CN115171236A

CN115171236A - Inspection management method, inspection management platform and inspection management client

Info

Publication number: CN115171236A
Application number: CN202210751398.7A
Authority: CN
Inventors: 刘云; 刘允锋; 王斌; 刘芳
Original assignee: Beijing Feitian Jingwei Technology Co ltd
Current assignee: Beijing Feitian Jingwei Technology Co ltd
Priority date: 2022-06-29
Filing date: 2022-06-29
Publication date: 2022-10-11
Anticipated expiration: 2042-06-29
Also published as: CN115171236B

Abstract

The application relates to a patrol management method, a patrol management platform and a patrol management client. The management platform can generate an inspection task according to the position information of the equipment to be inspected; the inspection task comprises a plurality of sub inspection tasks; aiming at each sub-inspection task, the sub-inspection task is sent to a client of the inspector, and the client can display the recommended inspection route, prompt the inspector to inspect according to the corresponding recommended inspection route and upload the running state information of the equipment to be inspected; after receiving the inspection starting instruction, the client continuously detects the real-time positioning information and feeds the real-time positioning information back to the management platform; the management platform matches the real-time positioning information with the proposed routing inspection route; if the real-time positioning information deviates from the proposed routing inspection route, sending route deviation prompt information to the client; and generating a route deviation event of the inspector, and storing the route deviation event into inspection task execution information of the inspector.

Description

Inspection management method, inspection management platform and inspection management client

Technical Field

The application relates to the technical field of data processing, in particular to a patrol management method, a patrol management platform and a patrol management client.

Background

The circuit inspection is one of daily works of the power department, and the defects of the equipment can be found in time through efficient inspection, so that corresponding treatment can be carried out in time, and major accidents are avoided.

Due to the factors such as capital status and technical maturity, many areas still adopt the traditional manual inspection mode. When the patrolling personnel carry out the patrolling task, the patrolling personnel are relatively free and difficult to monitor and manage. This can lead to a certain extent that the task of patrolling and examining consumes longer, and the completion degree is relatively poor, and the whole efficiency of patrolling and examining is lower.

Disclosure of Invention

The application provides a patrol inspection management method, a patrol inspection management platform and a patrol inspection management client, which can realize supervision and management of multiple links in a manual patrol inspection process so as to improve patrol inspection efficiency.

In a first aspect, the present application provides a method for routing inspection management, which is applied to a management platform, and the method includes:

generating a polling task according to the position information of the equipment to be polled; the inspection task comprises a plurality of sub inspection tasks, a suggested inspection route corresponding to each sub inspection task, and equipment to be inspected corresponding to each sub inspection task;

aiming at each sub-inspection task, distributing the sub-inspection task to a corresponding inspector, and sending the sub-inspection task, a suggested inspection route corresponding to the sub-inspection task and equipment to be inspected corresponding to the sub-inspection task to a client of the inspector so that the inspector inspects the equipment to be inspected according to the suggested inspection route corresponding to the sub-inspection task and uploads the running state information of the equipment to be inspected;

receiving real-time positioning information, and matching the real-time positioning information with the proposed routing inspection route; the real-time positioning information is obtained by continuously detecting after any client receives the inspection starting instruction;

if the real-time positioning information deviates from the suggested routing inspection route, sending route deviation prompt information to the client so that the client displays the route deviation prompt information to remind the inspector to adjust the routing inspection route;

and generating a route deviation event of the inspector according to the route deviation prompt information, and storing the route deviation event into inspection task execution information of the inspector.

Optionally, the method further includes:

if the real-time positioning information is determined to belong to the inspection range of any equipment to be inspected in the recommended inspection route, transmitting inspection information registration prompt information to the client, so that the client registers the prompt information according to the inspection information, displays an equipment running state information input interface corresponding to the equipment to be inspected, and feeds back running state information of the equipment to be inspected, which is recorded by the inspector in a selected input mode, to the management platform; the equipment running state information input interface comprises at least one of a video input option, an image input option, a voice input option and a character input option;

and analyzing the running state information of the equipment to be inspected, and determining the running state of the equipment to be inspected.

Optionally, the method further includes:

determining the routing inspection plan of each power device according to the historical routing inspection record of each power device; the historical inspection record comprises the time of the previous inspection and the running state of the power equipment in the previous inspection; the routing inspection plan comprises planned routing inspection time and key routing inspection items;

determining the current equipment to be patrolled and patrolling and the key patrolling items of the equipment to be patrolled and patrolled according to the patrolling and examining plan of each power equipment;

according to the positional information of the equipment to be patrolled and examined, generate and patrol and examine the task, patrol and examine the task and include that a plurality of sub patrol and examine the suggestion that the task corresponds and patrol and examine the route, include:

and generating an inspection task according to the position information and the key inspection items of the equipment to be inspected, wherein the inspection task comprises a plurality of sub inspection tasks, a suggested inspection route corresponding to each sub inspection task, the equipment to be inspected corresponding to each sub inspection task, and the key inspection items of the equipment to be inspected corresponding to each sub inspection task.

Optionally, the method further includes:

predicting the predicted completion time of each sub-inspection task by combining road condition information; the predicted completion time comprises predicted passing time between every two adjacent devices to be inspected in the proposed inspection route and inspection time of each device to be inspected;

determining corresponding actual inspection time according to the reporting time of the real-time positioning information corresponding to the sub inspection task;

determining the prediction probability of completing the sub-inspection tasks on time according to the predicted completion time and the actual inspection time;

and if the prediction probability is smaller than a preset threshold value, sending inspection speed acceleration prompt information to the client to remind the inspector of improving the inspection speed.

Optionally, the method further includes:

aiming at each sub-inspection task, if a task completion prompt is received before the predicted completion time, planning a newly-added inspection task and sending the newly-added inspection task to a corresponding client;

and if receiving a task receiving prompt and a newly increased inspection task completion prompt returned by the client, generating a corresponding excess completion event of the inspector, and storing the excess completion event into inspection task execution information of the inspector.

In a second aspect, the present application provides a method for routing inspection management, which is applied to a client, and the method includes:

receiving a sub inspection task, a suggested inspection route corresponding to the sub inspection task and equipment to be inspected corresponding to the sub inspection task; the sub inspection tasks, the suggested inspection routes corresponding to the sub inspection tasks and the equipment to be inspected corresponding to the sub inspection tasks are generated according to the position information of the equipment to be inspected;

displaying the recommended routing inspection route, prompting an inspector to inspect equipment to be inspected according to the recommended routing inspection route, and uploading running state information of the equipment to be inspected;

after receiving a polling starting instruction, continuously detecting real-time positioning information and feeding back the real-time positioning information to a management platform;

receiving route deviation prompt information; the route deviation prompting information is sent when the management platform matches the real-time positioning information with the proposed routing inspection route and determines that the real-time positioning information deviates from the proposed routing inspection route;

and displaying the route deviation prompt information to remind the inspector to adjust the inspection route.

Optionally, the method further includes:

receiving patrol information registration prompt information which is sent when the management platform determines that the real-time positioning information belongs to the patrol range of any equipment to be patrolled in the proposed patrol route;

registering prompt information according to the inspection information, and displaying an equipment running state information input interface corresponding to the equipment to be inspected; the equipment running state information input interface comprises at least one of a video input option, an image input option, a voice input option and a character input option; recording the running state information of the equipment to be inspected by the inspector in a selected input mode;

and feeding back the running state information of the equipment to be inspected to the management platform.

Optionally, feeding back the running state information of the device to be inspected to the management platform includes:

detecting a network connection state;

if the network is in a connection state, feeding back the running state information of the equipment to be inspected to the management platform;

if the network is in the unconnected state, the transmitted information node is recorded so that transmission continues from the transmitted information node while the network is in the connected state.

In a third aspect, the present application provides a patrol management platform, including:

the inspection task generating module is used for generating an inspection task according to the position information of the equipment to be inspected; the inspection task comprises a plurality of sub inspection tasks, a suggested inspection route corresponding to each sub inspection task, and equipment to be inspected corresponding to each sub inspection task;

the inspection task distribution module is used for distributing the sub inspection tasks to corresponding inspectors according to each sub inspection task, sending the sub inspection tasks, the recommended inspection routes corresponding to the sub inspection tasks and the equipment to be inspected corresponding to the sub inspection tasks to clients of the inspectors, so that the inspectors can inspect the equipment to be inspected according to the recommended inspection routes corresponding to the sub inspection tasks and upload the running state information of the equipment to be inspected;

the real-time positioning information matching module is used for receiving real-time positioning information and matching the real-time positioning information with the recommended routing inspection route; the real-time positioning information is obtained by continuously detecting any client after receiving a patrol starting instruction;

a route deviation prompt message sending module, configured to send a route deviation prompt message to the client if it is determined that the real-time positioning message deviates from the proposed routing inspection route, so that the client displays the route deviation prompt message to remind the inspector to adjust the routing inspection route;

and the route deviation event generating module is used for generating a route deviation event of the inspector according to the route deviation prompt information and storing the route deviation event into inspection task execution information of the inspector.

Optionally, the inspection management platform further includes: an equipment operating state determination module configured to:

when the real-time positioning information is determined to belong to the inspection range of any equipment to be inspected in the recommended inspection route, transmitting inspection information registration prompt information to the client, so that the client can display an equipment running state information input interface corresponding to the equipment to be inspected according to the inspection information registration prompt information and feed back the running state information of the equipment to be inspected, which is recorded by the inspector in a selected input mode, to the management platform; the equipment running state information input interface comprises at least one of a video input option, an image input option, a voice input option and a character input option;

Optionally, the inspection management platform further includes: the equipment of waiting to patrol and examine confirms the module for:

determining a routing inspection plan of each power device according to the historical routing inspection record of each power device; the historical inspection record comprises the time of the previous inspection and the running state of the power equipment in the previous inspection; the routing inspection plan comprises planned routing inspection time and key routing inspection items;

determining the current equipment to be inspected and key inspection items of the equipment to be inspected according to the inspection plan of each power equipment;

the patrol task generation module is specifically used for:

Optionally, the inspection management platform further includes: patrol and examine time-consuming monitoring module for:

predicting the predicted completion time of each sub-inspection task by combining road condition information; the predicted completion time comprises the predicted passing time between every two adjacent devices to be inspected in the recommended inspection route and the inspection time of each device to be inspected;

determining corresponding actual polling time according to the reporting time of the real-time positioning information corresponding to the sub polling tasks;

Optionally, the inspection management platform further includes: newly add and patrol and examine task allocation module for:

In a fourth aspect, the present application provides a polling client, including:

the receiving module is used for receiving the sub-inspection tasks, the recommended inspection routes corresponding to the sub-inspection tasks and the equipment to be inspected corresponding to the sub-inspection tasks; the sub inspection task, the recommended inspection route corresponding to the sub inspection task and the equipment to be inspected corresponding to the sub inspection task are generated according to the position information of the equipment to be inspected;

the display module is used for displaying the recommended routing inspection route, prompting an inspector to inspect the equipment to be inspected according to the recommended routing inspection route and uploading the running state information of the equipment to be inspected;

the real-time positioning information detection module is used for continuously detecting the real-time positioning information after receiving the patrol starting instruction and feeding the real-time positioning information back to the management platform;

the receiving module is also used for prompting the deviation of the route; the route deviation prompting information is sent when the management platform matches the real-time positioning information with the proposed routing inspection route and determines that the real-time positioning information deviates from the proposed routing inspection route;

the display module is also used for displaying the route deviation prompt information to remind the inspector to adjust the inspection route.

Optionally, the polling client further includes: the equipment running state entering module is used for:

receiving patrol information registration prompt information, wherein the patrol information registration prompt information is sent when the management platform determines that the real-time positioning information belongs to the patrol range of any equipment to be patrolled in the proposed patrol route;

Optionally, the running state recording module of the device feeds back the running state information of the device to be patrolled and examined to the management platform, and is specifically configured to:

detecting a network connection state;

In a fifth aspect, the present application provides an electronic device, comprising: a memory having stored thereon a computer program which is loadable by the processor and which performs the method of the first or second aspect.

In a sixth aspect, the present application provides a computer readable storage medium storing a computer program capable of being loaded by a processor and performing the method of the first or second aspect.

In a seventh aspect, the present application provides a computer program product comprising: a computer program; the computer program, when executed by a processor, implements a method as set forth in any one of the first aspect or the second aspect.

The application provides a patrol management method, a patrol management platform and a patrol management client. The management platform can generate an inspection task according to the position information of the equipment to be inspected; the inspection task comprises a plurality of sub inspection tasks, a suggested inspection route corresponding to each sub inspection task, and equipment to be inspected corresponding to each sub inspection task; aiming at each sub-inspection task, distributing the sub-inspection task to a corresponding inspector, sending the sub-inspection task, a recommended inspection route corresponding to the sub-inspection task and equipment to be inspected corresponding to the sub-inspection task to a client of the inspector, wherein the client can display the recommended inspection route, prompt the inspector to inspect the equipment to be inspected according to the recommended inspection route corresponding to the sub-inspection task, and upload the running state information of the equipment to be inspected; after receiving the inspection starting instruction, the client continuously detects the real-time positioning information and feeds the real-time positioning information back to the management platform; the management platform receives real-time positioning information and matches the real-time positioning information with the proposed routing inspection route; if the real-time positioning information deviates from the suggested routing inspection route, sending route deviation prompt information to the client so that the client displays the route deviation prompt information to remind the inspector to adjust the routing inspection route; and generating a route deviation event of the inspector according to the route deviation prompt information, and storing the route deviation event into inspection task execution information of the inspector. Based on the scheme of the application, a plurality of sub-inspection tasks and corresponding recommended inspection routes can be reasonably planned and distributed to each inspector; in the routing inspection process, the client detects the positioning information in real time and sends the positioning information to the platform; and the platform judges whether the position accords with the recommended patrol route, if the position deviates, the patrol personnel possibly have off-duty behavior, sends information to the client for prompting, and records the behavior as an examination basis. So, realize the supervision and the management to artifical a plurality of links of patrolling and examining the in-process to in the promotion efficiency of patrolling and examining.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly introduced below, and it is obvious that the drawings in the following description are some embodiments of the present application, and for those skilled in the art, other drawings can be obtained according to these drawings without inventive exercise.

Fig. 1 is a schematic view of an application scenario provided in an embodiment of the present application;

fig. 2 is a flowchart of an inspection management method according to an embodiment of the present application;

fig. 3 is a flowchart of another inspection management method according to an embodiment of the present application;

fig. 4 is a schematic diagram of an inspection management system according to an embodiment of the present application;

fig. 5 is a schematic structural diagram of an inspection management platform according to an embodiment of the present disclosure;

fig. 6 is a schematic structural diagram of an inspection management platform according to an embodiment of the present disclosure;

fig. 7 is a schematic structural diagram of an electronic device according to an embodiment of the application.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present application clearer, the technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application. It is to be understood that the embodiments described are only a few embodiments of the present application and not all 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 application.

In addition, the term "and/or" herein is only one kind of association relationship describing an associated object, and means that there may be three kinds of relationships, for example, a and/or B, which may mean: a exists alone, A and B exist simultaneously, and B exists alone. In addition, the character "/" herein generally indicates that the former and latter related objects are in an "or" relationship, unless otherwise specified.

The embodiments of the present application will be described in further detail with reference to the drawings attached hereto.

Due to the factors such as capital status and technical maturity, many areas still adopt the traditional manual inspection mode. However, the traditional inspection method has many disadvantages, such as: the manual recording mode has high cost and low efficiency, the basic data of the line is difficult to inquire and maintain, and the monitoring of whether the worker patrols and examines the line in place is difficult. When the patrolling personnel carry out the patrolling task, the patrolling personnel are relatively free and difficult to monitor and manage. This can lead to a certain extent that the task of patrolling and examining consumes longer, and the completion degree is relatively poor, and the whole efficiency of patrolling and examining is lower.

Based on this, the application provides a patrol inspection management method, a patrol inspection management platform and a patrol inspection management client, which can realize multi-link supervision and management in the manual patrol inspection process so as to improve the patrol inspection efficiency.

Fig. 1 is a schematic view of an application scenario provided in the present application. In the process of polling equipment in a district where a certain power supply is located, polling management is carried out by applying the scheme of the application. Specifically, a corresponding management platform is deployed in a server set in a power supply station, and a client is deployed on a terminal device carried by an inspector. The management platform and the client communicate with each other to jointly realize the inspection management method, so that the inspection personnel can be supervised and managed. Specific implementations can be found in the following examples.

Fig. 2 is a flowchart of an inspection management method according to an embodiment of the present application, where the method of the present embodiment may be applied to a management platform in a server in the above scenario. As shown in fig. 2, the method includes:

s201, generating a polling task according to the position information of the equipment to be polled; the inspection task comprises a plurality of sub inspection tasks, a suggested inspection route corresponding to each sub inspection task, and equipment to be inspected corresponding to each sub inspection task.

The method of the embodiment can be applied to any equipment inspection, and can predetermine the object (equipment to be inspected) of the inspection aiming at any equipment inspection. The device information (position information, device number information, and previous inspection result information) of each device to be inspected is clear and can be correspondingly stored in the data table.

Based on the equipment to be patrolled and examined, can generate this task of patrolling and examining. In order to facilitate distribution, all the equipment to be inspected can be divided into a plurality of sub inspection tasks, and meanwhile, the corresponding recommended inspection route of each sub inspection task is determined. The recommended routing inspection route is an optimal route for all devices to be inspected in the sub routing inspection task.

Preferably, the division mode of the sub-inspection tasks can adopt the division standard of short overall path, more to-be-inspected equipment and less return as the division standard. Therefore, time waste in the way can be reduced as much as possible, and the inspection efficiency is improved.

In some specific implementation modes, the corresponding inspection task can be planned according to the actual requirement of the inspection. For example, if the inspection request is completed in a short time and the number of the personnel is not limited, the inspection personnel can be called as many as possible under the allowable condition, and the corresponding number of sub inspection tasks are planned.

S202, aiming at each sub-inspection task, distributing the sub-inspection task to a corresponding inspector, sending the sub-inspection task, a recommended inspection route corresponding to the sub-inspection task and equipment to be inspected corresponding to the sub-inspection task to a client of the inspector, so that the inspector inspects the equipment to be inspected according to the recommended inspection route corresponding to the sub-inspection task and uploads the running state information of the equipment to be inspected.

After the inspection task is determined, each sub inspection task can be respectively distributed to the corresponding inspector to form the corresponding association relationship between the sub inspection task and the inspector. And meanwhile, the sub-inspection tasks, the corresponding recommended inspection routes and the equipment to be inspected are sent to the client of the inspector.

Correspondingly, the client of the inspection staff can receive the information and display the recommended inspection route so as to prompt the inspection staff to inspect the equipment to be inspected according to the recommended inspection route and upload the running state information of the equipment to be inspected after inspection.

Specifically, the proposed routing inspection route can be displayed in a map, and meanwhile, equipment to be inspected is marked on the proposed routing inspection route. The routing inspection sequence can be set according to the trend of the proposed routing inspection route, and the labels of the equipment to be inspected are arranged according to the sequence.

After the routing inspection is started, the section of the proposed routing inspection route leading to the next equipment to be inspected from the current position can be highlighted. Meanwhile, along with the advance of the inspector, the passed road sections can be cancelled to be highlighted or directly hidden. After the inspection of a certain equipment to be inspected is finished, the corresponding equipment identification can be canceled from highlighting or be directly hidden. Every equipment of waiting to patrol and examine all shows like this, realizes patroller's high-efficient guide.

S203, receiving the real-time positioning information, and matching the real-time positioning information with the proposed routing inspection route; the real-time positioning information is obtained by continuously detecting after any client receives the inspection starting instruction.

When any inspector is ready to start inspection, an inspection starting instruction can be input to the client through the input module. After the client receives the instruction, the client can detect the real-time positioning information and feed the information back to the management platform in the process of polling by the polling personnel. Specifically, the device where the client is located has a GPS positioning module, and can acquire positioning information of the GPS positioning module in real time as real-time positioning information.

Correspondingly, the management platform can receive the real-time positioning information and match the recommended routing inspection route. The real-time positioning information represents the actual path information of the inspector, and the proposed inspection route represents the planning path information. By comparing the two pieces of information, whether the inspector advances according to the planned path can be determined.

And S204, if the real-time positioning information deviates from the recommended routing inspection route, sending route deviation prompt information to the client so that the client displays the route deviation prompt information to remind an inspector to adjust the routing inspection route.

After matching, if the real-time positioning information deviates from the recommended routing inspection path, the inspection staff can be determined not to travel according to the recommended routing inspection path, and at the moment, route deviation prompt information can be sent to the client. Correspondingly, after the client receives the route deviation prompt information, the information can be displayed so as to remind an inspector to adjust the routing inspection route and return to the recommended routing inspection route for traveling.

Considering that the positioning information may have deviation, whether the deviation exists can be determined by calculating the distance between the real-time positioning information and the proposed routing inspection route. Specifically, when the distance from the real-time positioning information to the recommended routing inspection route at a certain moment exceeds a preset distance value, the distance can be considered to deviate from the recommended routing inspection route.

Based on this, in other embodiments, a reminder may also be made when an imminent departure from the proposed routing is predicted. Specifically, according to a plurality of pieces of real-time positioning information in a period of time, the traveling route of the inspection tour clerk can be predicted, and if the prediction result shows that the route is about to deviate from the recommended inspection tour route, a prompt is initiated.

In some embodiments, the route correction function may be provided at the client, and the route correction option may be displayed at the same time when the client displays the route deviation prompting information. For example, a deviation in the route may be generated because road maintenance or other reasons may result in the proposed route inspection being unable to follow the route section in the route. At this time, the inspector can ignore the prompt information of the route deviation and input the route correction instruction by selecting the route correction option. After the client receives the route correction instruction, the proposed routing inspection route is corrected based on the real-time positioning information of the corresponding time period, and meanwhile, route deviation prompt information can be eliminated.

And S205, generating a route deviation event of the inspector according to the route deviation prompt information, and storing the route deviation event into inspection task execution information of the inspector.

After the routing inspection worker deviates from the recommended routing inspection route, the routing inspection worker is explained to possibly leave the post in the routing inspection process, and accordingly, a routing deviation event of the routing inspection worker is generated and stored in routing inspection task execution information of the routing inspection worker. The inspection task execution information of the inspector can also comprise information such as inspection task completion degree and the like, and can be used as an attendance check basis of the inspector.

The management platform of the embodiment can generate the inspection task according to the position information of the equipment to be inspected; the inspection task comprises a plurality of sub inspection tasks, a suggested inspection route corresponding to each sub inspection task, and equipment to be inspected corresponding to each sub inspection task; the sub-inspection tasks are distributed to corresponding inspectors for each sub-inspection task, the sub-inspection tasks, the recommended inspection routes corresponding to the sub-inspection tasks and the to-be-inspected equipment corresponding to the sub-inspection tasks are sent to clients of the inspectors, the clients can display the recommended inspection routes and prompt the inspectors to inspect the to-be-inspected equipment according to the recommended inspection routes corresponding to the sub-inspection tasks, and running state information of the to-be-inspected equipment is uploaded; after receiving the inspection starting instruction, the client continuously detects the real-time positioning information and feeds the real-time positioning information back to the management platform; the management platform receives the real-time positioning information and matches the real-time positioning information with the proposed routing inspection route; if the fact that the real-time positioning information deviates from the recommended routing inspection route is determined, route deviation prompt information is sent to the client side, so that the client side displays the route deviation prompt information to remind an inspector to adjust the routing inspection route; and generating a route deviation event of the inspector according to the route deviation prompt information, and storing the route deviation event into the inspection task execution information of the inspector. Based on the scheme of the application, a plurality of sub-inspection tasks and corresponding recommended inspection routes can be reasonably planned and distributed to each inspector; in the routing inspection process, the client detects the positioning information in real time and sends the positioning information to the platform; and the platform judges whether the position conforms to the proposed routing inspection route, if the position deviates, the routing inspection worker possibly has off-post behaviors, sends information to the client for prompting, and records the behaviors as an assessment basis. Therefore, supervision and management of multiple links in the manual inspection process are achieved, and inspection efficiency is improved conveniently.

In some embodiments, the inspector can upload the equipment information to the management platform through the client in the inspection process, so that paperless inspection is realized. Specifically, the method further comprises: if the real-time positioning information is determined to belong to the inspection range of any equipment to be inspected in the recommended inspection route, transmitting inspection information registration prompt information to the client, so that the client registers the prompt information according to the inspection information, displays an equipment running state information input interface corresponding to the equipment to be inspected, and feeds back the running state information of the equipment to be inspected, which is recorded by an inspector in a selected input mode, to the management platform; the equipment running state information input interface comprises at least one of a video input option, an image input option, a voice input option and a character input option; and analyzing the running state information of the equipment to be inspected, and determining the running state of the equipment to be inspected.

After the real-time positioning information is matched with the proposed routing inspection route in the step S203, whether the real-time positioning information enters the routing inspection range of a certain device to be inspected can be determined based on the matching result. If the inspection scope has been entered, it is indicated that the inspector may need to begin recording inspection data. At this time, corresponding patrol inspection information registration prompt information can be sent to the client, and the information can include equipment information of the equipment to be patrolled and inspected, an equipment running state information input interface corresponding to the equipment to be patrolled and inspected, and the like. Correspondingly, after the client receives the polling information registration prompt message, the corresponding equipment running state information input interface can be displayed. Some entry mode options may be displayed on this interface, including but not limited to at least one of a video entry option, an image entry option, a voice entry option, and a text entry option. The patrol inspector can select a corresponding input mode to input the running state information of the equipment according to the field condition and the patrol inspection requirement. The recorded device operation state information may include a live video, a device picture, a device state description voice, a device state description text, and the like. After the input is completed, the client can feed the running state information back to the management platform. The management platform can analyze the operation state information to determine the operation state of the equipment to be inspected, such as normal and abnormal. If the equipment has an abnormality, the reason of the abnormality can be analyzed and recorded.

For on-site videos, equipment pictures and the like, whether the equipment is abnormal can be determined through image analysis, for example, problems of bare wire skin, inclined tower, abnormal hanging and the like can be solved.

The embodiment can judge whether the inspector arrives at the to-be-inspected equipment according to the positioning of the client, and if the inspector arrives at the to-be-inspected equipment, the client is controlled to automatically pop up an information registration interface, so that the inspector can quickly complete the registration of the corresponding equipment. And the inspection efficiency is improved. The running state of the equipment is automatically analyzed, judged and classified according to the information registered by the inspector, and the running state can be fed back to the inspector for verification, so that the correct information input is ensured.

In some embodiments, the client may feed back the running state information of the device to be inspected to the management platform in a breakpoint retransmission manner. Specifically, the network connection state may be detected; if the network is in a connection state, feeding back the running state information of the equipment to be inspected to the management platform; if the network is in the unconnected state, the transmitted information node is recorded so that transmission continues from the transmitted information node while the network is in the connected state.

The method comprises the steps that running state information is normally sent to a management platform under the condition that the network condition is good, once the network condition is not good and transmission cannot be conducted, transmission nodes are recorded, and uploading continues from the recorded transmission nodes after the network is recovered.

The method of the embodiment can avoid repeatedly uploading data due to the influence of network quality.

In some embodiments, the running state of the equipment obtained by each inspection can be used as the basis for the subsequent inspection. Specifically, the method may further include: determining a routing inspection plan of each power device according to the historical routing inspection record of each power device; the historical patrol records comprise the time of the past patrol and the running state of the power equipment of the past patrol; the routing inspection planning comprises planning routing inspection time and key routing inspection items; and determining the current equipment to be inspected and the key inspection items of the equipment to be inspected according to the inspection planning of each power equipment. Correspondingly, foretell according to the positional information who waits to patrol and examine equipment, generates and patrols and examines the task, patrols and examines the task and includes that a plurality of sons patrol and examine the suggestion that task corresponds with every son and patrol and examine the route, can include: generating an inspection task according to the position information and the key inspection items of the equipment to be inspected, wherein the inspection task comprises a plurality of sub inspection tasks, a suggested inspection route corresponding to each sub inspection task, the equipment to be inspected corresponding to each sub inspection task, and the key inspection items of the equipment to be inspected corresponding to each sub inspection task.

Aiming at each power device, the subsequent routing inspection planning can be determined according to the historical routing inspection record. For example, if the historical polling record of a certain power device indicates that the power device has device abnormality caused by device aging, a more frequent polling plan can be made for the power device. Meanwhile, the same abnormality of the same batch of equipment can be estimated, so the same inspection plan can be adopted for the same batch of equipment. The key routing inspection item can be an abnormal condition with high frequency in the historical routing inspection record, and/or an abnormal condition in the last routing inspection, and/or an abnormal condition which is estimated to possibly occur.

Correspondingly, the power equipment at the same patrol time can be arranged in the same patrol task according to the scheduled patrol time of each power equipment. When the sub-inspection tasks are issued, the key inspection items of each equipment to be inspected can be issued at the same time, so that inspectors can be reminded to pay attention to the key inspection items.

According to the method, items needing key inspection can be analyzed according to historical inspection time and equipment running states, meanwhile, subsequent inspection plans are made, and then inspection is conducted on a corresponding batch of equipment at corresponding time according to the inspection plans of the equipment. The routing inspection time arrangement is reasonable, the routing inspection items have side points, and the overall routing inspection efficiency is improved.

In other embodiments, supervision of inspection speed may also be added. Specifically, the method may further include: predicting the predicted completion time of each sub-inspection task by combining the road condition information; the predicted completion time comprises predicted passing time between every two adjacent devices to be inspected in the proposed inspection route and inspection time of each device to be inspected; determining the corresponding actual polling time according to the reporting time of the real-time positioning information corresponding to the sub polling tasks; determining the prediction probability of completing the sub-inspection tasks on time according to the predicted completion time and the actual inspection time; and if the prediction probability is smaller than the preset threshold, sending inspection speed acceleration prompt information to the client to remind an inspector to improve the inspection speed.

The proposed routing inspection route of each sub-routing inspection task can be regarded as a combination of a plurality of road sections formed by taking the equipment to be inspected as nodes. After the sub-inspection task is issued, the predicted passing time of each corresponding road section can be predicted by combining the road condition information within the predicted time-consuming duration; and the inspection time of each device to be inspected can be predicted by combining empirical data. The empirical data may include information of the time spent at the corresponding device in the past rounds.

In the process of executing the sub-routing inspection task, the actual passing speed of each road section and the actual inspection time of each device can be determined by combining the real-time positioning information reported at each moment. And based on the actual inspection progress, calculating the actual inspection time, comparing the actual inspection time with the predicted completion time, and judging the probability (prediction probability) that the inspection task can be completed on time. If the prediction probability is smaller than the preset threshold value, the possibility that the inspection can be finished on time continuously according to the current speed is too low, and then prompt information for accelerating the inspection speed can be sent to the client. Correspondingly, after receiving the prompt message, the client can display the prompt message to remind the inspector to improve the inspection speed.

Wherein, completing the polling task on time means that the actual consumed time is less than or equal to the expected completion time.

The method calculates the approximate time spent on completing the task, then calculates the actual time spent, and reminds the inspector to accelerate the inspection if the time spent between every two devices exceeds the budget and the approximate rate cannot be completed on time. Therefore, the time waste of the inspector is avoided as much as possible, and the inspection efficiency is improved.

In some embodiments, the method may further include: aiming at each sub-inspection task, if a task completion prompt is received before the predicted completion time, planning a newly-added inspection task and sending the newly-added inspection task to a corresponding client; and if receiving a task receiving prompt and a newly increased inspection task completion prompt returned by the client, generating a corresponding excess completion event of the inspector and storing the excess completion event into inspection task execution information of the inspector.

And after the inspector finishes the sub-inspection tasks, the client uploads a task completion prompt. And if the management platform receives the corresponding task completion prompt before the predicted completion time, the management platform indicates that the inspector completes the corresponding sub-inspection task in advance. At this time, the management platform can also plan a new inspection task for the inspector. And the inspector can select to receive the new task, then feeds back and receives a task prompt through the client, and feeds back a new inspection task completion prompt through the client after the task is completed. And for the additionally completed newly increased polling tasks, corresponding excessive completion events of the polling personnel can be generated and stored in polling task execution information of the polling personnel to be used as the basis for checking and scoring. Of course, the inspector can choose not to accept the newly added task and return to the working position.

Wherein, the mode of planning newly-increased task of patrolling and examining includes: checking the equipment inspection condition in a nearby preset range according to the last real-time positioning information corresponding to the sub inspection task; and if the equipment which is not patrolled exists, generating a newly-added patrolling task.

In the embodiment, the inspection personnel can select to execute the newly-increased inspection task, record the task completed in excess, add the appraisal, excite the working enthusiasm of the inspection personnel, and further improve the inspection efficiency.

Fig. 3 is a flowchart of an inspection management method according to an embodiment of the present application, where the method of the present embodiment may be applied to a client in a terminal device in the above scenario. As shown in fig. 3, the method includes:

s301, receiving the sub-inspection tasks, the suggested inspection routes corresponding to the sub-inspection tasks and the equipment to be inspected corresponding to the sub-inspection tasks; the sub-inspection task, the recommended inspection route corresponding to the sub-inspection task and the equipment to be inspected corresponding to the sub-inspection task are generated according to the position information of the equipment to be inspected.

S302, displaying the recommended routing inspection route, prompting an inspector to inspect the equipment to be inspected according to the recommended routing inspection route, and uploading the running state information of the equipment to be inspected.

And S303, after receiving the inspection starting instruction, continuously detecting the real-time positioning information and feeding back the real-time positioning information to the management platform.

S304, receiving route deviation prompt information; the route deviation prompt information is sent when the management platform matches the real-time positioning information with the proposed routing inspection route and determines that the real-time positioning information deviates from the proposed routing inspection route.

S305, displaying route deviation prompt information to remind an inspector to adjust the inspection route.

Optionally, the method further includes:

receiving patrol information registration prompt information which is sent when the management platform determines that the real-time positioning information belongs to the patrol range of any equipment to be patrolled in the recommended patrol route;

Optionally, the running state information of the device to be inspected is fed back to the management platform, including:

detecting a network connection state;

The method executed by the client in this embodiment corresponds to the method executed by the management platform in the embodiment corresponding to fig. 2, and the specific implementation manner of this embodiment may refer to the description in the foregoing embodiment, which is not described herein again.

In a specific embodiment, the real-time uploading of the inspection target data by the inspection personnel is realized through an APP and a set of online systems, and paperless office is realized; through the GPS technology, the shooting time recording mode and the like, the problem of counterfeit data is reduced. Therefore, based on the GPS positioning technology and the fault statistical analysis capability, people, facilities and tasks are taken as cores to assist all power supply stations in realizing digital routing inspection management on facilities in the jurisdiction.

Specifically, the method comprises the following steps:

1) In the GPS inspection, the route can be planned for inspection personnel by utilizing GPS satellite positioning, so that the working efficiency is enhanced;

2) The GPS polling accurately identifies whether the personnel are in place, and the polling information is shared in a computer information system in real time, so that the working efficiency is improved, and the personnel management is enhanced;

3) And patrol and examine through GPS, the managers can formulate more detailed more accurate work of patrolling and examining, will patrol and examine work and distribute every personnel of patrolling and examining more rationally on, avoid heavily examining, leak phenomenon such as examining to improve work efficiency.

And the inspection personnel inputs normal or abnormal tower information in the system, takes pictures on site and submits the pictures to upload, and the system can plan the next inspection according to the historical inspection record according to the normal or abnormal tower information marked by the uploaded data information in a classified manner.

In the work of patrolling and examining of daily circuit, how to judge whether the staff keeps on a check, there is certain difficulty to managers, and the work of patrolling and examining of circuit is an important environment in the electric power safety production, and the work of patrolling and examining is effective, can in time discover the defect that equipment exists, avoids the emergence of major accident.

This application patrols the line personnel and can use APP to shoot, uploads target data in real time to need not the staff and produce again with the paper record, later manual entering is uploaded again, improves work efficiency.

As shown in fig. 4, the specific inspection process is as follows: a worker holds a mobile device with a GPS functional module for polling and uploads data to a system through the Internet; a manager can log in the online system through a computer to check the polling condition (for example, the manager can check the polling arrival rate of the polling person, the guarantee rate of the equipment, the change trend of the operation index of the equipment, the occurrence time and the processing result of the abnormal condition of the equipment and the like through a statistical query module in the system); and storing the classified and aggregated data in a database server.

The embodiment can realize GPS positioning track recording, and in the process of polling the polling personnel, the tower information is shot and uploaded, and the personnel positioning information is uploaded through the GPS positioning technology and is displayed in the background server, so that the supervision effect on the polling work of the personnel is realized. Reduce personnel's personal book, improve work efficiency, accurate location problem node makes things convenient for personnel to manage.

Fig. 5 is a schematic structural diagram of an inspection management platform according to an embodiment of the present application, and as shown in fig. 5, the inspection management platform 500 of the present embodiment includes: the system comprises an inspection task generating module 501, an inspection task distributing module 502, a real-time positioning information matching module 503, a route deviation prompting information sending module 504 and a route deviation event generating module 505.

The inspection task generating module 501 is configured to generate an inspection task according to the position information of the device to be inspected; the inspection task comprises a plurality of sub inspection tasks, a suggested inspection route corresponding to each sub inspection task and equipment to be inspected corresponding to each sub inspection task;

the inspection task distribution module 502 is used for distributing the sub inspection tasks to corresponding inspectors according to each sub inspection task, and sending the sub inspection tasks, the recommended inspection routes corresponding to the sub inspection tasks and the equipment to be inspected corresponding to the sub inspection tasks to clients of the inspectors, so that the inspectors can inspect the equipment to be inspected according to the recommended inspection routes corresponding to the sub inspection tasks and upload the running state information of the equipment to be inspected;

the real-time positioning information matching module 503 is configured to receive the real-time positioning information and match the real-time positioning information with the proposed routing inspection route; the real-time positioning information is obtained by continuously detecting any client after receiving the inspection starting instruction;

a route deviation prompt information sending module 504, configured to send route deviation prompt information to the client if it is determined that the real-time positioning information deviates from the proposed routing inspection route, so that the client displays the route deviation prompt information to remind an inspector to adjust the routing inspection route;

and the route deviation event generating module 505 is configured to generate a route deviation event of the inspector according to the route deviation prompt information, and store the route deviation event into inspection task execution information of the inspector.

Optionally, the inspection management platform 500 further includes: a device operating state determining module 506, configured to:

when the real-time positioning information is determined to belong to the inspection range of any equipment to be inspected in the recommended inspection route, transmitting inspection information registration prompt information to the client, so that the client registers the prompt information according to the inspection information, displays an equipment running state information input interface corresponding to the equipment to be inspected, and feeds back running state information of the equipment to be inspected, which is recorded by an inspector in a selected input mode, to the management platform; the equipment running state information input interface comprises at least one of a video input option, an image input option, a voice input option and a character input option;

Optionally, the inspection management platform 500 further includes: a device to be inspected determining module 507, configured to:

determining a routing inspection plan of each power device according to the historical routing inspection record of each power device; the historical patrol records comprise the time of the past patrol and the running state of the power equipment of the past patrol; the routing inspection planning comprises planning routing inspection time and key routing inspection items;

patrol and examine task generation module specifically is used for:

generating an inspection task according to the position information and the key inspection items of the equipment to be inspected, wherein the inspection task comprises a plurality of sub inspection tasks, a suggested inspection route corresponding to each sub inspection task, the equipment to be inspected corresponding to each sub inspection task, and the key inspection items of the equipment to be inspected corresponding to each sub inspection task.

Optionally, the inspection management platform 500 further includes: a patrol time monitoring module 508 for:

predicting the predicted completion time of each sub-inspection task by combining the road condition information; the predicted completion time comprises predicted passing time between every two adjacent devices to be inspected in the proposed inspection route and inspection time of each device to be inspected;

determining the corresponding actual polling time according to the reporting time of the real-time positioning information corresponding to the sub polling tasks;

and if the prediction probability is smaller than the preset threshold, sending inspection speed acceleration prompt information to the client to remind an inspector to improve the inspection speed.

Optionally, the inspection management platform 500 further includes: a newly-added inspection task allocation module 509, configured to:

and if receiving a task receiving prompt and a newly increased inspection task completion prompt returned by the client, generating a corresponding excess completion event of the inspector and storing the excess completion event into inspection task execution information of the inspector.

The apparatus of this embodiment may be configured to execute the method corresponding to the management platform in any of the above embodiments, and the implementation principle and the technical effect are similar, which are not described herein again.

Fig. 6 is a schematic structural diagram of an inspection management platform according to an embodiment of the present application, and as shown in fig. 6, an inspection client 600 according to this embodiment includes: a receiving module 601, a display module 602, and a real-time positioning information detecting module 603.

The receiving module 601 is used for receiving the sub inspection tasks, the suggested inspection routes corresponding to the sub inspection tasks and the equipment to be inspected corresponding to the sub inspection tasks; the sub-inspection tasks, the suggested inspection routes corresponding to the sub-inspection tasks and the equipment to be inspected corresponding to the sub-inspection tasks are generated according to the position information of the equipment to be inspected;

the display module 602 is used for displaying the recommended routing inspection route, prompting an inspector to inspect the equipment to be inspected according to the recommended routing inspection route, and uploading the running state information of the equipment to be inspected;

the real-time positioning information detection module 603 is configured to continuously detect the real-time positioning information after receiving the inspection start instruction, and feed back the real-time positioning information to the management platform;

the receiving module 601 is further configured to send route deviation prompt information; the route deviation prompt information is sent when the management platform matches the real-time positioning information with the proposed routing inspection route and determines that the real-time positioning information deviates from the proposed routing inspection route;

the display module 602 is further configured to display a route deviation prompt message to remind the inspector to adjust the inspection route.

Optionally, the inspection management platform 600 further includes: an equipment operating status logging module 604, configured to:

Optionally, the device running state entering module 604 is specifically configured to, when feeding back the running state information of the device to be inspected to the management platform:

detecting a network connection state;

The apparatus of this embodiment may be configured to execute the method corresponding to the client in any of the above embodiments, and the implementation principle and the technical effect are similar, which are not described herein again.

Fig. 7 is a schematic structural diagram of an electronic device according to an embodiment of the present application, and as shown in fig. 7, an electronic device 700 according to the embodiment may include: a memory 701 and a processor 702.

The memory 701 has stored thereon a computer program that can be loaded by the processor 702 and executed to perform the method in the above-described embodiments.

The processor 702 is coupled to the memory 701, such as via a bus.

Optionally, the electronic device 700 may also include a transceiver. It should be noted that the transceiver in practical application is not limited to one, and the structure of the electronic device 700 is not limited to the embodiment of the present application.

The Processor 702 may be a CPU (Central Processing Unit), a general-purpose Processor, a DSP (Digital Signal Processor), an ASIC (Application Specific Integrated Circuit), an FPGA (Field Programmable Gate Array), or other Programmable logic device, transistor logic device, hardware component, or any combination thereof. Which may implement or perform the various illustrative logical blocks, modules, and circuits described in connection with the disclosure. The processor 702 may also be a combination of computing functions, e.g., comprising one or more microprocessors, DSPs, and microprocessors, among others.

A bus may include a path that transfers information between the above components. The bus may be a PCI (Peripheral Component Interconnect) bus, an EISA (Extended Industry Standard Architecture) bus, or the like. The bus may be divided into an address bus, a data bus, a control bus, etc. For ease of illustration, only one thick line is shown, but this is not intended to represent only one bus or type of bus.

The Memory 701 may be a ROM (Read Only Memory) or other type of static storage device that can store static information and instructions, a RAM (Random Access Memory) or other type of dynamic storage device that can store information and instructions, an EEPROM (Electrically Erasable Programmable Read Only Memory), a CD-ROM (Compact Disc Read Only Memory) or other optical Disc storage, optical Disc storage (including Compact Disc, laser Disc, optical Disc, digital versatile Disc, blu-ray Disc, etc.), a magnetic Disc storage medium or other magnetic storage device, or any other medium that can be used to carry or store desired program code in the form of instructions or data structures and that can be accessed by a computer, but is not limited to these.

The memory 701 is used for storing application program codes for executing the scheme of the application, and the processor 702 is used for controlling the execution. The processor 702 is configured to execute application program code stored in the memory 701 to implement the aspects illustrated in the foregoing method embodiments.

Wherein, the electronic device includes but is not limited to: mobile terminals such as mobile phones, notebook computers, digital broadcast receivers, PDAs (personal digital assistants), PADs (tablet computers), PMPs (portable multimedia players), in-vehicle terminals (e.g., car navigation terminals), and the like, and fixed terminals such as digital TVs, desktop computers, and the like. But also a server, etc. The electronic device shown in fig. 7 is only an example, and should not bring any limitation to the functions and the scope of use of the embodiments of the present application.

The electronic device of this embodiment may be configured to perform the method of any of the above embodiments, and the implementation principle and the technical effect are similar, which are not described herein again.

When the electronic device of this embodiment is used to execute the method corresponding to the management platform in any embodiment, the electronic device may specifically be a computer, a server, and other devices with a computing function. When the electronic device of this embodiment is used to execute the method corresponding to the client in any embodiment, the electronic device may specifically be a device having a display function and an entry function, such as a smart phone, a smart watch, and a smart bracelet.

The present application also provides a computer readable storage medium storing a computer program that can be loaded by a processor and executed to perform the method as in the above embodiments.

The present application further provides a computer program product comprising: a computer program; which when executed by a processor implements the method as in the above embodiments.

Those of ordinary skill in the art will understand that: all or a portion of the steps of implementing the above-described method embodiments may be performed by hardware associated with program instructions. The program may be stored in a computer-readable storage medium. When executed, the program performs steps comprising the method embodiments described above; and the aforementioned storage medium includes: various media that can store program codes, such as ROM, RAM, magnetic or optical disks.

Claims

1. A routing inspection management method is applied to a management platform, and comprises the following steps:

aiming at each sub-inspection task, distributing the sub-inspection task to a corresponding inspector, and sending the sub-inspection task, a recommended inspection route corresponding to the sub-inspection task and equipment to be inspected corresponding to the sub-inspection task to a client of the inspector, so that the inspector inspects the equipment to be inspected according to the recommended inspection route corresponding to the sub-inspection task and uploads the running state information of the equipment to be inspected;

receiving real-time positioning information, and matching the real-time positioning information with the proposed routing inspection route; the real-time positioning information is obtained by continuously detecting any client after receiving a patrol starting instruction;

2. The method of claim 1, further comprising:

3. The method of claim 2, further comprising:

4. The method according to any one of claims 1-3, further comprising:

5. The method of claim 4, further comprising:

6. A routing inspection management method is applied to a client side, and comprises the following steps:

7. The method of claim 6, further comprising:

8. The method according to claim 7, wherein the feeding back the running state information of the equipment to be inspected to the management platform comprises:

detecting a network connection state;

9. The utility model provides a management platform patrols and examines which characterized in that includes:

10. The utility model provides a client patrols and examines which characterized in that includes:

the real-time positioning information detection module is used for continuously detecting the real-time positioning information after receiving the inspection starting instruction and feeding the real-time positioning information back to the management platform;