation junction boxes [well, as explained based on FIG. The cable sheath on the left side of the single-core cable 1a and the cable sheath on the right side of the single-core cable 1[] are connected by the connecting wire 5a for bonding, and the cable sheath on the right side of the center-of-gravity cable 1a, etc. Connect the cable sheath of 1C to the connecting wire 5c for bond 11.
, and apply a crosspond connection v1 to the phase U for each 111-fiber woople.

Furthermore, in the device of the present invention, a current 111 (hereinafter referred to as current i1, including a current detection device consisting of a j-love element, etc.) is provided in the portion of the Moeki Q-layer protection device 7.
Alternatively, as shown in FIG. You can make it work.

The current layer received by the above-mentioned insulated junction box is the same for each of the three single-core cables that make up the single-core cable line, so one cross-pond connection Three signal lines are output from the detection f to the processing device 30, and the respective detection signals can be output from the controller 1 to the front part of the roll sender.

Moreover, in the embodiment shown in FIG.
(As in the embodiment shown in Figure 1, the anti-corrosion layer protection device 7
Here is an example where the anti-corrosion layer protection bag @7a is placed in the part where the ground is taken from the middle of the connection wire for the 1-sbond, without providing it to the couple sheath on both sides of the insulator 11 of the insulation connection box 10. It shows.

In this embodiment, the current layer 20a is as described above.
An anti-corrosion layer protection device 7a is arranged at a portion branching from the middle of the cross-bonding connection wire 5a toward the ground, a current layer 20a is provided for the anti-corrosion layer protection device 7a, and detection is performed using this current Wl 20 a. The information is output toward the detected data processing device 3o.

Furthermore, for the single-core cables 1b and 1c, a current of 812° is arranged in the same way as for the single-core cable 1a, and the detected information can be outputted to the detected data processing device. It will be done like this.

Detection information on the cross-bond section of the center-of-gravity cable line 1 configured as described above is transmitted to the detection data processing device 6 in the same manner as shown in FIG. In the embodiment shown in FIG. 4, the detection signals 1:4.j from each current 81 can be directly transmitted as electric signals to the detection data processing device P730. In this embodiment, the detection signals from each current layer are transmitted to the detection .gamma.-data processing device f??30 by an optical fiber cable 35.

To explain this embodiment in the case of the insulated junction box 10a, the signal from the current 1f20a installed in the insulated junction box 10a is output from the signal line installed corresponding to each current layer. During the signal transmission, it is converted into an optical signal and transmitted to the =Iin1 Herol Center via the optical fiber cable 35.

That is, in the case of this embodiment, a light weight converter +'1ff31.32 is provided at both ends of each optical fiber cable, and the output of each ammeter is converted into an optical signal by the photoelectric converter 31, and then the optical fiber The optical signal is transmitted to the control center via a cable, and the optical signal is converted into an electrical signal by the photoelectric conversion device 32 in the controllers 1 to 1/1, and input into the detection data processing-1/I-device 30.

Such optical/electrical signal conversion means is provided for each insulating junction box in each cross bond section.
In the N-I~Roll rental system, by centrally processing the signals from the all-C insulated junction boxes installed on the single-core wool line 1, the abnormal voltage is detected for each cross-bond section of each single-core cable. This makes it possible to detect the occurrence state.

In addition, in the device of the present invention, as described above, although it is possible to set up an optical fiber coupler corresponding to each current n1, as shown in FIG. It is also possible to arrange one optical fiber cable 37 corresponding to 20a, 20b, and 20C.

In this case, the current word output circuits provided in C for the three single-core cables are combined into one photoelectric multiplex converter 36, and the photoelectric multiplex converter U36 converts the photoelectric signal. I try to do this and get 1q.

Furthermore, the optical signal, marked Ic J, and thus transmitted to one optical fiber cable 37 is transferred to a photoelectric multiplexing device 38 at the end of the optical fiber cable 37.
The signal is converted into an electrical signal corresponding to each signal detection means, and inputted to the detected data processing device 3o, and the signal processing step f1 is performed.

In the embodiment shown in FIG. 4 described above, the device corresponding to the device shown in FIG. 1 is included, but in the case of the device shown in FIG. A signal transmission circuit as shown in is provided.

In the embodiment shown in FIG. 5, the photoelectric conversion device 331 The information from the electrical signals detected by the electric current can be converted into optical signals, and the information can be transmitted to the controller via the corresponding optical fiber cables. I'm trying to do it as much as I can.

In general, in this embodiment, in order to reduce the number of optical fiber cables, it is also possible to transmit the optical multiplexed signal using one optical fiber cable, as shown in FIG. 7Ia. Of course this is true.

Further, in the device of the present invention, conventionally known devices can be used as the photoelectric conversion device and the photoelectric multiplexing device.

As described above, the abnormal voltage detected at each insulating junction box is input to the detection data processing device 30 installed in the roll center, where the signal is processed and the abnormal voltage is compared with the normal voltage. If an abnormal condition is detected in the anti-corrosion layer protector after a comparison operation is performed, the cross bond section where the abnormality occurred and other information will be displayed on the control center display. Therefore, immediate countermeasures will be taken.

In addition, when 10 circuits of single-core cable lines are laid, the necessary data for each cross bond section, such as the distance of the section, abnormal voltage value, and its slack, must be set in the computer at Con I Rollsenter. By comparing the initially set value and the detected value output from the current 51, the computer can output data for each cross bond section of each center of gravity cable, such as the occurrence of y4 normal voltage. Make it.

Additionally, if an abnormal voltage flows through the couple sheath, the corrosion protection layer protection device may be damaged by the abnormal voltage.
Even if the corrosion protection layer is not destroyed, the information that the abnormal voltage has flowed will be stored in the computer storage means for each single-core cable line or each single-core couple. Corresponding to the history of each cross bond,
When performing regular repairs on each line of single-core cable lines,
It is necessary to be able to reliably carry out six tasks such as maintenance of anti-corrosion layer protection equipment and other inspections.

(Effects of the Invention) The method for monitoring the anti-corrosion layer protection device in a single-core cable line according to the present invention satisfies the above-mentioned concept, so it is possible to perform corrosion protection without interrupting the power transmission of the single-core cable line. It is possible to constantly monitor the state of the layer protection device, and it becomes easy to identify the section in the event of an accident.

In addition, the device of the present invention is particularly effective when installing a single-core cable line over a long section, and allows for easy centralized control at the control center. On the other hand, since the history of abnormal voltage flow, etc. can be stored as data, it becomes possible to easily perform maintenance after the high-voltage power transmission circuit is installed.

[Brief explanation of the drawing]

FIG. 1 is an explanatory diagram showing the configuration of a monitoring device for a corrosion protection layer protection device of the present invention, FIG. 2 is an explanatory diagram showing the configuration of another embodiment of the present invention, and FIG. 3 is an insulated junction box of the present invention. 414 is a circuit diagram of the configuration of the signal transmission circuit of the present invention, FIG. 4a is an explanatory diagram of the embodiment showing the arrangement of optical fiber cables, and FIG. FIG. 6 is an explanatory diagram of a corresponding signal transmission circuit, and FIG. 6 is an explanatory diagram of a conventional cross bond connection method. Numbers in the diagram: 1...Single-core cable line, 5...Connection wire for cross bond, 6...Sheath current suppressor, 7...Corrosion protection Layer protector, 1o...
Insulated connection box, 11... Insulator, 12...
・Conductor part, 13...Cable sheath, 14・
...Anti-corrosion layer, 2o...Current port, 3o...
...Detected data processing device, 31/32...
Photoelectric conversion device! Rows, 35, 37... Optical fiber cable, 36, 38... Photoelectric multiplex converter. Ward S Q Lily ~ ~ ~

Claims (3)

[Claims] (1) In a center-of-gravity cable line in which each single line of three-phase AC is connected via an insulated junction box, and the sheaths of adjacent single lines are connected at each connection part by a cross-bond connection method, a cable installed in the insulated junction box In order to detect the current generated in the anti-corrosion layer protection device, a detection means is provided corresponding to each center of gravity cable, and the current flowing through the circuit of the current detection means is detected by the detection data processing device of the control center for each center of gravity cable. monitoring of a corrosion protection layer protection device in a center of gravity cable line, characterized in that the operating state of the corrosion protection layer protection device can be constantly monitored by inputting the information into the input data and comparing the output value of each detection means with a set value. Method. (2) The detection means is provided in each insulated junction box of the center-of-gravity cable line, and means is provided for transmitting the detected values from the detection means to a control center that performs centralized management, and the detection means and the control center are Claim 1, characterized in that the connection is made through a normal power transmission line.
A method for monitoring an anti-corrosion layer protection device in a center-of-gravity cable line as described in Section 1. (3) An optical fiber cable is used as the detection data transmission means, and a photoelectric conversion device is provided at both ends of the optical fiber cable.
A method for monitoring a corrosion protection layer protection device in a single-core cable line according to item 1 or 2.