CN117893025A - Wiring management method and system based on comprehensive wiring device - Google Patents

Abstract

The application discloses a wiring management method and system based on a comprehensive wiring device, wherein the method comprises the following steps: acquiring corresponding multiple pieces of equipment state information and implementation site environment video information based on the site ID; performing security evaluation analysis based on the plurality of equipment state information and implementation site environment video information to obtain risk feedback information; the implementation site environment video information is specifically a person walking video obtained by shooting any person walking on all trafficable paths in the temporary office site. According to the application, the running state safety analysis is performed based on the equipment state information, the implementation environment safety analysis is performed based on the implementation site environment video information, and the risk feedback information is further obtained, so that the abnormal prompt of the running state or the implementation environment is provided for the staff in time, the implementation efficiency of the staff when the temporary office place is built is improved, and the safety of the user when the temporary office place is used is also improved.

Description

Wiring management method and system based on comprehensive wiring device

Technical Field

The application relates to the technical field of data processing, in particular to a wiring management method and system based on a comprehensive wiring device.

Background

At present, when a new office point or a temporary project needs to be set up due to the business development requirement of an enterprise, a temporary office place needs to be set up at the moment. In implementation, an enterprise can use a comprehensive wiring device integrated with power and a network to improve implementation efficiency, so that sufficient power or network is provided for each office device, but the enterprise has higher requirements on the safety of building a temporary office field scene.

In the scene of building a temporary office field, because electric power and a network are vital connection facilities, if large-scale comprehensive wiring is needed, the following potential safety hazards may be faced in the implementation process: for example, power overloads and shorts: in large-scale comprehensive wiring, a large number of equipment and power sockets are required to be connected, when a group of equipment is connected to one socket at the same time, once the rated load of the socket is exceeded, the conditions of overload, short circuit or overheating of the socket can be caused, and fire or equipment failure can be caused; for example, hardware devices are improperly placed: the incorrect placement of the hardware equipment may bring potential safety hazards to personnel, such as electric shock, tripping, etc. Therefore, there is still a problem of insufficient security when building a temporary office field scene.

Disclosure of Invention

In order to overcome the defects and shortcomings in the prior art, a wiring management method and system based on a comprehensive wiring device. In order to achieve the above purpose, the present application adopts the following technical scheme:

According to an aspect of the present application, there is provided a wiring management method based on integrated wiring devices for a cloud server, the cloud server being further connected to a plurality of integrated wiring devices, at least one user terminal, respectively, each integrated wiring device having a unique device ID, the method comprising:

Acquiring corresponding multiple pieces of equipment state information and implementation site environment video information based on the site ID;

performing security evaluation analysis based on the plurality of equipment state information and the implementation site environment video information to obtain risk feedback information;

In the security assessment analysis based on the plurality of device status information and the implementation site environment video information, the method specifically comprises the following steps:

performing running state safety analysis based on the plurality of equipment state information to obtain a first safety analysis result set;

performing implementation environment safety analysis based on the implementation site environment video information to obtain a second safety analysis result set;

If the first safety analysis result set and the second safety analysis result set are empty sets, exiting the current flow, otherwise summarizing according to the first safety analysis result set and the second safety analysis result set to generate risk feedback information, wherein the risk feedback information corresponds to the site ID, and the risk feedback information is used for sending a user terminal associated with the site ID;

the implementation site environment video information is specifically a person walking video obtained by shooting any person walking on all trafficable paths in the temporary office site.

Preferably, in the operation state security analysis based on the plurality of device state information to obtain the first security analysis result set, the method specifically includes:

Initializing a first safety analysis result set, and traversing each piece of equipment state information in sequence;

Judging the running fluctuation condition of the current load battery based on the current traversed equipment state information to update a first safety analysis result set according to the equipment ID, wherein the running fluctuation condition is a fluctuation condition aiming at voltage, current and frequency;

judging the load condition of the current load battery based on the current traversed equipment state information so as to update a first safety analysis result set according to the equipment ID;

And analyzing the high Wen Qingkuang of the current load battery on the basis of the high-temperature identification model to update the first safety analysis result set according to the equipment ID.

Preferably, each integrated wiring device is provided with two storage batteries for power supply switching, the method further comprising: performing adaptive power supply switching response based on risk feedback information, specifically including:

Sequentially traversing risk feedback information, and judging whether any one of a first operation abnormality identification, a second operation abnormality identification, a third operation abnormality identification or a high-temperature abnormality identification exists in the analysis result of the currently traversed equipment;

If so, judging whether the SOC of the storage battery in a standby state is larger than a preset discharging SOC threshold value or not based on the equipment ID, if so, generating a power supply switching instruction based on the equipment ID, otherwise, generating power supply prompt information based on the equipment ID, wherein the power supply switching instruction is used for being sent to a controller to perform master-slave switching control on a power supply, and the power supply prompt information is used for being sent to a user terminal to prompt a worker to timely charge a comprehensive wiring device corresponding to the equipment ID;

if not, the processing is not performed.

According to another aspect of the present application, there is also provided a wiring management system based on an integrated wiring device, the system including:

The information collection module is used for acquiring a plurality of corresponding equipment state information and implementation site environment video information based on the site ID;

The risk feedback module is used for carrying out safety evaluation analysis based on the state information of the plurality of devices and the video information of the implementation site environment so as to obtain risk feedback information;

the power supply switching module is used for performing self-adaptive power supply switching response based on the risk feedback information;

In the security assessment analysis based on the plurality of device status information and the implementation site environment video information, the method specifically comprises the following steps:

performing running state safety analysis based on the plurality of equipment state information to obtain a first safety analysis result set;

performing implementation environment safety analysis based on the implementation site environment video information to obtain a second safety analysis result set;

If the first safety analysis result set and the second safety analysis result set are empty sets, exiting the current flow, otherwise summarizing according to the first safety analysis result set and the second safety analysis result set to generate risk feedback information, wherein the risk feedback information corresponds to the site ID, and the risk feedback information is used for sending a user terminal associated with the site ID;

the implementation site environment video information is specifically a person walking video obtained by shooting any person walking on all trafficable paths in the temporary office site.

Compared with the prior art, the application has the following advantages and beneficial effects:

(1) According to the application, the corresponding multiple device state information and implementation site environment video information are acquired based on the site ID, the operation state safety analysis is further performed based on the multiple device state information to obtain a first safety analysis result set, the implementation site environment video information is further performed based on the implementation site environment video information to obtain a second safety analysis result set, and the first safety analysis result set and the second safety analysis result set are summarized to generate risk feedback information, so that abnormal prompt of the operation state or the implementation environment is provided for the staff in time, the implementation efficiency and the maintenance efficiency of the staff when the temporary office site is built are improved, the situation that fire or device faults are caused by abnormal operation of a power supply is reduced through the timely abnormal prompt, the potential safety hazard of passing blocking caused by improper placement of hardware devices is also reduced, and meanwhile, the safety of the user when using the temporary office site is improved.

(2) In the application, in the first safety analysis result set obtained by carrying out operation state safety analysis based on a plurality of pieces of equipment state information, the safety parameter range table is utilized to respectively match the corresponding preset safety threshold range and preset safety fluctuation times of voltage, current and frequency so as to judge the operation fluctuation condition of the current load battery, the load condition of the current load battery is judged according to the residual loadable power, the high-temperature condition of the current load battery is analyzed by utilizing the high-temperature identification model, and the first safety analysis result set is updated by setting the corresponding abnormal identification, thereby providing the analysis condition of the operation state of the current load battery for the staff, timely notifying the staff of the abnormal condition in the aspect of power supply so as to carry out timely maintenance, further reducing equipment damage, and improving the reliability of the equipment and the safety of user use.

(3) In the application, in the second safety analysis result set obtained by carrying out the implementation environment safety analysis based on the implementation site environment video information, the walking position is identified based on the site key image frame sequence, the obstacle position is identified based on the site key image frame sequence, the path obstruction points are marked according to the path traffic influence degree, if the path obstruction points exist, at least one obstruction area is constructed based on the path obstruction points, the at least one obstruction area is packed and added into the second safety analysis result set, the second safety analysis result set is utilized to help the staff to timely find potential safety hazards when the staff passes in the temporary office place, and the obstruction area is timely sent to the staff and the arrangement of the temporary office place is timely adjusted, so that the possibility of accidents is reduced, and the implementation efficiency and safety of the staff when the staff builds the temporary office place are improved.

(4) According to the application, the risk feedback information and the SOC of the storage battery in the standby state are combined to perform the inspection before the power supply switching, the abnormal condition existing in the analysis of the current load battery is analyzed by using the risk feedback information, the over-discharge condition of the storage battery after the switching is avoided by analyzing the SOC of the storage battery in the standby state, the reliability and the safety during the power supply switching are improved, and the power supply stability of the temporary office place is further improved.

Drawings

FIG. 1 is a schematic flow chart of a wiring management method based on an integrated wiring device in embodiment 1 of the present application;

fig. 2 is a schematic structural diagram of a path obstruction influence table in embodiment 1 of the present application;

FIG. 3 is a schematic diagram of the structure of risk feedback information in embodiment 1 of the present application;

FIG. 4 is a schematic flow chart of a wiring management method based on the comprehensive wiring device in the embodiment 2 of the application;

FIG. 5 is a schematic block diagram of a wiring management system based on an integrated wiring device in accordance with embodiment 3 of the present application;

fig. 6 is a schematic structural diagram of a terminal according to embodiment 4 of the present application;

fig. 7 is a schematic structural diagram of a computer device according to embodiment 5 of the present application.

Detailed Description

In order that those skilled in the art will better understand the present application, a technical solution in the embodiments of the present application will be clearly and completely described below with reference to the accompanying drawings in which it is apparent that the described embodiments are only some embodiments of the present application, not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the present application without making any inventive effort, shall fall within the scope of the present application.

It should be noted that the terms "first," "second," and the like in the description and the claims of the present application and the above figures are used for distinguishing between similar objects and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used may be interchanged where appropriate such that the embodiments of the application described herein may be implemented in sequences other than those illustrated or otherwise described herein. Furthermore, the terms "comprises," "comprising," and "having," and any variations thereof, are intended to cover a non-exclusive inclusion, such that a process, method, system, article, or apparatus that comprises a list of steps or elements is not necessarily limited to those steps or elements expressly listed but may include other steps or elements not expressly listed or inherent to such process, method, article, or apparatus.

In embodiment 1, the present embodiment provides a wiring management method based on integrated wiring devices, where the method is used in a cloud server, where the cloud server is further connected to a plurality of integrated wiring devices and at least one user terminal, the cloud server is used to collect and implement field environment video information and device state information corresponding to each integrated wiring device, and perform security assessment analysis to obtain risk feedback information, and the user terminal is used to receive the risk feedback information to perform security prompt on a field implementation process, where each integrated wiring device has a unique device ID, and further each device state information corresponds to one device ID.

In this embodiment, the integrated wiring device is used to manage power supply and manage network transmissions. The integrated wiring device comprises a controller, a power module, a switch module, a communication module, a power interface component and a network interface component, wherein the controller is respectively connected with the power module, the switch module and the communication module, the power interface component is connected with the power module, and the switch module is also respectively connected with the network interface component and the power module;

In this embodiment, the power module includes a power management sub-module, a first storage battery, and a second storage battery, the power interface component includes a first power input end, a second power input end, and a plurality of power output ends, the power management module is connected to the first storage battery, the second storage battery, the plurality of power output ends, and the switch module, the first power input end is used for charging the first storage battery, the second power input end is used for charging the second storage battery, the power management sub-module is used for collecting an operation state of the power module, performing switching control on charging and discharging conditions of the first storage battery and the second storage battery, and performing power supply control on the switch module, and the plurality of power output ends are used for connecting an external access device to provide power supply;

In this embodiment, the network interface component is connected to the switch module, and the network interface component is used to connect to an external access device to provide network data transmission.

As shown in fig. 1, the method includes:

Step S100: acquiring corresponding multiple pieces of equipment state information and implementation site environment video information based on the site ID;

In this embodiment, different implementation sites respectively correspond to different site IDs, and a plurality of device state information and implementation site environment video information belonging to the same implementation site are matched according to the same site ID; for example, a hash value may be obtained by performing a hash calculation using address information of the implementation site, and the hash value may be determined as the site ID.

In this embodiment, each integrated wiring device is provided with two storage batteries for power supply switching, and each piece of equipment state information is obtained by sending the integrated wiring device corresponding to the equipment state information to a cloud server through a built-in communication module, where the equipment state information includes a load battery identifier, a first battery SOC, a second battery SOC, a load battery operation data set, and a switch operation data set;

In this embodiment, the load battery identifier is used to determine the currently used battery, if the load battery identifier is the first battery identifier, the currently used battery is indicated to be the first battery, if the load battery identifier is the second battery identifier, the currently used battery is indicated to be the second battery, and if the load battery identifier is the third battery identifier, the currently unused battery is indicated to be the third battery identifier.

In this embodiment, the load battery operation data set is data collected for the current load battery, and exemplary load battery operation data sets include time sequence data corresponding to output load, voltage, current, frequency and temperature respectively, and each device state information is collected based on a preset collection period; the preset acquisition period may be set by those skilled in the art according to actual acquisition requirements, and may be set to, for example, 5 seconds, 10 seconds, 30 seconds, 5 minutes, 10 minutes, etc., which are not particularly limited herein. In order to timely early warn safety risks, the preset collection period is set to be less than or equal to 30 seconds.

The time sequence data corresponding to the output load specifically comprises the occupation condition and the power amplitude of each power supply output end at each moment. Illustratively, the occupancy situation is divided into two states, namely an occupied state and an unoccupied state; the power amplitude is 0 when in the unoccupied state and greater than 0 when in the occupied state. The time sequence data corresponding to the output load is dimensioned according to the total number of the power supply output terminals, for example, when the total number of the power supply output terminals is 5, the time sequence data corresponding to the output load is 5-dimensional data, and each dimension corresponds to one power supply output terminal.

The switch operation data set is data collected for the switch module, and the switch operation data set comprises time sequence data corresponding to the utilization rate of processing resources and the temperature respectively and port state data corresponding to the serial number of each network port; the port state data includes data corresponding to port network traffic, port utilization, port error rate, port packet loss rate, respectively. For example, the port network traffic, the port utilization, the port error rate, and the port packet loss rate may all be obtained by monitoring the designated port according to a preset monitoring period.

In the embodiment, the implementation field environment video information is specifically a person walking video obtained by shooting any person walking on all passable paths in the temporary office field; for example, the implementation site environment video information can be obtained by shooting by a worker after setting up a temporary office place by using a user terminal.

Step S200: performing security evaluation analysis based on the plurality of equipment state information and implementation site environment video information to obtain risk feedback information;

in performing security assessment analysis based on a plurality of device status information and implementation site environment video information, the method specifically comprises:

Step S210: performing running state safety analysis based on the plurality of equipment state information to obtain a first safety analysis result set; the method specifically comprises the following steps:

Step S211: initializing a first safety analysis result set, and traversing each piece of equipment state information in sequence;

illustratively, the first set of security analysis results is initialized, specifically created and set to the empty set.

Step S212: judging the running fluctuation condition of the current load battery based on the current traversed equipment state information so as to update a first safety analysis result set according to the equipment ID, wherein the running fluctuation condition is a fluctuation condition aiming at voltage, current and frequency; the method specifically comprises the following steps:

Step S212a: in a pre-stored safety parameter range table, respectively matching a corresponding preset safety threshold range and preset safety fluctuation times for voltage, current and frequency; the preset number of security fluctuations may be set according to actual security requirements, for example, 1 time for a high security requirement level, 3 times, 4 times, 5 times for a low security requirement level, and the like, which are not particularly limited herein.

Step S212b: sequentially traversing time sequence data corresponding to voltage, current and frequency, counting actual fluctuation times according to a corresponding preset safety threshold range, and adding an operation abnormality identification corresponding to any one parameter in the voltage, the current and the frequency into a first safety analysis result set if the actual fluctuation times of the parameter are greater than or equal to the preset safety fluctuation times corresponding to the parameter; illustratively, the first operational anomaly identification corresponds to voltage, the second operational anomaly identification corresponds to current, and the third operational anomaly identification corresponds to frequency.

Step S213: judging the load condition of the current load battery based on the current traversed equipment state information so as to update a first safety analysis result set according to the equipment ID; the method specifically comprises the following steps:

Step S213a: determining the preset rated power of the current load battery according to the load battery identification;

In this embodiment, the first storage battery and the second storage battery are both provided with corresponding preset rated powers, and the preset rated powers are determined according to the actually used battery specification and model, so that the currently used storage battery is distinguished through the load battery identifier.

Step S213b: the remaining loadable power is calculated, specifically expressed as:

Wherein P _remain represents the residual loadable power of the current load battery, P _ref represents the preset rated power of the current load battery, represents the average power of the a-th power supply output end in a preset acquisition period, N represents the total number of power supply output ends, P (a, k) represents the power amplitude of the a-th power supply output end of the time sequence data corresponding to the output load in the current traversed equipment state information at the kth moment, and T represents the time sequence total number in the time sequence data corresponding to the output load;

step S213c: if the residual loadable power is smaller than 0, judging that a load abnormal condition exists, adding a load abnormal identifier into a first safety analysis result set, otherwise, not performing update processing;

In actual application, the load condition of the current load battery is judged through the residual loadable power, workers are prompted through the load abnormality identification to take countermeasures in time, stable supply of the power supply is guaranteed, power faults and accidents are avoided, and safety and reliability of the temporary office place after comprehensive wiring are improved.

Step S214: analyzing the current load battery height Wen Qingkuang of the load battery operation data set based on the high-temperature identification model to update a first safety analysis result set according to the equipment ID; the method specifically comprises the following steps:

Step S214a: extracting time sequence data corresponding to the temperature from the load battery operation data set;

Step S214b: inputting time sequence data corresponding to the temperature into a pre-trained high Wen Shibie model to output and obtain high-temperature identification information;

In this embodiment, the high Wen Shibie model is obtained by machine learning training using a plurality of sets of data, where the plurality of sets of data includes a first type of data and a second type of data, and each set of data in the first type of data includes: time sequence training data with high temperature abnormal trend and a first label value for identifying that the time sequence training data has high temperature abnormal trend; each set of data in the second class of data comprises: time sequence training data without high temperature abnormal trend and a second label value for identifying that the time sequence training data does not have high temperature abnormal trend;

Illustratively, the first tag value corresponds to TRUE of the Boolean type and the second tag value corresponds to FALSE of the Boolean type.

Step S214c: if the high-temperature identification information is the first label value, the high-temperature abnormal trend is indicated in the high-temperature condition of the current load battery, and the high-temperature abnormal identification is added to the first safety analysis result set;

Step S214d: if the high-temperature identification information output by the high-temperature identification model is the second label value, the high-temperature identification information indicates that the high-temperature condition of the current load battery does not have a high-temperature abnormal trend, and at the moment, no updating processing is performed;

in practical application, in the first safety analysis result set obtained by carrying out operation state safety analysis based on a plurality of pieces of equipment state information, the safety parameter range table is utilized to respectively match the corresponding preset safety threshold range and preset safety fluctuation times of voltage, current and frequency so as to judge the operation fluctuation condition of the current load battery, the load condition of the current load battery is judged according to the residual loadable power, the high-temperature condition of the current load battery is analyzed by utilizing the high-temperature identification model, and the first safety analysis result set is updated by setting corresponding abnormal identifications, so that the analysis condition of the operation state of the current load battery is provided for workers, the abnormal condition in the aspect of power supply of the workers is timely notified to carry out timely maintenance, the equipment damage is further reduced, and the reliability of the equipment and the safety of user use are improved.

Step S220: performing environmental safety analysis based on the implementation site environmental video information to obtain a second safety analysis result set; the method specifically comprises the following steps:

step S221: extracting the video information of the implementation site environment according to a preset sampling rate to obtain a site key image frame sequence, wherein each key image frame corresponds to a frame serial number;

Illustratively, the preset sampling rate may be set to 1:5 to 1:20, are not particularly limited herein. In practical application, because a large amount of repeated information is arranged between adjacent image frames in the video information, the on-site key image frame sequence is extracted according to the preset sampling rate, so that a large amount of unnecessary calculation time is reduced when the walking position recognition or the obstacle position recognition is carried out later, and the analysis efficiency of implementing the environmental safety analysis is improved.

Step S222: carrying out walking position identification based on the field key image frame sequence to obtain field passing path information;

The walking position identification based on the on-site key image frame sequence specifically comprises the following steps:

step S222a: traversing a scene key image frame sequence, and sequentially inputting the scene key image frame sequence into a pre-trained first field analysis model to determine the position coordinates of feet in each key image frame;

In this embodiment, the first site analysis model is obtained through machine learning training using a plurality of sets of data, where the plurality of sets of data includes a third type of data and a fourth type of data, and each set of data in the third type of data includes: an image containing the foot and a tag identifying the foot's position coordinates in the image, each set of data in the fourth type of data comprising: an image that does not contain a foot and a tag that identifies that the image does not contain a foot;

Step S222b: in a pre-stored site reference plan view, carrying out plane position point mapping on the position coordinates of feet in each key image frame in sequence, wherein each plane position point corresponds to one frame serial number;

In this embodiment, the field reference plan is obtained by uploading the field reference plan to the cloud server in advance, and because the implementation field environment video information is a picture in the temporary office field, the position coordinates of the feet in each key image frame have a corresponding plane position point after identification.

Step S222c: sequentially connecting two plane position points belonging to the adjacent frame sequence number relationship to obtain a set of field path point sets related to the plane position point connection relationship, and performing de-duplication on the field path point sets to obtain field traffic path information;

In this embodiment, when all the key image frames are ordered in the order from small to large according to the frame sequence numbers, two frame sequence numbers having an adjacent relationship in order at this time have an adjacent frame sequence number relationship.

In this embodiment, since there may be overlapping walking positions in all key image frames, at this time, the site path point set has a repeated connection relationship group, and timely deduplication is required to reduce the waste of storage resources and computing resources. Illustratively, the venue traffic path information is represented as: { connection relation 1: point1 (x 1, y 1), point2 (x 2, y 2); connection relation 2: point1 (x 1, y 1), point3 (x 3, y 3); connection relation 3: point1 (x 1, y 1), point4 (x 4, y 4); connection relation 4: point2 (x 1, y 1), point5 (x 5, y 5); … … connection relation n: pointP (xP, yP), pointQ (xQ, yQ) }, point1, point2 … … pointQ, both of which are used herein by way of example only to distinguish between different planar location points.

In actual application, the first site analysis model is utilized to identify walking positions, then the position coordinates of feet in each key image frame are mapped into plane position points in a pre-stored site reference plane diagram, and the two plane position points belonging to the adjacent frame serial number relation are connected and de-duplicated to obtain site passing path information, so that the walking path of personnel in the site environment video information can be represented, and data support is provided for analysis of the blocking condition of subsequent obstacles.

Step S223: performing obstacle position identification based on the field key image frame sequence to obtain field obstacle position information;

In the recognition of obstacle positions based on a scene key image frame sequence, the method specifically comprises the following steps:

Step S223a: traversing a scene key image frame sequence, and sequentially inputting the scene key image frame sequence into a pre-trained second field analysis model to determine the position coordinates of the obstacle in each key image frame;

In this embodiment, the second site analysis model is obtained by machine learning training using a plurality of sets of data, where the plurality of sets of data includes a fifth type of data and a sixth type of data, and each set of data in the fifth type of data includes: an image containing an obstacle, a tag identifying the type and location coordinates of the obstacle in the image, each set of data in the sixth category of data comprising: an image that does not contain an obstacle and a tag that identifies that the image does not contain an obstacle;

Exemplary types of obstructions include box type, furniture type, wire type, equipment type, carpet type. For example, in the case of case types, cases such as cartons and the like are placed on a walking path, so that people are hindered from walking, hidden danger of accidental collision or falling exists, and particularly in emergency situations, the cases can obstruct rapid evacuation of people; for example, in furniture types, there are desks or chairs that are placed in hallways, which would cause the walkway to become narrowed or blocked, with the potential for accidental collisions; for example, in the wire type, a power extension cord placed on the floor has the potential for accidental tripping; for example, in the device type, office devices such as printers, copiers, and the like are placed in a travel path with the potential for accidental tripping; for example, in carpet types, the carpet in the travel path is broken or rough with the potential for accidental tripping.

In this embodiment, the first site analysis model and the second site analysis model may be obtained by training using the yolov model, and a person skilled in the art may replace the existing recognition model according to the actual situation, which is not limited herein.

Step S223b: in a pre-stored site reference plan, carrying out plane position point mapping on position coordinates of the obstacle in each key image frame in sequence, wherein each plane position point corresponds to one frame serial number;

In this embodiment, since the implementation site environment video information is a picture in the temporary office field, the position coordinates of the obstacle in each key image frame have a corresponding planar position point after recognition.

Step S223c: obtaining a site obstacle point set by counting the plane position points of all obstacles, and performing de-duplication on the site obstacle point set to obtain site obstacle information;

In this embodiment, since the positions of the same obstacle in all the key image frames may overlap, at this time, there are repeated planar position points of the obstacle in the site obstacle point set, and timely deduplication is required to reduce the waste of storage resources and computing resources. In actual application, by traversing the site obstacle point set, taking the currently traversed plane position point as a reference, comparing with any one plane position point in the site obstacle point set, if the types of obstacles of the two plane position points are the same and the plane position points of the two plane position points are also the same, regarding the plane position point with repeated obstacles, and completing one-time deduplication operation by removing any one plane position point from the site obstacle point set;

Illustratively, the site obstacle information is expressed as: { obstacle 1: < obstacle type 1, point1 (x 1, y 1) >; obstacle 2: < obstacle type 2, point1 (x 1, y 1) >; obstacle 3: < obstacle type 3, point2 (x 2, y 2) >; … … obstacle n: < obstacle type Q, point1 (xQ, yQ) >. Point1, point2 … … pointQ are used here to distinguish planar location points of different obstacles, and are used here by way of example only.

Step S224: extracting all existing path points based on the site traffic path information, and traversing each path point in turn to calculate the path traffic influence degree of each path point, wherein the path traffic influence degree is specifically expressed as:

Let _i denote the path traffic impact of the ith waypoint, cnt _i denote the number of obstacles around the ith waypoint with blocking impact identification, β _i denote the concentration of the ith waypoint, γ _i denote the obstacle distance fluctuation coefficient of the ith waypoint, total_cnt denote the total number of all obstacles in the field, d (i, j) denote the relative distance between the ith waypoint and the jth obstacle around with blocking impact identification, and/> denote the average of the relative distances between the ith waypoint and the jth obstacle around with blocking impact identification;

In this embodiment, d (i, j) may be calculated by substituting an equation between two points into an abscissa and an ordinate of a plane position point;

In this embodiment, for any one of the path points, when the relative distance between the path point and one of the obstacles is less than or equal to the first preset distance, the obstacle impact identifier with the obstacle is set for the path point.

For example, the blocking effect identification may be determined by a path blocking effect table including a plurality of blocking sets, each blocking set corresponding to one path point one-to-one; each obstruction set comprises a relative distance between the path point and each obstacle, if any relative distance is smaller than or equal to a first preset distance, an obstruction influence mark is set for the relative distance, otherwise, no processing is carried out;

As shown in fig. 2, the path blocking influence table includes a blocking set 1, blocking sets 2, … …, and a blocking set x, where blocking set 1 corresponds to path point 1, blocking set 2 corresponds to path point 2, and blocking set x corresponds to path point x. In the obstruction set 1, the relative distance (1, 1) is used for recording the relative distance between the path point 1 and the obstacle 1, the relative distance (1, 2) is used for recording the relative distance between the path point 1 and the obstacle 2, and the relative distance (1, n) is used for recording the relative distance between the path point 1 and the obstacle n; in the obstruction set x, the relative distance (x, 1) is used for recording the relative distance between the path point x and the obstacle 1, the relative distance (x, 2) is used for recording the relative distance between the path point x and the obstacle 2, and the relative distance (x, n) is used for recording the relative distance between the path point x and the obstacle n;

The first preset distance may be set to any value from 1 to 15 cm, and may specifically be set according to actual blocking requirements.

Step S225: for each path point, marking the path point as a path blocking point if the path traffic influence is greater than a preset path influence threshold;

step S226: if the path obstruction points exist, constructing at least one obstruction area based on the path obstruction points, packaging the at least one obstruction area and adding the at least one obstruction area into a second safety analysis result set, otherwise, not processing the second safety analysis result set;

In this embodiment, each blocking area includes at least one path blocking point, and in constructing at least one blocking area based on the path blocking point, specifically includes:

step S226a: sequentially traversing the path obstruction points, and if the path obstruction point traversed at present is the path obstruction point traversed at first, creating an obstruction area based on the path obstruction point;

Step S226b: if the currently traversed path obstruction point is a path obstruction point which is not traversed first, executing the following processes until the traversal is finished:

judging whether the path blocking point and each blocking area have a subordinate relation or not based on a second preset distance; for example, if the relative distance between the currently traversed path blocking point and any path blocking point in one blocking area is smaller than the second preset distance, the currently traversed path blocking point has a subordinate relationship with the blocking area, otherwise, the currently traversed path blocking point has no subordinate relationship;

merging the blocking areas based on the subordinate relations of the common path blocking points, if the path blocking point currently traversed has subordinate relations with at least two blocking areas, merging the at least two blocking areas into the same blocking area, and adding the path blocking point currently traversed into the merged blocking area;

if the currently traversed path obstruction point has an affiliated relation with only one obstruction area, adding the currently traversed path obstruction point into the obstruction area;

If the currently traversed path obstruction point has no subordinate relationship with any obstruction area, a new obstruction area is created based on the currently traversed path obstruction point.

In this embodiment, the preset path influence threshold is greater than 0, and the magnitude of the preset path influence threshold may be adjusted according to the requirement of actually blocking the channel, which is not specifically limited herein.

In practical application, in the second safety analysis result set obtained by carrying out the environmental safety analysis based on the implementation site environmental video information, the walking position is identified based on the site key image frame sequence, the obstacle position is identified based on the site key image frame sequence, the path obstruction points are marked according to the path passing influence degree, if the path obstruction points exist, at least one obstruction area is built based on the path obstruction points, the obstruction area is packed and added into the second safety analysis result set, the second safety analysis result set is utilized to help the staff to timely find potential safety hazards when the staff passes through the temporary office place, the obstruction area is timely sent to the staff, and the arrangement of the temporary office place is timely adjusted, so that the possibility of accidents is reduced, and the implementation efficiency and safety of the staff when the temporary office place is built are improved.

Step S230: if the first safety analysis result set and the second safety analysis result set are empty sets, exiting the current flow;

In this embodiment, the empty set indicates that there is no data in the set of security analysis results, which may be indicated by NULL, for example.

Step S240: and otherwise, summarizing according to the first safety analysis result set and the second safety analysis result set to generate risk feedback information.

In this embodiment, the risk feedback information corresponds to a site ID, and the risk feedback information is used to send to a user terminal associated with the site ID to accurately prompt, and each worker registers address information of the implementation site through the user terminal during operation, so as to be associated with the corresponding site ID.

In this embodiment, the risk feedback information is classified and integrated data according to the first safety analysis result set and the second safety analysis result set to complete the summarizing process.

As shown in connection with fig. 3, the risk feedback information includes, for example, a venue ID, a first set of security analysis results, and a second set of security analysis results. In the first safety analysis result set, device analysis result 1 to device analysis result n are included, and in the second safety analysis result set, blocking area 1 to blocking area n are included.

The first safety analysis result set comprises at least one device analysis result, each device analysis result corresponds to a device ID, and the device analysis result comprises any one or any combination of a first operation abnormality identification, a second operation abnormality identification, a third operation abnormality identification, a load abnormality identification and a high-temperature abnormality identification, and data in the first safety analysis result set is updated specifically according to actual abnormal conditions;

The second safety analysis result set comprises at least one blocking area, and a worker can find a pre-stored site reference plan according to the site ID, so that a position of an improper placement of an obstacle in the temporary office site is found according to the at least one blocking area, and the worker is assisted to find the blocking area in the temporary office site, so that the site operation efficiency of the worker in the temporary office site is improved;

In actual application, the method and the system acquire the corresponding multiple device state information and the implementation site environment video information based on the site ID, further perform operation state safety analysis based on the multiple device state information to obtain a first safety analysis result set, perform implementation environment safety analysis based on the implementation site environment video information to obtain a second safety analysis result set, and summarize according to the first safety analysis result set and the second safety analysis result set to generate risk feedback information, further provide an operation state or an abnormal prompt of an implementation environment for a worker in time, improve the implementation efficiency of the worker when the worker builds a temporary office site, reduce the fire disaster or equipment failure caused by abnormal power supply operation through timely abnormal prompt, reduce the potential safety hazards caused by improper placement of hardware equipment, and improve the safety of the user when using the temporary office site.

In embodiment 2, the present embodiment optimizes discharge of the integrated wiring device on the basis of embodiment 1 above to improve safety during power switching, and provides a wiring management method based on the integrated wiring device.

As shown in fig. 4, the method further includes:

Step S300: performing self-adaptive power supply switching response based on risk feedback information; the method specifically comprises the following steps:

Step S310: sequentially traversing risk feedback information, and judging whether any one of a first operation abnormality identification, a second operation abnormality identification, a third operation abnormality identification or a high-temperature abnormality identification exists in the analysis result of the currently traversed equipment;

step S320: if so, judging whether the SOC of the storage battery in a standby state is larger than a preset discharging SOC threshold value or not based on the equipment ID, if so, generating a power supply switching instruction based on the equipment ID, otherwise, generating power supply prompt information based on the equipment ID, wherein the power supply switching instruction is used for being sent to a controller to perform master-slave switching control on a power supply, and the power supply prompt information is used for being sent to a user terminal to prompt a worker to timely charge a comprehensive wiring device corresponding to the equipment ID;

In the present embodiment, the preset discharge SOC threshold value may be set to any value of 10 to 20%, and is not particularly limited herein.

For example, the battery in the standby state may be determined according to the load battery identifier, that is, the current load battery is determined by using the load battery identifier, and then the other unused battery is the battery in the standby state, so as to select the corresponding SOC state, that is, the first battery SOC or the second battery SOC.

Step S330: if not, the processing is not performed.

During practical application, the risk feedback information and the SOC of the storage battery in the standby state are combined to conduct inspection before power supply switching, abnormal conditions existing in current load battery analysis are analyzed through the risk feedback information, the SOC of the storage battery in the standby state is used for analyzing to avoid over-discharge of the storage battery after switching, reliability and safety during power supply switching are improved, effectiveness and safety of power supply transmission are guaranteed, and power supply stability of a temporary office place is improved.

In embodiment 3, this embodiment provides a wiring management system based on an integrated wiring device, which corresponds to the method provided in the above embodiment, and the same contents are not repeated.

As shown in fig. 5, the system includes:

The information collection module is used for acquiring a plurality of corresponding equipment state information and implementation site environment video information based on the site ID;

The risk feedback module is used for carrying out safety evaluation analysis based on the state information of the plurality of devices and the implementation site environment video information so as to obtain risk feedback information;

In this embodiment, the system further includes:

and the power supply switching module is used for carrying out self-adaptive power supply switching response based on the risk feedback information.

In embodiment 4, as shown in fig. 6, this embodiment provides a terminal, including: at least one memory and at least one processor; wherein the at least one memory is configured to store program code, and the at least one processor is configured to invoke the program code stored in the at least one memory to perform any of the integrated wiring device-based wiring management methods of the above embodiments.

In embodiment 5, the present embodiment provides a computer device, which may be a server, and the internal structure thereof may be as shown in fig. 7. The computer device includes a processor, a memory, a network interface, and a database connected by a system bus. Wherein the processor of the computer device is configured to provide computing and control capabilities. The memory of the computer device includes a non-volatile storage medium and an internal memory. The non-volatile storage medium stores an operating system, computer programs, and a database. The internal memory provides an environment for the operation of the operating system and computer programs in the non-volatile storage media. The database of the computer device is a physical layer for storing various databases. The network interface of the computer device is used for communicating with an external terminal through a network connection. The computer program, when executed by a processor, implements a wiring management method based on an integrated wiring device.

It will be appreciated by those skilled in the art that the structure shown in FIG. 7 is merely a block diagram of some of the structures associated with the present inventive arrangements and is not limiting of the computer device to which the present inventive arrangements may be applied, and that a particular computer device may include more or fewer components than shown, or may combine some of the components, or have a different arrangement of components.

In embodiment 6, the present embodiment provides a storage medium for storing program code for executing the above-described one wiring management method based on the integrated wiring device.

The foregoing description is only of the preferred embodiments of the present disclosure and description of the principles of the technology being employed. It will be appreciated by persons skilled in the art that the scope of the disclosure referred to in this disclosure is not limited to the specific combinations of features described above, but also covers other embodiments which may be formed by any combination of features described above or equivalents thereof without departing from the spirit of the disclosure. Such as those described above, are mutually substituted with the technical features having similar functions disclosed in the present disclosure (but not limited thereto).

Moreover, although operations are depicted in a particular order, this should not be understood as requiring that such operations be performed in the particular order shown or in sequential order. In certain circumstances, multitasking and parallel processing may be advantageous. Likewise, while several specific implementation details are included in the above discussion, these should not be construed as limiting the scope of the present disclosure. Certain features that are described in the context of separate embodiments can also be implemented in combination in a single embodiment. Conversely, various features that are described in the context of a single embodiment can also be implemented in multiple embodiments separately or in any suitable subcombination.

The above examples are preferred embodiments of the present application, but the embodiments of the present application are not limited to the above examples, and any other changes, modifications, substitutions, combinations, and simplifications that do not depart from the spirit and principle of the present application should be made in the equivalent manner, and the embodiments are included in the protection scope of the present application.

Claims (10)

1. A wiring management method based on integrated wiring devices, for a cloud server, the cloud server further being respectively connected to a plurality of integrated wiring devices, at least one user terminal, each integrated wiring device having a unique device ID, the method comprising:

Acquiring corresponding multiple pieces of equipment state information and implementation site environment video information based on the site ID;

performing security evaluation analysis based on the plurality of equipment state information and the implementation site environment video information to obtain risk feedback information;

In the security assessment analysis based on the plurality of device status information and the implementation site environment video information, the method specifically comprises the following steps:

performing running state safety analysis based on the plurality of equipment state information to obtain a first safety analysis result set;

performing implementation environment safety analysis based on the implementation site environment video information to obtain a second safety analysis result set;

If the first safety analysis result set and the second safety analysis result set are empty sets, exiting the current flow, otherwise summarizing according to the first safety analysis result set and the second safety analysis result set to generate risk feedback information, wherein the risk feedback information corresponds to the site ID, and the risk feedback information is used for sending a user terminal associated with the site ID;

the implementation site environment video information is specifically a person walking video obtained by shooting any person walking on all trafficable paths in the temporary office site.

2. The method of claim 1, wherein the performing the operation state security analysis based on the plurality of device state information to obtain the first security analysis result set specifically comprises:

Initializing a first safety analysis result set, and traversing each piece of equipment state information in sequence;

Judging the running fluctuation condition of the current load battery based on the current traversed equipment state information to update a first safety analysis result set according to the equipment ID, wherein the running fluctuation condition is a fluctuation condition aiming at voltage, current and frequency;

judging the load condition of the current load battery based on the current traversed equipment state information so as to update a first safety analysis result set according to the equipment ID;

And analyzing the high Wen Qingkuang of the current load battery on the basis of the high-temperature identification model to update the first safety analysis result set according to the equipment ID.

3. The method according to claim 2, wherein in the case of determining the operational fluctuation of the current load battery based on the currently traversed device state information, specifically comprising:

in a pre-stored safety parameter range table, respectively matching a corresponding preset safety threshold range and preset safety fluctuation times for voltage, current and frequency;

Sequentially traversing time sequence data corresponding to voltage, current and frequency, counting actual fluctuation times according to a corresponding preset safety threshold range, and adding an operation abnormality identification corresponding to any one parameter in the voltage, the current and the frequency into a first safety analysis result set if the actual fluctuation times of the parameter are greater than or equal to the preset safety fluctuation times corresponding to the parameter.

4. The method of claim 2, wherein in determining a load condition of the current load battery based on the currently traversed device state information, specifically comprising:

determining the preset rated power of the current load battery according to the load battery identification;

the remaining loadable power is calculated, specifically expressed as:

Wherein P _remain represents the residual loadable power of the current load battery, P _ref represents the preset rated power of the current load battery, represents the average power of the a-th power supply output end in a preset acquisition period, N represents the total number of power supply output ends, P (a, k) represents the power amplitude of the a-th power supply output end of the time sequence data corresponding to the output load in the current traversed equipment state information at the kth moment, and T represents the time sequence total number in the time sequence data corresponding to the output load;

If the residual loadable power is smaller than 0, judging that a load abnormal condition exists, adding a load abnormal identifier into the first safety analysis result set, and otherwise, not performing update processing.

5. The method of claim 2, wherein in analyzing the high temperature condition of the current load battery based on the high Wen Shibie model for the load battery operation dataset, specifically comprising:

extracting time sequence data corresponding to the temperature from the load battery operation data set;

Inputting the time sequence data corresponding to the temperature into a high Wen Shibie model to output to obtain high-temperature identification information;

The high-temperature identification model is obtained through machine learning training by using a plurality of groups of data, wherein the plurality of groups of data comprise first-class data and second-class data, and each group of data in the first-class data comprises: time sequence training data with high temperature abnormal trend and a first label value for identifying that the time sequence training data has high temperature abnormal trend; each set of data in the second class of data comprises: time sequence training data without high temperature abnormal trend and a second label value for identifying that the time sequence training data does not have high temperature abnormal trend;

If the high-temperature identification information is the first label value, the high-temperature abnormal trend is indicated in the high-temperature condition of the current load battery, and the high-temperature abnormal identification is added to the first safety analysis result set;

if the high-temperature identification information output by the high-temperature identification model is the second label value, the high-temperature identification information indicates that the high-temperature condition of the current load battery does not have a high-temperature abnormal trend, and at the moment, updating processing is not performed.

6. The method according to claim 1, wherein in the performing the environmental security analysis based on the performing field environmental video information to obtain the second security analysis result set, specifically comprising:

Extracting the implementation site environment video information according to a preset sampling rate to obtain a site key image frame sequence, wherein each key image frame corresponds to a frame sequence number;

Carrying out walking position identification based on the field key image frame sequence to obtain field passing path information;

performing obstacle position identification based on the field key image frame sequence to obtain field obstacle position information;

extracting all existing path points based on the site traffic path information, and traversing each path point in turn to calculate the path traffic influence degree of each path point;

for each path point, marking the path point as a path blocking point if the path traffic influence is greater than a preset path influence threshold;

If the path obstruction points exist, constructing at least one obstruction area based on the path obstruction points, packaging the at least one obstruction area and adding the at least one obstruction area into a second safety analysis result set, otherwise, not processing the second safety analysis result set;

the path traffic influence degree is specifically expressed as:

Let _i denote the path traffic impact of the ith waypoint, cnt _i denote the number of obstacles around the ith waypoint with blocking impact identification, β _i denote the concentration of the ith waypoint, γ _i denote the obstacle distance fluctuation coefficient of the ith waypoint, total_cnt denote the total number of all obstacles in the field, d (i, j) denote the relative distance between the ith waypoint and the jth obstacle around with blocking impact identification, and/> denote the average of the relative distances between the ith waypoint and the jth obstacle around with blocking impact identification;

And setting a blocking influence mark with an obstacle for any path point when the relative distance between the path point and the obstacle is smaller than or equal to a first preset distance.

7. The method according to claim 6, wherein in the walking position identification based on the on-site key image frame sequence, specifically comprising:

Traversing a field key image frame sequence and sequentially inputting the field key image frame sequence into a pre-trained first field analysis model to determine the position coordinates of feet in each key image frame, wherein the first field analysis model is obtained by using a plurality of groups of data through machine learning training, the plurality of groups of data comprise third data and fourth data, and each group of data in the third data comprises: an image containing the foot and a tag identifying the foot's position coordinates in the image, each set of data in the fourth type of data comprising: an image that does not contain a foot and a tag that identifies that the image does not contain a foot;

in a pre-stored site reference plan view, carrying out plane position point mapping on the position coordinates of feet in each key image frame in sequence, wherein each plane position point corresponds to one frame serial number;

sequentially connecting two plane position points belonging to the adjacent frame sequence number relationship to obtain a set of field path point sets related to the plane position point connection relationship, and performing de-duplication on the field path point sets to obtain field traffic path information;

when all the key image frames are ordered according to the frame sequence numbers from small to large, two frame sequence numbers with adjacent relations in sequence have the adjacent frame sequence number relation.

8. The method of claim 6, wherein in the obstacle location identification based on the sequence of live key image frames, specifically comprising:

Traversing a field key image frame sequence and sequentially inputting the field key image frame sequence into a pre-trained second field analysis model to determine the position coordinates of the obstacle in each key image frame, wherein the second field analysis model is obtained by using a plurality of groups of data through machine learning training, the plurality of groups of data comprise fifth data and sixth data, and each group of data in the fifth data comprises: an image containing an obstacle, a tag identifying the type and location coordinates of the obstacle in the image, each set of data in the sixth category of data comprising: an image that does not contain an obstacle and a tag that identifies that the image does not contain an obstacle;

in a pre-stored site reference plan, carrying out plane position point mapping on position coordinates of the obstacle in each key image frame in sequence, wherein each plane position point corresponds to one frame serial number;

And obtaining a site obstacle point set by counting the plane position points of all the obstacles, and performing de-duplication on the site obstacle point set to obtain site obstacle information.

9. The method of claim 1, wherein each integrated wiring device is provided with two batteries for power switching, the method further comprising:

performing adaptive power supply switching response based on risk feedback information, specifically including:

Sequentially traversing risk feedback information, and judging whether any one of a first operation abnormality identification, a second operation abnormality identification, a third operation abnormality identification or a high-temperature abnormality identification exists in the analysis result of the currently traversed equipment;

If so, judging whether the SOC of the storage battery in a standby state is larger than a preset discharging SOC threshold value or not based on the equipment ID, if so, generating a power supply switching instruction based on the equipment ID, otherwise, generating power supply prompt information based on the equipment ID, wherein the power supply switching instruction is used for being sent to a controller to perform master-slave switching control on a power supply, and the power supply prompt information is used for being sent to a user terminal to prompt a worker to timely charge a comprehensive wiring device corresponding to the equipment ID;

if not, the processing is not performed.

10. A wiring management system based on an integrated wiring device, comprising:

The information collection module is used for acquiring a plurality of corresponding equipment state information and implementation site environment video information based on the site ID;

The risk feedback module is used for carrying out safety evaluation analysis based on the state information of the plurality of devices and the video information of the implementation site environment so as to obtain risk feedback information;

the power supply switching module is used for performing self-adaptive power supply switching response based on the risk feedback information;

In the security assessment analysis based on the plurality of device status information and the implementation site environment video information, the method specifically comprises the following steps:

performing running state safety analysis based on the plurality of equipment state information to obtain a first safety analysis result set;

performing implementation environment safety analysis based on the implementation site environment video information to obtain a second safety analysis result set;

If the first safety analysis result set and the second safety analysis result set are empty sets, exiting the current flow, otherwise summarizing according to the first safety analysis result set and the second safety analysis result set to generate risk feedback information, wherein the risk feedback information corresponds to the site ID, and the risk feedback information is used for sending a user terminal associated with the site ID;

the implementation site environment video information is specifically a person walking video obtained by shooting any person walking on all trafficable paths in the temporary office site.