JPH09189774A - Lightning observation system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To contribute to the planning of insulation and lightning countermeasures of a transmission/transformation facility by detecting a thundercloud quickly utilizing a lightning radar and feeding power to an observing section only when it is required thereby observing the actual state of lightning stroke current. SOLUTION: Upon detecting a thundercloud, a lightning radar 90 delivers a signal to a power supply controller 70 through an interface 80 and then the controller 70 delivers a power ON command to a central observation system 60. The power ON command is further delivered on a mobile telephone line to a data transmission terminal 50 thence to a lightning stroke current waveform observation unit 20 through a data collection terminal 30. The unit 20 delivers a power supply control signal from a photoelectric converting section to each circuit and measures and records the lightning stroke current waveform. A lightning stroke current waveform data is then delivered to the terminal 30 thence delivered, along with a lightning stroke time data, to the system 60 through the terminal 50. Since a thundercloud is detected quickly and the actual state of lightning stroke current is observed, the inventive system contributes to the planning of insulation and lightning countermeasures of a transmission/transformation facility.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention detects a thundercloud using an existing power company's lightning radar network system,
The present invention relates to a lightning observation system in which the actual condition of a lightning current is accurately and efficiently observed, recorded and transmitted by an observation facility to which main power is supplied at that time.

[0002]

2. Description of the Related Art Conventionally, the values and waveforms of voltage, current, impedance, etc. when a lightning accident occurs in a transmission tower have been conducted for the purpose of insulation design of power transmission and transformation equipment and lightning protection measures. There is provided a system for detecting and collecting these observation data from a remote place by wire or wireless communication (see JP-A-62-48231 and JP-A-3-270650). In addition, for different purposes, it is also required to promptly detect the occurrence of a thundercloud and promptly provide accurate lightning information in order to ensure the safety of a player on a golf course, for example.

[0003] Here, thunderclouds generally occur frequently in remote areas of the mountains, their locations are wide, and their times of occurrence are irregular. Therefore, if the observation accuracy is to be increased as much as possible, many difficulties and inconveniences are involved in transportation and installation of the observation device, securing of its power source, control of observation timing, transmission of observation data, and the like.

In particular, when a commercial power source cannot be secured as the power source for the observation device and the battery has to be used, the battery has a life of about one month, so the personnel are frequently visited to the site to replace the battery. Must be dispatched, and the unit price of the battery is extremely high. The above-described steel tower information collecting device described in JP-A-62-48231 has such a problem.

On the other hand, when a storage battery is used as the power source of the observation device, as shown in JP-A-3-270650, power is supplied from the storage battery only to a pager or the like for obtaining a start signal during non-observation. It is devised to extend the life of the storage battery by turning off the main power supply of the observer and turning on the main power supply of the storage battery only at the time of observation to supply power to the microcomputer and the like. However, this conventional technique generally has a problem that the circuit configuration tends to be complicated.

Another conventional technique is to extend the life of the storage battery by detecting an abnormality in the electric field distribution in the air due to the occurrence of a thundercloud with a sensor and turning on the main power source of the observation device. The disadvantage is that the entire device is expensive.

Further, as described in JP-A-3-270650, it is also possible to use a solar cell together with a storage battery, but the surface of the solar cell substantially acts as an antenna during a lightning strike. As a result, inductive noise may enter the observation device and cause an observation failure. Therefore, it is not a good idea to use a solar cell as a power source for the observation device.

[0008] In addition, the lightning current usually has various characteristics such as its peak value and duration, and the data of the peak value of the lightning current waveform and the wave front steepness are insufficient. It is difficult to design and manufacture detection equipment,
These problems have made conventional lightning observation systems insufficient in detection / observation accuracy and price-performance ratio.

The present invention has been made to solve the above problems, and its purpose is to accurately and efficiently observe the actual state of lightning current, and to provide insulation / lightning protection measures and safety measures for power transmission and transformation equipment. Another object of the present invention is to provide an economical lightning observation system capable of transmitting observation data to a remote place, detecting the occurrence of a thundercloud efficiently and prolonging the life of the power supply battery of the observation unit.

[0010]

In order to achieve the above object, the present invention provides a lightning radar for detecting a thundercloud, a power supply control device for outputting a power-on command when a thundercloud is detected by the lightning radar, and an output from the power supply control device. The central observation device that receives and records the observed lightning current waveform data and lightning time data while relaying and transmitting the specified power-on command, the current sensor installed in the transmission tower, and the output of the current sensor Lightning current waveform observation device for storing the lightning current waveform data measured based on the, and the lightning current waveform data stored in the lightning current waveform observation device and the lightning time data based on the standard clock by the recovery command from the central observation device. And a data collection terminal that temporarily stores these data, and a transmission command from the central observation device temporarily records them in the data collection terminal. It is equipped with a data transmission terminal that transmits the lightning current waveform data and the lightning stroke time data to the central observation device, and strikes the power-on command sent from the power control device via the central observation device, the data transmission terminal and the data collection terminal. When the current waveform observing device receives the lightning current waveform observing device, the main power supply is turned on. In addition,
Communication between the central observing device and the data transmission terminal is preferably performed using a mobile communication line.

[0011]

In the present invention, the main power source of the lightning current waveform observing device is normally turned off, and only when a thundercloud is generated by the lightning radar, the main power source is turned on by a command from the power source control device to start the measurement and recording operation. Therefore, the battery is consumed less and the frequency of replacement is also reduced. In addition, the observation data is transmitted from the transmission tower to a central observation device located at a remote location through a mobile communication line.

[0012]

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 diagram showing the overall configuration of the embodiment. In the figure, 100 is, for example, a 500 kV power transmission tower, and two current sensors 13 composed of a lightning rod 11 and an air core Rogowski coil 12 at both ends of the tower.
Is arranged.

The detection outputs of the current sensor 13 are added and input to the lightning current waveform observation device 20. The lightning current waveform observing device 20 is for measuring the lightning current waveform detected by the current sensor 13 and recording it in an internal memory card. The detailed configuration will be described later.

A data recovery terminal 30 is connected to the lightning current waveform observation device 20 by an optical fiber cable. The data collection terminal 30 uses the lightning current waveform data stored in the lightning current waveform observing device 20 and the lightning stroke time data stored in the standard clock 40 as a central observing device 60 described later.
It is automatically read out in response to a recovery command from the computer, temporarily stored, and then transmitted to the data transmission terminal 50 in response to a subsequent transmission command. Here, the lightning current waveform data and the lightning time data can be manually collected.

The data recovery terminal 30 also has a function of managing and relaying signal transmission between the lightning current waveform observing device 20 and the standard clock 40, and the timing of the lightning stroke detected by the lightning current waveform observing device 20 is standard. The time of the lightning stroke can be confirmed by sending it to the clock 40, and the time of the internal clock of the lightning current waveform observing device 20 can be further calibrated based on the standard clock 40. That is, the standard timepiece 40 maintains time accuracy by receiving radio waves at the timing of lightning and calibrating the time. Then, at the time of a lightning stroke, the trigger signal sent from the lightning current waveform observing device 20 is received via the data collection terminal 30 to temporarily store the lightning stroke time, and this lightning stroke time data is output by the collection instruction from the data collection terminal 30. To do.

The data transmission terminal 50 receives a power-on command from the power supply control device 70 via the central observation device 60 by wireless communication using a mobile communication line such as a pager or a mobile phone, and receives the data collection terminal 30. It is sent to the lightning current waveform observing device 20 via. The data transmission terminal 50 may be integrated with the data collection terminal 30. Furthermore, if there is no restriction on the size, the mounting location, etc., it is possible to integrate the lightning current waveform observation device 20 as well. In addition, the lightning stroke current waveform data and the lightning stroke time data collected by the data collection terminal 30 are transmitted by wireless communication according to a transmission command from the central observation device 60.

The central observation device 60 transmits and receives data and control signals between the data transmission terminal 50 and the power supply control device 70 as described above, while recording and displaying lightning current waveform data and lightning time data. To do. Power control device 70
Is connected to the network of the lightning radar 90 of the electric power company via the interface 80, and determines the power on / off by a predetermined algorithm based on the position and intensity of the thundercloud detected by the lightning radar 90, and the power on command. To the central observing device 60.

Next, FIG. 2 shows the configuration of the lightning current waveform observing device 20. In the figure, an amplifier 201 is connected to the current sensor 13, and a high-speed transient recorder unit 202 for converting a lightning current waveform into a digital signal and storing the digital signal is connected to the output side of the amplifier 201.

The photoelectric conversion unit 203 includes a light emitting diode (L
ED) and two photodiodes (PD) each are provided, and the trigger signal or data from the high speed transient recorder unit 202 is converted into an optical signal and transmitted to the data collection terminal 30, and further, the data collection terminal 30. The optical signal sent from the device is photoelectrically converted and output to the power supply circuit 204.

A battery 205 is connected to the power supply circuit 204, and the power supply circuit 204 receives a power supply control signal (power-on command) from the photoelectric conversion unit 203. 20
A predetermined power supply voltage suitable for each logic circuit and analog circuit inside is generated and supplied.

In the present embodiment configured as described above,
If the thunder radar 90 detects a thundercloud, the interface 8
A signal is sent to the power supply control device 70 via 0, and the power supply on command is sent from the power supply control device 70 to the central observation device 60. This power-on command is sent from the central observation device 60 to the data transmission terminal 50 via the mobile communication line, and is also sent to the photoelectric conversion unit 203 of the lightning current waveform observation device 20 via the data collection terminal 30.

Thus, as described above, the photoelectric conversion unit 203
A power supply control signal is output from the power supply circuit 204, and power is supplied to each circuit in the lightning current waveform observation apparatus 20 by the operation of the power supply circuit 204, so that the lightning current waveform can be measured and recorded.

When collecting the accumulated lightning current waveform data and transmitting it to the central observing device 60 side, a transmission command from the central observing device 60 is transmitted via the data transmitting terminal 50 and the data collecting terminal 30. The data is sent to the conversion unit 203 and transmitted to the high speed transient recorder unit 202. The high-speed transient recorder unit 202 reads the internally recorded lightning current waveform data, converts it into an optical signal by the light emitting diode of the photoelectric conversion unit 203, and transmits it to the data collection terminal 30. Then, it is sent to the data transmission terminal 50 together with the lightning stroke time data, and then the central observation device 6
It is transmitted to 0.

3 and 4 show the current sensor 1 of this embodiment.
3 shows the performance evaluation test results of the observation unit composed of the lightning current waveform observation device 20 and FIG. 3, and FIG. 3 shows the input / output (linearity) characteristic of a large current, and FIG. 4 shows the rise response characteristic (frequency characteristic). Shows. In FIG. 3, it was confirmed that currents up to ± 300 kA can be measured with an accuracy within ± 10%. Further, in FIG. 4, the oscillating current is applied to measure the waveform rise time and the peak value, and the rise time is 1
It is considered that the input waveform can be reproduced almost accurately with a waveform up to μs. In addition, in the vibration waveform of 1MHz-
It seems to have sufficient bandwidth without falling below 3 dB.

FIG. 5 shows actual lightning data obtained by field verification according to this embodiment. This verification was performed by installing this device on a 66 kV transmission tower.
It has been proved that the lightning strike current waveform observing device 20 can accurately observe and record actual lightning without any abnormality.

[0026]

As described above, according to the present invention, the lightning radar of an existing electric power company is used to quickly detect a thundercloud, and power is supplied to the observation unit only when necessary to accurately determine the actual state of the lightning current. It can be observed in. For this reason, it is possible to contribute to the planning of insulation / lightning protection measures and safety measures for power transmission and transformation equipment, and it is possible to extend the battery life of the observation part and realize an economical and easy-to-maintain lightning observation system.

[Brief description of the drawings]

FIG. 1 is an overall configuration diagram of an embodiment of the present invention.

FIG. 2 is a configuration diagram of a lightning current waveform observation apparatus according to an embodiment.

FIG. 3 is a diagram showing input / output characteristics in the embodiment.

FIG. 4 is a diagram showing a rising response characteristic in the embodiment.

FIG. 5 is a diagram showing actual lightning data obtained by field verification according to the embodiment.

[Explanation of symbols]

 11 Lightning Injector 12 Rogowski Coil 13 Current Sensor 20 Lightning Current Waveform Observation Device 30 Data Collection Terminal 40 Standard Clock 50 Data Transmission Terminal 60 Central Observation Device 70 Power Control Unit 80 Interface 90 Lightning Radar 100 Transmission Tower 201 Amplifier 202 High Speed Transient Recorder Unit 203 Photoelectric conversion unit 204 Power supply circuit 205 Battery

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Mochizuki Higashi Kanagawa Prefecture Yokohama City Tsurumi Ward 4-1, Egasaki-cho Electric Power Technology Laboratory (72) Inventor Kazuhiko Mizumoto 1 Yurakucho, Chiyoda-ku, Tokyo 7-1-1 Toko Electric Co., Ltd. (72) Inventor Hiroro Wakishima 1-17-1 Yurakucho, Chiyoda-ku, Tokyo Toko Electric Co., Ltd. (72) Hirofumi Fujioka 1-chome, Yurakucho, Chiyoda-ku, Tokyo 7-1 Toko Electric Co., Ltd. (72) Inventor Masanori Matsuoka 1-7-1, Yurakucho, Chiyoda-ku, Tokyo Toko Electric Co., Ltd. (72) Toshiyuki Hanawa 1-7, Yurakucho, Chiyoda-ku, Tokyo No. 1 Toko Electric Co., Ltd. (72) Inventor Kiyoshi Mizuno 1-17-1 Yurakucho, Chiyoda-ku, Tokyo Toko Electric Co., Ltd. (72) Inventor Motoki Maruyama 1-7-1 Yurakucho, Chiyoda-ku, Tokyo Toko Electric Co., Ltd. (72) Inventor Yasuhiro Shiraishi 1-1-7, Yurakucho, Chiyoda-ku, Tokyo Toko Electric Co., Ltd.

Claims (2)

[Claims] 1. A lightning radar that detects a thundercloud, a power supply control device that outputs a power-on command when a thundercloud is detected by the lightning radar, a power-on command output from the power supply control device that is relayed and transmitted, and observed. A central observation device that receives, records, and displays lightning current waveform data and lightning time data, a current sensor installed on the transmission tower, and a lightning current waveform that stores the lightning current waveform data measured based on the output of the current sensor Observing device, and a recovery command from the central observing device, data for retrieving the lightning current waveform data stored in the lightning current waveform observing device and the lightning time data based on the standard clock, and temporarily storing these data. The lightning current waveform data and the lightning time data temporarily stored in the data collection terminal are transmitted by the collection terminal and the transmission command from the central observation device. It is equipped with a data transmission terminal that transmits to the central observing device, and when the lightning current waveform observing device receives the power-on command sent from the power supply control device via the central observing device, the data transmitting terminal and the data collecting terminal, this lightning current A lightning observation system characterized by turning on the main power of the waveform observation device. 2. The lightning observation system according to claim 1, wherein communication between the central observation device and the data transmission terminal is performed using a mobile communication line.