JP2003047173A - Thunderbolt information offering method, thunderbolt information offering system, and central device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a thunderbolt information offering system, which allows offering not only simply thunderbolt forecast, but also influence on client's facilities by thunderbolt by quantitatively calculating. SOLUTION: Transmission and distribution lines which are influenced by thunderbolt are extracted from a transmission and distribution line database which registers the transmission and distribution lines corresponding to location information based on forecasted thunderbolt location information (S102), and the thunderbolt intensity of each location of the extracted transmission and distribution lines, based on the forecasted thunderbolt location information and thunderbolt intensity information, and lighting resistance characteristics of the lighting-resistant facilities provided with the extracted transmission and distribution lines (S103 and S104). Failure occurrence rate of each location is calculated, based on the calculated thunderbolt intensity and the lighting resistance characteristic (S107). The thunderbolt information including the calculated failure occurrence rate is offered (S1011), by extracting clients who utilize the extracted transmission and distribution lines, from a client database, which registers information of clients who utilize transmission and distribution lines, by corresponding to the transmission and distribution lines (S108).

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a lightning strike information providing method and a lightning strike information providing system for providing a lightning strike information including predicted lightning strike position information and lightning strike intensity information to a terminal device connected from a central device through a communication network. In particular, the present invention relates to a lightning strike information providing method, a lightning strike information providing system, and a central device which provide a customer with the probability of an accident caused by a lightning strike as lightning strike information.

[0002]

2. Description of the Related Art Since a lightning strike may cause a fatal accident, a power outage, a momentary voltage drop (hereinafter referred to as a momentary voltage drop), etc.
Attempts have been made to predict the intensity and location of lightning in consideration of past lightning conditions. Further, in recent years, a technique for providing the predicted lightning strike information to a golf course, a factory, etc. has been disclosed.

Japanese Patent Application Laid-Open No. 200-2000 is related to such a technique.
Lightning Prediction System and Central Research Institute of Electric Power Industry, page 235 (Research Report: 175
3030 Transmission and distribution line lightning protection design guidebook Central Research Institute of Electric Power Industry, Power Technology Research Institute, March 2, 1976
The lightning prediction system disclosed in the 5th (issued on the 5th) is known (hereinafter represented by a lightning prediction system).

FIG. 16 is a schematic diagram showing the structure of a conventional lightning strike forecasting system. In the figure, A is an altitude of 5,000 m to 10,000 m
It is an antenna that irradiates a thunder cloud T located at a radio wave of 5,000 MHz band and captures the reflected radio wave. The signal related to the reflected radio wave captured by the antenna is the computer 1
01, and the computer 101 predicts the position, time, intensity, and the like at which a lightning strike occurs based on the output signal. At this time, the lightning strike position, the lightning strike time, and the lightning strike intensity are calculated after correction by referring to the lightning strike database 101D that has accumulated past lightning strike data.

The lightning strike information such as the calculated lightning strike position, lightning strike time, and lightning strike intensity is transmitted to the terminal devices 102, 102, 102, ... Connected via the communication network N. As the lightning strike information, a lightning strike position, a lightning strike time, a lightning strike intensity, etc. are displayed as illustrated. As a result, accidents can be prevented in advance by taking measures such as calling for the suspension of play at a golf course and switching to an emergency power source at a factory or the like.

[0006]

In a factory that manufactures cathode ray tubes, glass, etc., blackouts and momentary drops affect the manufacturing process, and a large number of defective products are manufactured. Such damage may amount to several hundred million yen. However, conventional lightning strike forecasting systems simply
Only the lightning strike time or the intensity of lightning strike is provided, and it is necessary for the factory or the like to judge the possibility of an accident such as a voltage sag.

Whether or not an accident such as a power failure or an instantaneous dip occurs in the event of a lightning strike is determined by various factors such as the line type of the power transmission and distribution line, the type of insulator, the distance from the lightning strike position, and the topography. However, there is a problem that it is extremely difficult for the customer to make the judgment.

Further, the power transmission / distribution line is provided like a branch of a tree in each direction around the power plant or the substation to provide electricity to each customer. When an accident occurs at a certain place, other customers who use the power transmission and distribution line are also likely to have an accident as well, but conventionally, lightning strike information is provided independently of this. However, it was difficult to say that it provides useful lightning strike information to customers.

The present invention has been made in view of such circumstances, and an object of the present invention is to provide a customer who uses a power transmission and distribution line affected by a lightning strike with lightning strike information to prevent an accident. A lightning strike information providing method, a lightning strike information providing system, and a central apparatus capable of efficiently providing lightning strike information to customers who belong to the same high-risk transmission and distribution line.

Another object of the present invention is to calculate the lightning strike intensity at each point of the power transmission and distribution line, and based on the calculated lightning strike intensity and the lightning resistance characteristic of the lightning protection equipment provided in the power transmission and distribution line, a power failure at each point.・ By calculating the incidence of accidents such as instantaneous voltage drops and providing them to customers, it is not limited to mere lightning strike prediction,
A lightning strike information providing method and a lightning strike information providing system capable of quantitatively calculating and providing the influence of a lightning strike on a customer's facility.

Further, another object of the present invention is to provide a lightning strike information providing system capable of providing a more accurate accident rate by appropriately correcting the accident rate according to the facility operated by the customer. To do.

[0012]

A lightning strike information providing method according to a first aspect of the present invention is a lightning strike information providing method for providing lightning strike information including predicted lightning strike position information and lightning strike intensity information, based on the predicted lightning strike position information. , The step of extracting the transmission and distribution line affected by lightning from the transmission and distribution line database in which the transmission and distribution line is registered corresponding to the position information, and the information of the customer who uses the transmission and distribution line in association with the transmission and distribution line. It is characterized by comprising a step of extracting a customer who uses the extracted transmission and distribution line from the registered customer database, and a providing step of providing lightning strike information to the extracted customer.

The lightning strike information providing system according to the second invention is
In a lightning strike information providing system for providing lightning strike information including predicted lightning strike position information and lightning strike intensity information to a terminal device connected from a central device through a communication network, the central device is based on the predicted lightning strike position information, Registers the means for extracting transmission and distribution lines affected by lightning from the transmission and distribution line database in which the transmission and distribution lines are registered in correspondence with the position information, and the information of customers who use the transmission and distribution lines in association with the transmission and distribution lines. From the customer database that has been extracted, means for extracting a customer who uses the extracted power transmission and distribution line, and transmission means for transmitting lightning strike information to the terminal device related to the extracted customer, wherein the terminal device receives the transmitted lightning strike. It is characterized in that it comprises means for outputting information.

The lightning strike information providing system according to the third invention is
2nd invention WHEREIN: The said central device is based on the predicted lightning strike position information and lightning intensity information, and the lightning strike characteristic of the lightning protection equipment with which the said power transmission and distribution line is equipped, The lightning intensity of each point of the said transmission and distribution line extracted. And a means for calculating the accident rate at each point based on the calculated lightning intensity and lightning resistance characteristics, and the transmitting means transmits the lightning information including the calculated accident rate. It is characterized in that it is configured as follows.

The lightning strike information providing system according to the fourth invention is
In the third invention, the customer database is registered with equipment information on equipment operated by a customer, and the central device further comprises means for correcting the accident rate based on the equipment information. To do.

The central device according to the fifth aspect of the present invention provides the lightning strike information including the predicted lightning strike position information and the lightning strike intensity information to the terminal device connected through the communication network to the predicted lightning strike position information. Based on this, a means for extracting the transmission and distribution lines affected by lightning from the transmission and distribution line database in which the transmission and distribution lines are registered corresponding to the location information, and the customer who uses the transmission and distribution lines in association with the transmission and distribution lines. It is characterized by comprising means for extracting a customer who uses the extracted transmission and distribution line from a customer database in which information is registered, and transmission means for transmitting lightning strike information to a terminal device related to the extracted customer.

In the first invention, the second invention, and the fifth invention, the central unit predicts a lightning strike by a known method, or receives the lightning strike information predicted by another computer and stores the content thereof. To do. The lightning strike information includes lightning strike position information indicating a predicted lightning strike position, time, expected direction of thundercloud, speed, etc., and lightning strike intensity information indicating a predicted lightning current. When the central unit predicts or stores lightning strike information, based on the predicted lightning strike position information,
A transmission / distribution line affected by lightning is extracted from the transmission / distribution line database in which the transmission / distribution line is registered corresponding to the position information.

Then, the customer who uses the extracted transmission and distribution line is extracted from the customer database in which the information of the customer who uses the transmission and distribution line is registered in association with the transmission and distribution line. Then, the lightning strike information is transmitted to the extracted terminal device of the customer. As a result, the customer's terminal device affected by lightning strikes,
The lightning strike information is output. As described above, when there is a lightning strike, there is a high possibility that an accident will occur in the customer's equipment that uses the power transmission and distribution lines in the vicinity of the lightning strike. It is possible to obtain useful lightning strike information.

According to the third aspect of the invention, since the lightning strike intensity varies according to the distance from the lightning strike position and the lightning resistance characteristics of the lightning protection equipment provided in the power transmission and distribution line, the lightning strike position information and the lightning strike intensity information of the predicted lightning strike information are obtained. And the lightning strike intensity at each point of the power transmission and distribution line is calculated based on the lightning resistance characteristics of the lightning protection equipment included in the extracted power transmission and distribution line.

The lightning resistance is based on the type of transmission / distribution line (for example, 6k).
V- ₅₀₀ kV), lightning impulse flashover voltage V _{50 of} lightning protection equipment, whether or not the line is at the end, grounding interval of the lightning protection equipment, ground resistance value, power transmission / distribution line exists in urban area, or exists on bedrock Its characteristics are determined by various factors such as whether it is along a mountain ridge.

Specifically, the lightning intensity (voltage value or current value at each point) at each point of the power transmission and distribution line is determined by the lightning current, the ground clearance of the line conductor, the distance between the line and the lightning strike point, and the ground resistance of the lightning protection facility. Calculate based on the value.

Further, the probability of flashover occurring in the lightning protection equipment is calculated based on the calculated lightning intensity and lightning resistance characteristics at each point of the transmission and distribution line. In other words, even if there is a lightning strike, if the lightning resistance of the power transmission and distribution line is strong, the possibility of flashover occurring in the lightning protection equipment is reduced, and as a result, accidents such as power outages and voltage dips occur. Less likely to occur. On the other hand, if the lightning resistance is weak, there is a high possibility that flashover will occur, and as a result, an accident will also occur. In addition, the probability of flashover in the lightning protection equipment of the transmission and distribution line
Since there is a correlation between the probability of an accident such as a momentary dip, we decided to calculate the accident rate from this and provide the customer with the accident rate at each location. This allows
Instead of just lightning strike information, customers can quantitatively know the impact of lightning strikes, and take appropriate measures such as shutting down operations or switching to an emergency power source in consideration of the accident rate provided. It is possible to take

According to the fourth aspect of the present invention, the customer database is registered with equipment information relating to the equipment operated by the customer. The central unit corrects the accident rate based on this equipment information. That is, the equipment in the facility differs depending on the business category of the customer. For example, in a factory that uses an electromagnetic switch, some effect occurs when the voltage drop is 40% or more, but in a factory that uses a high-pressure discharge lamp, the voltage drop is about 20%. But it has a big impact.
From this, it was decided to correct the accident rate appropriately based on the equipment information and provide the corrected accident rate, so it is possible to provide a more accurate accident rate to the customer. Become.

[0024]

BEST MODE FOR CARRYING OUT THE INVENTION The present invention will be described below in detail with reference to the drawings showing an embodiment. Embodiment 1 FIG. 1 is a schematic diagram showing the configuration of a lightning strike information providing system according to the present invention. In the figure, A, A, A ... are altitudes of 5,000 m
It is an antenna that irradiates a Thundercloud T located at 10,000 m with a 5 GHz band Doppler radar and captures the reflected Doppler radar. The signal related to the reflection Doppler radar captured by the antenna A is output to the computer 3, and the computer 3 predicts the position, time, course direction, intensity and the like at which the lightning strike occurs based on the output signal. At that time, the computer 3 refers to the lightning strike database 3D that has accumulated past lightning strike data, and corrects the predicted lightning strike position, lightning strike time, the course direction of the thundercloud T, lightning strike intensity, and the like in order to improve accuracy.

The lightning strike information such as the lightning strike position information, the lightning strike time information, and the lightning intensity information calculated by the computer 3 in this way is connected to the central unit 1 through the communication network N.
Sent to. In addition, in the present embodiment, although the lightning strike prediction is performed by the computer 3,
You may make it predict by the central unit 1. The central device 1 provides the predicted lightning strike information to the customer's terminal devices 2, 2, 2, ... Connected via the communication network N. The terminal device 2 is a personal computer, a mobile phone, a PDA (Perso
It may be a portable information terminal such as a digital assistant), a facsimile machine, or a telephone.

FIG. 2 is a block diagram showing the configuration of the central unit 1 of the present invention. As shown in the figure, the CPU 11 is connected to the storage unit 1 such as a RAM 12 and a hard disk via a bus 17.
5, a communication unit 16 such as a gateway for transmitting and receiving information to and from the computer 3 and the terminal device 2, a display unit 13 such as a liquid crystal display, and an input unit 1 such as a keyboard and a mouse.
4 is connected. The RAM 12 includes a storage unit 15 and a display unit 1.
3, and a control program 12P for controlling the input unit 14 and the like is stored.

In the storage unit 15, a transmission / distribution line database 151 (hereinafter, referred to as a transmission / distribution line database in which transmission / distribution lines are registered corresponding to position information).
The transmission and distribution line DB 151) is provided. Figure 3
Is an explanatory diagram showing a line form of the power transmission and distribution line and an image of lightning strike information, and FIG. 4 is an explanatory diagram showing a record layout of the power transmission and distribution line DB 151. As shown in FIG. 3, transmission and distribution lines run from the substation to each region to supply electricity to customers' factories and the like. The power transmission / distribution line is branched into a plurality of systems (in the present embodiment, system A, system B,
System C), the effects of power outages and voltage drops caused by lightning strikes are reduced. The power transmission / distribution line is further branched even in the same system. For example, in the system A, the power transmission / distribution line A1 is branched, and the power transmission / distribution line A2 is branched. In addition, when there is a lightning strike in a particular system, some influence occurs on the power transmission and distribution lines belonging to the system. For example, when there is a lightning strike near the coordinate value G3, an accident may occur in the power transmission and distribution lines A1 to A8 belonging to the system A. The present invention extracts a transmission and distribution line affected by a lightning strike and provides a customer who uses the transmission and distribution line with the calculated accident occurrence rate.

As shown in the figure, the lightning strike information indicates the position and time zone at which a lightning strike is predicted, and the predicted lightning current I ₀ is also displayed. Next, the contents of the power transmission / distribution line DB 151 will be described. As shown in FIG. 4, the power transmission and distribution line DB 151 stores the system of the power transmission and distribution line in association with the coordinate values that are position information. If there is a lightning strike,
Since there is a high possibility that an accident such as a power failure or a momentary dip will occur on the power transmission and distribution lines of the same system, the central unit 1 refers to the power transmission and distribution line DB 151 when the lightning strike position information is obtained and the occurrence of the accident The power transmission and distribution line for which is predicted is extracted.

For example, when a lightning strike is predicted at the coordinate value F4 in FIG. 3, the system A is extracted. If a lightning strike is predicted at the coordinate value F5, the systems A and B are extracted.
It should be noted that these system data may be appropriately input from the input unit 14.

In addition to this, the storage unit 15 is provided with a customer database (hereinafter referred to as customer DB) 152 in which information of customers who use the power transmission and distribution lines is registered. Figure 5
FIG. 6 is an explanatory diagram showing a record layout of the customer DB 152. In the customer DB 152, the customer's name, e-mail address, FAX number, main equipment such as a factory operated by the customer, and the like are associated with the positional information of the transmission / distribution line system used by the customer and the factory of the customer. The customer information of is registered. After extracting the system of the power transmission and distribution line based on the lightning strike position information, the customer belonging to the same system is extracted by referring to the customer DB 152 and the lightning strike information is provided. Providing lightning strike information is e-M
It may be performed by an appropriate means such as mail, FAX, telephone or the like.

The storage unit 15 also includes a lightning protection characteristic database (hereinafter referred to as a lightning protection characteristic DB) 153 in which the lightning protection characteristics of the lightning protection equipment provided in each power transmission and distribution line are registered.
FIG. 6 is an explanatory diagram showing a record layout of the lightning protection characteristic DB 153. As shown in the figure, the line type for each transmission and distribution line,
The line length etc. are registered, and these are factors that affect the lightning resistance characteristics in case of a lightning strike. The contents stored in each field will be described below. The line type affects the line insulation, and a line type of about 6.6 kV to 500 kV is usually used. The line length represents the distance from the base end to the end of each transmission and distribution line.

The surge impedance Z of the line conductor shows the characteristic of the line itself. The power transmission / distribution line is provided with electric poles for supporting the electric power transmission / distribution lines, and these electric poles are provided with lightning arresters such as insulators and arc horns. Generally, the smaller the ground resistance of the lightning arrester, the less likely the flashover will occur. The ground resistance R _{AR of the} lightning arrester is also registered in the lightning resistance characteristic DB 153 for each transmission and distribution line. The limit voltage E _a of each lightning arrester is also registered.

The narrower the ground resistance of the lightning arrester, the less the possibility of flashover occurring. In the lightning resistance characteristic DB 153, the interval of the ground resistance of the lightning arrester is registered for each power transmission / distribution line.

The lightning impulse flashover voltage V ₅₀ is registered for each transmission and distribution line. The voltage transiently generated in a short time includes a voltage generated in an actual system and a voltage artificially used for a test. The former is called lightning surge,
The latter is called a lightning impulse. The impulse voltage has the polarity,
It is determined by three factors: waveform and peak value. Since the impulse voltage is a voltage that elapses in an extremely short time, it is largely controlled by accidental causes (presence or absence of interstitial ions in the gap, presence or absence of electron emission from the electrode surface due to external causes, etc.) and is the same. Even when an impulse voltage having the same peak value and the same waveform is applied to the gap, a phenomenon that flashover occurs at some time and no flashover occurs at another time easily occurs.

Therefore, in order to determine the flashover voltage value in the impulse voltage test, an impulse voltage wave having the same peak value is added several times, half of which causes flashover, and the other half does not cause flashover. The peak value of the impulse voltage with a discharge rate of 50% is used to represent the flashover voltage, which is referred to as the 50% flashover voltage. Also in the present embodiment, the lightning impulse flashover voltage V _{50 of} each transmission and distribution line is determined. Generally, when the lightning impulse flashover voltage V ₅₀ is large, the possibility of flashover occurring is reduced.

Further, since the lightning strike intensity has a characteristic proportional to the ground height of the power transmission and distribution line, the ground height of each power transmission and distribution line is registered in the lightning resistance characteristic DB 153. In addition, topographical information such as whether the power transmission and distribution line is in the city, along the mountain ridge, on rock, or in the vicinity of the forest, the shape of the end of the power transmission and distribution line (finished, Lightning resistance characteristics vary greatly depending on whether or not there is a branch, etc.)
Various lightning resistance characteristics are registered in 53 for each transmission and distribution line.

In the present invention, the discharge current I _AR at each point of the power transmission and distribution line extracted in consideration of the above-mentioned lightning resistance characteristics is calculated as the lightning strike intensity. The details of this point will be described later. When the calculated discharge current I _AR exceeds the flashover current I _f that causes a flashover at each point, a flashover often occurs in the insulator or the like of the lightning arrester. Further, when a flashover occurs, it is recognized that the higher the discharge current I _AR is, the higher the probability that an accident such as a power failure or an instantaneous drop occurs.

FIG. 7 is a graph showing the relationship between the ground resistance of the lightning arrester and the flashover current I _f . In the graph of FIG. 7, the earth resistance value R of the lightning arrester is plotted on the horizontal axis and the flashover current _If is plotted on the vertical axis, and the change in the lightning impulse flashover voltage V ₅₀ of each transmission and distribution line is shown.
The flashover current I _f can be generally calculated by the following equation 1.

I _f = (V ₅₀ −E) ÷ {(α−C) Zr} (1) where, E: AC voltage (peak value of ground voltage) (kV) α: of each layer against the rise of the column top potential, Ratio of increase in potential of insulator mounting portion (normally, α = 1 is acceptable) C: Coupling rate of overhead ground wire and line conductor Zr: Impedance of increase in potential (Ω).

For example, when the ground resistance R of the lightning arrester is 40Ω, the lightning impulse flashover voltage V ₅₀ is 125k.
At V, the discharge current I _AR exceeds the flashover current I _f when the discharge current I _AR is 7 kA or more. Therefore, the possibility of flashover increases, and the possibility of an accident such as power failure or instantaneous voltage drop increases. On the other hand, when the lightning impulse flashover voltage V ₅₀ is 150 kV, the discharge current I _AR is be about 7 kA, it does not exceed the flashover current I _f,
Flashover is less likely to occur and accidents are less likely to occur.

The data relating to the graph of FIG.
It is the characteristic for the case of 2kV and the height of the ground is 10m.
Various conditions (for example, track type 33kV, ground clearance 15
m, terrain characteristics, etc.), various flashover characteristics are stored in the flashover characteristic file 15 of the storage unit 15.
It is stored in 4.

Next, the causal relationship between the discharge current I _AR and the flashover current I _f and the accident occurrence rate will be described. FIG. 8 is a graph showing a causal relationship between the discharge current I _AR and the flashover current I _f and the accident occurrence rate. The horizontal axis represents the ratio of the flashover current I _f to the discharge current I _AR (overrate I _AR / I _f ), and the vertical axis represents the accident occurrence rate.

As shown in FIG. 8, if the overrate exceeds 1.0, the probability of sudden occurrence of an accident such as a power failure or a momentary dip increases. That is, the calculated discharge current I _AR is greater than the flashover current I _f has been observed empirically that accident rate increases. On the other hand, if the overrate is 1.0 or less, the accident rate also drops sharply. That is, the discharge current I _AR is the flashover current I
_If it is smaller than _f , it is recognized that the accident rate is extremely low. These data were created by collecting accident statistics due to actual lightning strikes, and FIG. 8 shows the characteristics when the line type is 22 kV and the ground clearance is 10 m. In addition to this, various types of accident rate characteristics are stored in the accident rate file 155 of the storage unit 15 according to various conditions (for example, track type is 33 kV, ground clearance is 15 m, terrain characteristics, etc.). Has been done. The accident rate is the lightning strike location, lightning intensity, power transmission and distribution line name, ground resistance value,
It is also possible to calculate using the multiway analysis of variance method from the values such as the grounding interval, the lightning strike point, and the distance between the transmission and distribution lines.

Further, the storage unit 15 is provided with a correction data file 156 storing a correction value for correcting the accident rate according to the equipment. FIG. 9 is an explanatory diagram showing a record layout of the correction data file 156.
As shown in the figure, the voltage drop degree and the correction value are stored in association with each facility. The voltage drop degree is a value obtained by dividing a voltage value that has some influence on the device due to a voltage sag by a normal reference voltage value. For example, an applied variable speed motor has a 15% voltage level compared to a normal reference voltage value. Is lowered,
An accident such as a momentary dip occurs.

On the contrary, when the voltage drops from the normal reference voltage by about 5%, the influence is small. In the present invention, the accident occurrence rate is multiplied by a correction value according to the customer's equipment to increase its reliability. For example, the electromagnetic switch is less affected by the instantaneous voltage drop, so the calculated accident occurrence rate is multiplied by 0.7 to correct. On the other hand, high-pressure discharge lamps, etc.
Correct the calculated accident rate by multiplying it by 1.2. In addition,
The power transmission / distribution line DB 151 and the like of the storage unit 15 described above do not necessarily have to be prepared in the central device 1, and may be stored in another computer (not shown) and appropriately read and used.

The procedure of calculating the accident rate according to the present invention having the above-mentioned structure will be described. FIG. 10 is a flowchart showing the procedure of calculating the accident rate. First, lightning strike information such as lightning strike position information and lightning strike intensity information predicted by the computer 3 is acquired (step S101). The central device 1
The coordinate values of the predicted lightning location information that predicts a lightning strike (Fig. 3
Read). Then, referring to the power transmission / distribution line DB 151, the power transmission / distribution line affected by the lightning strike is extracted (step S102).

The central unit 1 calculates the lightning voltage U ₀ (kV) at each point of the extracted transmission and distribution line (step S).
103). The lightning voltage U ₀ due to the discharge at each point is the predicted lightning current I ₀ (kA), its traveling speed vc (c is the light speed 3).
00 m / μs), the ground clearance h (m) of the power transmission / distribution line, the predicted distance y (m) from the lightning strike point, etc.

[0048]

[Equation 1]

The central unit 1 refers to the lightning protection DB 153 to read the lightning protection (ground height h, etc.). Then, the distance y obtained from the predicted lightning strike position information and the predicted lightning intensity I ₀ , which is the lightning intensity, are substituted into Equation 2 to sequentially calculate the lightning voltage U ₀ at each point. FIG. 11 is a graph showing the characteristics of the lightning voltage U ₀ at each point. FIG. 11 shows the characteristics of the lightning voltage U ₀ when the ground height h of the power transmission and distribution line is 10 m. Distance y from lightning point on the horizontal axis, providing a lightning voltage U ₀ on the vertical axis, a plurality of lightning current I ₀ that is predicted, which was investigated the relationship between the distance y and the lightning voltage U ₀ of the lightning point is there. As shown in the graph, it can be understood that the lightning current I ₀ is strong and the lighter voltage U ₀ is larger as the distance from the lightning strike point is shorter.

Next, in consideration of lightning resistance characteristics, the discharge current I _AR of the lightning arrester at each point of the extracted power transmission and distribution line is calculated (step S104). The value of the discharge current I _AR greatly varies depending on the above-mentioned lightning resistance characteristics such as the ground resistance of the lightning arrester, and can be roughly estimated by the following Expression 3.

[0051]

[Equation 2]

Here, U ₀ is the calculated lightning voltage (V), E
_a is the limiting voltage (V) of the lightning arrester, Z is the surge impedance (Ω) of the line conductor, and R _AR is the ground resistance (Ω) of the lightning arrester.

The central unit 1 reads out the lightning resistance characteristics of the lightning arrester provided on each transmission and distribution line from the lightning resistance characteristics DB 153 (for example, ground resistance R _AR (Ω) of the lightning arrester). The discharge current I _AR of the lightning arrester at each point is calculated from the read lightning resistance characteristic and the calculated lightning voltage U ₀ . FIG. 12 is a graph showing the characteristics of the discharge current I _AR with respect to the lightning voltage U ₀ . In the graph of FIG. 12, when the surge impedance Z of the line conductor is 400Ω, the line type is 6 kV class, and the limiting voltage E _a of the lightning arrester is 30 kV, the ground resistance R _AR of the lightning arrester is prepared, and the lightning voltage U It is a plot of the characteristics of the discharge current I _AR with respect to ₀ . As shown in the graph, it can be understood that the discharge current I _AR also increases as the lightning voltage U ₀ increases.

After obtaining the discharge current I _AR of the lightning arrester at each point, the central unit 1 refers to the flashover current I _f of the lightning arrester at each point and refers to the flashover characteristic file 154 with the lightning resistance characteristic as a key. Extract. For example, as shown in FIG. 7, when the lightning resistance characteristics of the lightning arrester are such that the ground resistance R is 40Ω, the transmission / distribution line type is 22 kV class, the line height is 10 m, and the lightning impulse flashover voltage V ₅₀ is 150 kV, An overcurrent I _{f of} 10 kA is extracted. In this way, the central unit 1 reads the lightning protection characteristics of the lightning protection device at each position from the lightning protection characteristics DB 153, searches the flashover characteristics file 154 with the read lightning protection characteristics as a key, and extracts the flashover current _If (step S105). ).

After the flashover current I _f is extracted, the central unit 1 calculates the overrate by comparing the extracted flashover current I _f with the calculated discharge current I _AR (step S106). The over rate is calculated by the following equation 4. Overrate = I _AR / I _f (4)

The central unit 1 obtains the accident occurrence rate by referring to the accident occurrence rate file 155 based on the calculated overrate and lightning resistance characteristics (step S107). For example, as shown in FIG. 8, when the transmission / distribution line type is 22 kV, the track height is 10 m, and the overrate is 1.1, the accident rate is 80%. As described above, the central device 1 determines the lightning protection characteristics of the lightning protection device included in the power transmission and distribution line as the lightning protection characteristics DB
3, the accident rate file 155 is searched using the read lightning protection characteristics and the calculated over rate as keys,
Extract the accident rate.

As shown in FIG. 13, the accident occurrence rate at each point obtained as described above is associated with the position coordinates and RA.
It is stored in M12. FIG. 13 is an explanatory diagram showing the stored contents of the calculated accident occurrence rate. RAM12 as shown
Stores the calculated accident occurrence rate at each point in association with the position information. Subsequently, the central unit 1 is the customer DB 1
The customer who uses the power transmission / distribution line extracted in step S102 is extracted from 52 (step S108). Then, using the location information of the customer extracted from the customer DB 152 as a key, R
The accident rate corresponding to the position information is extracted from AM12. For example, the accident rate is 10% in the O information system of the position information G4.

Further, the central apparatus 1 refers to the customer DB 152, extracts the equipment of the customer of the transmission destination by using the position information as a key, and extracts the correction value from the correction data file 156 (step S109). Then, the accident occurrence rate is corrected by multiplying the accident occurrence rate by the extracted correction value (step S101).
0). For example, as shown in FIG. 5, the ○ Δ chemical of the position information E5 uses the high-pressure discharge lamp, so the correction value 1.
Extract 2. If the accident rate is 80%, the corrected accident rate is 96%.

The central unit 1 uses e-Ma from the customer DB 152.
The il address or the like is read out, and the corrected accident occurrence rate is transmitted to each customer (step S1011). The accident rate may be reported by FAX, telephone or the like. Also, correction of the accident rate is only necessary if the customer desires,
If the customer does not desire correction, steps S109 and S1010 may be skipped and the accident rate before correction may be transmitted.

The terminal device 2 outputs the transmitted lightning strike information from a monitor, a printer or the like (not shown) (step S10).
12). As the lightning strike information, the calculated accident rate, lightning strike position, lightning strike time, etc. are output. FIG. 14 is an explanatory diagram showing an example of lightning strike information output to the terminal device 2. In this way, in addition to the conventional lightning strike information, the probability of an accident occurring is quantitatively provided, so that the customer can more effectively take measures against lightning strikes (such as the timing of switching to the emergency power supply). .

Second Embodiment FIG. 15 is a block diagram showing a hardware configuration of a central device 1 of the present invention according to a second embodiment. The computer program for executing the central device 1 according to the first embodiment may be pre-installed and provided in the central device 1 as in the second embodiment, or may be a CD-ROM or MO.
It is also possible to provide it with a portable recording medium such as. Further, the computer program can be provided by being propagated as a carrier wave via a line. The contents will be described below.

In the central unit 1 shown in FIG. 15, the transmission and distribution lines are extracted, the terminal devices are extracted, and the lightning strike intensity is calculated.
Recording medium 1a storing a computer program for calculating and correcting an accident rate and transmitting lightning strike information
(CD-ROM, MO, DVD-ROM, etc.) is installed in the storage unit 15. Such a computer program is loaded into the RAM 12 of the central device 1 and executed. This functions as the central device 1 of the present invention as described above.

The second embodiment is configured as described above, and since the other configurations and operations are the same as those of the first embodiment, corresponding parts are designated by the same reference numerals and detailed description thereof will be given. Omit it.

(Supplementary Note 1) In the lightning strike information providing method for providing the lightning strike information including the predicted lightning strike position information and the lightning strike intensity information, the power transmission and distribution line is registered corresponding to the position information based on the predicted lightning strike position information. From the transmission and distribution line database, the step of extracting the transmission and distribution line affected by lightning strikes, and the extracted transmission and distribution line from the customer database that stores the information of customers who use the transmission and distribution line in association with the transmission and distribution line. A lightning strike information providing method comprising: a step of extracting a customer to be used; and a providing step of providing lightning strike information to the extracted customer. (Appendix 2) Predicted lightning location information and lightning intensity information,
And, based on the lightning resistance characteristics of the lightning protection equipment provided in the extracted power transmission and distribution line, a step of calculating the lightning intensity at each point of the extracted power transmission and distribution line, and based on the calculated lightning intensity and lightning resistance characteristics, The method for providing lightning strike information according to appendix 1, further comprising: a step of calculating an accident occurrence rate, wherein the providing step provides lightning strike information including the calculated accident occurrence rate. (Supplementary Note 3) In the lightning strike information providing system for providing the lightning strike information including the predicted lightning strike position information and the lightning strike intensity information to the terminal device connected through the communication network, the central device is the predicted lightning strike position information. Based on the above, a means for extracting the transmission and distribution lines affected by lightning from the transmission and distribution line database in which the transmission and distribution lines are registered corresponding to the position information, and the customer who uses the transmission and distribution lines in association with the transmission and distribution lines From the customer database that registered the information of, the means for extracting the customer who uses the extracted power transmission and distribution line, to the terminal device related to the extracted customer, and a transmission means for transmitting the lightning strike information, the terminal device, A lightning strike information providing system comprising means for outputting transmitted lightning strike information. (Supplementary Note 4) The central device determines the lightning strike intensity at each point of the extracted power transmission and distribution line based on the predicted lightning strike position information and lightning intensity information, and the lightning protection characteristics of the lightning protection equipment included in the extracted power transmission and distribution line. It further comprises means for calculating, and means for calculating the accident occurrence rate at each point based on the calculated lightning strike intensity and lightning resistance characteristics, and the transmitting means transmits the lightning strike information including the calculated accident occurrence rate. The lightning strike information providing system according to appendix 3, which is configured. (Supplementary Note 5) The customer database is registered with equipment information regarding equipment operated by customers, and the central device further comprises means for correcting the accident rate based on the equipment information. The lightning strike information providing system according to attachment 4. (Supplementary note 6) The central device that provides the lightning strike information including the predicted lightning strike position information and the lightning strike intensity information to the terminal device connected through the communication network, corresponds to the position information based on the predicted lightning strike position information. From the transmission and distribution line database that registered the transmission and distribution line, the means for extracting the transmission and distribution line affected by lightning, and the customer database that registered the information of the customer who uses the transmission and distribution line in association with the transmission and distribution line, A central apparatus comprising: a means for extracting a customer who uses the extracted power transmission and distribution line; and a transmission means for transmitting lightning strike information to a terminal device related to the extracted customer. (Appendix 7) Predicted lightning strike location information and lightning intensity information,
And, based on the lightning resistance characteristics of the lightning protection equipment provided in the extracted power transmission and distribution line, means for calculating the lightning intensity at each point of the extracted power transmission and distribution line, and based on the calculated lightning intensity and lightning resistance characteristics, 7. The central apparatus according to appendix 6, further comprising: means for calculating an accident occurrence rate, wherein the transmitting means is configured to send the lightning strike information including the calculated accident occurrence rate. (Supplementary Note 8) The customer database is registered with equipment information about equipment operated by a customer, and further comprises means for correcting the accident rate based on the equipment information. Central device. (Supplementary Note 9) In a computer program for causing a computer to provide lightning strike information including predicted lightning strike position information and lightning strike intensity information to a terminal device connected via a communication network, the computer is based on the predicted lightning strike position information. , A step of extracting a transmission / distribution line affected by lightning from the transmission / distribution line database in which the transmission / distribution line is registered corresponding to the position information, and a customer who uses the transmission / distribution line in association with the computer to the transmission / distribution line. And a step of causing a customer who uses the extracted power transmission and distribution line to be extracted from a customer database in which the information of (1) is registered. (Supplementary Note 10) The computer is caused to calculate the lightning strike intensity at each point of the extracted power transmission and distribution line based on the predicted lightning strike position information and the lightning intensity information, and the lightning resistance characteristics of the lightning protection equipment included in the extracted power transmission and distribution line. 10. The computer program according to appendix 9, further comprising the steps of: causing the computer to calculate an accident occurrence rate at each point based on the calculated lightning intensity and lightning resistance characteristics. (Additional remark 11) The customer database is registered with equipment information on equipment operated by a customer, and further causes a computer to execute a step of correcting the accident rate based on the equipment information. The computer program of item 10. (Supplementary Note 12) A computer-readable recording medium in which a computer program for causing a computer to provide lightning strike information including predicted lightning strike position information and lightning strike intensity information to a terminal device connected via a communication network is read. In the computer, the step of causing the computer to extract the transmission and distribution line affected by the lightning from the transmission and distribution line database in which the transmission and distribution line is registered corresponding to the position information based on the predicted lightning position information, A computer program for executing a step of extracting a customer who uses the extracted transmission and distribution line from a customer database in which information of customers who use the transmission and distribution line in association with the distribution line is registered. A characteristic computer-readable recording medium.

[0065]

As described above in detail, in the first invention, the second invention, and the fifth invention, the central unit corresponds to the position information based on the predicted lightning position information of the lightning information. The transmission and distribution lines affected by lightning are extracted from the transmission and distribution line database in which the transmission and distribution lines are registered. Then, the customer who uses the extracted power transmission / distribution line is extracted from the customer database in which the information of the customer who uses the power transmission / distribution line is registered in association with the power transmission / distribution line. Then, the lightning strike information is transmitted to the extracted terminal device of the customer. As a result, the lightning strike information is output to the terminal device of the customer who is affected by the lightning strike. As described above, when there is a lightning strike, there is a high possibility that an accident will occur in the customer's equipment that uses the transmission and distribution lines in the vicinity,
By providing the lightning strike information to the customer, the customer can obtain more useful lightning strike information.

In the third invention, the lightning strike intensity varies according to the distance from the lightning strike position and the lightning resistance characteristics of the lightning protection equipment provided in the power transmission and distribution line. Therefore, the lightning strike position information and the lightning strike intensity information of the predicted lightning strike information are obtained. And the lightning strike intensity at each point of the power transmission and distribution line is calculated based on the lightning resistance characteristics of the lightning protection equipment included in the extracted power transmission and distribution line.

Further, the probability of flashover occurring in the lightning protection equipment is calculated based on the calculated lightning intensity and lightning resistance characteristics at each point of the power transmission and distribution line. In addition, since there is a correlation between the probability of occurrence of flashover in lightning protection equipment of the power transmission and distribution line and the probability of occurrence of accidents such as power outages and voltage drops,
Based on this, the accident rate was calculated and the accident rate at each location was provided to the customer. This allows the customer to quantitatively know how much the impact of lightning strike is, not just the lightning strike information.Taking into account the accident rate provided, operations can be stopped or switching to an emergency power source can be performed. It is possible to take appropriate measures.

In the fourth aspect of the present invention, the customer database is registered with the equipment information on the equipment operated by the customer. The central unit corrects the accident rate based on this equipment information. That is, the equipment in the facility varies according to the customer's business type. From this, it was decided to correct the accident rate appropriately based on the equipment information and provide the corrected accident rate, so it is possible to provide a more accurate accident rate to the customer. As described above, the present invention can exhibit excellent effects.

[Brief description of drawings]

FIG. 1 is a schematic diagram showing a configuration of a lightning strike information providing system according to the present invention.

FIG. 2 is a block diagram showing a configuration of a central device of the present invention.

FIG. 3 is an explanatory diagram showing an image of a line form of a power transmission and distribution line and lightning strike information.

FIG. 4 is an explanatory diagram showing a record layout of a power transmission and distribution line DB.

FIG. 5 is an explanatory diagram showing a record layout of a customer DB.

FIG. 6 is an explanatory diagram showing a record layout of a lightning resistance characteristic DB.

FIG. 7: Ground resistance of lightning arrester and flashover current I _f
It is a graph which shows the relationship with.

FIG. 8 is a graph showing a causal relationship between a discharge current I _AR and a flashover current I _f, and an accident occurrence rate.

FIG. 9 is an explanatory diagram showing a record layout of a correction data file.

FIG. 10 is a flowchart showing a procedure of calculating an accident rate.

FIG. 11 is a graph showing characteristics of lightning voltage U ₀ at each point.

FIG. 12 is a graph showing characteristics of discharge current I _AR with respect to lightning voltage U ₀ .

FIG. 13 is an explanatory diagram showing stored contents of a calculated accident occurrence rate.

FIG. 14 is an explanatory diagram showing an example of lightning strike information output to a terminal device.

FIG. 15 is a block diagram showing a hardware configuration of a central device of the present invention according to the second embodiment.

FIG. 16 is a schematic diagram showing a configuration of a conventional lightning forecast system.

[Explanation of symbols] 1 Central device 1a recording medium 15 memory 151 Transmission and distribution line database 152 Customer Database 153 Lightning Protection Database 154 Flashover characteristic file 155 Accident Rate File 156 Correction data file 2 terminal devices 3 computers 3D lightning strike database A antenna T thundercloud

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Tsunao Takarani             4-1, Kamiodanaka, Nakahara-ku, Kawasaki-shi, Kanagawa             No. 1 within Fujitsu Limited (72) Inventor Satoru Yoneya             3-3-22 Nakanoshima, Kita-ku, Osaka City, Osaka Prefecture             Kansai Electric Power Co., Inc. (72) Inventor Hiroshi Tayama             3-3-22 Nakanoshima, Kita-ku, Osaka City, Osaka Prefecture             Kansai Electric Power Co., Inc. F-term (reference) 5G064 AA07 AB03 AC01 AC08 BA02                       BA12 CB03 CB08 DA03                 5G066 AA03 AE07 AE09

Claims (5)

[Claims] 1. A lightning strike information providing method for providing lightning strike information including predicted lightning strike position information and lightning strike intensity information, wherein a power transmission / distribution line is registered corresponding to the position information based on the predicted lightning strike position information. Use the extracted transmission and distribution line from the step of extracting the transmission and distribution line affected by lightning from the line database and the customer database in which the information of the customer who uses the transmission and distribution line in association with the transmission and distribution line is registered. A lightning strike information providing method comprising: a step of extracting a customer; and a providing step of providing lightning strike information to the extracted customer. 2. A lightning strike information providing system for providing lightning strike information including predicted lightning strike position information and lightning strike intensity information to a terminal device connected through a communication network from the central device, wherein the central device is the predicted lightning strike position. Based on the information, a means to extract the transmission and distribution lines affected by lightning from the transmission and distribution line database in which the transmission and distribution lines are registered corresponding to the location information, and to use the transmission and distribution lines in association with the transmission and distribution lines From a customer database in which customer information is registered, there is provided a means for extracting a customer who uses the extracted power transmission and distribution line, and a transmitting means for transmitting lightning strike information to a terminal device related to the extracted customer. A lightning strike information providing system comprising means for outputting transmitted lightning strike information. 3. The central unit is configured to determine, based on predicted lightning strike position information and lightning intensity information, and lightning protection characteristics of lightning protection equipment included in the extracted transmission and distribution line, the intensity of lightning strike at each point of the extracted transmission and distribution line. And a means for calculating the accident rate at each location based on the calculated lightning intensity and lightning resistance characteristics, wherein the transmitting means transmits lightning information including the calculated accident rate. The lightning strike information providing system according to claim 2, wherein the system is configured as described above. 4. The customer database is registered with equipment information on equipment operated by customers, and the central apparatus further comprises means for correcting the accident rate based on the equipment information. The lightning strike information providing system according to claim 3. 5. A central device that provides lightning strike information including predicted lightning strike position information and lightning strike intensity information to a terminal device connected via a communication network, and responds to the position information based on the predicted lightning strike position information. From the transmission and distribution line database in which the transmission and distribution lines are registered, the means for extracting the transmission and distribution lines that are affected by lightning, and the customer database in which the information of customers who use the transmission and distribution lines in association with the transmission and distribution lines is registered A central apparatus comprising: a means for extracting a customer who uses the extracted power transmission and distribution line; and a transmission means for transmitting lightning strike information to a terminal device related to the extracted customer.