CN115100440B - Power supply supervision feedback system based on super capacitor energy storage - Google Patents

Abstract

The invention discloses a super-capacitor energy storage based power supply supervision feedback system, which belongs to the field of power supplies and is used for solving the problem that most of inspection modes of a power supply before use or delivery are manual inspection.

Description

Power supply supervision feedback system based on super capacitor energy storage

Technical Field

The invention belongs to the field of power supplies, relates to a power supply supervision feedback technology, and particularly relates to a power supply supervision feedback system based on super-capacitor energy storage.

Background

A power supply is a device that converts other forms of energy into electrical energy and provides the electrical energy to an electrical circuit (electronic device). The power source is derived from the principle of magnetic electricity generation, and is generated by renewable energy sources such as water power, wind power, sea tide, dam water pressure difference, solar energy and the like, coal burning, oil residue and the like. Common power sources are dry cell (dc) and household 110V-220V ac power sources.

Before the power was put into use or before dispatching from the factory, need whether damaged, the power receives the aspect such as extrusion to the power surface and examine, present inspection mode is mostly manual inspection, and manual inspection inefficiency to manual inspection can't accomplish to extrude the degree and measure in unison, for this reason, we propose the power supervision feedback system based on super capacitor energy storage.

Disclosure of Invention

Aiming at the defects in the prior art, the invention aims to provide a power supply supervision feedback system based on super capacitor energy storage.

The technical problem to be solved by the invention is as follows:

how to accurately feed back power supply quality supervision based on appearance factors and construction factors.

The purpose of the invention can be realized by the following technical scheme:

the power supply supervision feedback system based on super capacitor energy storage comprises a user terminal, an appearance analysis module, a supervision feedback module, a construction comparison module, a data acquisition module, a volume construction module, a database, a data transmission module and a server, wherein the database is connected with the server through the data transmission module;

the data acquisition module is used for acquiring real-time appearance diagrams and specification data of power supplies of the same type and sending the real-time appearance diagrams and the specification data to the server, and the server sends the real-time appearance diagrams to the appearance analysis module and sends the specification data to the volume construction module;

the appearance analysis module is used for analyzing the appearance of the power supply to generate an appearance normal signal or an appearance abnormal signal;

the volume construction module is used for constructing a real-time three-dimensional construction drawing of the power supply and feeding back the real-time three-dimensional construction drawing to the server, and the server sends the real-time three-dimensional construction drawing of the power supply to the construction comparison module;

the structure comparison module is used for comparing a real-time three-dimensional structure diagram of the power supply with a preset three-dimensional structure diagram to generate a structure abnormal signal, a structure normal signal or a comparison signal again;

the monitoring feedback module is used for feeding back a monitoring result of the power supply, generating a primary alarm signal or a secondary alarm signal and feeding back the primary alarm signal or the secondary alarm signal to the server, and the server sends the primary alarm signal or the secondary alarm signal to the user terminal.

Furthermore, the preset appearance picture is a picture of each visual angle of the power supply;

the specification data is the length, width and height of the power supply for a rectangular power supply, and the height and diameter of the power supply for a cylindrical power supply.

Further, the analysis process of the appearance analysis module is specifically as follows:

acquiring a real-time appearance diagram of the power supply, and acquiring a real-time front view, a real-time rear view, a real-time left view, a real-time right view, a real-time bottom view and a real-time top view of the power supply;

selecting one picture from a real-time front view, a real-time back view, a real-time left view, a real-time right view, a real-time bottom view and a real-time top view as a real-time analysis picture;

establishing a coordinate system by taking the upper left corner of the analysis picture as an original point, inputting any three groups of position coordinates, and picking a group of real-time picture analysis grids from the analysis picture according to the original point and the three groups of position coordinates;

similarly, selecting pictures with the same visual angle from a preset appearance picture of the power supply as preset analysis pictures, and inputting three groups of same position coordinates to pick a group of preset picture analysis grids from the preset analysis pictures;

acquiring the number of pixel points of all colors in the real-time picture analysis grid and the preset picture analysis grid, and performing nested comparison;

if the pixel points of any color are different, generating an appearance abnormal signal;

and if the pixel points of all colors are completely the same, selecting a picture from the real-time appearance image of the power supply as a real-time analysis picture again, repeating the steps, and if the pixel points of all colors are still completely the same, generating a normal appearance signal.

Further, the appearance analysis module feeds back the appearance normal signal or the appearance abnormal signal to the server;

if the server receives the appearance normal signal, no operation is carried out;

and if the server receives the appearance abnormal signal, the appearance abnormal signal is sent to the supervision feedback module.

Further, the alignment process of constructing the alignment module specifically comprises the following steps:

acquiring a real-time three-dimensional construction diagram and a preset three-dimensional construction diagram of a power supply, and establishing a real-time three-dimensional coordinate system by taking any point on the real-time three-dimensional construction diagram as an original point and establishing a preset three-dimensional coordinate system by taking any point on the preset three-dimensional construction diagram as the original point;

respectively extracting a real-time contour line in the real-time three-dimensional structural diagram and a preset contour line in the preset three-dimensional structural diagram;

setting a plurality of real-time track points in each real-time contour line, and acquiring real-time three-dimensional coordinates of the plurality of track points in a real-time three-dimensional coordinate system;

similarly, a plurality of preset track points are set in each preset contour line, and preset three-dimensional coordinates of the plurality of preset track points in a preset three-dimensional coordinate system are obtained;

comparing the real-time three-dimensional coordinates of a plurality of real-time track points in the real-time contour line with the preset three-dimensional coordinates of a plurality of preset track points in the corresponding preset contour line;

if the real-time three-dimensional coordinate is completely the same as the preset three-dimensional coordinate, generating a normal signal;

if the real-time three-dimensional coordinates are different from the preset three-dimensional coordinates, marking an original point in a real-time three-dimensional coordinate system on a real-time three-dimensional structural diagram and using the original point as a real-time fixed point, inputting a plurality of three-dimensional coordinates to mark in the real-time three-dimensional structural diagram and using the three-dimensional coordinates as a plurality of real-time measuring points, and measuring the distances between the real-time measuring points and the real-time fixed point to obtain a plurality of groups of real-time distances;

similarly, an original point in a preset three-dimensional coordinate system is marked on a preset three-dimensional structure diagram and used as a preset fixed point, then a plurality of same three-dimensional coordinates are input and marked in the preset three-dimensional structure diagram and used as a plurality of preset measuring points, and the distances between the preset measuring points and the preset fixed point are measured to obtain a plurality of groups of preset distances;

and comparing the real-time interval with the corresponding preset interval, if the real-time interval is different from the corresponding preset interval, generating a construction abnormal signal, and if the real-time interval is the same as the corresponding preset interval, generating a re-comparison signal.

Further, the construction comparison module feeds back a construction abnormal signal, a construction normal signal or a re-comparison signal to the server;

if the server receives the construction abnormal signal, the construction abnormal signal is sent to the supervision feedback module;

if the server receives a signal for constructing the normal state, no operation is carried out;

and if the server receives the re-comparison signal, the server performs comparison again through the construction comparison module.

Further, the feedback process of the supervision feedback module is specifically as follows:

if the construction abnormal signal and the appearance abnormal signal are received at the same time, a primary alarm signal is generated;

and if any one of the structural abnormal signal or the appearance abnormal signal is received, generating a secondary alarm signal.

Further, the level of the primary alarm signal is higher than the level of the secondary alarm signal.

Compared with the prior art, the invention has the beneficial effects that:

the invention firstly analyzes the appearance of a power supply through an appearance analysis module to generate an appearance normal signal or an appearance abnormal signal, and sends the appearance abnormal signal to a supervision feedback module, then constructs a real-time three-dimensional structural diagram of the power supply by using a volume construction module, and sends the real-time three-dimensional structural diagram of the power supply to a construction comparison module, the construction comparison module compares the real-time three-dimensional structural diagram of the power supply with a preset three-dimensional structural diagram to generate a construction abnormal signal, a construction normal signal or a re-comparison signal, and sends the construction abnormal signal to the supervision feedback module, and finally the supervision feedback module feeds back the supervision result of the power supply, and generates a primary alarm signal or a secondary alarm signal to be sent to a user terminal according to the construction abnormal signal and the appearance abnormal signal.

Drawings

In order to facilitate understanding for those skilled in the art, the present invention will be further described with reference to the accompanying drawings.

FIG. 1 is an overall system block diagram of the present invention.

Detailed Description

The technical solutions of the present invention will be described below clearly and completely in conjunction with the embodiments, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In an embodiment, please refer to fig. 1, a super capacitor energy storage based power supply monitoring feedback system is proposed, which includes a user terminal, an appearance analysis module, a monitoring feedback module, a construction comparison module, a data acquisition module, a volume construction module, a database, a data transmission module and a server;

the power source in the present invention is a super capacitor, and the super capacitor generally includes four components, namely, a double electrode, an electrolyte, a current collector, and a separator. The super capacitor obtains super capacitance by using an electric double layer structure consisting of an activated carbon porous electrode and an electrolyte. In the super capacitor, porous electrodes are made of activated carbon materials, electrolyte solution is filled between two opposite porous carbon electrodes, when voltage is applied to two ends of the super capacitor, positive and negative electrons are respectively gathered on the opposite porous electrodes, and positive and negative ions in the electrolyte solution are respectively gathered on interfaces opposite to positive and negative plates under the action of an electric field, so that a double current collecting layer is formed;

before the system is used, the user terminal is used for a worker to input personal information to register and log in the system and send the personal information to a server for storage; the personal information comprises the name of the staff, the mobile phone number of real-name authentication and the like;

the database is connected with the server through the data transmission module, the user terminal is used for inputting the model of the power supply and sending the model to the server, the server sends the model of the power supply to the database, the database acquires a preset appearance diagram and a preset three-dimensional construction diagram of the power supply according to the model, and the preset appearance diagram and the preset three-dimensional construction diagram of the power supply are sent to the server through the data transmission module;

the preset appearance pictures are pictures of all visual angles of the power supply, namely a preset front view, a preset rear view, a preset left view, a preset right view, a preset bottom view and a preset top view;

in this embodiment, two factors, namely, the appearance and the three-dimensional structure of the power supply, are preferably selected for supervision feedback, and supervision feedback can be performed by referring to other factors during specific implementation, but not specifically limited thereto, first, the data acquisition module is configured to acquire a real-time appearance diagram and specification data of the power supply of the same model, and send the real-time appearance diagram and the specification data to the server, the server sends the real-time appearance diagram to the appearance analysis module, and the server sends the specification data to the volume construction module;

specifically, if the power supply is rectangular, the specification data are the length, width and height of the power supply, and if the power supply is cylindrical, the specification data are the height and diameter of the power supply, and the default here is that the power supply is rectangular or cylindrical, and other irregular power supplies are not considered; in specific implementation, the data acquisition module is a camera device capable of shooting a power supply, a distance sensor arranged on the surface of the power supply, and the like, and is not specifically limited herein;

the appearance analysis module is used for analyzing the appearance of the power supply, and the analysis process specifically comprises the following steps:

step S100: acquiring a real-time appearance diagram of the power supply, and acquiring a real-time front view, a real-time rear view, a real-time left view, a real-time right view, a real-time bottom view and a real-time top view of the power supply;

step S200: selecting one picture from a real-time front view, a real-time back view, a real-time left view, a real-time right view, a real-time bottom view and a real-time top view as a real-time analysis picture;

step S300: establishing a coordinate system by taking the upper left corner of the analysis picture as an original point, inputting any three groups of position coordinates, and picking a group of real-time picture analysis grids from the analysis picture according to the original point and the three groups of position coordinates;

similarly, selecting pictures with the same visual angle from a preset appearance picture of the power supply as preset analysis pictures, and inputting three groups of same position coordinates to pick a group of preset picture analysis grids from the preset analysis pictures;

step S400: acquiring the number of pixel points of all colors in the real-time picture analysis grid and the preset picture analysis grid, and performing set comparison;

step S500: if the pixel points of any color are different, generating an appearance abnormal signal;

if the pixel points of all colors are completely the same, selecting a picture from the real-time appearance image of the power supply as a real-time analysis picture again, repeating the steps, and if the pixel points of all colors are still completely the same, generating a normal appearance signal;

the appearance analysis module feeds back the appearance normal signal or the appearance abnormal signal to the server, and if the server receives the appearance normal signal, no operation is performed; if the server receives the appearance abnormal signal, the appearance abnormal signal is sent to the supervision feedback module;

in the embodiment of the invention, the volume construction module is used for constructing the real-time three-dimensional construction diagram of the power supply and feeding the real-time three-dimensional construction diagram of the power supply back to the server, and the server sends the real-time three-dimensional construction diagram of the power supply to the construction comparison module, wherein the volume construction module is in the prior art, and the volume construction module can be a Boxshot 3D tool specifically, or a tool or software for automatically generating the three-dimensional diagram after directly inputting specification data of a product;

the structure comparison module is used for comparing a real-time three-dimensional structure diagram of the power supply with a preset three-dimensional structure diagram, and the comparison process specifically comprises the following steps:

step S1: acquiring the real-time three-dimensional structural diagram and the preset three-dimensional structural diagram of the power supply, and establishing a real-time three-dimensional coordinate system by taking any point on the real-time three-dimensional structural diagram as an original point and establishing a preset three-dimensional coordinate system by taking any point on the preset three-dimensional structural diagram as the original point; wherein any point on the real-time three-dimensional structure diagram and any point on the preset three-dimensional structure diagram are theoretically the same point;

step S2: respectively extracting a real-time contour line in the real-time three-dimensional construction drawing and a preset contour line in the preset three-dimensional construction drawing;

and step S3: setting a plurality of real-time track points (the real-time track points need to comprise a starting point and an end point of the real-time contour line) in each real-time contour line, and acquiring real-time three-dimensional coordinates of the plurality of track points in a real-time three-dimensional coordinate system;

similarly, a plurality of preset track points are set in each preset contour line, and preset three-dimensional coordinates of the plurality of preset track points in a preset three-dimensional coordinate system are obtained;

and step S4: comparing the real-time three-dimensional coordinates of a plurality of real-time track points in the real-time contour line with preset three-dimensional coordinates of a plurality of preset track points in a corresponding preset contour line;

step S5: if the real-time three-dimensional coordinate is completely the same as the preset three-dimensional coordinate, generating a construction normal signal, and if the real-time three-dimensional coordinate is not the same as the preset three-dimensional coordinate, entering the next step;

step S6: marking an original point in a real-time three-dimensional coordinate system on a real-time three-dimensional structural diagram and using the original point as a real-time fixed point, then inputting a plurality of three-dimensional coordinates to mark the real-time three-dimensional structural diagram and using the three-dimensional coordinates as a plurality of real-time measuring points SCu, u =1,2, \8230;, z and z are positive integers, u represents the number of the real-time measuring points, and the distances between the real-time measuring points and the real-time fixed point are measured to obtain a plurality of groups of real-time distances SJu;

similarly, an original point in a preset three-dimensional coordinate system is marked on a preset three-dimensional structure diagram and serves as a preset fixed point, then a plurality of same three-dimensional coordinates are input and marked in the preset three-dimensional structure diagram and serve as a plurality of preset measuring points YCi, i =1,2, \8230;, x and x are positive integers, i represents the number of the preset measuring points, and the distances between the preset measuring points and the preset fixed point are measured to obtain a plurality of groups of preset distances YJi;

step S7: comparing the real-time interval with the corresponding preset interval, namely comparing the real-time interval SJ1 with the preset interval YJ1, comparing the real-time interval SJ2 with the preset interval YJ3, 8230, comparing the real-time interval SJz with the preset interval YJx;

if the real-time interval is different from the corresponding preset interval, generating a construction abnormal signal, and if the real-time interval is the same as the corresponding preset interval, generating a re-comparison signal;

the construction comparison module feeds back construction abnormal signals, construction normal signals or re-comparison signals to the server;

if the server receives the construction abnormal signal, the construction abnormal signal is sent to the supervision feedback module, if the server receives the construction normal signal, no operation is carried out, and if the server receives the re-comparison signal, the re-comparison is carried out through the construction comparison module;

the supervision feedback module is used for feeding back the supervision result of the power supply, and the feedback process specifically comprises the following steps:

if the structure abnormal signal and the appearance abnormal signal are received simultaneously, a primary alarm signal is generated, and if any one of the structure abnormal signal and the appearance abnormal signal is received, a secondary alarm signal is generated;

understandably, the level of the primary alarm signal is higher than the level of the secondary alarm signal;

the monitoring feedback module feeds back the primary alarm signal or the secondary alarm signal to the server, the server sends the primary alarm signal or the secondary alarm signal to the user terminal, and the user terminal receives the primary alarm signal or the secondary alarm signal and then identifies the corresponding power supply and the like, so that whether the normal use of the power supply is influenced or not is judged.

In another embodiment, a working method of a power supply supervision feedback system based on super-capacitor energy storage is provided, and specifically comprises the following steps:

step S101, a user terminal inputs the model of a power supply and sends the model to a server, the server sends the model of the power supply to a database, the database acquires a preset appearance diagram and a preset three-dimensional construction diagram of the power supply according to the model, and the preset appearance diagram and the preset three-dimensional construction diagram of the power supply are sent to the server through a data transmission module;

step S102, a data acquisition module acquires real-time appearance diagrams and specification data of power supplies of the same type, and sends the real-time appearance diagrams and the specification data to a server, the server sends the real-time appearance diagrams to an appearance analysis module, and the server sends the specification data to a volume construction module;

step S103, analyzing the appearance of the power supply through an appearance analysis module, acquiring a real-time appearance diagram of the power supply, acquiring a real-time front view, a real-time rear view, a real-time left view, a real-time right view, a real-time bottom view and a real-time top view of the power supply, selecting one of the real-time front view, the real-time rear view, the real-time left view, the real-time right view, the real-time bottom view and the real-time top view as a real-time analysis picture, establishing a coordinate system by taking the upper left corner of the analysis picture as an original point, inputting any three groups of position coordinates, picking one group of real-time picture analysis grids from the analysis picture according to the original point and the three groups of position coordinates, generating an appearance abnormal signal if the pixel points of any color are different, selecting one of the pictures from the real-time appearance diagram of the power supply as a preset analysis picture, acquiring the pixel points of all colors in the real-time picture analysis grids and the preset picture analysis grids, performing a set comparison, if the pixel points of all colors are completely the same, generating an appearance abnormal signal, and feeding back the appearance signal to a normal server, and if the pixel points of all colors are completely the same, and the server receives the appearance signal, and the server generates an abnormal signal, and if the server receives the abnormal signal;

step S104, a volume construction module constructs a real-time three-dimensional construction drawing of a power supply and feeds the real-time three-dimensional construction drawing of the power supply back to a server, the server sends the real-time three-dimensional construction drawing of the power supply to a construction comparison module, the construction comparison module compares the real-time three-dimensional construction drawing of the power supply with a preset three-dimensional construction drawing to obtain the real-time three-dimensional construction drawing and the preset three-dimensional construction drawing of the power supply, and a real-time three-dimensional coordinate system and a preset three-dimensional coordinate system are established by taking any point on the real-time three-dimensional construction drawing as an origin and any point on the preset three-dimensional construction drawing as the origin; wherein, any point on the real-time three-dimensional construction diagram and any point on the preset three-dimensional construction diagram are theoretically the same point, a real-time contour line in the real-time three-dimensional construction diagram and a preset contour line in the preset three-dimensional construction diagram are respectively extracted, a plurality of real-time track points are set in each real-time contour line, real-time three-dimensional coordinates of a plurality of track points in a real-time three-dimensional coordinate system are obtained, a plurality of preset track points are set in each preset contour line, preset three-dimensional coordinates of a plurality of preset track points in a preset three-dimensional coordinate system are obtained, the real-time three-dimensional coordinates of a plurality of real-time track points in the real-time contour line are compared with the preset three-dimensional coordinates of a plurality of preset track points in the corresponding preset contour lines, if the real-time three-dimensional coordinates are completely the same as the preset three-dimensional coordinates, a construction normal signal is generated, if the real-time three-dimensional coordinates are not the same as the preset three-dimensional coordinates, marking an original point in a real-time three-dimensional coordinate system on a real-time three-dimensional structural diagram and using the original point as a real-time fixed point, inputting a plurality of three-dimensional coordinates to mark the real-time three-dimensional structural diagram and using the three-dimensional coordinates as a plurality of real-time measuring points SCu, measuring the distances between the real-time measuring points and the real-time fixed point to obtain a plurality of groups of real-time distances SJu, marking the original point in a preset three-dimensional coordinate system on a preset three-dimensional structural diagram and using the original point as a preset fixed point, inputting a plurality of same three-dimensional coordinates to mark the preset three-dimensional structural diagram and using the same three-dimensional coordinates as a plurality of preset measuring points YCi, measuring the distances between the preset measuring points and the preset fixed point to obtain a plurality of groups of preset distances YJi, comparing the real-time distances with the corresponding preset distances, and generating a structural abnormal signal if the real-time distances are different from the corresponding preset distances, if the real-time interval is the same as the corresponding preset interval, generating a re-comparison signal, feeding back a construction abnormal signal, a construction normal signal or the re-comparison signal to the server by the construction comparison module, if the server receives the construction abnormal signal, sending the construction abnormal signal to the supervision feedback module, if the server receives the construction normal signal, not performing any operation, and if the server receives the re-comparison signal, performing comparison again by the construction comparison module;

and step S105, the supervision feedback module feeds back a supervision result of the power supply, if the construction abnormal signal and the appearance abnormal signal are received at the same time, a primary alarm signal is generated, if any one of the construction abnormal signal or the appearance abnormal signal is received, a secondary alarm signal is generated, the supervision feedback module feeds back the primary alarm signal or the secondary alarm signal to the server, and the server sends the primary alarm signal or the secondary alarm signal to the user terminal.

The preferred embodiments of the invention disclosed above are intended to be illustrative only. The preferred embodiments are not intended to be exhaustive or to limit the invention to the precise forms disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and the practical application, to thereby enable others skilled in the art to best utilize the invention. The invention is limited only by the claims and their full scope and equivalents.

Claims (5)

1. The power supply supervision feedback system based on super capacitor energy storage comprises a user terminal, an appearance analysis module, a supervision feedback module, a construction comparison module, a data acquisition module, a volume construction module, a database, a data transmission module and a server, and is characterized in that the database is connected with the server through the data transmission module, the user terminal is used for inputting the model of a power supply and sending the model of the power supply to the server, the server sends the model of the power supply to the database, and the database acquires a preset appearance diagram and a preset three-dimensional construction diagram of the power supply according to the model and sends the preset appearance diagram and the preset three-dimensional construction diagram of the power supply to the server through the data transmission module;

the data acquisition module is used for acquiring real-time appearance diagrams and specification data of power supplies of the same type and sending the real-time appearance diagrams and the specification data to the server, and the server sends the real-time appearance diagrams to the appearance analysis module and sends the specification data to the volume construction module;

the appearance analysis module is used for analyzing the appearance of the power supply to generate an appearance normal signal or an appearance abnormal signal;

the volume construction module is used for constructing a real-time three-dimensional construction drawing of the power supply and feeding back the real-time three-dimensional construction drawing to the server, and the server sends the real-time three-dimensional construction drawing of the power supply to the construction comparison module;

the structure comparison module is used for comparing a real-time three-dimensional structure diagram of the power supply with a preset three-dimensional structure diagram to generate a structure abnormal signal, a structure normal signal or a comparison signal again;

the monitoring feedback module is used for feeding back a monitoring result of the power supply, generating a primary alarm signal or a secondary alarm signal and feeding the primary alarm signal or the secondary alarm signal back to the server, and the server sends the primary alarm signal or the secondary alarm signal to the user terminal;

the analysis process of the appearance analysis module is as follows:

acquiring a real-time appearance diagram of the power supply, and acquiring a real-time front view, a real-time rear view, a real-time left view, a real-time right view, a real-time bottom view and a real-time top view of the power supply;

selecting one picture from a real-time front view, a real-time back view, a real-time left view, a real-time right view, a real-time bottom view and a real-time top view as a real-time analysis picture;

establishing a coordinate system by taking the upper left corner of the analysis picture as an original point, then inputting any three groups of position coordinates, and picking a group of real-time picture analysis lattices from the analysis picture according to the original point and the three groups of position coordinates;

similarly, selecting pictures with the same visual angle from a preset appearance picture of the power supply as preset analysis pictures, and inputting three groups of same position coordinates to pick a group of preset picture analysis grids from the preset analysis pictures;

acquiring the number of pixel points of all colors in the real-time picture analysis grid and the preset picture analysis grid, and performing nested comparison;

if the pixel points of any color are different, generating an appearance abnormal signal;

if the pixel points of all colors are completely the same, selecting a picture from the real-time appearance image of the power supply as a real-time analysis picture again, repeating the steps, and if the pixel points of all colors are still completely the same, generating a normal appearance signal;

the alignment process of the construction and alignment module is as follows:

acquiring a real-time three-dimensional construction drawing and a preset three-dimensional construction drawing of a power supply, and establishing a real-time three-dimensional coordinate system by taking any point on the real-time three-dimensional construction drawing as an original point and establishing a preset three-dimensional coordinate system by taking any point on the preset three-dimensional construction drawing as an original point;

respectively extracting a real-time contour line in the real-time three-dimensional structural diagram and a preset contour line in the preset three-dimensional structural diagram;

setting a plurality of real-time track points in each real-time contour line, and acquiring real-time three-dimensional coordinates of the plurality of track points in a real-time three-dimensional coordinate system;

similarly, a plurality of preset track points are set in each preset contour line, and preset three-dimensional coordinates of the plurality of preset track points in a preset three-dimensional coordinate system are obtained;

comparing the real-time three-dimensional coordinates of a plurality of real-time track points in the real-time contour line with the preset three-dimensional coordinates of a plurality of preset track points in the corresponding preset contour line;

if the real-time three-dimensional coordinate is completely the same as the preset three-dimensional coordinate, generating a construction normal signal;

if the real-time three-dimensional coordinates are different from the preset three-dimensional coordinates, marking an original point in a real-time three-dimensional coordinate system on a real-time three-dimensional structural diagram and using the original point as a real-time fixed point, then inputting a plurality of three-dimensional coordinates to mark in the real-time three-dimensional structural diagram and using the three-dimensional coordinates as a plurality of real-time measuring points, and measuring the distances between the real-time measuring points and the real-time fixed point to obtain a plurality of groups of real-time distances;

similarly, an original point in a preset three-dimensional coordinate system is marked on a preset three-dimensional structure diagram and serves as a preset fixed point, then a plurality of same three-dimensional coordinates are input to be marked in the preset three-dimensional structure diagram and serve as a plurality of preset measuring points, and the distance between the plurality of preset measuring points and the preset fixed point is measured to obtain a plurality of groups of preset intervals;

and comparing the real-time interval with the corresponding preset interval, if the real-time interval is not the same as the corresponding preset interval, generating a construction abnormal signal, and if the real-time interval is the same as the corresponding preset interval, generating a re-comparison signal.

2. The supercapacitor energy storage based power supply supervision feedback system according to claim 1, wherein the preset appearance diagram is a picture of each view angle of the power supply;

the specification data is the length, width and height of the power supply for a rectangular power supply, and the height and diameter of the power supply for a cylindrical power supply.

3. The supercapacitor energy storage based power supply supervision feedback system according to claim 1, wherein the appearance analysis module feeds back an appearance normal signal or an appearance abnormal signal to a server;

if the server receives the appearance normal signal, no operation is carried out;

and if the server receives the appearance abnormal signal, the appearance abnormal signal is sent to the supervision feedback module.

4. The supercapacitor energy storage based power supply supervision and feedback system according to claim 1, wherein the configuration and comparison module feeds back a configuration abnormal signal, a configuration normal signal or a re-comparison signal to a server;

if the server receives the construction abnormal signal, the construction abnormal signal is sent to the supervision feedback module;

if the server receives a signal for constructing the normal state, no operation is carried out;

and if the server receives the re-comparison signal, the server performs comparison again through the construction comparison module.

5. The power supply supervision feedback system based on super capacitor energy storage according to claim 1, wherein the feedback process of the supervision feedback module is as follows:

if the construction abnormal signal and the appearance abnormal signal are received at the same time, a primary alarm signal is generated;

and if any one of the structural abnormal signal or the appearance abnormal signal is received, generating a secondary alarm signal.

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