JP6014854B2 - Solar panel equipment management system - Google Patents

Description

  The present invention relates to a facility management system for solar cell panels.

  Conventionally, in a photovoltaic power generation system, a plurality of solar cells (also referred to as solar cell modules) configured by electrically connecting a plurality of solar cells (cells) in series or in parallel are connected in series. By connecting and configuring what is called a solar cell string, the power generation voltage is increased, and furthermore, a plurality of solar cell strings are connected in parallel to form a solar cell array so that predetermined power can be obtained. Things are known.

  In this type of solar power generation system, a monitoring control device is provided between solar cell strings to detect an abnormality such as a failure of the solar cell string (see, for example, Patent Document 1).

JP-A-7-177852

  By the way, the larger the photovoltaic power generation facility, the larger the number of solar cell panels. For example, in the facility of the solar power generation facility installed in a mountain or the like, the number of solar cell panels is enormous.

  In such a photovoltaic power generation facility, it is not easy to identify a failure of a solar cell panel by monitoring for each string, and it is desired to monitor this solar cell panel for each solar cell panel.

  Therefore, the monitoring control device is individually attached to the solar panel that is physically installed based on the design drawing, and on the monitor screen of the solar panel and the monitoring monitor that is physically installed based on the design drawing. It is necessary to associate the arrayed solar cell panels.

  However, since the number of the solar cell panels is enormous, the serial number (management number (barcode information) of the supervisory control device) is provided in advance in the supervisory control device, and the solar cell panel is physically installed. A monitoring control device is attached in order from the top in order, and a correspondence diagram of a solar cell panel physically arranged in sequence based on the design drawing and a solar cell panel arranged and displayed on the monitor screen based on the design drawing When installing the solar cell, the operator must check the barcode number and the relationship between the serial number of the monitoring and control device and the order of the solar cell panel, There is an inconvenience that it takes too much time and labor to install the monitoring control device.

  The present invention has been made in view of the above circumstances, and a monitoring control device in which a management number is given in advance is given in advance to each solar panel that is physically installed based on a design drawing. Provide a solar panel equipment management system that can automatically match the solar panel number order with the supervisory control number management number even when installed regardless of the control number order. The purpose is to do.

The solar cell panel facility management system of the present invention,
A plurality of solar panels physically installed based on the blueprints;
Each is assigned its own management number in advance, is attached to each solar panel in any order regardless of the management number, monitors the operating state of each solar panel, and stores the management number as digital data And a plurality of monitoring control devices each having a memory unit that can rewrite the management number, a communication unit, and a detection unit that detects an operating state of each of the solar cell panels ,
A data collector that collectively obtains the management number and the operation state of each of the solar cell panels as digital data by communication with a communication unit of each monitoring control device attached to the plurality of solar cell panels;
A communication control unit that controls communication with the data collector , a virtual map storage unit that stores a solar cell panel correspondence diagram corresponding to a solar cell panel physically arranged based on the design drawing, on a virtual map; A storage unit that stores an operation state of the solar battery panel acquired by communication with the data collector and a management number of the monitoring control device, and monitoring control corresponding to the management number based on the management number of the monitoring control device A control server having a processing unit for associating a device with the solar cell panel correspondence diagram on the virtual map ,
The communication control unit is provided with a blocking unit that blocks communication with the monitoring control device corresponding to the remaining management number leaving communication with the monitoring control device corresponding to one management number,
The processing unit is attached to the top solar cell panel by repeatedly identifying the solar cell panel correspondence diagram and the monitoring control device corresponding to the one management number by blocking communication by the blocking unit. And a rewriting unit that rewrites the management number of the monitoring control device in the order of the arrangement of the solar cell panels according to the determination result of the determination unit. And

  According to the present invention, the monitoring control device in which the management number is given in advance to each solar cell panel that is physically installed in order based on the design drawing, regardless of the order of the management number given in advance. Even when it is attached, the order of the numbers of the solar battery panels and the order of the management numbers of the monitoring control device can be automatically matched.

It is a perspective view which shows an example of the arrangement | positioning state of the solar cell panel which concerns on the Example of the facility management system of the solar cell panel of this invention. It is a conceptual diagram of the solar energy power generation system which concerns on the solar cell panel shown in FIG. It is a partial expanded sectional view which shows typically the internal structure of the solar cell panel shown in FIG. It is a perspective view which shows the back surface state of the solar cell panel shown in FIG. It is a circuit diagram which shows typically the connection state of the photovoltaic cell shown in FIG. 3, and the input / output terminal box shown in FIG. 4, and the relationship between a data collector and a server. It is explanatory drawing which shows an example of arrangement | positioning of the solar cell panel shown in FIG. 1, Comprising: Many solar cell panels actually arrange | positioned based on a design drawing in areas, such as a mountainous area, are typically shown. It is explanatory drawing shown. It is a schematic diagram which expands partially and shows the arrangement position of many solar cell panels physically arrange | positioned based on the design drawing shown in FIG. It is a schematic diagram which shows the state where the collection range of data overlaps. It is explanatory drawing which shows the range of the solar cell panel which can be collected by one designated data collector. On the virtual map of the virtual map storage unit, the status of the solar panel correspondence map corresponding to the solar panel physically arranged based on the design drawing on the monitor screen and the control number displayed on the monitor screen It is explanatory drawing which shows an example, Comprising: It is explanatory drawing which shows typically the state from which all the management numbers are acquired. It is explanatory drawing which shows typically the state which started only the monitoring control apparatus of management number "100001," and interrupted | blocked communication with the monitoring control apparatus of the remaining management number. It is explanatory drawing which shows typically the state which started only the monitoring control apparatus of management number "100002", and interrupted | blocked communication with the monitoring control apparatus of the remaining management number. Only the monitoring control device with the management number “100003” is activated and the communication with the monitoring control device with the remaining management number is cut off, so that the monitoring control device attached to the top solar cell panel is identified. It is explanatory drawing which shows typically the state which rewritten the management number. It is explanatory drawing which shows typically an example of the management number of a monitoring control apparatus, and the number of a solar cell panel. It is explanatory drawing which shows typically the state by which the management number of the monitoring control apparatus attached to all the solar cell panels was rewritten in order of the number of the arrangement | sequence of a solar cell. It is a flowchart for demonstrating the flow of a process of rewriting the management number of a monitoring control apparatus. It is a schematic diagram for demonstrating a process when the management number which an adjacent data collector acquires overlaps. It is explanatory drawing which shows an example for acquiring the management number of a data collector typically.

Below, the facility management system of the solar cell panel which concerns on this invention is demonstrated, referring drawings.
(Description of solar panel)
FIG. 1 is a perspective view showing an arrangement state of solar cell panels according to an embodiment of the facility management system for the solar cell panels.

  In FIG. 1, reference numeral 1 denotes a solar cell panel (solar cell module). This solar cell panel 1 is configured by electrically connecting a plurality of solar cells 2 in series or in parallel.

In the solar power generation system, a plurality of solar cell panels 1 are electrically arranged in series to form a solar cell stream 3. Here, the solar cell stream 3 is composed of four solar panels 1.

A plurality of solar cell streams 3 are connected in parallel, and a solar cell array 4 is constructed as conceptually shown in FIG. Each of the solar cell streams 3 is connected to a connection box 5.
The connection box 5 is electrically connected to a power conditioner (PCS) 7 through a current collector panel 6. These solar power generation systems are known matters.

  As shown in FIG. 3, the solar cell panel 1 is provided with white plate tempered glass on the surface on which the sunlight strikes, and the side on which the sunlight strikes is the light receiving surface 8. A weather resistant film is provided on the back surface 9 opposite to the light receiving surface 8.

  As shown in FIG. 3, a plurality of solar cells 2 are disposed between the light receiving surface 8 and the back surface 9. In the solar battery cell 2, adjacent cells are electrically connected in series or in parallel by an interconnector 11. An example of the electrical connection is schematically shown in FIG.

  As shown in FIGS. 1, 3, and 4, each solar cell panel 1 is enclosed in a rectangular shape by a rectangular frame 12 made of aluminum, and the rectangular frame 12, white tempered glass, and a weather-resistant film film. The space surrounded by is filled with resin 10.

  For example, as schematically shown in FIG. 5, the solar cell panel 1 includes a plurality of cell series connection bodies 13 </ b> A configured by connecting the + side and the − side of solar cells 2 adjacent to each other in series. 13B and 13C are connected in parallel.

  The electric power of the solar cell panel 1 is taken out via the input / output terminal box 14. As shown in FIGS. 3 and 4, the input / output terminal box 14 is provided on the back surface 9 side of the solar cell panel 1.

  As shown in FIG. 5, the input / output terminal box 14 includes a diode series connection D in which backflow prevention diodes D1, D2, and D3 are connected in series.

  The negative side of the cell series connection body 13A is connected to the anode side of the backflow prevention diode D1. The + side of the cell series connection body 13A is connected to the cathode side of the backflow prevention diode D1.

  The negative side of the cell series body 13B is connected to the anode side of the backflow prevention diode D2 and to the cathode side of the backflow prevention diode D1. The + side of the cell series body 13B is connected to the cathode side of the backflow prevention diode D2.

  The negative side of the cell series body 13C is connected to the anode side of the backflow prevention diode D3 and to the cathode side of the backflow prevention diode D2. The + side of the cell series body 13C is connected to the cathode side of the backflow prevention diode D3.

  As shown in FIGS. 1 and 4, the solar cell panel 1 is disposed obliquely on the gantry 15 so that the light receiving surface 8 can efficiently receive solar irradiation light. The gantry 15 includes, for example, a basic concrete block 15A, a solar cell panel support column 15B, and a support frame 15C.

  When the solar panel 1 is in a normal operating state (operating state scheduled in design) when it is exposed to sunlight, a predetermined analog output voltage V is generated at both ends of the diode series connection body D by power generation of each solar battery cell 2. Generated.

  The input / output terminal box 14 has an input terminal PV− and an output terminal PV +. Its input terminal PV− is connected to the anode of the backflow prevention diode D1, and its output terminal PV + is connected to the cathode of the backflow prevention diode D3. A backflow preventing diode D4 is provided between the input terminal PV− and the output terminal PV +.

The input / output terminal box 14 is used to configure a solar cell stream 3 by electrically connecting a plurality of solar cell panels 1 in series.
The solar cell panel 1 is connected in series to the adjacent solar cell panels 1 via the input / output terminal box 14, and in FIG. 4, reference numeral 16 denotes a connection cord constituting the solar cell stream 3.

(Configuration of monitoring and control device)
First, for convenience of explanation, it is assumed that the number of the solar battery panel 1 and the management number of the monitoring control device 17 are the same.

  In this input / output terminal box 14, a monitoring control device 17 that monitors the operating state of the solar cell panel 1 is modularized and incorporated. For example, the power generation output of the solar cell panel 1 is used as the power source of the monitoring control device 17.

The monitoring control device 17 has a detection unit 17 ′. The detection unit 17 ′ includes a current detection unit 17A that detects an analog output current I of the solar cell panel 1, a voltage detection unit 17B that detects an analog output voltage V of the solar cell panel 1, and the temperature of the solar cell panel 1. consists of a temperature detecting unit 1 7C for detecting, which is electrically detected by the analog output voltage V and temperature detecting section 17C which is detected by the analog output current I and the voltage detection unit 17B detected by the current detection unit 17A analog The temperature information constitutes detection information related to the operating state of the solar cell panel 1 .

  The monitoring control device 17 includes a data conversion unit (data processing unit) 17D that converts detection information of the detection unit 17 ′ into digital data, a data collector (collector) 18 having a function described later, and a control server (server) described later. The communication unit 17E that communicates with the monitoring control center MC that centrally monitors the solar battery panel 1 via the Internet in cooperation with the network 19 and the self management number given in advance are stored as digital data. In addition, a memory unit 17F in which the management number can be rewritten is provided.

  Here, the communication unit 17E includes a transmission unit and a reception unit in order to communicate with the data collector 18. In this embodiment, the control server 19 controls the data collector 18 to communicate with the data collector 18 at predetermined time intervals when acquiring detection information of each solar cell panel 1.

  The monitoring control center MC has a database for storing and storing digital data related to the analog output voltage V for each solar cell panel 1, digital data related to the analog output current I, and digital data related to temperature from the past to the present time. (The illustration is omitted).

Thereby, the supervisory control center MC can grasp the change of the output information for each solar cell panel 1 with time and can perform the failure diagnosis.
According to this embodiment, the monitoring control device 17 is integrally incorporated in the input / output terminal box 14 of each solar cell panel 1.

  Accordingly, the solar battery panels 1 are connected in series to form the solar battery stream 3, and at the same time, the operation state of each solar battery panel 1 can be monitored and controlled. Can be done.

  Moreover, compared with the case where the monitoring control for each solar cell stream 3 is performed, the monitoring control of the operating state can be quickly performed for each solar cell panel 1, and when the solar cell panel 1 breaks down, the replacement thereof is possible. Repair can be performed at low cost.

  Furthermore, there is an effect that a solar cell monitoring and control system can be constructed at a lower cost than a configuration in which a microcomputer is built in the solar cell panel 1 and a failure diagnosis is performed.

  In this embodiment, the monitoring control device 17 is built in the input / output terminal box 14. However, the present invention is not limited to this, and various modifications can be made without departing from the spirit of the present invention.

  For example, the monitoring control device 17 is built in a space where the solar cells 2 are not provided, that is, in a marginal space of the solar cell panel 1, and the monitoring control device 17 is integrated with the solar cell panel 1. You can also.

  However, when the monitoring control device 17 is built in the solar cell panel 1, even if the monitoring control device 17 itself fails and the solar cell panel 1 does not fail, the solar cell panel 1 itself must be replaced. Therefore, the replacement repair cost becomes too high.

  On the other hand, when the monitoring control device 17 is built in the input / output terminal box 14, if the monitoring control device 17 itself fails, it is only necessary to replace the input / output terminal box 14, so that replacement and repair can be performed at low cost. There is an effect that can be performed.

(Overview of facility management system for solar panel)
In the description so far, it has been described that the number of the solar battery panel 1 and the management number of the monitoring control device 17 are the same.

  However, if the monitoring control device 17 is attached to the solar cell panel 1 by associating the solar cell panel 1 with the management number given in advance one by one, it takes a lot of time for the installation work.

Therefore, the monitoring control device 17 in which the management number is given in advance to each of the solar cell panels 1 that are physically installed in order based on the design drawing is random regardless of the order of the management numbers given in advance. It shall be attached.
FIG. 6 schematically shows a large number of solar cell panels 1 that are actually physically disposed in an area such as a mountainous area based on a design drawing.

In FIG. 6, “•” indicates the data collector 18, and a circle indicated by a thin line centering on “•” indicates information from the monitoring controller 17 in which the data collector 18 is attached to the solar cell panel 1 (given in advance). The self-management number and the detection information relating to the operating state of the solar battery panel 1 ) can be obtained as digital data in a batch.

  The number of solar battery panels 1 that can be collectively acquired as digital data by the data collector 18 and the reach of radio waves can be predetermined in design. For example, in mountainous areas and the like, the distance that radio waves reach is limited due to topography and obstacles. Taking these into consideration in design, the installation position of the data collector 18 and the number of monitoring control devices 17 managed by the data collector 18 are determined.

  The number of pieces of detection information of the solar battery panel 1 that can be collected by the data collector 18 (the number of monitoring control devices 17 managed by the data collector 18) is, for example, in the range from 128 to 256.

  The number of monitoring control devices 17 that can be collected by each data collector 18 collectively may be the same for each data collector 18 or may be different. In the following description, it is assumed that the number of the monitoring control devices 17 that can collect the detection information collectively by each data collector 18 is the same.

A plurality of solar cell panels 1 are provided in each area. FIG. 7 is a schematic diagram partially showing the arrangement positions of a large number of solar cell panels 1 physically arranged based on the design diagram shown in FIG.
The solar cell panel 1 is divided into a plurality of areas, and a plurality of solar cell panels 1 are provided.

  For example, a plurality of data collectors 18 are provided for each of the areas a1 to a6. The data collector 18 is arranged based on the design drawing so that the data collection ranges overlap as shown in FIG. 8 in order to prevent data loss.

(Detailed configuration of data collector 18 and control server 19)
A management number for identifying the data collector is assigned to the data collector 18 in advance . Here, for convenience of explanation, it is assumed that the management numbers are arranged in the order determined by the design drawing.

  As shown in FIG. 5, the data collector 18 includes a communication unit 18 </ b> A with the monitoring control device 17, a storage unit 18 </ b> B that temporarily stores digital data, and a communication unit 18 </ b> C with the control server 19.

The control server 19 stores on the virtual map a communication control unit 19A that controls communication with the data collector 18 and a solar cell panel correspondence diagram corresponding to the solar cell panels 1 that are physically arranged based on the design drawing. a virtual map storage unit 19B, and the storage unit 19C which stores a management number with the operating state of the solar cell panel 1 obtained by communication with the data collector the monitor control apparatus 17, the management number of the monitoring and control device 17 And a processing unit 19D for associating the monitoring control device 17 corresponding to the management number with the solar cell panel correspondence diagram on the virtual map.

The communication control unit 19A can block communication with the data collector 18 corresponding to the management number by designating the management number of the data collector 18.
Therefore, by designating the area of the solar cell panel 1 and the management number of the data collector 18, the range of the solar cell panel 1 that can be collected by the data collector 18 is determined. For example, FIG. 9 shows the range of the solar cell panel 1 that can be collected by the single designated data collector 18.

  Here, the solar cell panel 1 shall be numbered in order from left to right. As shown in FIGS. 10 to 15, the management number is composed of items of id number, type model number, uid unit number, and static id area number.

  For example, as shown in FIG. 15, the first solar cell panel 1 is provided with a monitoring control device 17 having a management number “100003”, and the second solar cell panel 1 is monitored and controlled with a management number “100004”. The device 17 is attached, the monitoring control device 17 with the management number “100005” is attached to the third solar cell panel 1, and the monitoring control device 17 with the management number “100002” is attached to the fourth solar cell panel 1. It is assumed that the monitoring control device 17 having the management number “100001” is attached to the fifth solar cell panel 1.

  Thus, when the management number of the monitoring control device 17 is randomly attached to the solar cell panel 1, any solar cell panel 1 has a failure or abnormality on the monitor screen 20a of the monitoring device 20 of the monitoring control center MC. When judging whether it is, there is an inconvenience that it is difficult to recognize immediately.

  Therefore, in this embodiment, the communication control unit 19A leaves communication with the monitoring control device 17 corresponding to one management number among all the monitoring control devices 17 with which the designated data collector 18 can communicate. A blocking unit 19a that blocks communication with the monitoring control device 17 corresponding to the remaining management number is provided.

The processing unit 19D, the top of the solar cell by repeating to identify the monitor control apparatus 17 corresponding to one of the management number for one solar panel corresponding view 1 'by blocking of the communication by the blocking section 19a A determination unit 19b that determines the management number of the monitoring control device 17 attached to the panel 1, and the management number in order from the monitoring control device 17 attached to the top solar cell panel 1 according to the determination result of the determination unit 19b. A rewriting unit 19c for rewriting is provided.

  FIG. 11 shows a solar cell panel corresponding diagram 1 ′ corresponding to the solar cell panel 1 physically arranged on the virtual map of the virtual map storage unit 19B based on the design drawing. The state displayed on the screen 20a is shown.

  The management number given in advance is used for finding out whether or not there is a failure at the time of installation. It is unclear which management number of the monitoring control device 17 is attached to which solar cell panel 1, but anyway, when there is no failure in the monitoring control device 17 corresponding to all the management numbers, As shown in FIG. 10, all the solar cell panel corresponding FIG.

  When there is a failure in the monitoring control device 17, the solar cell panel correspondence diagram 1 'corresponding to the solar cell panel 1 to which the monitoring control device 17 is attached is not turned on.

  Here, for convenience of explanation, it is assumed that the management number is displayed on the monitor screen 20a, but it is not always necessary to display the management number on the monitor screen 20a. Further, it is not necessary to display the solar cell panel correspondence diagram 1 ′ on the monitor screen 20 a. All processing can be performed in the control server 19 by software incorporated in the control server 19.

  First, the control server 19 leaves communication with the monitoring control device 17 corresponding to the management number “100001” and performs communication with the monitoring control device 17 corresponding to the remaining management numbers “100002” to “100005”,. Cut off.

  Then, all of the solar cell panel correspondence diagrams 1 ′ corresponding to the monitoring control device 17 whose communication is cut off are turned off, and only the communicating solar cell panel correspondence diagram 1 ′ is turned on.

  The control server 19 determines whether or not the lit solar cell panel correspondence diagram 1 ′ corresponds to the top solar cell panel 1. Since the monitoring control device 17 corresponding to the management number “100001” is attached to the fifth solar cell panel 1 in this example, as shown in FIG. Illuminated.

  Next, the control server 19 leaves communication with the monitoring control device 17 corresponding to the management number “100002”, and the monitoring control device 17 corresponding to the remaining management numbers “100001”, “100003” to “100005”,. Block communication with.

  Similarly, the control server 19 determines whether or not the lit solar cell panel correspondence diagram 1 ′ corresponds to the top solar cell panel 1. In this example, since the monitoring control device 17 corresponding to the management number “100002” is attached to the fourth solar cell panel 1, as shown in FIG. 12, the fourth solar cell panel corresponding FIG. Illuminated.

  Next, the control server 19 leaves communication with the monitoring control device 17 corresponding to the management number “100003” and corresponds to the remaining management numbers “100001”, “100002”, “100004”, “100005”,. Communication with the monitoring control device 17 is cut off.

  Similarly, the control server 19 determines whether or not the lit solar cell panel correspondence diagram 1 ′ corresponds to the top solar cell panel 1. In this example, the monitoring control device 17 corresponding to the management number “100003” is attached to the first solar cell panel 1, and therefore, as shown in FIG. Illuminated.

  When the head solar cell panel 1 is specified, the control server 19 performs control to rewrite the management number “100003” of the monitoring control device 17 attached to the solar cell panel 1 to “1”.

The control server 19 performs the same processing on the second and subsequent solar cell panels 1 to associate the order of the solar cell panels 1 with the order of the management numbers as shown in FIG.
Hereinafter, an example of this process will be described with reference to the flow shown in FIG.

(Example of management number rewrite processing steps)
The control server 19 introduces the solar cell panel correspondence diagram 1 ′ corresponding to the solar cell panels 1 physically arranged based on the design drawing from the database on the virtual map (S.1).

The control server 19 specifies the positions of all the data collectors 18 (S.2). The specification of the position of the data collector 18 will be described later.
Next, one data collector 18 is activated, and all the solar cell panel correspondence diagrams 1 ′ corresponding to the monitoring control devices 17 in the entire range covered by the one data collector 18 are turned on. (S.3).

  Next, the control server 19 turns on the solar panel correspondence diagram 1 ′ corresponding to one of the monitoring control devices 17 according to the order of the management numbers, and turns off all the remaining monitoring control devices according to the management numbers. (S.4).

  In this example, the control server 19 determines whether or not the monitoring control device 17 corresponding to the management number “100001” is the first monitoring control device 17 in the area (S.5). If the monitoring control device 17 does not correspond to the first solar cell panel 1, the process returns to step 4.

  Next, the control server 19 turns on the monitoring control device 17 corresponding to the management number “100002” and turns off the monitoring control devices 17 corresponding to all remaining management numbers.

  The control server 19 is an S.I. 4, S.M. By repeating the process 5, the management number of the monitoring control device 1 attached to the first solar cell panel 1 (first solar cell panel 1) is specified (S.6).

  In this example, since the management number of the monitoring control device attached to the top solar cell panel 1 is “100003”, the control server 19 manages the monitoring control device 17 attached to this solar cell panel 1. Correspondence for rewriting the number “100003” to “1” is performed (S.6).

The control server 19 sets the S.D. in the order of the management numbers for the remaining monitoring control devices 17 that are not associated with the rewriting of the management numbers. 4 to S.M. 6 is performed to associate the management numbers of all the monitoring control devices 17 with the rewriting of the management numbers (S.7). Then, Con toll server 19 determines whether or not the correspondence rewriting management number for all of the monitoring control device 17 has been completed (S.8).

  Then, when the management number rewriting association is completed for all the monitoring control devices 17, the control server 19 performs a process of rewriting the management number for each monitoring control device 17 according to the rewriting association information ( S.8).

  That is, the control server 19 transmits to the data collector 18 a command signal for simultaneously rewriting the management numbers of all the monitoring control devices 17 and rewriting information of the management numbers.

As a result, the management number of the monitoring control device 17 attached to the top solar cell panel 1 is rewritten in the order of arrangement of the solar cell panels 1.
Subsequently, the control server 19 starts the second and subsequent data collectors 18 in order.

The control server 19 also performs S.P. 4 to S.M. 8 is performed to rewrite the management number of the monitoring control device 17 (S.9). Thus, the order of the management number of the first solar cell panel 1 from the monitoring control unit in the order of the sequence 17 is associated.

In the above example, the operation information of the solar battery panel 1 that can be collected by the data collector 18 has been described as not overlapping.
However, as shown in FIG. 8, even when the management numbers of the monitoring control devices 17 to be managed by the adjacent data collectors 18 are overlapped, the management number order of the monitoring control devices 17 is the same as the order of the solar battery panels 1. Can be associated.

(When the data collector 18 adjacent to the side acquires the management number by overlapping)
When the data collectors 18 adjacent to each other overlap and acquire the management number, the control server 19 can determine which solar cell panel 1 the overlap starts and which solar cell panel 1 ends.

  For example, as schematically shown in FIG. 17, the management numbers A, B, C, and D obtained by being overlapped by the left data collector 18 and the management obtained by being overlapped by the right data collector 18 Assume that numbers A, B, C, and D exist.

  In this case, for the data collector 18 on the left side, the management number of the monitoring control device 17 attached to the solar cell panel 1 immediately before the solar cell panel 1 to which the monitoring control device 17 with the management number A is attached is acquired. The management number of the monitoring control device 17 attached to the solar cell panel 1 immediately after the solar cell panel 1 to which the monitoring control device 17 with the management number D is attached is not acquired.

  On the other hand, for the data collector 18 on the right side, the management number of the monitoring control device 17 attached to the solar cell panel 1 immediately before the solar cell panel 1 to which the monitoring control device 17 with the management number A is attached is not acquired. The management number of the monitoring control device 17 attached to the solar cell panel 1 immediately after the solar cell panel 1 to which the monitoring control device 17 having the management number D is attached is acquired.

Therefore, in the control server 19, the management number A is the management number of the monitoring control device 17 belonging to the left data collector 18, and the management number D is the management number of the monitoring control device belonging to the right data collector 18. Can be recognized.

  For the management numbers B and C, the control server 19 determines that the management number B corresponds to the monitoring control device 17 belonging to the left data collector 18, and the management number C belongs to the right data collector 18. It is determined that it corresponds to the monitoring control device 17 to be performed.

Assuming that the solar cell panels 1 are arranged squarely and symmetrically, even if they are made to correspond in this way, no contradiction occurs.
The same applies when the data collectors 18 are adjacent vertically. This concept can be extended to the case where three or more monitoring control devices 17 to be managed by the data collector 18 overlap.

  In general, even if the solar cell panels 1 are not arranged in a square shape, the control server 19 overlaps because the number of solar cell panels 1 arranged in the lateral direction is determined by design. Can recognize the number of management numbers. For this reason, the arrangement | sequence shape of the solar cell panel 1 is not restricted to a square.

(Rewrite processing of management number of data collector 18)
As for the data collector 18 as well, the data collector 18 to which the management number is given in advance is assigned in the order of the areas of the solar cell panels 1 that are physically installed in order based on the design drawing. Even when the data collectors 18 are arranged regardless of the order, the management numbers can be associated with the order of the areas.

For example, as shown in FIG. 18, the control server 19 activates the data collectors 18 at once and acquires information on the management numbers of the data collectors 18.
When the data collectors 18 are started all at once, the data collector corresponding points P corresponding to all the management numbers are turned on on the monitor screen.

The control server 19 activates only the data collector 18 with the first management number, and performs a process of stopping the activation of the remaining data collectors 18 with the second and subsequent management numbers.

  The control server 19 repeats this process until the data collector 18 having the management number corresponding to the first area b1 is specified. When the management number corresponding to the first area b1 is specified, the management number of the data collector 18 is rewritten to the management number of the first area b1.

The control server 19 performs the same process for the data collector 18 corresponding to the management number corresponding to the remaining areas b2,.
If this process is performed for all the data collectors 18, the order of the management numbers of the data collectors 18 can be made to correspond to the order of the areas b1 to b6,.

  In the above description, for convenience of explanation, first, the order of the management numbers of the monitoring control device 17 is made to correspond to the order of the arrangement of the solar battery panels 1 first, and the order of the management numbers of the data collector 18 to the order of the areas. Was explained later as corresponding.

  However, this is for convenience of explanation. When there are a plurality of data collectors 18, first, a rewrite process for matching the numbers of the management numbers of the data collectors 18 to the numbers of the areas b 1 to b 6,. I do.

Next, the data collector 18 is activated in accordance with the order of the management numbers after the rewriting process, and thereby the rewriting process of the monitoring control device 17 of the solar cell panel 1 is performed.

  If such a rewriting process is performed, even if the monitoring control device 17 is connected to the solar cell panel 1 and attached to the solar cell panel 1 with the management number of the monitoring control device 17 corresponding to the random number, the solar cell panel 1 The operation information can be acquired in the order of arrangement.

(Modification)
In the above embodiment, the control server 19 has been described as automatically rewriting.
However, the present invention is not limited to this.
For example, designation means for designating a predetermined management number by the monitoring device of the monitoring control center MC and designating the management number of the monitoring control device 17 that blocks communication via the control server 19 and the data collector 18 It is good also as a structure to provide.

  If comprised in this way, it will monitor in the order of the number of the solar cell panel 1, even when the monitoring control apparatus 17 to which the management number was given previously was attached to the solar cell panel 1 in arbitrary orders, confirming the management number. It is possible to match the number of the control device 17.

DESCRIPTION OF SYMBOLS 1 ... Solar cell panel 2 ... Solar cell 3 ... Solar cell stream 14 ... Input / output terminal box 17 ... Monitoring control device 17 '... Detection part 17A ... Current detection part 17B ... Voltage detection part 17C ... Temperature detection part 17D ... Data conversion Part (processing part)
17E ... Communication unit 17F ... Memory unit 18 ... Data collector (collector)
19 ... Control server (server)
19A ... Communication control unit 19B ... Virtual map storage unit 19C ... Storage unit 19D ... Processing unit MC ... Monitoring control center 20 ... Monitoring monitor device 20a ... Monitor screen V ... Analog output voltage I ... Analog output current

Claims (7)

A plurality of solar panels physically installed based on the blueprints;
Each is assigned its own management number in advance, is attached to each solar panel in any order regardless of the management number, monitors the operating state of each solar panel, and stores the management number as digital data And a plurality of monitoring control devices each having a memory unit that can rewrite the management number, a communication unit, and a detection unit that detects an operating state of each of the solar cell panels ,
A data collector that collectively obtains the management number and the operation state of each of the solar cell panels as digital data by communication with a communication unit of each monitoring control device attached to the plurality of solar cell panels;
A communication control unit that controls communication with the data collector , a virtual map storage unit that stores a solar cell panel correspondence diagram corresponding to a solar cell panel physically arranged based on the design drawing, on a virtual map; A storage unit that stores an operation state of the solar battery panel acquired by communication with the data collector and a management number of the monitoring control device, and monitoring control corresponding to the management number based on the management number of the monitoring control device A control server having a processing unit for associating a device with the solar cell panel correspondence diagram on the virtual map ,
The communication control unit is provided with a blocking unit that blocks communication with the monitoring control device corresponding to the remaining management number leaving communication with the monitoring control device corresponding to one management number,
The processing unit is attached to the top solar cell panel by repeatedly identifying the solar cell panel correspondence diagram and the monitoring control device corresponding to the one management number by blocking communication by the blocking unit. And a rewriting unit that rewrites the management number of the monitoring control device in the order of the arrangement of the solar cell panels according to the determination result of the determination unit. A solar panel equipment management system. The solar cell panel facility management system according to claim 1 , wherein the data collector and the control server are connected to each other via the Internet. The control server is provided with a transmission unit that transmits information relating to the solar cell panel correspondence map stored in the virtual map storage unit and information from the monitoring control device to the monitoring device. monitor screen is provided to display the solar cell panel corresponding view, claim 1, characterized in that it is recognizable management number of the monitoring control system on the monitor screen is attached to the top of the solar cell panel Or the facility management system of the solar cell panel of Claim 2 . The monitoring device is provided with a designation means for designating the predetermined management number and designating a monitoring control device that cuts off the communication via the control server and the data collector. The facility management system for a solar cell panel according to claim 3 , The solar cell panel is divided into a plurality of areas, and a plurality of the data collectors are provided for each of the divided areas. The plurality of data collectors are overlapped across the sections to perform the monitoring control. The solar cell panel facility management system according to any one of claims 1 to 4 , wherein the management number is acquired from an apparatus. A management number for identifying the data collector is assigned to the plurality of data collectors, the data collectors are arranged in any order in the sections, and the control server corresponds to the area of the solar cell panel. virtual area storage unit for storing a virtual area is provided, wherein the control server, the claims and blocking communication with the data collector, wherein the data collector identifies the area of the solar cell panel to obtain 5. A facility management system for solar cell panels according to 5 . The solar cell panel is connected in series to solar cell panels adjacent to each other via an input / output terminal box, and the monitoring control device is modularized and built in the input / output terminal box. The facility management system for a solar cell panel according to any one of claims 1 to 6 .