CN112713656B - Photovoltaic tracker field debugging system, 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 the 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 that the debugging terminal and the tracker are connected in a debugging mode; after the debugging terminal is connected with the tracker, the information of the tracker is read from a debugging server, and parameter debugging is carried out on the tracker; the invention also discloses a photovoltaic tracker field debugging method. The invention solves the technical problems of complex field debugging operation, inconvenient equipment carrying and high system maintenance cost caused by lack of unified management of data in the photovoltaic tracker in the prior art.

Description

Photovoltaic tracker field debugging system, 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

The photovoltaic power generation is a power generation mode for directly converting light energy into electric energy, has a plurality of advantages in the practical application process as a novel clean energy source, obtains very wide application, and is a key for reasonably and massively applying solar energy because of how to improve the conversion efficiency of the solar energy. However, in practical application, because field debugging cannot be performed in a box, for routine maintenance debugging of a photovoltaic tracking system such as a photovoltaic tracker, parameters need to be configured to a control board in a wireless manner. The basic process is as follows: connecting a LORA module for debugging on the handheld computer, opening special upper computer software, and modifying factory parameters of the LORA module in a wireless configuration mode; the module is then reconnected to configure the operating parameters of the tracker. During this process, other control boxes in the vicinity must be powered down, otherwise radio interference occurs, resulting in configuration of local parameters to the other control boxes. The method has very high requirements for debugging personnel, and if misoperation or parameter mismatching occurs, the defect elimination work at the later stage is very time-consuming; carrying large-scale debugging equipment is also a laborious task if water is present or under complex conditions such as climbing is required; moreover, the lack of unified management of data, such as the fact that the debugging personnel are different, can lead to the fact that the debugging condition of the parameters of the tracker is not known in the next maintenance, which certainly increases the maintenance cost of the system.

Disclosure of Invention

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

The technical scheme provided by the invention is as follows:

a photovoltaic tracker field commissioning system comprising:

the debugging terminal is used for starting a debugging program by scanning an identification code, and 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 that the debugging terminal and the tracker are connected in a debugging mode;

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

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

Further, the adapter has a magnetic attraction function.

Further, the debug server includes:

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

the tracker management module is used for acquiring tracker information, wherein the tracker information comprises a tracker identifier, equipment information and 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 debug server further includes:

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

Further, the debug server further includes:

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

Further, the debug terminal includes:

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

a second communication interface for communicating with the adapter and sending the debug command to the adapter, the second communication interface including but not limited to a bluetooth interface;

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

the second communication interface is further configured to send a debug parameter to the tracker through the first LORA unit;

the third communication interface is further configured to send the debug parameter to the debug 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 are connected in a debugging mode;

after the debugging terminal is connected with the tracker, the information of the tracker is read from a debugging server, and parameter debugging is carried out on the tracker;

and the debugging server stores the debugged parameter information.

Further, the debug server includes:

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

the tracker management module is used for acquiring tracker information, wherein the tracker information comprises a tracker identifier, equipment information and 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 debug server further includes:

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

Further, the debug server further includes:

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

Further, the debug terminal includes:

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

a second communication interface for communicating with the adapter and sending the debug command to the adapter, the second communication interface including but not limited to a bluetooth interface;

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

the second communication interface is further configured to send a debug parameter to the tracker through the first LORA unit;

the third communication interface is further configured to send the debug parameter to the debug 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:

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

2. One intelligent terminal such as a smart phone and a special adapter can finish debugging, and is convenient for carrying of debugging personnel.

3. The remote control and the real-time data management of the debugging server greatly improve the working efficiency of the field debugging of the photovoltaic tracking system and effectively reduce the labor cost.

Drawings

The main features, technical features, advantages and implementation of the present invention will be further described in the following description of the preferred embodiments in a clearly understood manner with reference to the accompanying drawings.

FIG. 1 is a schematic 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 debug server of the present invention;

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

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

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

Reference numerals illustrate:

01. the system comprises a debugging terminal, an adapter, a debugging server, a configuration module, a second communication interface, a third communication interface, a user management module, a tracker management module, a storage module, a log module and 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 explain the specific embodiments of the present invention with reference to the accompanying drawings. It is evident that the drawings in the following description are only examples of the invention, from which other drawings and other embodiments can be obtained by a person skilled in the art without inventive effort.

For the sake of simplicity of the drawing, the parts relevant to the present invention are shown only schematically in the figures, which do not represent the actual structure thereof as a product. Additionally, in order to simplify the drawing for ease of understanding, components having the same structure or function in some of the drawings are shown schematically with only one of them, or only one of them is labeled. Herein, "a" means not only "only this one" but also "more than one" case.

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 further 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 one embodiment of the present invention, as shown in FIG. 1, a photovoltaic tracker field commissioning system, comprising:

the debugging terminal 01 is used for starting a debugging program by scanning an identification code, 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 are connected in a debugging mode;

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 identifier, and parameter debugging is carried out on the tracker;

the debug server 03 can save 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 smart phone or a tablet personal computer which is convenient to carry; the adapter 02 is configured with a lithium battery for converting a debugging command into a serial port test signal, and the adapter 02 has a magnetic attraction function on a shell thereof, and can be attracted on a tracker or a nearby upright post or cross beam during debugging, so that the portable device is convenient to carry; and the debugging server 03 is connected with the tracker and is used for storing the debugged parameter information. When a worker is in field debugging, the factory information of the tracker can be read from the debugging server 03 only by scanning an identification code such as a two-dimensional code through a debugging terminal 01 such as a smart phone APP, parameter debugging is carried out by conveniently connecting the tracker through the adapter 02, and the debugged parameters are automatically stored in the debugging server 03. The operation is simple, the requirements for debugging personnel are not high, and the debugging terminal 01 can be an intelligent terminal with small volume such as a smart phone and a tablet personal computer, so that the debugging personnel can carry the debugging terminal conveniently.

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

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

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

and the storage module 33 is used for storing the registration information, the tracker information and the parameter information after the tracker is debugged.

In the embodiment of the invention, the debug server 03 receives the registration information of the management debug terminal 01, the tracker information and the parameter information after the tracker is debugged, so that a system administrator can conveniently manage the authority of the current user of the server, and the running and debugging conditions of the tracker can be known in real time. Preferably, the software architecture of the debug server 03 adopts a B/S architecture, so that not only system administrators, project managers, sales personnel and the like can know the running and debugging conditions of the tracker in real time in a mode of authorizing access to web pages.

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

the log module 34 is configured to record log data of the debug terminal 01 for debugging the tracker.

Specifically, log data of the debugging terminal 01 for debugging the tracker is recorded through the log module, so that a system administrator can conduct authority management on the current user of the debugging server 03, query equipment and operation logs in a database, and keep statistics and report output work on the equipment which is delivered and debugged on site, thereby facilitating daily maintenance work of the system administrator.

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

the industrial control interface 34 is configured to receive the tracker information sent by the tracker industrial control computer when leaving the factory, where the tracker information includes the tracker identifier, the device information and the control parameter.

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

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

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

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

a second communication interface 12 for communicating with the adaptor 02 and transmitting the debug command to the adaptor 02, the second communication interface including but not limited to a bluetooth interface;

a third communication interface 13 for communicating with the debug server 03 for reading tracker information from the debug 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 debug parameters to the debug server 03.

In this embodiment, the debug terminal 01 configures the debug parameters of the tracker by reading the tracker information from the debug server 03, generates a debug command, sends the debug command to the adapter 02, and sends the debug parameters after the debug to the debug server 03, so that for a debugger, an intelligent terminal such as a mobile phone and a special adapter can complete the debug without connecting devices such as a Lora module through a USB interface, and the device is convenient to carry and debug and operation.

In one embodiment of the invention, as shown in fig. 6, a photovoltaic tracker field commissioning method, the method comprising:

s1, a debugging terminal scans a tracker identification code, starts a debugging program and generates a debugging command;

s2, converting a debugging command into a serial port test signal by the adapter, and sending the serial port test signal to the tracker through a first LORA unit of the adapter so that the debugging terminal and the tracker are connected in a debugging mode;

s3, after the debugging terminal is connected with the tracker, the information of the tracker is read from a debugging server, and parameter debugging is carried out on the tracker;

s4, the debugging server stores the debugged parameter information.

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 smart phone or a tablet personal computer which is convenient to carry; the adapter 02 is configured with a lithium battery for converting a debugging command into a serial port test signal, and the adapter 02 has a magnetic attraction function on the shell, and can be attracted on a column or a cross beam near the tracker during debugging, so that the portable device is convenient to carry; and the debugging server 03 is connected with the tracker and is used for storing the debugged parameter information. When a worker is in field debugging, the factory information of the tracker can be read from the debugging server 03 only by scanning an identification code such as a two-dimensional code through a debugging terminal 01 such as a smart phone APP, parameter debugging is carried out by conveniently connecting the tracker through the adapter 02, and the debugged parameters are automatically stored in the debugging server 03. The operation is simple, the requirements for debugging personnel are not high, and the debugging terminal 01 can be an intelligent terminal with small volume such as a smart phone and a tablet personal computer, so that the debugging personnel can carry the debugging terminal conveniently.

Further, the debugging server 03 of the photovoltaic tracker field debugging method in the invention comprises the following steps:

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

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

and the storage module 33 is used for storing the registration information, the tracker information and the parameter information after the tracker is debugged.

In the embodiment of the invention, the debug server 03 receives the registration information of the management debug terminal 01, the tracker information and the parameter information after the tracker is debugged, so that a system administrator can conveniently manage the authority of the current user of the server, and the running and debugging conditions of the tracker can be known in real time. Preferably, the software architecture of the debug server 03 adopts a B/S architecture, so that not only system administrators, project managers, sales personnel and the like can know the running and debugging conditions of the tracker in real time in a mode of authorizing access to web pages.

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

the log module 34 is configured to record log data of the debug terminal 01 for debugging the tracker.

Specifically, log data of the debugging terminal 01 for debugging the tracker is recorded through the log module, so that a system administrator can conduct authority management on the current user of the debugging server 03, query equipment and operation logs in a database, and keep statistics and report output work on the equipment which is delivered and debugged on site, thereby facilitating daily maintenance work of the system administrator.

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

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

Specifically, the tracker information is received through the industrial control interface 35, so that each piece of tracker information of the factory is saved in the debug server.

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

In one embodiment of the present invention, a debug terminal 01 of a photovoltaic tracker field debug method includes:

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

a second communication interface 12 for communicating with the adaptor 02 and transmitting the debug command to the adaptor 02, the second communication interface including but not limited to a bluetooth interface;

a third communication interface 13 for communicating with the debug server 03 for reading tracker information from the debug 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 debug parameters to the debug server 03.

In this embodiment, the debug terminal 01 configures the debug parameters of the tracker by reading the tracker information from the debug server 03, generates a debug command, sends the debug command to the adapter 02, and sends the debug parameters after the debug to the debug server 03, so that for a debugger, an intelligent terminal such as a mobile phone and a special adapter can complete the debug without connecting devices such as a Lora module through a USB interface, and the device is convenient to carry and debug and operation.

In summary, the photovoltaic tracker field debugging system and method do not need to be connected with equipment such as the Lora module and the like through a USB interface, are simple to operate, and have low requirements on debugging personnel; and moreover, the intelligent terminal such as a smart phone and a special adapter can finish debugging, so that the debugging personnel can carry the intelligent terminal conveniently, and the remote control and the real-time data management of the debugging server greatly improve the working efficiency of the field debugging of the photovoltaic tracking system and effectively reduce the labor cost.

In the description of the present specification, the descriptions of the terms "one embodiment," "some embodiments," "examples," "particular examples," or "some examples" and 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 present invention. In this specification, schematic representations of the above terms do not necessarily refer to the same embodiments or examples. 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 needed. The foregoing is merely a preferred embodiment of the present invention and it should be noted that modifications and adaptations to those skilled in the art may be made without departing from the principles of the present invention, which are intended to be comprehended within the scope of the present invention.

The foregoing description of the preferred embodiments of the present invention should not be taken as limiting the scope of the invention, but rather should be understood to cover all modifications, equivalents, and alternatives falling within the scope of the invention as defined by the following description and drawings, or by direct or indirect application to other relevant art(s).

Claims (6)

1. A photovoltaic tracker field commissioning system, comprising:

the debugging terminal is used for starting a debugging program by scanning an identification code, and 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 that the debugging terminal and the tracker are connected in a debugging mode;

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

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

the debug server includes:

the user management module is used for receiving registration information of the debugging terminal, wherein 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, wherein the tracker information comprises the tracker identification, equipment information and control parameters;

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

the debugging terminal comprises:

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

a second communication interface for communicating with the adapter and sending the debug command to the adapter, the second communication interface including but not limited to a bluetooth interface;

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

the second communication interface is further configured to send a debug parameter to the tracker through the first LORA unit;

the third communication interface is further configured to send the debug parameter to the debug server.

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

3. A photovoltaic tracker field commissioning system according to claim 1,

the debug server further includes:

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

4. The photovoltaic tracker field commissioning system of claim 1, wherein the commissioning server further comprises:

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

5. A photovoltaic tracker field commissioning method applied to the photovoltaic tracker field commissioning 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 are connected in a debugging mode;

after the debugging terminal is connected with the tracker, the information of the tracker is read from a debugging server, and parameter debugging is carried out on the tracker;

and the debugging server stores the debugged parameter information.

6. A debug terminal for use in the photovoltaic tracker field commissioning system of claim 1, said debug terminal comprising:

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

a second communication interface for communicating with the adapter and sending the debug command to the adapter, the second communication interface including but not limited to a bluetooth interface;

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

the second communication interface is further configured to send a debug parameter to the tracker through the first LORA unit;

the third communication interface is further configured to send the debug parameter to the debug server.

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