JP2013070476A - Surge protection system, server, lightning scale determination method, and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To protect electrical equipment from lightning surge and detect a scale of lightning generated in an area.SOLUTION: A control device 10to 10of each base station BSto BSarranged in a base station management area 1, when surge voltage is applied, protects a device in the base station BS from the lightning surge by an external interface, and transmits the value of the surge voltage which is detected with a plurality of fuses to a server 20. The server 20, on the basis of the value of the surge voltage which is received from each control device 10to 10within a predetermined time, determines and displays the scale of the lightning which is generated in the whole base station management area 1.

Description

  The present invention relates to a surge protection system, a server, a lightning scale discrimination method, and a program.

  There is known a surge protection device that detects a lightning surge intrusion from a commercial power source or a device side and forcibly cuts off the power supply from the commercial power source.

  Patent Document 1 describes a surge protection device that protects an electrical device from a lightning surge by disconnecting the electrical device from a power line when a lightning surge is detected.

JP 2006-296047 A

  Although conventional surge protection devices can protect electrical devices from lightning surges, it has not been known how much lightning has occurred in the entire area where surge protection devices are installed.

  The present invention has been made in view of the above circumstances, and a surge protection system, a server, and a lightning scale capable of detecting the scale of lightning generated in an area as well as protecting electrical equipment from lightning surges. An object is to provide a discrimination method and a program.

In order to achieve the above object, a surge protection system according to the first aspect of the present invention provides:
A surge protection system comprising a plurality of surge protection devices arranged in a predetermined area, and a server connected to each of the surge protection devices via a communication network,
Each of the surge protection devices is
Surge voltage detecting means for detecting the value of the surge voltage;
Surge voltage transmission means for transmitting surge voltage detection information indicating a value of the surge voltage detected by the surge voltage detection means to the server, and
The server
Based on surge voltage detection information received within a predetermined time from each of the surge protection devices, a lightning scale determination means for determining the scale of lightning generated in the predetermined area;
A lightning scale display means for displaying information indicating a lightning scale determined by the lightning scale determination means,
It is characterized by that.

In order to achieve the above object, a server according to the second aspect of the present invention provides:
A server connected via a communication network to a plurality of surge protection devices arranged in a predetermined area,
Based on surge voltage detection information indicating the value of the surge voltage received within a predetermined time from each of the surge protection devices, a lightning scale determination means for determining the scale of lightning generated in the predetermined area;
A lightning scale display means for displaying information indicating a lightning scale determined by the lightning scale determination means;
It is characterized by providing.

In order to achieve the above object, a lightning scale discrimination method according to a third aspect of the present invention is:
Receives surge voltage detection information indicating the value of the surge voltage within a predetermined time from a plurality of surge protection devices arranged in a predetermined area,
Based on the received surge voltage detection information, determine the scale of lightning generated in the predetermined area,
Displaying information indicating the magnitude of the determined lightning,
It is characterized by that.

In order to achieve the above object, a program according to the fourth aspect of the present invention provides:
A computer connected via a communication network with a plurality of surge protection devices arranged in a predetermined area,
Lightning scale determination means for determining the scale of lightning generated in the predetermined area based on surge voltage detection information indicating the value of the surge voltage received within a predetermined time from each of the surge protection devices,
A lightning scale display means for displaying information indicating a lightning scale determined by the lightning scale determination means;
To function as.

  According to the present invention, it is possible not only to protect electrical equipment from lightning surges, but also to detect the scale of lightning generated in the area.

It is a block diagram which shows the structure of the surge protection system which concerns on the 1st Embodiment of this invention. It is a figure which shows the structure in a base station. It is a figure which shows the structure of a control apparatus. It is a figure which shows the structure of a fuse part. It is a block diagram which shows the structure of a server. It is a flowchart which shows an example of operation | movement of a lightning strike scale discrimination | determination process. It is a block diagram which shows the structural example of the fuse part which concerns on the 2nd Embodiment of this invention.

  Hereinafter, embodiments for carrying out the present invention will be described in detail with reference to the drawings. In the drawings, the same or equivalent parts are denoted by the same reference numerals.

(First embodiment)
FIG. 1 is a block diagram showing a configuration of a surge protection system 100 according to the first embodiment of the present invention. The surge protection system 100 includes four base stations BS _{1 to} BS ₄ control devices 10 ₁ to 10 ₄ arranged in the base station management area 1, and a server 20. The control devices 10 ₁ to 10 ₄ and the server 20 are connected via a network 2 such as the Internet. In the case where the base stations BS _{1 to} BS ₄ and the control devices 10 ₁ to 10 ₄ are not distinguished from each other, the base station BS and the control device 10 are denoted by reference numerals and will be described below.

As shown in FIG. 1, the control device (surge protection device) 10 is installed in the base station BS, and is connected to a plurality of external devices 4 via a built-in external interface 11 and signal line 3. Thus, each external device 4 is monitored and controlled. Note that the external device 4 is, for example, an air conditioner or lighting in the base station BS, a device for performing a wireless device with a wireless terminal, or the like, and a device that requires power. It is assumed that the withstand voltage against the lightning surge of the external device 4 is smaller than the withstand voltage of the control device 10.
In addition, the control device 10 functions as a surge protection device that protects the external device 4 and the control device 10 itself from a lightning surge. Hereinafter, the monitoring and control functions of the electric device of the control device 10 will be briefly described, and the lightning surge protection function will be mainly described.

  As illustrated in FIG. 1, the control device 10 includes an external interface 11, an internal circuit 12, and a communication unit 13.

  The external interface 11 is connected to each external device 4 via the signal line 3 and communicates with each external device 4. It is conceivable that a surge voltage is applied to the control device 10 from the external device 4 via the signal line 3 when receiving a lightning strike or a direct lightning strike due to a lightning strike. The external interface 11 has a lightning surge protection function that protects the control device 10 from being affected when a surge voltage is applied.

  The external interface 11 includes a main circuit 111, a diode group 112, and a fuse portion 113.

  The main circuit 111 includes a CPU (Central Processing Unit) and the like, and outputs data transmitted from the external device 4 to the internal circuit 12, and processing to transmit communication data output from the internal circuit 12 to the external device 4. Execute.

  The diode group 112 is switched so that the lightning surge current 5 flows through the fuse portion 113 so that the lightning surge current 5 generated by the surge voltage of a high load is not loaded on the control device 10. There is a possibility that a surge voltage is applied to the control device 10 from all the external devices 4 to be controlled. For this reason, when a surge voltage exceeding a predetermined value is applied to all the signal lines 3 connected to the external device 4 at a voltage larger than a voltage that normally operates, The lightning surge current 5 generated by the surge voltage is passed through the fuse portion 113 so that the surge voltage is not applied to the circuit 111 side. Thereby, it is possible to prevent a surge voltage from being applied to the internal circuit 12 of the control device 10. Therefore, the control device 10 can prevent a failure due to a lightning surge.

  The fuse portion 113 allows the lightning surge current 5 that has been passed by the diode group 112 to flow to the frame ground (hereinafter referred to as “FG”). The fuse unit 113 detects whether or not the lightning surge current 5 is equal to or greater than a predetermined current capacity by fusing fuses having different capacities included therein, and the lightning surge current 5 is determined by a predetermined current capacity. When it is detected that this is the case, disconnection notification signals 91 to 94 for notifying the internal circuit 12 are output.

  The configuration of the fuse portion 113 will be described with reference to FIG. The fuse unit 113 includes four fuses 71 to 74 and four resistors 61 to 64.

  Each fuse 71 to 74 is blown when the lightning surge current 5 generated by the surge voltage exceeds the set current capacity. The fuses 71 to 74 have switches (hereinafter referred to as “SW”) 81 to 84.

  The current capacity of each fuse is set so that the current capacity increases from the upstream side to the downstream side where the lightning surge current 5 flows. Further, it is desirable that the current capacity of the fuse 74 on the most downstream side is the same as the magnitude of the current generated by the voltage having the same height as the withstand voltage of the control device 10. Further, it is desirable that the current capacity of the fuse 73 is the same as the magnitude of the current generated by the same voltage as the withstand voltage of the external device 4. Here, the following description will be made assuming that the current capacities of the fuses 71 to 74 are set so that the surge voltage is blown at 1 kV, 2 kV, 3 kV, and 4 kV.

  The withstand voltage of the control device 10 is the maximum voltage that the control device 10 can withstand. In the case of the control device 10, since it is protected by a lightning surge protection function, more specifically, the diode is applied so that the voltage directly applied to the control device 10 is reduced to a level that the control device 10 can withstand. Of the voltages with a magnitude that allows the group 112 to pass a part or all of the current to the FG, the maximum voltage is the withstand voltage of the control device 10. Note that the breakdown voltage of the control device 10 is greater than the breakdown voltage of the external device 4.

  SW81 to 84 are switches that are turned on when the fuses 71 to 74 are blown. SW81 to 84 are turned on, and signal changes caused by connection to a signal ground (hereinafter referred to as “SG”) are output to the internal circuit 12 as disconnection notification signals 91 to 94. That is, the disconnection notification signals 91 to 94 are signals that notify the fuses 71 to 74 that are blown.

  The resistors 61 to 64 are resistors for allowing the lightning surge current 5 to flow through the fuses 72 to 74 and the FG when the fuses 71 to 74 are blown. In addition, it is desirable that the resistors 61 to 64 have sufficient rated power so that they are not damaged even if an assumed large current flows.

  As described above, the fuse unit 113 causes the lightning surge current 5 to flow through the FG when the lightning surge current 5 that has been supplied by the diode group 112 is within the current capacity of the fuses 71 to 74. When the lightning surge current 5 is larger than the current capacity of each of the fuses 71 to 74, the lightning surge current 5 is supplied to the FG, the corresponding fuses 71 to 74 are blown, and the blowout is notified to the internal circuit 12. . As a result, the fuse unit 113 can notify the internal circuit 12 by subdividing the magnitude of the surge voltage.

  Returning to FIG. 1, the internal circuit 12 includes a CPU, a ROM (Read Only Memory), a RAM (Random Access Memory), and the like, and executes the main process of the control device 10 by executing a program stored in the ROM. Run. For example, the internal circuit 12 outputs communication data for monitoring or controlling the external device 4 to the main circuit 111 of the external interface 11. Further, the internal circuit 12 receives the output of the communication data from the main circuit 111 that has acquired the communication data transmitted from the external device 4 in accordance with the monitoring or control. It is assumed that the ROM of the internal circuit 21 stores ID information that allows the control device 10 to be distinguished from other control devices 10.

  The communication unit 13 includes a NIC (Network Interface Card) or the like, and performs communication (information transmission / reception) with the server 20 via the network 2 based on the control of the internal circuit 12. For example, the communication unit 13 transmits information indicating the magnitude of the generated surge voltage to the server 20 via the network 2.

  Returning to FIG. 1, the server 20 is connected to the control device 10 in each base station BS via the network 2, and monitors and controls each base station BS. Further, the server 20 determines the scale of lightning strikes occurring in the base station management area 1 based on the information received from each control device 10. As shown in FIG. 1, the server 20 includes a communication unit 21, a storage unit 22, an operation unit 23, a display unit 24, and a control unit 25.

  The communication unit 21 includes a NIC (Network Interface Card) or the like, and performs communication (information transmission / reception) with the control device 10 via the network 2 based on the control of the control unit 25. For example, the communication unit 21 receives information indicating the magnitude of the generated surge voltage from the control device 10 via the network 2.

The storage unit 22 includes a hard disk and stores various information and data.
The operation unit 23 is used to input various information to the server 20 and includes input devices such as buttons and keys.
The display unit 24 outputs various information and includes a display device such as a display.

  The control unit 25 includes a CPU, a ROM, a RAM, and the like, and controls each unit of the server 20 by executing a program stored in the ROM. The control unit 25 also functions as a software timer, and can acquire the current time or measure a predetermined time. Moreover, the control part 25 performs the lightning strike scale prediction process which discriminate | determines the magnitude of the lightning strike which generate | occur | produced in the base station management area 1 based on the information received from the control apparatus 10 of each base station BS. Details of the lightning scale prediction process will be described later.

Next, the operation of the surge protection system 1 when a lightning strike occurs according to the first embodiment will be described.
When a lightning strike or a direct lightning strike to the base station BS occurs due to a lightning strike, a surge voltage is applied from the external device 4 to the external interface 11 of the control device 10 via the signal line 3. At this time, the diode group 112 of the external interface 11 passes the lightning surge current 5 generated by the surge voltage to the fuse portion 113. The fuse portion 113 causes the lightning surge current 5 flowing from the diode group 112 to flow to the FG via the fuses 71 to 74. Thereby, the control device 10 is protected by preventing the surge voltage from being directly applied to the control device 10.

At this time, each of the fuses 71 to 74 of the fuse unit 113 is blown when the flowing lightning surge current 5 exceeds its own current capacity, and outputs a blow notification signal 91 to 94 indicating the blown to the internal circuit 12. .
For example, when a lightning surge current 5 generated by applying a 1.5 kV surge voltage flows through the signal line 3, only the fuse 71 that blows at a surge voltage of 1 kV is blown, and the switch 81 is turned on, and the control device 10, a disconnection notification signal 91 is output.
Further, when a lightning surge current 5 generated by applying a 2.5 kV surge voltage flows through the signal line 3, the fuses 71 and 72 that blow when the surge voltage is 1 kV and 2 kV are blown, and the switches 81 and 82 are switched. The disconnection notification signals 91 and 92 are output to the control device 10.
Further, when a lightning surge current 5 generated by applying a 3.5 kV surge voltage flows through the signal line 3, the fuses 71, 72, and 73 that are blown at a surge voltage of 1 kV, 2 kV, and 3 kV are blown and switched. 81, 82, 83 are turned ON, and disconnection notification signals 91, 92, 93 are output to the control device 10.
Further, when a lightning surge current 5 generated by applying a surge voltage of 4.5 kV flows through the signal line 3, fuses 71, 72, 73, 74 are blown when the surge voltage is 1 kV, 2 kV, 3 kV, 4 kV. The switches 81, 82, 83, 84 are turned on and the disconnection notification signals 91, 92, 93, 94 are output to the control device 10.

  When the internal circuit 12 receives the disconnection notification signals 91 to 94 from the fuse unit 113, the internal circuit 12 executes processing for protecting the external device 4 and itself from lightning surges based on the pattern of the received disconnection notification signals 91 to 94. . For example, when the disconnection notification signal 93 is received, the applied surge voltage is equal to or higher than the withstand voltage of the external device 4, so that the internal circuit 12 interrupts the power supply to the external device 4 via the external interface 11. Thus, the failure of the external device 4 is avoided.

Further, when the internal circuit 12 receives the disconnection notification signals 91 to 94 from the fuse unit 113, the internal circuit 12 determines the value of the surge voltage based on the pattern of the received disconnection notification signals 91 to 94.
For example, when only the disconnection notification signal 91 is received, the control unit 25 may determine that a 1.5 kV surge voltage has occurred. Further, when the disconnection notification signals 91 and 92 are received, the control unit 25 may determine that a 2.5 kV surge voltage has occurred. Further, when the disconnection notification signals 91, 92, and 93 are received, the internal circuit 12 may determine that a 3.5 kV surge voltage has occurred. Further, when the disconnection notification signals 91, 92, 93, 94 are received, the control unit 25 may determine that a surge voltage of 4 kV or more has occurred.

  Subsequently, the control unit 25 controls the communication unit 21 to transmit the surge voltage detection information indicating the determined surge voltage value to the server 20.

On the other hand, the server 20 performs a lightning strike magnitude determination process shown in FIG.
When the server 20 is powered on, the control unit 25 determines whether or not surge voltage detection information has been received from the control device 10 of the base station BS within a predetermined time (for example, within 1 minute) ( Step S11). Each base station BS is arranged in a relatively narrow base station management area 1. Therefore, when a lightning strike occurs, there is a high possibility of receiving a plurality of pieces of surge voltage detection information from each of the control devices 10 ₁ to 10 ₄ of the base stations BS within a predetermined time.

  When it is determined that the surge voltage detection information has not been received (step S11; No), it is understood that no surge voltage due to lightning strikes is generated in each base station BS. Accordingly, the control unit 25 repeats the process of determining whether or not surge voltage detection information has been received from each control device 10 within a predetermined time (step S11).

  When it is determined that the surge voltage detection information has been received (step S11; No), the control unit 25 generates the surge voltage generated in the base station management area 1 based on the surge voltage value indicated by the received surge voltage detection information. Is determined (step S12). Specifically, the control unit 25 determines the average value of the surge voltage value indicated by the surge voltage detection information received from each control device 10 as the value of the surge voltage generated in the base station management area 1.

  For example, when the surge voltage detection information received from the respective control devices 10 of the four base stations BS in step S11 indicates a surge voltage of 3.5 kV, the control unit 25 is in the base station management area 1. What is necessary is just to discriminate | determine that the surge voltage of 3.5 kV generate | occur | produced.

  Further, when the surge voltage detection information received from each control device 10 of the four base stations BS in step S11 indicates a surge voltage of 1.5 kV, 1.5 kV, 2.5 kV, and 2.5 kV, respectively, The control unit 25 may take an average of these and determine that a 2 kV surge voltage has occurred in the base station management area 1.

  Subsequently, the control unit 25 uses the value of the surge voltage generated in the base station management area 1 determined in step S12 as information indicating the scale of the lightning generated in the base station management area 1, and the lightning occurrence time (step The time when the surge voltage detection information is received in S11) is displayed on the display unit 24 (step S13). By checking this display, the user can grasp how much lightning has occurred in the entire base station management area 1. Therefore, it is possible to take countermeasures such as issuing an alarm according to the scale of lightning or blocking power supply to other management facilities in the base station management area 1. This is the end of the lightning strike magnitude determination process.

  Thus, according to the present embodiment, the control device 10 installed in each base station BS not only protects the devices in the base station BS from lightning surges when a surge voltage is applied, The value of the surge voltage is acquired using a plurality of fuses 71 to 74 and transmitted to the server 20. And the server 20 discriminate | determines the magnitude | size of the lightning strike which generate | occur | produced in the whole base station management area 1 based on the value of the surge voltage received from each control apparatus 10. FIG. Therefore, according to the lightning surge system 100 according to the present embodiment, it is possible not only to protect electrical equipment from lightning surges, but also to detect the scale of lightning generated in the base station management area 1.

(Second Embodiment)
Next, the surge protection system 100 according to the second embodiment of the present invention will be described in detail. Note that the configuration of the surge protection system 100 according to the second embodiment of the present invention is the same as that of the first embodiment except for the configuration of the fuse portion 113, and thus the description thereof is omitted.

  The configuration of the fuse portion 113 of the surge protection system according to the second embodiment is shown in FIG. Compared to the first embodiment, the second embodiment is characterized in that three fuses 71 to 73 are connected in parallel.

  The operations of the fuses 71 to 74 are basically the same as those in the first embodiment. That is, the fuses 71 to 74 are blown when the lightning surge current 5 generated by the surge voltage exceeds the set current capacity. The fuses 71 to 74 have switches (hereinafter referred to as “SW”) 81 to 84.

  The current capacity of the most downstream fuse 74 through which the lightning surge current flows is set to be equal to the magnitude of the current generated by the voltage having the same height as the withstand voltage of the control device 10. The fuses 71 to 73 are set to have the same magnitude as the current generated by a voltage having the same height as the withstand voltage of the external device 4.

  Similarly to the first embodiment, SWs 81 to 84 are switches that are turned on when the fuses 71 to 74 are blown, and the SWs 81 to 84 are turned on to form a signal ground (hereinafter referred to as “SG”). ) Is output to the internal circuit 12 as disconnection notification signals 91-94.

  The resistors 61 to 64 are resistors for causing the lightning surge current 5 to flow through the fuses 72 to 74 and the FG when the fuses 71 to 74 are blown out, as in the first embodiment.

Subsequently, the operation of the surge protection system according to the second embodiment will be described.
The operation of causing the lightning surge current 5 generated by the induced lightning or direct lightning to flow through the fuse portion 113 is the same as that in the first embodiment, and thus the description thereof is omitted.

The lightning surge current 5 flows through the fuse portion 113 due to the applied lightning surge voltage. The fuse 71 is blown when the lightning surge current 5 flowing through the fuse 71 exceeds the current capacity. The switch 81 is turned ON by this melting and outputs a disconnection notification signal 91 to the internal circuit 12. When receiving the disconnection notification signal 91, the internal circuit 12 interrupts the power supply to the external device 4 via the external interface 11 in order to protect the external device 4. In addition, the control unit 25 determines the magnitude of the surge voltage applied from the disconnection notification signal 91 and transmits it to the server 20.
Next, when there is no risk of lightning, the internal circuit 12 of the control device 10 supplies power to the external device 4 again. At this time, in the present embodiment, the fuse 71 is not exchanged and remains blown.

Next, when a lightning strike occurs again, the lightning surge current 5 flows to the fuse 72 via the resistor 61. The fuse 72 blows when the lightning surge current 5 flowing through the fuse 72 exceeds the current capacity. The switch 82 is turned ON by this melting and outputs a disconnection notification signal 92 to the internal circuit 12. When receiving the disconnection notification signal 92, the internal circuit 12 shuts off the power supply to the external device 4 via the external interface 11 in order to protect the external device 4. Further, the internal circuit 12 determines the magnitude of the surge voltage applied from the disconnection notification signal 91 and transmits it to the server 20.
Next, when there is no risk of lightning, the internal circuit 12 of the control device 10 supplies power to the external device 4 again. At this time, in the present embodiment, the fuses 71 and 72 are not exchanged or the like and remain blown.

Next, when a lightning strike occurs again, the lightning surge current 5 flows to the fuse 73 via the resistors 61 and 62. The fuse 73 is blown when the lightning surge current 5 flowing through the fuse 73 exceeds the current capacity. The switch 83 is turned ON by this melting and outputs a disconnection notification signal 93 to the internal circuit 12. When receiving the disconnection notification signal 93, the control device 10 cuts off power supply to the external device 4 via the external interface 11 in order to protect the external device 4. Further, the internal circuit 12 determines the magnitude of the surge voltage applied from the disconnection notification signal 93 and transmits it to the server 20.
When the lightning surge current 5 flows again to the fuse portion 113 after the fuse 73 is blown, the lightning surge current 5 flows to the FG via the resistor 63.

  As described above, in the second embodiment, the three fuses 71, 72, 73 having the same current capacity are connected in parallel. Therefore, the lightning surge current 5 exceeding the current capacity of the fuses 71, 72, 73 can be detected three times without replacing the fuse. That is, the application of the surge voltage having the same magnitude can be notified to the control device 10 a plurality of times without replacing the fuses 71, 72, 73. Therefore, without replacing the fuses 71, 72, and 73, it is possible to perform control a plurality of times to cut off the power supply from the control device 10 to the external device 4 and avoid a failure.

  As described above, according to the second embodiment, even in a system in which a fuse cannot be easily replaced, the external device 4 and the control device that controls the external device 4 without replacing the fuse. As shown in FIG. 10, it is possible to appropriately protect a plurality of devices having different withstand voltages against the surge voltage from the surge voltage.

  The present invention is not limited to the above-described embodiments, and various changes can be made without departing from the spirit of the present invention.

  For example, in each of the above-described embodiments, the average value of the surge voltage received from each control device 10 is determined and displayed as information indicating the scale of lightning generated in the base station management area 1. However, based on the average value of the determined surge voltage, the scale of the lightning strike may be classified and displayed as “small”, “medium”, “large” or the like. By doing in this way, it can be set as the display which is easy for a user to realize the scale of a lightning strike.

Moreover, in each said embodiment, the average value of the value of the surge voltage which the surge voltage detection information received from each control apparatus 10 showed was discriminate | determined as the scale of the lightning which generate | occur | produced in the base station management area 1. FIG. On the other hand, a surge voltage with a greater weight applied to the surge voltage value indicated by the surge voltage detection information received from the control device 10 of the base station BS arranged at a position close to the center in the base station management area 1 May be determined as the scale of lightning generated in the base station management area 1. In this case, the storage unit 22 of the server 20 needs to store in advance location information of each base station BS, center location information of the base station management area 1, and the like.
By doing in this way, the value of the surge voltage generated near the center of the base station management area 1 is more strongly reflected on the scale of lightning generated in the base station management area 1. Accordingly, the scale of lightning generated in the base station management area 1 can be obtained more accurately.

Moreover, in each said embodiment, the average value of the surge voltage which the surge voltage detection information received from each control apparatus 10 showed was discriminate | determined as the value of the surge voltage which generate | occur | produced in the base station management area 1. FIG.
However, the maximum value of the surge voltage indicated by the received surge voltage detection information may be the value of the surge voltage generated in the base station management area 1.

  In each of the above embodiments, the internal circuit 12 of the control device 10 determines the value of the surge voltage based on the disconnection notification signals 91 to 94 received from the fuse unit 113 of the external interface 11 and transmits it to the server 20. On the other hand, the internal circuit 12 transmits the disconnection notification signals 91 to 94 received from the fuse unit 113 directly to the server 20, and determines the magnitude of the surge voltage from the disconnection notification signals 91 to 94 received by the server 20. May be.

  In each of the above embodiments, the number of fuses in the fuse unit 113 has been described as four. However, the number of fuses provided in the fuse unit 113 is arbitrary. The current capacity of each fuse is also arbitrary. Further, the number of fuses in the fuse unit 113 and the current capacity may be different in each control device 10.

  In addition, by applying an operation program that defines the operation of the server 20 according to the present invention to an existing personal computer, information terminal device, or the like, it is possible to cause the personal computer or the like to function as the server 20 according to the present invention. .

  Further, the distribution method of such a program is arbitrary. For example, the program can be read by a computer such as a CD-ROM (Compact Disk Read-Only Memory), a DVD (Digital Versatile Disk), an MO (Magneto Optical Disk), or a memory card. It may be distributed by storing in a recording medium, or distributed via a communication network such as the Internet.

  A part or all of the above-described embodiment can be described as in the following supplementary notes, but is not limited thereto.

(Appendix 1)
A surge protection system comprising a plurality of surge protection devices arranged in a predetermined area, and a server connected to each of the surge protection devices via a communication network,
Each of the surge protection devices is
Surge voltage detecting means for detecting the value of the surge voltage;
Surge voltage transmission means for transmitting surge voltage detection information indicating a value of the surge voltage detected by the surge voltage detection means to the server, and
The server
Based on surge voltage detection information received within a predetermined time from each of the surge protection devices, a lightning scale determination means for determining the scale of lightning generated in the predetermined area;
A lightning scale display means for displaying information indicating a lightning scale determined by the lightning scale determination means,
Surge protection system characterized by that.

(Appendix 2)
The lightning scale determination means determines an average value of surge voltages indicated by a plurality of surge voltage detection information received within the predetermined time as a lightning scale generated in the predetermined area.
The surge protection system according to appendix 1, wherein

(Appendix 3)
The lightning scale determining means sets the average value with a greater weight to the value of the surge voltage indicated by the surge voltage detection information received from the surge protection device disposed near the center of the predetermined area. It is determined as the scale of lightning generated in the area.
The surge protection system according to Supplementary Note 2, wherein

(Appendix 4)
The lightning scale determination means determines the maximum value of the surge voltage indicated by the plurality of surge voltage detection information received within the predetermined time as the scale of lightning generated in the predetermined area,
The surge protection system according to appendix 1, wherein

(Appendix 5)
The surge voltage detection means has a plurality of fuses, and detects the value of the surge voltage by fusing each fuse,
The surge protection system according to any one of appendices 1 to 4, characterized in that:

(Appendix 6)
The plurality of fuses are connected in parallel;
The surge protection system according to appendix 5, wherein

(Appendix 7)
A server connected via a communication network to a plurality of surge protection devices arranged in a predetermined area,
Based on surge voltage detection information indicating the value of the surge voltage received within a predetermined time from each of the surge protection devices, a lightning scale determination means for determining the scale of lightning generated in the predetermined area;
A lightning scale display means for displaying information indicating a lightning scale determined by the lightning scale determination means;
A server comprising:

(Appendix 8)
Receives surge voltage detection information indicating the value of the surge voltage within a predetermined time from a plurality of surge protection devices arranged in a predetermined area,
Based on the received surge voltage detection information, determine the scale of lightning generated in the predetermined area,
Displaying information indicating the magnitude of the determined lightning,
A lightning scale discrimination method characterized by the above.

(Appendix 9)
A computer connected via a communication network with a plurality of surge protection devices arranged in a predetermined area,
Lightning scale determination means for determining the scale of lightning generated in the predetermined area based on surge voltage detection information indicating the value of the surge voltage received within a predetermined time from each of the surge protection devices,
A lightning scale display means for displaying information indicating a lightning scale determined by the lightning scale determination means;
Program to function as.

1 Base Station Management Area 2 Network 3 Signal Line 4 External Device 5 Lightning Surge Current 10 Control Device 11 External Interface 111 Main Circuit 112 Diode Group
DESCRIPTION OF SYMBOLS 113 Fuse part 12 Internal circuit 13 Communication part 20 Server 21 Communication part 22 Storage part 23 Operation part 24 Display part 25 Control part 61-64 Resistance 71-74 Fuse 81-84 Switch BS Base station 100 Surge protection system

Claims (9)

A surge protection system comprising a plurality of surge protection devices arranged in a predetermined area, and a server connected to each of the surge protection devices via a communication network,
Each of the surge protection devices is
Surge voltage detecting means for detecting the value of the surge voltage;
Surge voltage transmission means for transmitting surge voltage detection information indicating a value of the surge voltage detected by the surge voltage detection means to the server, and
The server
Based on surge voltage detection information received within a predetermined time from each of the surge protection devices, a lightning scale determination means for determining the scale of lightning generated in the predetermined area;
A lightning scale display means for displaying information indicating a lightning scale determined by the lightning scale determination means,
Surge protection system characterized by that. The lightning scale determination means determines an average value of surge voltages indicated by a plurality of surge voltage detection information received within the predetermined time as a lightning scale generated in the predetermined area.
The surge protection system according to claim 1. The lightning scale determining means sets the average value with a greater weight to the value of the surge voltage indicated by the surge voltage detection information received from the surge protection device disposed near the center of the predetermined area. It is determined as the scale of lightning generated in the area.
The surge protection system according to claim 2. The lightning scale determination means determines the maximum value of the surge voltage indicated by the plurality of surge voltage detection information received within the predetermined time as the scale of lightning generated in the predetermined area,
The surge protection system according to claim 1. The surge voltage detection means has a plurality of fuses, and detects the value of the surge voltage by fusing each fuse,
The surge protection system according to any one of claims 1 to 4, wherein the surge protection system is provided. The plurality of fuses are connected in parallel;
The surge protection system according to claim 5. A server connected via a communication network to a plurality of surge protection devices arranged in a predetermined area,
Based on surge voltage detection information indicating the value of the surge voltage received within a predetermined time from each of the surge protection devices, a lightning scale determination means for determining the scale of lightning generated in the predetermined area;
A lightning scale display means for displaying information indicating a lightning scale determined by the lightning scale determination means;
A server comprising: Receives surge voltage detection information indicating the value of the surge voltage within a predetermined time from a plurality of surge protection devices arranged in a predetermined area,
Based on the received surge voltage detection information, determine the scale of lightning generated in the predetermined area,
Displaying information indicating the magnitude of the determined lightning,
A lightning scale discrimination method characterized by the above. A computer connected via a communication network with a plurality of surge protection devices arranged in a predetermined area,
Lightning scale determination means for determining the scale of lightning generated in the predetermined area based on surge voltage detection information indicating the value of the surge voltage received within a predetermined time from each of the surge protection devices,
A lightning scale display means for displaying information indicating a lightning scale determined by the lightning scale determination means;
Program to function as.

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