JP2002162431A - Fault-point orientation system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To facilitate patrol for maintenance and inspection by displaying on a map, a point where a fault has occurred. SOLUTION: This fault point orientation system is provided with a plurality of data collection terminals for collecting the amount of electricity on a transmission/distribution line, and a central unit for receiving data on the amount of electricity collected by the collection terminal and orienting a fault point near a data collecting terminal by using the collected data. Each collection terminal 600 is equipped with a GPS(global positioning system) reception part 64 and transmits positional information, acquired by reception part 64 together with the collected data on the amount of electricity to a central unit 701. The central unit 701 displays the position of the terminal existing on a map within a fault point orientation area, by using the positional information on the terminal existing near the fault point.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fault point locating system for locating a fault point using electric quantity data collected by a plurality of data collection terminals on a transmission and distribution line.

[0002]

2. Description of the Related Art In general, as a method for locating a fault in a transmission and distribution line, a data collection terminal device for taking in current and voltage is installed at both ends of a system or at a system branch point, and impedance calculation is performed using current and voltage at the time of occurrence of a fault. To determine the distance from each terminal device to the failure point, and to locate the failure point from the system surge propagation delay difference at the time of failure to each terminal device. There is also known a method in which a data collection terminal device is installed on a transmission line tower or the like, and a fault point is located for each installed terminal device from operation determination or collected current data.

In these conventional fault point location methods, sampling of the collected electric quantity data is synchronized with a synchronization time and a synchronization pulse obtained from an omnidirectional positioning system (GPS: global positioning system). In any of the conventional techniques described above, the conventional orientation output information is a distance starting from a point of a transmission line (for example, one end of the transmission line), for example, a kilometer display, or a tower number display immediately adjacent to a failure occurrence point. It has become.

[0004]

In the above-described method of locating by impedance calculation and the method of locating a system surge, the locating position is affected by the length and constant of the system, and there is a problem in locating accuracy. . In addition, in the method of installing a data collection terminal device for each tower, it is possible to perform high-precision orientation on a tower-by- tower basis by accurately detecting system faults at each terminal device. It is difficult to search for and identify a specific place (surrounding terrain, the nearest road) simply by displaying the distance and the tower number. In particular, in a complicated system configuration such as a power distribution system, searching for a failure occurrence point and specifying work are complicated and require much labor.

Accordingly, the present invention uses position information and known position information of a data collection terminal device obtained by GPS,
By displaying the position of the terminal device on the map in cooperation with the map software, it is possible to visually and intuitively recognize the location of the failure, and to provide a failure point location system that facilitates subsequent maintenance and inspection work. Is what you do.

[0006]

In order to solve the above-mentioned problems, the invention according to claim 1 comprises a plurality of data collection terminal devices for collecting electricity amounts on transmission and distribution lines, and an electricity amount by these data collection terminal devices. And a central unit for locating a failure point near the data collection terminal device using the collected data, wherein the data collection terminal device has a GPS receiving unit, The position information acquired by the receiving unit is transmitted to the central device together with the collected data, and the central device uses the position information of the data collection terminal device existing near the failure point to determine the position of the data collection terminal device. This is displayed on the map of the fault point locating range.

According to a second aspect of the present invention, a plurality of data collection terminal devices for collecting the amount of electricity on a transmission and distribution line, and electricity collection data transmitted by these data collection terminal devices,
In a failure point location system including a central device that locates a failure point in the vicinity of the data collection terminal device using the collected data, the central device holds in advance position information of each data collection terminal device, The position of the data collection terminal device is displayed on a map of the failure point locating range using known position information on the data collection terminal device existing near the failure point.

[0008] The invention described in claim 3 is claim 1 or 2.
In the failure point location system according to the above, the central device includes:
An abnormality of the data collection terminal device is monitored based on collected data transmitted from each data collection terminal device, and a position of the data collection terminal device in which the abnormality is detected is displayed on a map of a fault point locating range.

[0009]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is a system configuration diagram to which the present embodiment is applied. In FIG. 1, 100, 200, and 300 are substations at A-end, B-end, and C-end, respectively, 401 and 402 are transmission and distribution lines, 501 to 507 are towers, and 601 to 607 are data collection terminals installed in each tower. The device 701 is a central device (fault point locating device) installed at a remote monitoring station.

[0010] The data collection terminal devices 601 to 607
Are connected by a wired transmission line or a wireless transmission line such as a low-power radio, a mobile phone, or a PHS.
01, 402, and the collected data can be added to the collected data transmitted from the previous stage and transmitted to the terminal device at the subsequent stage. The data is transmitted to 701 and aggregated. Further, the terminal devices 601 to 607 can acquire high-accuracy time information from artificial satellites using GPS, and can synchronize the collected data using the time information.

That is, if each terminal device adds the time information to the electric quantity at the time of collecting the electric quantity and collects it in the central apparatus 701, the central apparatus 701 can correct the timing difference between the collected data, that is, the time difference. It is. For example, when the data collected by the first and second terminal devices are data collected at times (t ₁ , t ₂ ), respectively, the time difference (Δt = t ₂ −t ₁ ) and the amount of electricity Using the frequency f and the electric quantity of the second terminal device, 2πf △ t [rad] (π
By performing phase correction (addition) of pi.
It can be handled as if the quantity of electricity of the terminal device is as if collected at time t _1. Such a technique is established, for example, in Japanese Patent Application Laid-Open No. 6-338037, and if these techniques are used, phase synchronization of an electric quantity vector can be performed between a plurality of terminal devices.

Here, the accurate positions of the respective terminal devices can be detected by the GPS provided in each of the terminal devices 601 to 607, and such position information is transmitted to the central device 701 together with the collected data. Each of the terminal devices 601 to 607
Is known, it is possible to pre-register these position information in the memory in the central device 701. In this case, only the time information by GPS is added to the collected data and transmitted. Is enough.

FIG. 2 shows the configuration of the terminal devices 601 to 607. Here, it is assumed that all the terminal devices have the same configuration and are denoted by reference numeral 600. In FIG. 2, reference numeral 61 denotes a current sensor for detecting a current of the system,
63 is a system input unit for converting analog current data into a digital signal, 62 is a GPS antenna, 64 is a GPS receiving unit for acquiring time information and position information, and 65 is current system data and GPS from the system input unit 63. An arithmetic unit for detecting a fault in the system and monitoring the abnormality of the data collection terminal device using the time information and the position information by the receiving unit 64, and a transmission unit 66 for transmitting collected data, time information, position information, and the like.

The principle of the fault point locating in this embodiment is as follows. When a difference current equal to or more than a predetermined value is detected in two consecutive sections, a current collecting point (data collection terminal device) sandwiched between these two sections is detected. The vicinity is determined as a failure point. For example, in FIG. 3A, the n-th tower, the n + 1-th tower,
A data collection terminal device is installed in..., And both ends of the sections L ₁ and L ₂ before and after the n + 1st tower and the section (L ₁ +
If a difference current equal to or more than a certain value is detected at both ends of L ₂ ), the central unit 701 determines that the fault point is near the n + 1st tower. If such a locating method is adopted, point determination is performed using the tower position, which is the actual failure occurrence point, as the locating result, and there is an advantage that the locating accuracy is improved.

In particular, in an actual system fault, a simple fault occurs more frequently than a multipoint fault, and thus the above-described locating method is effective. In addition, even when an eccentric multiple fault has actually occurred, in conducting a patrol of the electric wire, first, a specific steel tower is patroled in accordance with the above-mentioned orientation results. It is sufficient to shift to patrol of two sections sandwiching.

As shown in FIG. 3 (b), the data collection terminal devices of the n-th tower and the (n + 2) -th tower are normal,
When there is a defect in the current input portion of the terminal device of the n + 1st pylon sandwiched between these, even if a difference current of a certain value or more is detected at both ends of the sections L ₁ and L ₂ , the section (L ₁ + L ₂ )
No difference current is detected at both ends. Information indicating that the terminal device of the n + 1st tower is abnormal is transmitted to the central device 701 based on the presence or absence of such a difference current detection.

The collected data (current data), time information, and position information by each of the terminal devices 601 to 607 are transmitted to the central device 701 via a wired or wireless transmission path and are collected. The central device 701 includes the terminal devices 601-607.
And locating the fault point as the position of the terminal device in accordance with the above-described locating principle. At the same time, the positions of the normal (healthy) terminal device and the abnormal terminal device are also specified. In locating the fault and specifying the positions of the normal terminal device and the abnormal terminal device, the collected position data and the aggregated position information are used.

FIG. 4 shows the display device 70 in the central device 701.
It is a conceptual diagram for displaying the fault point (position of the terminal device which detected the fault point), the normal terminal device, and the position of an abnormal terminal device in 1A. The position information of the normal terminal device and the abnormal terminal device are input to the display device 701A together with the position information of the terminal device corresponding to the failure point, and the information is input to the position search / display control unit 702. On the other hand, reference numeral 703 denotes a map database, which holds a ground map or the like in a fault point locating range as raster information and a road or town map as vector information.

Recently, a geographic information system (GIS: Geographic Information System) has been established as a technique for superimposing various data on a map, displaying the data on a computer screen, and enabling analysis and quick judgment. GIS-compatible map applications are also becoming popular. An application technique of the GIS includes a method of specifying a position based on position information (latitude / longitude, etc.) from a wide range of map information. In the present embodiment, a geographical condition around the terminal device (for example, , Road, city, etc.) are displayed together with the position of the terminal device.

That is, the position search / display control unit 702 refers to the map in the map database 703 for the input position information of each terminal device using the well-known GIS, and uses the terminal device (the failure point detection terminal device, The position of the normal terminal device, the abnormal terminal device) on the map is searched, and image data in which these terminal devices are superimposed on the surrounding geographical situation is output. Then, the image data is displayed on the display unit 704. Here, the position information of each terminal device input to the position search / display control unit 702 is, for example, the latitude / longitude or altitude of the installation location of the terminal device, but other information is used on the map using the position information of the terminal device. May be made to correspond one to one. FIG. 5 shows an example of the display screen of the display unit 704, in which the positions of the fault point detecting terminal device, the normal terminal device, and the abnormal terminal device are displayed on the map in a superimposed manner. Note that the broken lines in the display screen correspond to transmission and distribution lines.

According to the present embodiment, it is possible to visually and intuitively grasp a fault point and a place where an abnormal terminal device is located, and specific installation of the terminal device which cannot be obtained by simply displaying the distance and the tower number. Since the location and the surrounding geographical conditions are displayed, patrol for maintenance and inspection is facilitated.

Although the above corresponds to the first and third embodiments of the present invention, since each terminal device is fixed to a steel tower (or power transmission line) as described above, each position information is known and invariable. is there. Therefore, if these pieces of position information are registered in advance in the memory of the central device 701 and are used when each terminal device is displayed on a map, acquisition and transmission of position information by GPS becomes unnecessary, and each terminal device becomes unnecessary. It is possible to omit the position information acquisition / registration means in the device and to simplify the transmission contents. An example in which the known position information of the terminal device is used in this way corresponds to the second embodiment of the present invention.

[0023]

As described above, according to the present invention, the point of occurrence of a failure and the location of an abnormal terminal device are displayed on a map. Identifying and recognizing becomes easier, and work efficiency of maintenance and inspection is also improved.

[Brief description of the drawings]

FIG. 1 is a system configuration diagram to which an embodiment of the present invention is applied.

FIG. 2 is a configuration diagram of a data collection terminal device.

FIG. 3 is a diagram for explaining the presence / absence of detection of a current vector and a difference current when a system failure occurs and an abnormality occurs in a terminal device.

FIG. 4 is a conceptual diagram for displaying a position of each terminal device in a central device.

FIG. 5 is a diagram illustrating a display example on a central device.

[Explanation of symbols]

 100, 200, 300 Substations 401, 402 Transmission and distribution lines 501 to 507 Steel towers 601 to 607 Data collection terminal device 701 Central device (fault point locating device) 701A Display device 702 Position search / display control unit 703 Map database 704 Display unit 61 Current sensor 62 Antenna 63 System input unit 64 GPS receiving unit 65 Operation unit 66 Transmission unit

Continuation of the front page (72) Inventor Koji Yutani 1-1, Tanabe-Nita, Kawasaki-ku, Kawasaki-shi, Kanagawa Prefecture F-term in Fuji Electric Co., Ltd. (reference) 2G033 AA02 AB01 AC02 AC04 AD14 AD15 AE06 AG00

Claims (3)

[Claims] 1. A plurality of data collection terminal devices for collecting the amount of electricity on a transmission and distribution line, and electricity amount collection data transmitted by these data collection terminal devices is transmitted. A fault location system including a central device for locating a failure point, wherein the data collection terminal device includes a GPS receiving unit;
The position information acquired by the PS receiving unit is transmitted to the central device together with the collected data, and the central device uses the position information of the data collection terminal device existing near the failure point to determine the position of the data collection terminal device. Is displayed on a map of a fault point locating range. 2. A plurality of data collection terminal devices for collecting an amount of electricity on a transmission / distribution line; electricity amount collection data transmitted by these data collection terminal devices; A central device for locating a failure point, wherein the central device previously holds the position information of each data collection terminal device, and has a known position related to the data collection terminal device existing near the failure point. A location of the data collection terminal device is displayed on a map of a failure point location range using the position information of the data collection terminal device. 3. The fault locating system according to claim 1, wherein the central device monitors an abnormality of the data collection terminal device based on collected data transmitted from each data collection terminal device,
A fault point location system, wherein a position of a data collection terminal device in which an abnormality is detected is displayed on a map of a fault point location range.