CN112713656A - Photovoltaic tracker field debugging system and method and debugging terminal - Google Patents

Abstract

The invention discloses a photovoltaic tracker field debugging system, which comprises: the debugging terminal is used for scanning an identification code to start a debugging program, and the identification code is a tracker identification; the adapter is provided with a first communication interface and a first LORA unit and is used for converting a debugging command into a serial port test signal and sending the serial port test signal to the tracker through the first LORA unit so as to enable the debugging terminal to establish debugging connection with the tracker; after the debugging terminal is connected with the tracker, reading tracker information from a debugging server, and performing parameter debugging on the tracker; the invention also discloses a photovoltaic tracker field debugging method. The photovoltaic tracker solves the technical problems that in the prior art, field debugging operation of the photovoltaic tracker is complex, equipment is inconvenient to carry, and system maintenance cost is increased due to lack of unified management of data.

Description

Photovoltaic tracker field debugging system and method and debugging terminal

Technical Field

The invention relates to the field of photovoltaic power station debugging, in particular to a photovoltaic tracker field debugging system, a photovoltaic tracker field debugging method and a photovoltaic tracker field debugging terminal.

Background

Photovoltaic power generation is a power generation mode for directly converting light energy into electric energy, is used as a novel clean energy source, has a great number of advantages in the actual application process, obtains very wide application, and how to improve the conversion efficiency of solar energy is the key for reasonably and massively applying the solar energy, and a photovoltaic tracking system is generated at the right moment. However, in practical application, since on-site debugging cannot be performed, for daily maintenance and debugging of a photovoltaic tracking system such as a photovoltaic tracker, parameters need to be configured to the control board in a wireless manner. The basic process is as follows: connecting an LORA module for debugging to a handheld computer, opening special upper computer software, and modifying factory parameters of the LORA module in a wireless configuration mode; then the module is reconnected to configure the operation parameters of the tracker. In the process, other control boxes nearby must be powered off, otherwise wireless interference can be generated, and local parameters are configured to other control boxes. The method has very high requirements on debugging personnel, and if misoperation or wrong parameter matching occurs, the defect eliminating work at the later stage is very time-consuming; if water exists or climbing is needed, and the like, carrying large debugging equipment is also a relatively laborious thing; moreover, the lack of uniform management of data, such as the debugging situation that the parameters of the tracker are not known in the next maintenance due to the difference of the debugging personnel, will certainly increase the maintenance cost of the system.

Disclosure of Invention

The invention aims to provide a photovoltaic tracker field debugging system, a photovoltaic tracker field debugging method and a photovoltaic tracker field debugging terminal, which are used for solving the technical problems that in the prior art, the photovoltaic tracker field debugging operation is complex, the equipment is inconvenient to carry, and the system maintenance cost is increased due to lack of unified management of data.

The technical scheme provided by the invention is as follows:

a photovoltaic tracker field commissioning system, comprising:

the debugging terminal starts a debugging program by scanning an identification code, wherein the identification code is a tracker identifier and is fixed on the tracker;

the adapter is provided with a first communication interface and a first LORA unit and is used for converting a debugging command into a serial port test signal and sending the serial port test signal to the tracker through the first LORA unit so as to enable the debugging terminal to establish debugging connection with the tracker;

after the debugging terminal is connected with the tracker, the tracker information can be read from a debugging server by scanning the tracker identification, and the parameter debugging is carried out on the tracker;

the debugging server can store the parameter information after the tracker is debugged.

Further, the adapter has a magnetic attraction function.

Further, the debugging server includes:

the user management module is used for receiving registration information of the debugging terminal, and the registration information comprises a user name and authority information of the debugging terminal;

the tracker management module is used for acquiring tracker information, and the tracker information comprises the tracker identification, the equipment information and the control parameters;

and the storage module is used for storing the registration information, the tracker information and the parameter information after the tracker is debugged.

Further, the debugging server further includes:

and the log module is used for recording log data of debugging the tracker by the debugging terminal.

Further, the debugging server further includes:

and the industrial control interface is used for receiving the tracker information sent by the tracker industrial personal computer when leaving the factory.

Further, the debugging terminal includes:

the configuration module is contained in a debugging program and used for configuring debugging parameters of the tracker and generating a debugging command;

the second communication interface is used for being in communication connection with the adapter and sending the debugging command to the adapter, and the second communication interface comprises but is not limited to a Bluetooth interface;

a third communication interface for communicating with the debug server and for reading tracer information from the debug server;

the second communication interface is further used for sending debugging parameters to the tracker through the first LORA unit;

the third communication interface is further configured to send the debugging parameters to the debugging server.

The invention also provides a photovoltaic tracker field debugging method, which comprises the following steps:

the debugging terminal scans the tracker identification code, starts a debugging program and generates a debugging command;

the adapter converts the debugging command into a serial port test signal, and sends the serial port test signal to the tracker through a first LORA unit of the adapter, so that the debugging terminal and the tracker establish debugging connection;

after the debugging terminal is connected with the tracker, reading tracker information from a debugging server, and performing parameter debugging on the tracker;

and the debugging server stores the debugged parameter information.

Further, the debugging server includes:

the user management module is used for receiving registration information of the debugging terminal, and the registration information comprises a user name and authority information of the debugging terminal;

the tracker management module is used for acquiring tracker information, and the tracker information comprises the tracker identification, the equipment information and the control parameters;

and the storage module is used for storing the registration information, the tracker information and the parameter information after the tracker is debugged.

Further, the debugging server further includes:

and the log module is used for recording log data of debugging the tracker by the debugging terminal.

Further, the debugging server further includes:

and the industrial control interface is used for receiving the information of the tracker when leaving the factory, which is sent by the industrial control computer of the tracker.

Further, the debugging terminal includes:

the configuration module is contained in a debugging program and used for configuring debugging parameters of the tracker and generating a debugging command;

the second communication interface is used for being in communication connection with the adapter and sending the debugging command to the adapter, and the second communication interface comprises but is not limited to a Bluetooth interface;

a third communication interface for communicating with the debug server and for reading tracer information from the debug server;

the second communication interface is further used for sending debugging parameters to the tracker through the first LORA unit;

the third communication interface is further configured to send the debugging parameters to the debugging server.

The photovoltaic tracker field debugging system, the photovoltaic tracker field debugging method and the photovoltaic tracker field debugging terminal provided by the invention have the following beneficial effects that:

1. the device such as the Lora module is not required to be connected through a USB interface, the operation is simple, and the requirement on debugging personnel is not high.

2. An intelligent terminal such as a smart phone and a special adapter can complete debugging, and debugging personnel can carry the intelligent terminal conveniently.

3. Through debugging server remote control and real-time data management, very big improvement photovoltaic tracking system field debugging's work efficiency, reduced the cost of labor effectively.

Drawings

The essential features, technical features, advantages and modes of realisation of the present invention will be further described in the following, in a clearly understandable manner, in connection with the description of preferred embodiments in connection with the accompanying drawings.

FIG. 1 is a schematic structural diagram of a photovoltaic tracker field commissioning system of the present invention;

FIG. 2 is a schematic diagram of a debug server according to the present invention;

FIG. 3 is a schematic diagram of another debugging server of the present invention;

FIG. 4 is a schematic diagram of a debugging server according to another embodiment of the present invention;

FIG. 5 is a schematic diagram of a debug terminal according to the present invention;

fig. 6 is a flowchart of a photovoltaic tracker field commissioning method of the present invention.

The reference numbers illustrate:

01. the system comprises a debugging terminal, 02, an adapter, 03, a debugging server, 11, a configuration module, 12, a second communication interface, 13, a third communication interface, 31, a user management module, 32, a tracker management module, 33, a storage module, 34, a log module and 35, an industrial control interface.

Detailed Description

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the following description will be made with reference to the accompanying drawings. It is obvious that the drawings in the following description are only some examples of the invention, and that for a person skilled in the art, other drawings and embodiments can be derived from them without inventive effort.

For the sake of simplicity, the drawings only schematically show the parts relevant to the present invention, and they do not represent the actual structure as a product. In addition, in order to make the drawings concise and understandable, components having the same structure or function in some of the drawings are only schematically illustrated or only labeled. In this document, "one" means not only "only one" but also a case of "more than one".

Any process or method descriptions in flow charts or otherwise described herein may be understood as representing modules, segments, or portions of code which include one or more executable instructions for implementing specific logical functions or steps of the process, and alternate implementations are included within the scope of the preferred embodiment of the present invention in which functions may be executed out of order from that shown or discussed, including substantially concurrently or in reverse order, depending on the functionality involved, as would be understood by those reasonably skilled in the art of the present invention.

In an embodiment of the present invention, as shown in fig. 1, a photovoltaic tracker field commissioning system includes:

the debugging terminal 01 scans an identification code to start a debugging program, wherein the identification code is a tracker identifier and is fixed on a tracker;

the adapter 02 is provided with a first communication interface and a first LORA unit and is used for converting a debugging command into a serial port test signal and sending the serial port test signal to the tracker through the first LORA unit so that the debugging terminal 01 and the tracker establish debugging connection;

after the debugging terminal 01 is connected with the tracker, the tracker information can be read from the debugging server 03 by scanning the tracker identification, and parameter debugging is carried out on the tracker;

the debugging server 03 can store the parameter information after the tracker is debugged.

In the embodiment of the invention, the debugging terminal 01 runs special debugging application software by scanning the identification code such as the two-dimensional code, and the debugging terminal 01 can be a portable smart phone or a tablet computer; the adapter 02 is provided with a lithium battery and used for converting the debugging command into a serial port test signal, and the adapter 02 or a shell thereof has a magnetic attraction function, so that the adapter can be attracted to a tracker or a nearby stand column or a nearby cross beam during debugging, and is convenient to carry; and the debugging server 03 is connected with the tracker and is used for storing the parameter information after debugging. When the staff debugs on site, the factory information of the tracker can be read from the debugging server 03 as long as the debugging terminal 01, such as a smart phone APP scanning identification code, such as a two-dimensional code, is used, the adapter 02 is conveniently connected with the tracker to debug parameters, and the debugged parameters are automatically stored in the debugging server 03. The operation is simple, the requirement on debugging personnel is not high, and the debugging terminal 01 can be a small intelligent terminal such as a smart phone and a tablet personal computer, so that the carrying of the debugging personnel is facilitated.

Further, as shown in fig. 2, the debugging server 03 includes:

the user management module 31 is configured to receive registration information of the debugging terminal 01, where the registration information includes a user name and authority information of the debugging terminal 01;

a tracker management module 32, configured to obtain tracker information, where the tracker information includes the tracker identifier, the device information, and the control parameter;

and the storage module 33 is configured to store the registration information, the tracker information, and the parameter information after the tracker is debugged.

In the embodiment of the invention, the debugging server 03 receives the registration information of the management debugging terminal 01, the tracker information and the parameter information after the tracker debugging, so that a system administrator can conveniently manage the authority of the current user of the server and know the operation and debugging conditions of the tracker in real time. Preferably, the debugging server 03 software architecture adopts a B/S architecture, and not only can a system administrator, but also personnel such as a project manager and sales can know the operation and debugging conditions of the tracker in real time by means of authorized access to a web page.

In another embodiment of the present invention, as shown in fig. 3, the debugging server 03 further includes:

and the log module 34 is used for recording log data of debugging the tracker by the debugging terminal 01.

Specifically, the log module records the log data of the debugging terminal 01 for debugging the tracker, so that a system administrator can perform authority management on the current user of the debugging server 03, query the equipment and the operation logs in the database, and facilitate the daily maintenance work of the system administrator for the work of continuously counting and outputting reports of the equipment which is delivered from the factory and has been debugged on site.

In another embodiment of the present invention, as shown in fig. 4, the debugging server 03 further includes:

and the industrial control interface 34 is used for receiving the information of the tracker when leaving the factory, which is sent by the industrial control computer of the tracker, and the information of the tracker comprises the identifier of the tracker, equipment information and control parameters.

Specifically, the factory data table from the tracker is received through the industrial control interface 34, so that the parameters of each tracker from the factory are saved in the server database.

Specifically, before a control box of the tracker leaves a factory, a factory program and factory parameters must be programmed, and the parameters include a wireless module parameter and a control box parameter. For the same project, the factory parameters of the control box must be ensured to be the same; moreover, in order to achieve interference-free debugging, the network ID numbers of the wireless modules must be different from each other and the control boxes of the project must be numbered when being produced; after parameter configuration is completed, after the test is passed, the parameters are stored in a local delivery data table; meanwhile, according to the information of the product such as the type, the production time, the batch number, the item number, the test serial number and the like, a unique identification code such as a two-dimensional code is produced to be used as a unique identifier of the product and correspond to factory parameters one by one, and a factory data table is stored in a local database and a debugging server database; and after the identification code printer finishes printing the identification code, the label is pasted on the control box body of the tracker.

In an embodiment of the present invention, as shown in fig. 5, the debug terminal 01 includes:

a configuration module 11, included in a debugging program, for configuring the debugging parameters of the tracker and generating a debugging command;

a second communication interface 12, configured to perform a communication connection with the adaptor 02 and send the debug command to the adaptor 02, where the second communication interface includes but is not limited to a bluetooth interface;

a third communication interface 13, configured to communicate with the debugging server 03, and configured to read tracker information from the debugging server 03;

the second communication interface 12 is further configured to send debug parameters to the tracker via the first LORA unit;

the third communication interface 13 is further configured to send the debugging parameters to the debugging server 03.

In this embodiment, the debugging terminal 01 reads the tracker information from the debugging server 03, configures the debugging parameters of the tracker, generates the debugging command, sends the debugging command to the adapter 02, and sends the debugged debugging parameters to the debugging server 03.

In an embodiment of the present invention, as shown in fig. 6, a photovoltaic tracker field commissioning method includes:

s1, scanning a tracker identification code by a debugging terminal, starting a debugging program and generating a debugging command;

s2, the adapter converts the debugging command into a serial port test signal, and the serial port test signal is sent to the tracker through a first LORA unit of the adapter, so that the debugging terminal and the tracker are in debugging connection;

s3, after the debugging terminal is connected with the tracker, reading tracker information from a debugging server, and performing parameter debugging on the tracker;

and S4, the debugging server stores the parameter information after debugging.

The debugging server 03 is connected with the tracker and used for storing the parameter information after debugging.

In the embodiment of the invention, the debugging terminal 01 runs special debugging application software by scanning the identification code such as the two-dimensional code, and the debugging terminal 01 can be a portable smart phone or a tablet computer; the adapter 02 is provided with a lithium battery and used for converting the debugging command into a serial port test signal, and the adapter 02 has a magnetic attraction function on the shell, so that the adapter can be attracted to a stand column or a cross beam near the tracker during debugging and is convenient to carry; and the debugging server 03 is connected with the tracker and is used for storing the parameter information after debugging. When the staff debugs on site, the factory information of the tracker can be read from the debugging server 03 as long as the debugging terminal 01, such as a smart phone APP scanning identification code, such as a two-dimensional code, is used, the adapter 02 is conveniently connected with the tracker to debug parameters, and the debugged parameters are automatically stored in the debugging server 03. The operation is simple, the requirement on debugging personnel is not high, and the debugging terminal 01 can be a small intelligent terminal such as a smart phone and a tablet personal computer, so that the carrying of the debugging personnel is facilitated.

Further, the debugging server 03 of the field debugging method for the photovoltaic tracker in the present invention includes:

the user management module 31 is configured to receive registration information of the debugging terminal 01, where the registration information includes a user name and authority information of the debugging terminal 01;

a tracker management module 32, configured to obtain tracker information, where the tracker information includes the tracker identifier, the device information, and the control parameter;

and the storage module 33 is configured to store the registration information, the tracker information, and the parameter information after the tracker is debugged.

In the embodiment of the invention, the debugging server 03 receives the registration information of the management debugging terminal 01, the tracker information and the parameter information after the tracker debugging, so that a system administrator can conveniently manage the authority of the current user of the server and know the operation and debugging conditions of the tracker in real time. Preferably, the debugging server 03 software architecture adopts a B/S architecture, and not only can a system administrator, but also personnel such as a project manager and sales can know the operation and debugging conditions of the tracker in real time by means of authorized access to a web page.

In another embodiment of the present invention, the commissioning server 03 of the photovoltaic tracker field commissioning method further includes:

and the log module 34 is used for recording log data of debugging the tracker by the debugging terminal 01.

Specifically, the log module records the log data of the debugging terminal 01 for debugging the tracker, so that a system administrator can perform authority management on the current user of the debugging server 03, query the equipment and the operation logs in the database, and facilitate the daily maintenance work of the system administrator for the work of continuously counting and outputting reports of the equipment which is delivered from the factory and has been debugged on site.

In another embodiment of the present invention, the commissioning server 03 of the photovoltaic tracker on-site commissioning method further includes:

and the industrial control interface 35 is used for receiving the tracker information sent by the tracker industrial personal computer when leaving the factory, wherein the tracker information comprises the tracker identifier, the equipment information and the control parameters.

Specifically, the industrial control interface 35 receives the tracker information, so that each piece of tracker information from the factory is saved in the debugging server.

Specifically, before a control box of the tracker leaves a factory, a factory program and factory parameters must be programmed, and the parameters include a wireless module parameter and a control box parameter. For the same project, the factory parameters of the control box must be ensured to be the same; moreover, in order to achieve interference-free debugging, the network ID numbers of the wireless modules must be different from each other and the control boxes of the project must be numbered when being produced; after parameter configuration is completed, after the test is passed, the parameters are stored in a local delivery data table; meanwhile, according to the information of the product such as the type, the production time, the batch number, the item number, the test serial number and the like, a unique identification code such as a two-dimensional code is produced to be used as a unique identifier of the product and correspond to factory parameters one by one, and a factory data table is stored in a local database and a debugging server database; and after the identification code printer finishes printing the identification code, the label is pasted on the control box body of the tracker.

In an embodiment of the present invention, a method for field debugging a photovoltaic tracker includes that a debugging terminal 01 includes:

a configuration module 11, included in a debugging program, for configuring the debugging parameters of the tracker and generating a debugging command;

a second communication interface 12, configured to perform a communication connection with the adaptor 02 and send the debug command to the adaptor 02, where the second communication interface includes but is not limited to a bluetooth interface;

a third communication interface 13, configured to communicate with the debugging server 03, and configured to read tracker information from the debugging server 03;

the second communication interface 12 is further configured to send debug parameters to the tracker via the first LORA unit;

the third communication interface 13 is further configured to send the debugging parameters to the debugging server 03.

In this embodiment, the debugging terminal 01 reads the tracker information from the debugging server 03, configures the debugging parameters of the tracker, generates the debugging command, sends the debugging command to the adapter 02, and sends the debugged debugging parameters to the debugging server 03.

In summary, the photovoltaic tracker field debugging system and method do not need to connect devices such as a Lora module through a USB interface, are simple to operate, and have low requirements on debugging personnel; moreover, an intelligent terminal such as a smart phone and a special adapter can complete debugging, debugging personnel can carry the intelligent terminal conveniently, and then, the work efficiency of field debugging of the photovoltaic tracking system is greatly improved and the labor cost is effectively reduced through remote control and real-time data management of the debugging server.

In the description herein, references to the terms "one embodiment," "some embodiments," "an example," "a specific example," or "some examples" or the like, mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

It should be noted that the above embodiments can be freely combined as necessary. The foregoing is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, various modifications and decorations can be made without departing from the principle of the present invention, and these modifications and decorations should also be regarded as the protection scope of the present invention.

The above description is only a preferred embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (8)

1. A photovoltaic tracker field debugging system, comprising:

the debugging terminal starts a debugging program by scanning an identification code, wherein the identification code is a tracker identifier and is fixed on the tracker;

the adapter is provided with a first communication interface and a first LORA unit and is used for converting a debugging command into a serial port test signal and sending the serial port test signal to the tracker through the first LORA unit so as to enable the debugging terminal to establish debugging connection with the tracker;

after the debugging terminal is connected with the tracker, the tracker information can be read from a debugging server by scanning the tracker identification, and the parameter debugging is carried out on the tracker;

and after debugging is finished, the debugging server can store the parameter information of the debugged tracker.

2. The photovoltaic tracker field commissioning system of claim 1, wherein said adaptor has a magnetic attraction function.

3. The photovoltaic tracker field commissioning system of claim 1,

the debugging server includes:

the user management module is used for receiving registration information of the debugging terminal, and the registration information comprises a user name and authority information of the debugging terminal;

the tracker management module is used for acquiring the tracker information, and the tracker information comprises the tracker identification, the equipment information and the control parameters;

and the storage module is used for storing the registration information, the tracker information and the parameter information after the tracker is debugged.

4. The photovoltaic tracker field commissioning system of claim 3,

the debug server further comprises:

and the log module is used for recording log data of debugging the tracker by the debugging terminal.

5. The photovoltaic tracker field commissioning system of claim 3, wherein said commissioning server further comprises:

and the industrial control interface is used for receiving the tracker information sent by the tracker industrial personal computer when leaving the factory.

6. The photovoltaic tracker field commissioning system of claim 1, wherein said commissioning terminal comprises:

the configuration module is contained in a debugging program and used for configuring debugging parameters of the tracker and generating a debugging command;

the second communication interface is used for being in communication connection with the adapter and sending the debugging command to the adapter, and the second communication interface comprises but is not limited to a Bluetooth interface;

a third communication interface for communicating with the debug server and for reading tracer information from the debug server;

the second communication interface is further used for sending debugging parameters to the tracker through the first LORA unit;

the third communication interface is further configured to send the debugging parameters to the debugging server.

7. A photovoltaic tracker field debugging method applied to the photovoltaic tracker field debugging system of claim 1, the method comprising:

the debugging terminal scans the tracker identification code, starts a debugging program and generates a debugging command;

the adapter converts the debugging command into a serial port test signal, and sends the serial port test signal to the tracker through a first LORA unit of the adapter, so that the debugging terminal and the tracker establish debugging connection;

after the debugging terminal is connected with the tracker, reading the tracker information from a debugging server, and performing parameter debugging on the tracker;

and the debugging server stores the debugged parameter information.

8. A debugging terminal applied to the photovoltaic tracker field debugging system of claim 1, wherein the debugging terminal comprises:

the configuration module is contained in a debugging program and used for configuring debugging parameters of the tracker and generating a debugging command;

the second communication interface is used for being in communication connection with the adapter and sending the debugging command to the adapter, and the second communication interface comprises but is not limited to a Bluetooth interface;

a third communication interface for communicating with the debug server and for reading tracer information from the debug server;

the second communication interface is further used for sending debugging parameters to the tracker through the first LORA unit;

the third communication interface is further configured to send the debugging parameters to the debugging server.

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