JPH0197111A - Transmission and distribution line monitoring system - Google Patents

Abstract

PURPOSE:To monitor many transmission and distribution lines correctly at the same time, by a constitution wherein all of the results of inspections with respect to the transmission and distribution lines, which are obtained by a multitude of sensors, are collected into a computer through slave stations, master stations and personal computers. CONSTITUTION:Signals, obtained by sensor main bodies 5a-8a, are propagated through optical fibers 5c-8c and are inputted into sensor devices 5b-8b, then, the results of inspections are outputted to slave stations 2, 2, 2. A master station 3 and three sets of slave stations 2, 2, 2 are connected through a main circuit optical fiber 9 and an auxiliary circuit optical fiber 10 and respective slave stations 2 output the obtained results of inspections to the main circuit optical fiber 9 to collect them into the master station 3. The master station 3 outputs the result of inspection to a personal computer 4. The personal computer 4 obtains the processing result of one unit of one monitor unit 1. Then, the personal computers 4 output the obtained processing results to the main circuit optical fiber 19 to collect them into a computer 14 and process all of informations from respective personal computers 4 systematically.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to a system for monitoring the status of power transmission and distribution lines in a plurality of substations, for example, and more specifically, it is capable of simultaneously monitoring the status of a large number of power transmission and distribution lines. Regarding power transmission and distribution line monitoring systems.

[Prior art]

Substations have a large number of power transmission and distribution lines that connect the power equipment and facilities within the station, and maintenance and management of each power transmission and distribution line is an important issue, and it is important to prevent accidents such as ground faults, breaks, and thermal damage. It is important to prevent accidents by detecting the signs when they occur, and to detect them early if they do occur.

[Problem that the invention seeks to solve]

However, since it takes a long time to inspect and monitor the condition of each of the many power transmission and distribution lines, it is currently impossible to carry out this process perfectly. There was a desire to develop a system that could simultaneously monitor.

The present invention was made in view of the above circumstances, and includes two optical lights for communication between a plurality of slave stations connected to various sensors that monitor the status of power transmission and distribution lines, and a master station connected to a personal computer. By having multiple monitoring units connected by fibers, and connecting the personal computer of each monitoring unit to the computer using two separate optical fibers for communication, it is possible to control a large number of power transmission and distribution lines. The purpose of the present invention is to provide a power transmission/distribution line monitoring system that can simultaneously monitor the status of the power transmission/distribution line.

[Means for solving problems]

A power transmission and distribution line monitoring system according to the present invention is a system for monitoring the state of a power transmission and distribution line that connects power equipment or facilities, in which each sensor is connected to a plurality of sensors provided to monitor the state of the power transmission and distribution line. a plurality of slave stations that collect test results from the slave stations; a master station that collects the test results from each slave station; a personal computer that processes the test results collected at the master station; and the slave station.

A plurality of monitoring units constituted by two optical fibers that transmit data between master stations, a computer that processes information from each of the personal computers, and the personal computer.

It is characterized by comprising two optical fibers for transmitting data between computers.

[Effect]

In the power transmission and distribution line monitoring system of the present invention, each sensor connected to the slave station obtains inspection results of the power transmission and distribution line. The slave station collects the test results obtained from each sensor and transmits them to the master station via an optical fiber. The personal computer processes the test results sent to the master station. Each personal computer transmits the obtained processing results to the computer via an optical fiber, and the computer processes the processing results comprehensively.

〔Example〕

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be specifically described below based on drawings showing embodiments thereof. FIG. 1 is a schematic diagram showing the configuration of a power transmission and distribution line monitoring system according to the present invention, and in the figure, 1 indicates a monitoring unit separately provided at each substation. Each monitoring unit 1 includes three slave stations 2, 2, 2, 1 master station 3, and 4 sensors for each slave station connected to each slave station 2, totaling 12 sensors 5,6°. 7.8, the personal computer 4 connected to the master station 3, and each slave station 2. Two optical fibers 9゜1 connecting the master station 3
Consists of 0.

Sensor 5 (6, 7, 8) is a sensor that detects a predetermined physical quantity, and is, for example, an active insulation diagnostic sensor.

It consists of an accident zone measurement sensor, a multi-point temperature measurement sensor, an accident point location sensor, a ground fault precursor discharge detection sensor, etc. sensor 5
(6, 7, 8) are sensor bodies 5a (6a, 7a, 8a) installed on power transmission and distribution lines, sensor bodies 5a
Sensor device 5b (6b, 7b) that detects the state of the power transmission and distribution line based on the output from (6a, 7a, 8a)
, 8b), and sensor body 5a (6a, 7a,
8a) and the sensor device 5b (6b, 7b, 8b).
c, 7c, 8c).

The signal obtained from the sensor body 5a (6a, 7a, 8a) is transmitted through an optical fiber or metal cable 5c (
6c.

7c, 8c) to the sensor device 5b (6b,
7b, 8b) and sensor device sb (6b
, 7b, 8b), the signals propagated are subjected to arithmetic processing, compared and evaluated with reference values input in advance, and the test results are output to the slave station 2.

The master station 3 and the three slave stations 2.2.2 are connected to two line optical fibers for communication consisting of polymer clad quartz core fibers (
Main line optical fiber9. They are connected by a side line optical fiber 10).

Each slave station 2 is equipped with a storage unit (not shown) for temporarily storing test results, and the test results are temporarily stored in the storage unit, and the test results are propagated through the main line optical fiber 9. Based on the transmission permission signal, this test result is outputted as an optical signal to the main line optical fiber 9, and is concentrated to the master station 3. The master station 3 outputs the test results collected from each slave station 2 to the personal computer 4. The personal computer 4 processes the input test results and obtains processing results with each monitoring unit 1 (each substation) as a minus unit.

The four computers 4 are connected by two line optical fibers (main line optical fiber 19, side line optical fiber 20) made of quartz-based optical fibers, and a is connected to a computer 14 which processes all information.

The personal computer 4 is equipped with a storage unit (not shown) that temporarily stores the processing results, and the obtained processing results are temporarily stored in the storage unit, and a processing result transmission permission signal is transmitted through the main line optical fiber 19. Based on this, the processing result is output as an optical signal to the main line optical fiber 19 and condensed to the computer 14. The computer 14 comprehensively processes all information from each personal computer 4.

As described above, the monitoring system of the present invention includes a plurality of communication small networks in which each monitoring unit 1 (each substation) is a unit and two line optical fibers 9 and 10 are used as propagation paths; The personal computers 4 of each monitoring unit 1 are connected to form one large communication network using two line optical fibers 19 and 20 as propagation paths.

In these networks, optical signals are normally propagated via main line optical fibers 9 and 19, but in the unlikely event that the optical fiber between adjacent slave stations or computers is cut, the side line optical fibers The monitoring system of the present invention is configured so that the optical signal is propagated using the fiber 10.degree. 20 (loopback method).

Next, the operation will be explained.

The sensor body 5a (6a, 7a, 8a) transmits a signal according to the state (predetermined physical quantity) of the power transmission and distribution line through an optical fiber or metal cable 5c (6c, 7c, 8c).
output to the sensor device 5b (6b, 7b, 8b)
is optical fiber or metal cable 5c (6c,
7c, 8c) is received, the received signal is arithmetic processed, compared and evaluated with a reference value, and the test result is output to the slave station 2. The slave station 2 stores this test result in its storage section.

When the slave station 2 receives the test result transmission permission signal propagated via the main line optical fiber 9, it outputs the test result stored in the storage section to the main line optical fiber 9. An optical signal indicating the test result is propagated through the main line optical fiber 9 and concentrated to the master station 3. The personal computer 4 processes the collected inspection results from each slave station 2, obtains processing results for each monitoring unit 1 (each substation), and stores the processing results in a storage section.

In each monitoring unit 1, each sensor 5°6.7.
8 (sensor devices 5b, 6b, 7b, 8b) preprocess the obtained signals, so the test results transmitted from the slave station 2 to the master station 3 are simple (for example, whether the maintenance status of the power transmission and distribution lines is normal or not). If a computer with a small capacity such as a personal computer is connected to the master station 3, these test results can be processed.

Upon receiving the processing result transmission permission signal propagated via the main line optical fiber 19, the personal computer 4 outputs the processing result stored in the storage section to the main line optical fiber 19. An optical signal indicating the processing result is propagated through the main line optical fiber 19 and condensed to the computer 14 .

The computer 14 comprehensively processes all the collected processing results and displays the contents of the comprehensive processing.

Therefore, by monitoring the overall processing content of the computer 14, it is possible to simultaneously monitor the status of power transmission and distribution lines at a plurality of substations.

Usually, as mentioned above, the main line optical fiber 9 (19)
An optical signal is propagated through. If the line optical fiber is cut between slave stations (between computers), the optical signal is propagated using the normal main line optical fiber 9 (19) and side line optical fiber 10 (20). .

This mechanism will be explained below by taking as an example a small network in which the inspection unit 1 is one unit.

FIG. 2 is a schematic diagram showing such a state, in which the main line optical fiber 9 and the side line optical fiber 10 between the two slave stations 2, 2 are cut. In such a case, two slave stations 2 that are not connected by line optical fiber 9.10
, 2, the main line optical fiber 9 and the side line optical fiber 10 are automatically connected to each other to form a new loop.

The optical signal is then propagated through this newly formed loop. As a result, even if the line optical fiber is cut, test results can be collected from the slave stations 2, 2 to the master station 3.

Note that this mechanism is exactly the same for the main line optical fiber 19 and the side line optical fiber 20 (large network) that connect the PCs 4, and if the line optical fiber is cut between the PCs, the inside of the PC will be damaged. At , the main line optical fiber 19 and the side line optical fiber 20 are automatically connected to form a new loop.

The reasons why non-silica optical fibers (polymer clad quartz core fibers) are used as communication optical fibers in small networks are 1. Although non-silica optical fibers are not suitable for long-distance transmission of optical signals, they are easy to handle. This is because on-site work is simple. Furthermore, the reason why silica-based optical fibers are used as communication optical fibers in large networks is that silica-based optical fibers can transmit large amounts of optical signals over long distances.

In this embodiment, a polymer clad quartz core fiber is used as the optical fiber in the small network, but other non-silica optical fibers such as multi-component glass fiber and plastic fiber may also be used.

〔effect〕

As detailed above, in the monitoring system of the present invention, the inspection results of power transmission and distribution lines obtained by a large number of sensors are
Since all the information is collected by a computer via a slave station, a master station, and a personal computer, it is possible to accurately monitor a large number of power transmission and distribution lines at the same time.

[Brief explanation of the drawing]

FIG. 1 is a schematic diagram showing the configuration of a power transmission and distribution line monitoring system according to the present invention, and FIG. 2 is a schematic diagram showing a state where a line optical fiber is partially cut in a monitoring unit. 1... Monitoring unit 2... Slave station 3... Master station
4...PC 5.6.7.8...Sensor 9,
19... Main line optical fiber 10.20... Side line optical fiber 24... Computer

Claims (1)

[Claims] 1. In a system for monitoring the status of power transmission and distribution lines that connect power equipment or facilities, the system is connected to a plurality of sensors provided to monitor the status of the power transmission and distribution lines, and each sensor performs an inspection. Multiple slave stations that collect results, a master station that collects test results from each slave station,
A computer that processes the test results collected at the master station, a plurality of monitoring units consisting of two optical fibers that transmit between the slave station and the master station, and a computer that processes information from each of the computers. A power transmission and distribution line monitoring system comprising: the personal computer; and two optical fibers for transmitting data between the computers. 2. The two optical fibers that transmit data between the slave station and the master station are non-silica optical fibers, and the two optical fibers that transmit data between the personal computer and the computer are quartz optical fibers.Claim 1 Transmission and distribution line monitoring system described in Section 1.