JP5447401B2 - Theft monitoring device for solar cell module and theft monitoring system using the same - Google Patents

Description

  The present invention relates to a theft monitoring device for a solar cell module and a theft monitoring system using the same.

  Conventionally, development related to a theft monitoring device for a solar cell module has been performed (see, for example, Patent Document 1).

  Recently, with the widespread use of large-scale solar power plants such as mega solar power plants, there has been a demand not only to detect the theft of solar cell modules but also to detect the location where the solar cell modules were stolen.

  In response to this requirement, it is conceivable to apply the solar cell array failure diagnosis method described in Patent Document 2 to theft detection. The solar cell array fault diagnosis method disclosed in Patent Document 2 applies a measurement signal waveform between a terminal of a solar cell string or a terminal of the solar cell array and the ground, and compares the response signal waveform with the measurement signal waveform. The failure (theft) position in the solar cell array is specified.

JP 2002-367046 A JP 2009-21341 A

  However, in the solar cell module theft monitoring device in which the solar cell array failure diagnosis method described in Patent Document 2 is applied to theft detection, when a plurality of solar cell modules are stolen, the plurality of stolen solar cell modules There was a problem that each of the could not be identified.

  The present invention has been made in view of the above circumstances, and even when a plurality of solar cell modules are stolen, the theft of solar cell modules capable of specifying the plurality of stolen solar cell modules. It is an object of the present invention to provide a monitoring device and a theft monitoring system using the same.

  The present invention was devised to achieve the above object, and connects a burglar monitoring device main body, the burglar monitoring device main body and a plurality of solar cell modules to be monitored, and from the burglar monitoring device main body. When signal lines formed to have different wiring lengths to the respective solar cell modules, and connected to the signal lines and the respective solar cell modules, respectively, and when monitoring signals are received via the signal lines A response element that returns a response signal to the signal line, and the burglar monitoring device main body transmits the monitoring signal from one end of the signal line, and sequentially transmits the response signals returned from the response elements. A solar cell module provided with a theft detection unit that receives and detects that the solar cell module corresponding to a response element to which the response signal is not returned is stolen; A flame monitoring device.

  One end of the signal line may be connected to the theft monitoring apparatus main body, and the other end may be branched to be connected to each of a plurality of solar cell modules to be monitored.

  The signal line may be formed such that a wiring length from the theft monitoring apparatus main body to each solar cell module is different by a certain length.

  The connection portion is provided on the signal line side connector provided at the end of the signal line and the solar cell module, and the response element is mounted, and when the signal line side connector is fitted, A module-side connector configured to electrically connect the signal line and the response element, and when the solar cell module is stolen, the signal line-side connector and the module-side connector are fitted together. The signal line and the response element may be configured to be electrically disconnected from each other.

  The present invention also includes a solar cell module theft monitoring device, and alarm means for issuing an alarm when the solar cell module theft monitoring device determines that the solar cell module has been stolen. It is a module theft monitoring system.

  According to the present invention, even when a plurality of solar cell modules are stolen, a theft monitoring device for a solar cell module capable of identifying the plurality of stolen solar cell modules and theft using the same. A monitoring system can be provided.

It is a figure which shows the theft monitoring system of the solar cell module using the theft monitoring device of the solar cell module which concerns on one embodiment of this invention, (a) is a schematic block diagram, (b) is the principal part enlarged view. is there. It is a figure explaining operation | movement of the theft monitoring apparatus of the solar cell module of FIG. It is a figure which shows an example of a theft position table used with the theft monitoring apparatus of the solar cell module of FIG. 3 is a flowchart showing an example of a control flow of a theft monitoring control process in the theft monitoring device for solar cell modules in FIG. 1. 6 is a flowchart showing another example of the control flow of the theft monitoring control process in the theft monitoring device for the solar cell module of FIG. 1.

  Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

  1A and 1B are diagrams showing a theft monitoring system for a solar cell module using a theft monitoring device for a solar cell module according to the present embodiment, where FIG. 1A is a schematic configuration diagram, and FIG. It is.

  As shown in FIGS. 1A and 1B, the solar cell module theft monitoring system 100 includes a solar cell module theft monitoring device 1 according to the present invention, and a solar cell module theft monitoring device 1 including a solar cell module M. And alarm means 20 for issuing an alarm when it is determined that has been stolen.

  The theft monitoring device 1 for a solar cell module according to the present embodiment connects a theft monitoring device main body 3 to a theft monitoring device main body 3 and a plurality of solar cell modules M to be monitored, and the theft monitoring device main body 3. To the respective solar cell modules M, the signal lines 4 formed so as to have different wiring lengths, and the signal lines 4 and the connection portions 5 between the respective solar cell modules M and fixed to the solar cell modules M. And a response element 5 c that returns a response signal to the signal line 4 when a monitoring signal is received from the theft monitoring device body 3 via the signal line 4.

  In the present embodiment, the signal line 4 has one end connected to the input / output unit 6 of the theft monitoring device body 3 and the other end branched to each of the plurality of solar cell modules M to be monitored. It is comprised so that. In the present embodiment, the signal lines 4 are formed so that the wiring length from the theft monitoring device body 3 to each solar cell module M is different by a certain length ΔL.

  Here, a case where there are n solar cell modules M to be monitored will be described. In this case, the signal line 4 is branched into n corresponding to the n solar cell modules M, and the end of the branched signal line 4 is connected to each solar cell module M. The In the following, for simplification of explanation, the module numbers of the solar cell modules M are 1, 2, 3, 4 in order of increasing wiring length from the theft monitoring device main body 3, that is, from the upper side to the lower side in FIG. ,..., N.

  In the present embodiment, the connection portion 5 is provided in the signal line side connector 5a provided at the end of the signal line 4 and the solar cell module M, and the response element 5c is mounted, and the signal line side connector 5a is connected. The module-side connector 5b is configured to be electrically connected to the signal line 4 and the response element 5c when fitted. The connection portion 5 is configured such that when the solar cell module M is stolen, the signal line side connector 5a and the module side connector 5b are disengaged, and the signal line 4 and the response element 5c are electrically disconnected. ing. The module-side connector 5b is formed integrally with the solar cell module M or is firmly fixed to the solar cell module M so that it cannot be removed from the solar cell module M during theft.

  The signal line side connector 5a and the module side connector 5b constituting the connecting portion 5 may be configured integrally with a connector used for taking out electric power from the solar cell module M or may be separated.

  The connection portion 5 may have any configuration as long as the signal line 4 and the response element 5c are electrically disconnected when the solar cell module M is stolen, and a connector type as shown in FIG. The response element 5c may be simply fixed firmly to the solar cell module M, and the solar cell module M may not be stolen unless the signal line 4 is cut.

  As the monitoring signal, a pulse signal may be used or an AC signal may be used. In this embodiment, a pulse signal is used as the monitoring signal.

  Any element can be used as the response element 5c as long as it returns a response signal when it receives the monitoring signal. For example, the input monitoring signal is activated as activation power, and pulsed simultaneously with activation. An element (for example, an element such as a one-shot multivibrator) configured to generate a response signal having a shape can be used. Of course, it is also possible to supply the response element 5c from the solar cell module M, and when an AC signal is used as a monitoring signal, a rectifying element may be further provided.

  Furthermore, the response element 5c can be configured to reflect the input monitoring signal and return the reflected monitoring signal as a response signal. In this case, for example, an inductor element or the like may be used as the response element 5c. Further, by opening the end portion of the signal line 4, it is possible to reflect the monitoring signal at the open end. However, in this case, depending on conditions, when the response signal reflected by the open end as the response element 5c and the signal line 4 and the response element 5c are electrically cut off when the solar cell module M is stolen, It may be difficult to distinguish the reflected signal reflected from the electrically interrupted location and it may be difficult to detect theft of the solar cell module M, and adjustments are made as appropriate to avoid such problems. There is a need. Thus, the response element 5c needs to be configured so that the response signal from the response element 5c and the reflected signal when the solar cell module M is stolen can be clearly distinguished.

  In the present embodiment, as the response element 5c, an element configured to start with the input pulse signal as the starting power and output a pulse-like response signal simultaneously with the starting is used. Moreover, for simplification of description, the following description will be made on the assumption that no reflection occurs at a location where the solar cell module M is electrically cut off when it is stolen.

  The theft monitoring device main body 3 transmits a monitoring signal (pulse signal) from one end of the signal line 4, sequentially receives the response signals returned from the response elements 5c, and does not receive a response signal. And a theft detection unit 10 for detecting that the solar cell module M corresponding to the response element 5c to which the response signal has not been returned has been stolen. The theft detection unit 10 is configured to transmit a monitoring signal at predetermined time intervals. The theft detection unit 10 is mounted on the basic circuit 3b in the control board 3a of the theft monitoring apparatus main body 3, and is realized by appropriately combining a memory (RAM, ROM), a CPU, an I / O interface, software, and the like.

  Here, operation | movement of the theft monitoring apparatus 1 of a solar cell module is demonstrated.

  As shown in FIG. 2, when a pulse signal as a monitoring signal is input from one end of the signal line 4, the pulse signal is branched and input to each of the response elements 5 c corresponding to each solar cell module M. Each response element 5c to which the pulse signal is input starts up using the input pulse signal as starting power, and outputs a pulse-like response signal simultaneously with starting. The response signal output from each response element 5c propagates through the signal line 4 in the direction opposite to the propagation direction of the monitoring signal, and is received by the input / output unit 6 of the theft monitoring device main body 3.

At this time, for example, the response signal returned from the response element 5c corresponding to the solar cell module M of module number 2 is compared with the response signal returned from the response element 5c corresponding to the solar cell module M of module number 1. Thus, the signal is received with a delay corresponding to the difference ΔL in the wiring length. Specifically, if the speed at which the monitoring signal propagates through the signal line 4 is v, the response signal returned from the response element 5c corresponding to the solar cell module M of any module number i is the module number i-1. Compared with the response signal returned from the response element 5c corresponding to the solar cell module M, the signal is received delayed by the delay time Δt calculated by the following equation (1).
Δt = 2 × ΔL / v (1)

  Accordingly, as shown in FIG. 2, when the solar cell module M is not stolen normally, each module number is in ascending order (that is, in order of decreasing wiring length) at each time interval (the above-described delay time Δt). Response signals from the response element 5c are sequentially received by the theft monitoring apparatus main body 3.

  When the solar cell module M is stolen, the response signal is not returned from the response element 5c corresponding to the stolen solar cell module M. Therefore, the theft detection unit 10 detects the response element 5c to which no response signal is returned. Thus, the module number of the stolen solar cell module M can be detected. In the example of FIG. 2, since the response signal is not returned from the response element 5c corresponding to the solar cell module M with the module number n-1, it can be determined that the solar cell module M with the module number n-1 has been stolen.

  Although not shown in FIG. 2, the signal line 4 and the response element 5 c are actually cut off at the connection portion 5 of the stolen solar cell module M. The reflected signal reflected at the designated location is also received by the theft monitoring apparatus main body 3. For this reason, the theft detection unit 10 is configured to distinguish between a reflection signal at the time of the theft and a response signal and detect only the response signal. In the present embodiment, when the characteristic impedance or the like is adjusted so that the signal strength of the reflected signal at the time of theft is reduced, and the signal strength of the received signal is greater than a predetermined threshold value set in advance by the theft detection unit 10 Only the response signal was judged to have been received.

  Further, in the present embodiment, the theft position table 11 in which the relationship between the time T from when the monitoring signal (pulse signal) is transmitted until the response signal is received and the module number of the solar cell module M is further mapped is provided. The theft detection unit 10 is configured to identify the module number of the stolen solar cell module M with reference to the theft position table 11.

A setting example of the theft position table 11 is shown in FIG. According to the theft position table 11 of FIG. 3, for example, if a response signal is not received at a time between X ₀ and X ₁ after transmitting a pulse signal, the solar cell module M of module number 1 is stolen. I can judge. Times X _{0 to} X _n in FIG. 3 may be set as appropriate by conducting experiments in advance.

  In addition, the theft detection unit 10 outputs the module number of the identified stolen solar cell module M to the alarm unit 20 as a theft position signal. In the present embodiment, the theft position signal also functions as a theft detection, but separately from the theft position signal, the theft detection signal is output to the alarm means 20 when the theft is detected. Also good.

  When the alarm means 20 receives the theft position signal from the theft detection unit 10 of the theft monitoring device 1 for the solar cell module, it turns on the warning lamp 21 to inform the administrator that the solar cell module M has been stolen. The theft position is displayed on the monitor 22, and at the same time, the alarm mail transmission means 23 transmits an alarm mail to the administrator's mobile phone or the like to notify that the solar cell module M has been stolen and the theft position. To do.

  The alarm means 20 is not limited to the above-described one. For example, a threatening means that emits sound or light is provided in the vicinity of each solar cell module M, and the warning means 20 activates a threatening means corresponding to the theft position. You may make it prevent theft.

  Next, a control flow of theft monitoring control (hereinafter referred to as a theft monitoring control process) in the theft monitoring device 1 of the solar cell module will be specifically described with reference to FIG.

  As shown in FIG. 4, in the theft monitoring control process, first, in step S1, the theft detection unit 10 inputs a pulse signal as a monitoring signal from the input / output unit 6 connected to one end of the signal line 4, Thereafter, the timer T is started in step S2.

In step S3, it waits until the time elapses X _0, after the time X _0, in step S4, the initial value 1 is assigned to the variable i.

In step S5, the theft detection unit 10 determines whether a response signal has been received. If NO is determined in step S5, it is determined in step S6 whether the timer T is equal to or less than X _i (currently X = 1 because i = ₁ ). If YES is determined, the process returns to step S5. That is, if i = 1, steps S5 and S6 are repeated until a response signal is received while the condition X ₀ <T ≦ X ₁ is satisfied.

If NO is determined in step S6, that is, if no response signal is received within the time of X ₀ <T ≦ X ₁ , the theft detection unit 10 determines that the solar cell module of module number 1 in step S7. It is determined that M has been stolen, and in step S8, the module number of the stolen solar cell module M is output to the alarm means 20 as a theft position signal, and the process proceeds to step S10.

On the other hand, if YES is determined in step S5, that is, if a response signal is received within the time of X ₀ <T ≦ X ₁ , in step S9, time X _i (currently i = 1, X ₁ ). The process waits until elapses and proceeds to step S10.

  In step S10, the variable i is incremented and the process proceeds to step S11. In step S11, it is determined whether the variable i is larger than n, which is the number of solar cell modules. If NO is determined, the process returns to step S5. That is, the flow of steps S5 to S11 is repeated n times.

  If YES is determined in step S11, that is, after determining whether or not n response signals are detected, the timer T is reset in step S12, and the process returns (returns to step S1).

  In the control flow of FIG. 4, the response element 5c to which no response signal is returned is detected, and the theft position information is transmitted every time the module number of the stolen solar cell module M is specified. Like the control flow shown, the module number of the identified stolen solar cell module may be stored, and the theft position information may be transmitted collectively. In the control flow of FIG. 5, the module number is stored without transmitting the theft position signal in step S8 in the control flow of FIG. 4, and step S13 is inserted between steps S11 and S12. Then, the theft position signal is transmitted collectively.

  Furthermore, when transmitting the stolen position signal in a lump, the module number of the solar cell module M corresponding to the response element 5c to which the response signal is returned is stored, and after receiving all the response signals, It is also possible to extract a module number that is not stored from 1 to n and specify the module number of the stolen solar cell module M.

  The operation of the present embodiment will be described.

  In the solar cell module antitheft monitoring device 1 according to the present embodiment, the signal lines 4 are formed such that the wiring lengths from the antitheft monitoring device body 3 to the solar cell modules M are different from each other. The connection part of the module M includes a response element 5c that returns a response signal when a monitor signal is received. The monitor signal is transmitted from one end of the signal line 4, and the response signals returned from the response elements 5c are sequentially transmitted. The response element 5c that is received and the response signal is not returned is detected, and the solar cell module M corresponding to the response element 5c that does not receive the response signal is detected to be stolen. .

  Thereby, even if a plurality of solar cell modules M are stolen, the plurality of stolen solar cell modules M can be individually specified.

  Further, the theft monitoring device 1 of the solar cell module is not configured to constantly flow current through the loop circuit 2 as in Patent Document 1, but is configured to transmit a monitoring signal at predetermined time intervals, so that power consumption is low. Can be suppressed.

  In the solar cell module theft monitoring device 1, the signal line 4 has one end connected to the theft monitoring device main body 3 and the other end branched to be connected to each of a plurality of solar cell modules M to be monitored. Therefore, it is possible to perform theft monitoring only by outputting one monitoring signal from the theft monitoring device main body 3, and it is possible to simplify the theft monitoring device main body 3 and further reduce power consumption. .

  Furthermore, in the theft monitoring device 1 of the solar cell module, the signal line 4 is formed so that the wiring length from the theft monitoring device body 3 to each solar cell module M is different by a certain length ΔL. Response signals can be received at equal intervals by the main body 3, and the theft position table 11 can be easily set.

  The present invention is not limited to the above-described embodiment, and it is needless to say that various modifications can be made without departing from the spirit of the present invention.

  For example, when there are a large number of solar cell modules M to be monitored, branching increases and the monitoring signal is attenuated. In such a case, a plurality of solar cell modules M to be monitored are arranged. Theft monitoring may be performed for each group by dividing into groups. In this case, since a monitoring signal is output to each group, it is possible to reduce the number of solar cell modules M to be monitored with respect to one monitoring signal and suppress attenuation of the monitoring signal.

  Moreover, in the said embodiment, although it comprised so that the edge part of the signal wire | line 4 extended from the theft monitoring apparatus main body 3 might be branched and connected to each of the several solar cell module M used as the monitoring object, it is not restricted to this. Instead, the theft monitoring device body 3 and each solar cell module M may be individually connected using a plurality of signal lines having different lengths. In this case, if the monitoring signal is transmitted simultaneously to each of the plurality of signal lines, the response signal is sequentially received from each response element 5c.

  In the said embodiment, although the case where the theft of the solar cell module M was detected was demonstrated, according to this invention, the connection part 5 is provided in each of the solar cell panel which comprises the solar cell module M, and solar It is also possible to detect theft of the battery panel.

DESCRIPTION OF SYMBOLS 1 Solar cell module theft monitoring apparatus 3 Theft monitoring apparatus main body 4 Signal line 5 Connection part 5a Signal line side connector 5b Module side connector 5c Response element 10 Theft detection part M Solar cell module

Claims (5)

The theft monitoring device body,
While connecting the theft monitoring device body and a plurality of solar cell modules to be monitored, signal lines formed so that the wiring length from the theft monitoring device body to each of the solar cell modules is different, and
A response element that is provided at each of the connection portions of the signal line and each of the solar cell modules and returns a response signal to the signal line when a monitoring signal is received via the signal line;
The theft monitoring apparatus main body transmits the monitoring signal from one end of the signal line, sequentially receives response signals returned from the response elements, and corresponds to a response element to which the response signal is not returned. A theft monitoring device for a solar cell module, comprising a theft detection unit for detecting that the solar cell module has been stolen. 2. The sun according to claim 1, wherein one end of the signal line is connected to the theft monitoring apparatus main body, and the other end is branched and connected to each of a plurality of solar cell modules to be monitored. Battery module theft monitoring device. 3. The theft monitoring device for solar cell modules according to claim 1, wherein the signal lines are formed such that wiring lengths from the theft monitoring device main body to the solar cell modules are different by a certain length. 4. The connecting portion is
The signal line side connector provided at the end of the signal line and the solar cell module, the response element is mounted, and when the signal line side connector is fitted, the signal line and the A module-side connector configured to be electrically connected to the response element,
2. When the solar cell module is stolen, the signal line side connector and the module side connector are disengaged, and the signal line and the response element are electrically disconnected. A theft monitoring device for a solar cell module according to any one of? A theft monitoring device for a solar cell module according to any one of claims 1 to 4,
Alarm means for issuing an alarm when the theft monitoring device of the solar cell module determines that the solar cell module has been stolen;
A theft monitoring system for solar cell modules, comprising: