CN115329877A - Battery replacement station fault information pushing method - Google Patents

Abstract

The invention relates to a method for pushing fault information of a power swapping station, which comprises the following steps: when equipment in the battery replacement station fails, the in-station system acquires failure information and sends the failure information to a server of an upper computer in a wired or wireless mode; and carrying out multi-layer step-by-step division on the fault information according to the attribute, the type, the grade and the position in a server of the upper computer, and pushing the fault information to a mobile terminal of a corresponding responsible person according to a division result. The invention provides a power station fault information pushing method, which is used for accurately pushing fault information to corresponding technicians after the fault information is accurately separated from layers step by step, so that repeated pushing or pushing to other irrelevant technicians is avoided, and a technical basis is provided for unattended operation of a power station.

Description

Battery replacement station fault information pushing method

Technical Field

The invention relates to the technical field of unattended operation of a power changing station, in particular to a power changing station fault information pushing method.

Background

The electric automobile is developed more and more rapidly, and one of bottlenecks hindering the development of the pure electric automobile is the charging problem of the power battery; traditional mode is that the adoption fills electric pile quick charge, but this mode has a great deal of shortcoming: the efficiency is still far less than that of fast oiling, the service life of the battery is shortened, and the maintenance cost of the battery is high. In order to solve the efficiency problem, the existing solution is to adopt a battery replacement mode to directly replace the battery on the electric vehicle, replace the fully charged battery from a battery replacement station, and replace the insufficient battery and then charge the battery in the battery replacement station, so that the cruising efficiency and the battery replacement efficiency of the electric vehicle are improved.

Along with the popularization of the power changing stations, the supervision of the power changing stations becomes an important problem, and because the number of the power changing stations is large, each power changing station cannot be monitored manually in real time, so that the supervision mode of the unattended power changing station is a trend of supervision of the power changing station, and in the unattended supervision mode, the pushing of fault information is a more critical link;

the existing fault information reaches 6000 pieces, the fault information is generated and is inevitably more and more along with the operation of the power station, maintenance personnel corresponding to the fault information can reach hundreds of persons, if the fault information is pushed to all the maintenance personnel every time, the fault information is actually equivalent to invalid pushing, because each maintenance personnel receives the fault information, no person is arranged to process, the problem of unmanned processing or multi-person repeated processing can possibly occur, and therefore, how to accurately push the fault information to the corresponding technical personnel is a big difficulty of the fault information pushing of the existing power station.

Disclosure of Invention

Therefore, the technical problem to be solved by the invention is to overcome the defects of fault information pushing in the prior art, and provide a method for pushing fault information of a power changing station, wherein the fault information is accurately pushed to corresponding technical personnel after being accurately separated from each other in multiple layers step by step, so that repeated pushing or pushing to other unrelated technical personnel is avoided, and a technical basis is provided for unattended operation of the power changing station.

In order to solve the technical problem, the invention provides a power station fault information pushing method, which comprises the following steps:

when equipment in the battery replacement station fails, the in-station system acquires failure information and sends the failure information to a server of an upper computer in a wired or wireless mode;

and carrying out multi-layer step-by-step division on the fault information according to the attribute, the type, the grade and the position in a server of the upper computer, and pushing the fault information to a mobile terminal of a corresponding responsible person according to a division result.

In an embodiment of the present invention, the fault information is classified according to attributes, different processing modes are determined, and the fault information is sent to different processing personnel, where the method includes:

all faults are sent to an operation responsible person;

the method comprises the steps that faults needing to be solved on site in a power change station are sent to a station patrol worker;

the fault which can be solved remotely sends the fault information to a remote monitoring person;

the fault which can be automatically repaired is automatically repaired within the set time, the fault information is not sent, the fault which cannot be automatically repaired within the set time is not sent, if the fault which can be solved on the site of the power exchange station needs to be solved, the fault information is sent to the station patrol personnel, and if the fault which can be solved remotely, the fault information is sent to the remote monitoring personnel.

In one embodiment of the invention, for the fault capable of being automatically repaired, after a plurality of times of automatic repair failures, the fault information is sent to a remote monitoring personnel.

In one embodiment of the invention, for the remotely-solvable fault, when the remote monitoring personnel fails to remotely repair or judges that the on-site solution is needed in the overload of the remote repair, the fault information is sent to the station patrol personnel.

In one embodiment of the invention, for the fault needing to be solved on the site of the power conversion station, the fault information is not sent again after the fault is solved, and when the fault is not solved, the fault information is continuously sent in a set time period.

In one embodiment of the invention, after the fault is processed, the content and the result of the fault processing are sent to an operation responsible person.

In an embodiment of the present invention, the classifying the fault information according to grades and determining a transmission timing sequence include:

basic fault information related to stopping battery replacement is sent to a corresponding responsible person at a first time;

and the function fault information which does not relate to the battery replacement stopping is sent to the corresponding responsible person at the preset time.

In an embodiment of the present invention, the step of classifying the fault information according to location, determining a specific location of the fault, and sending the specific location to a responsible person corresponding to the location includes:

carrying out large-class division according to sub-modules in the power swapping station;

the subclass is divided according to functional components or mechanism parts in the major class;

the sub-groups are divided into individual components in the subclasses.

In one embodiment of the invention, the potential safety hazard fault is sent to all the personnel at the same time, and fault information is continuously sent for a plurality of times in a time period until the fault is solved.

In an embodiment of the present invention, the content of the failure information push includes: time, place, name of sending fault component, fault grade, fault content description and prompt.

Compared with the prior art, the technical scheme of the invention has the following advantages:

according to the method for pushing the fault information of the power change station, after the power change station fails, the fault information is classified in a multi-layer and step-by-step mode according to the attribute, the type, the grade and the position, the fault information is screened, the fault information can be accurately pushed to technicians capable of solving the fault in the first time of the fault, and basic technical support is provided for unattended operation of the power change station.

Drawings

In order that the present disclosure may be more readily and clearly understood, reference is now made to the following detailed description of the embodiments of the present disclosure taken in conjunction with the accompanying drawings, in which

FIG. 1 is a flowchart illustrating steps of a power swapping station fault information pushing method according to the present invention;

FIG. 2 is a flow chart of the present invention for pushing fault information according to attribute classification;

FIG. 3 is a flow chart of the present invention for pushing fault information according to location classification;

FIG. 4 is a flow chart of the present invention for pushing fault information according to the classification of the classes;

Detailed Description

The present invention is further described below in conjunction with the following figures and specific examples so that those skilled in the art may better understand the present invention and practice it, but the examples are not intended to limit the present invention.

As described above, the unattended power exchange station is a trend and development direction for monitoring the power exchange station in the future, and in the daily operation process of the power exchange station, a special monitoring person does not need to be set, and an automatic monitoring mode is adopted, so that only when a fault occurs, fault information is pushed out, or remote solution or on-site repair is performed, and therefore when the fault occurs, it is vital that fault information can be accurately pushed to a technical person who can solve the fault.

Referring to fig. 1, the invention provides a power swapping station fault information pushing method, which includes the following steps:

collecting fault information: when equipment in the battery replacement station fails, a system in the station acquires fault information, specifically, the fault information may be acquired in various ways, including but not limited to: the method comprises the steps that a program is automatically detected by a power station, and program bugs causing faults are obtained; the sensing detection unit in the power swapping station acquires a real-time detection signal, compares the real-time detection signal with a preset standard and judges whether each action of the power swapping station is executed according to the preset standard or not; the vision detection unit in the power swapping station acquires an action image of the power swapping station during working and monitors the operation state of the power swapping station; when the fault information is detected, the fault information is sent to a server of the upper computer in a wired or wireless mode;

classified pushing of fault information: the server of host computer possesses the function of information reception, information classification, information transmission, has typeeed exhaustive fault type database in the server of host computer to carry out information classification to the fault type, the process of information classification is: the fault information is divided in a server of the upper computer in a multi-layer step-by-step mode according to attributes, types, grades and positions, screening conditions are gradually limited from a database, the fault information and corresponding technical personnel capable of solving the fault are determined, and finally the fault information is pushed to the mobile terminal of the corresponding responsible person at the first time according to the dividing results.

Example 1

Referring to fig. 2, specifically, the fault information is classified according to attributes, different processing manners are determined, and the fault information is sent to different processing personnel, and in this embodiment, the following types of necessary personnel are set according to division: patrol station personnel, remote monitoring person, operation responsible person, along with trading continuous perfect of power station, also can be according to the personnel of actual demand increase different grade type, according to personnel classification, fault information's propelling movement mode is:

all faults are sent to an operation responsible person; the operation responsible person is used as a first responsible person of the power changing station, all conditions in the working process of the power changing station need to be known, the conditions need to be sent to the operation responsible person as long as a fault occurs, fault types are not distinguished, one power changing station can be correspondingly provided with a plurality of operation responsible persons, and one operation responsible person can also correspondingly manage a plurality of power changing stations;

the method comprises the steps that fault information is sent to a station patrol worker when the fault needs to be solved on the site of a power exchanging station, the station patrol worker has certain field maintenance capacity, and after pushing is received, the station patrol worker needs to rush to the site to process the fault, for example, when hardware has a fault, the station patrol worker needs to go to the site to maintain and replace the hardware;

the remote monitoring personnel has certain remote maintenance capability, remotely controls the power switching station after receiving the pushing, and solves corresponding problems at the remote end, for example, when the software fails, the remote monitoring personnel needs to carry out bug repair or code modification on the software at the remote end;

the fault which can be automatically repaired is automatically repaired within a set time, and no fault information is sent, because the fault is automatically repaired, the fault information does not need to be sent to technical personnel such as patrol personnel, remote monitors and the like, but still needs to be sent to an operation responsible person, and the operation responsible person needs to record the fault; and if the fault which can be remotely solved is not automatically repaired within the set time, the fault information is sent to a station patrol person.

Specifically, under normal conditions, faults which are recorded in the fault type database and can be automatically repaired are fault information which is tested through automatic repair, but some fault information is recorded in the fault type database, the faults can be automatically repaired, but in the actual automatic repair process, automatic repair is not completed, for the fault information, if the fault information is always considered as the fault which can be automatically repaired, the fault cannot be repaired, and potential safety hazards are likely to occur in the long-term operation process.

Specifically, under normal conditions, faults which can be remotely solved and are recorded in a fault type database are all subjected to remote solution tests, fault information which is successfully remotely solved, however, some fault information is recorded in the fault type database, the faults can be remotely solved and are determined, but in the actual remote solution process, remote solution is not completed, for the fault information, if the faults which can be remotely solved are always determined, the faults can not be repaired, and in the long-term operation process, potential safety hazards are likely to occur, so that for the faults which can be remotely solved, when remote repair of remote monitoring personnel fails or the situation that field solution is needed is judged in overload of remote repair, the fault information is sent to station patrol personnel.

For a fault needing to be solved on a power exchange station site, fault information is not sent any more after the fault is solved, and the fault information is continuously sent in a set time period when the fault is not solved, generally, when a patrol worker arrives at the fault site first time to repair the fault, but if the fault is large, the repair needs a long time, when the patrol worker does not repair in one working cycle, at the moment, before the patrol worker finishes the working cycle (generally 1 hour), the fault information is pushed to the patrol worker in the next working cycle again, so that even if the fault is not solved in one working cycle, the fault information can be delivered to the patrol worker in the next working cycle, the condition that the patrol worker is overtime or the fault information is not solved is avoided, and the fault information is pushed to an operation responsible worker each time, the operation responsible worker pays attention to the fault information when noticing that one fault is not solved in a plurality of working cycles, and the responsible worker can contact with relevant working personnel to discuss specific details of the fault, so as to provide a reasonable fault solving scheme, and the fault can be quickly solved.

After the fault is processed, the content and the result of the fault processing are sent to the operation responsible person, and the operation responsible person can judge the timeliness and effectiveness of the relevant person for processing the fault according to the content and the result.

Specifically, within a period of time (such as a week or a month), the pushed fault information is counted, and the frequency (number of times) of the fault is calculated; for some faults with high frequency, the faults not only need to be solved in a short time, but also need to be solved for a long time, and for the faults with high frequency, the faults are certainly defects in design, so that the faults need to be solved from the root cause, and the faults are less and less along with the advance of unattended operation.

Example 2

By adopting the above scheme, after fault information is classified according to attributes, fault information can be respectively pushed to different types of technical staff (station patrol staff, remote monitors, operation responsible staff), but for maintenance of one power conversion station, there is no possibility that only one station patrol staff or one remote monitor is provided, because there are many sub-modules in the power conversion station and the related fields are different, therefore, it is impossible for one station patrol staff or one remote monitor to master all fault solutions, and therefore, fault information needs to be reclassified, in this embodiment, according to distribution conditions of sub-modules in the power conversion station, fault information is reclassified according to an occurrence position, a specific position of a fault is determined, and the fault information is correspondingly sent to the responsible staff corresponding to the position, which is shown in fig. 3, including:

performing large-class division according to the distribution condition of sub-modules in a power swapping station, where the power swapping station includes multiple sub-modules, for example: the system comprises a parking platform, a battery replacement mechanism, a lifting mechanism, a transportation mechanism, a turnover mechanism, a charging mechanism, a carrying mechanism, a control mechanism and the like, wherein a battery replacement station is divided into a plurality of classes according to modularization;

the major classes are divided into a plurality of minor classes according to the function components or mechanism components, each minor module comprises a plurality of different function components or mechanism components, for example, the battery replacement mechanism comprises a locking and unlocking component for disassembling and assembling a battery, the charging mechanism comprises a charging unit for charging the battery, and each major class is divided into a plurality of minor classes according to the function and the mechanism;

in the subclass, the groups are divided according to the individual components, and each functional assembly or mechanism component further includes a plurality of detection mechanisms at corresponding positions, which correspondingly detect the working condition of a single component, such as: in adding the unblock subassembly, detect the tapered end damage in adding the unblock subassembly, do not have the way and use with the cooperation of hasp subassembly, then only need send this fault information for adding the unblock subassembly, the personnel of patrolling the station of being responsible for tapered end maintenance can, divide into a plurality of subgroups with every subclass according to solitary working part like this, fault information can accurate propelling movement to appointed individual person, guarantee that fault information corresponds the technical staff of propelling movement, must solve this trouble.

Example 3

By adopting the scheme, after fault information is classified according to attributes and occurrence positions and then classified, the fault information can be accurately pushed to technicians capable of solving the fault, but in the actual operation and maintenance process, the fault information can reach tens of thousands, so that the problem that one technician only correspondingly solves one fault information is unrealistic and unnecessary, and along with the increase of the number of the power change stations, one technician needs to be simultaneously responsible for the maintenance work of a plurality of power change stations, therefore, one technician can receive a plurality of fault information at the same time, and the problem of which fault information is preferentially solved becomes a new problem.

Referring to fig. 4, in this embodiment, to solve this problem, classifying the fault information according to levels and determining a transmission timing includes:

basic fault information related to battery replacement stopping, for example: the method comprises the following steps that a power exchanging robot stops exchanging power, a stacker crane stops transportation and other faults, a first time is sent to a corresponding responsible person, the corresponding responsible person (a station patrol person or a remote monitor) also stops daily fault processing on hand after receiving fault information, the fault of the power exchanging is stopped due to the first time processing, and the fault information related to the power exchanging stop is directly related to the operation of a power exchanging station, and the faults are taken as emergency faults and are set to be the highest priority;

functional failure information not related to power replacement stopping, for example: faults such as abnormal starting of an air conditioner and incapability of charging of a charger are sent to corresponding responsible persons at preset time, generally, the faults are used as daily faults, set to be the lowest priority level, and sent to technical staff before work as daily work of the technical staff.

Of course, along with the operation and maintenance of the battery replacement station, in other embodiments, a more detailed priority relationship may be set according to a manual requirement, for example, in the functional failure information that does not involve the battery replacement stopping, the priority that the charger cannot charge is set to be higher than the priority that the air conditioner is abnormally started.

Example 4

The pushing modes of the fault information related to the embodiments 1 to 3 are all fault information generated during operation of the power swapping station, and mainly affect the work of the power swapping station, but when fault information threatening the safety of the power swapping station occurs, the pushing modes of the embodiments 1 to 3 are not applicable;

in this embodiment, for a potential safety hazard fault, for example: the method has the advantages that fire-fighting faults, theft faults and the like are transmitted to all personnel at the same time, and fault information is continuously transmitted for multiple times in different periods, so that the pushing mode of other common faults is distinguished, the warning effect is achieved, related personnel are prevented from missing information to look up until the faults are solved, and therefore, as long as one technician pays attention to the fault information, the technician can arrive at the fault site at the first time or inform the personnel capable of solving the faults to arrive at the site at the first time, the potential safety hazard diffusion is prevented, and other fault information except the potential safety hazard faults is not pushed under the condition that the manual operation mode is switched to.

Specifically, in each of embodiments 1 to 4, the occurrence content of the failure information is defined, and the content of the failure information push includes at least: time, place, name of sending fault component, fault grade, fault content description and prompt; in order to simplify the fault content description, the fault content description is coded, a set of rule definition fault codes are set, wherein the rule definition fault codes comprise the code number of a station, the code number of a component/functional component and the fault information serial number in the component, and in the prompt, a method and experience for solving the fault before can occur for reference.

Specifically, in embodiments 1 to 4, the failure information is pushed in a manner that, even if: the method can be pushed in a mode of short messages, apps and small programs.

As will be appreciated by one skilled in the art, embodiments of the present application may be provided as a method, system, or computer program product. Accordingly, the present application may take the form of an entirely hardware embodiment, an entirely software embodiment or an embodiment combining software and hardware aspects. Furthermore, the present application may take the form of a computer program product embodied on one or more computer-usable storage media (including, but not limited to, disk storage, CD-ROM, optical storage, and so forth) having computer-usable program code embodied therein.

The present application is described with reference to flowchart illustrations and/or block diagrams of methods, apparatus (systems), and computer program products according to embodiments of the application. It will be understood that each flow and/or block of the flowchart illustrations and/or block diagrams, and combinations of flows and/or blocks in the flowchart illustrations and/or block diagrams, can be implemented by computer program instructions. These computer program instructions may be provided to a processor of a general purpose computer, special purpose computer, embedded processor, or other programmable data processing apparatus to produce a machine, such that the instructions, which execute via the processor of the computer or other programmable data processing apparatus, create means for implementing the functions specified in the flowchart flow or flows and/or block diagram block or blocks.

These computer program instructions may also be stored in a computer-readable memory that can direct a computer or other programmable data processing apparatus to function in a particular manner, such that the instructions stored in the computer-readable memory produce an article of manufacture including instruction means which implement the function specified in the flowchart flow or flows and/or block diagram block or blocks.

These computer program instructions may also be loaded onto a computer or other programmable data processing apparatus to cause a series of operational steps to be performed on the computer or other programmable apparatus to produce a computer implemented process such that the instructions which execute on the computer or other programmable apparatus provide steps for implementing the functions specified in the flowchart flow or flows and/or block diagram block or blocks.

It should be understood that the above examples are only for clarity of illustration and are not intended to limit the embodiments. Other variations and modifications will be apparent to persons skilled in the art in light of the above description. This need not be, nor should it be exhaustive of all embodiments. And obvious variations or modifications derived therefrom are intended to be within the scope of the invention.

Claims (12)

1. A power swapping station fault information pushing method is characterized by comprising the following steps: the method comprises the following steps:

when equipment in the battery replacement station fails, the in-station system acquires failure information and sends the failure information to a server of an upper computer in a wired or wireless mode;

and carrying out multi-layer step-by-step division on the fault information according to the attribute, the type, the grade and the position in a server of the upper computer, and pushing the fault information to a mobile terminal of a corresponding responsible person according to a division result.

2. The power swapping station fault information pushing method according to claim 1, characterized in that: the fault information is classified according to attributes, different processing modes are determined, and the fault information is sent to different processing personnel, wherein the fault information comprises the following steps:

all faults are sent to an operation responsible person;

the method comprises the steps that faults needing to be solved on site in a power change station are sent to a station patrol worker;

the fault which can be solved remotely sends the fault information to a remote monitoring person;

the fault that can automatic repair, automatic repair is accomplished in the settlement time, does not send trouble information, does not have automatic repair to accomplish in the settlement time, if need reach the trouble that trades power station field solution, sends trouble information for the personnel of patrolling the station, if the trouble that can solve remotely, sends trouble information for remote monitoring personnel.

3. The power swapping station fault information pushing method as claimed in claim 2, wherein: and for the fault capable of being automatically repaired, after multiple automatic repair failures are carried out, the fault information is sent to a remote monitoring person.

4. The power swapping station fault information pushing method according to claim 2, characterized in that: for the fault which can be remotely solved, when the remote repair of the remote monitoring personnel fails or the on-site solution is needed in the overload judgment of the remote repair, the fault information is sent to the station patrol personnel.

5. The power swapping station fault information pushing method as claimed in claim 2, wherein: for the fault needing to be solved on the site of the power exchange station, the fault information is not sent after the fault is solved within the preset time, and when the fault is not solved within the preset time, the fault information is continuously sent within the set time period.

6. The power swapping station fault information pushing method according to claim 2, characterized in that: after the fault is processed, the content and the result of the fault processing are sent to an operation responsible person and a person who correspondingly solves the fault.

7. The power swapping station fault information pushing method according to claim 1, characterized in that: after the pushing of one fault information, before the fault is processed, other fault information is not pushed until the fault is solved.

8. The power swapping station fault information pushing method according to claim 1, characterized in that: the fault information is classified according to grades, and the time sequence of sending is determined, wherein the method comprises the following steps:

basic fault information related to the battery replacement stopping is sent to a corresponding responsible person at a first time;

and the function fault information which does not relate to the battery replacement stopping is sent to the corresponding responsible person at the preset time.

9. The power swapping station fault information pushing method according to claim 1, characterized in that: the fault information is classified according to the position, the specific position of the fault is determined, and the fault information is sent to a responsible person corresponding to the position, wherein the fault information comprises the following steps:

carrying out large-class division according to sub-modules in the power swapping station;

the subclass is divided according to functional components or mechanism parts in the major class;

the sub-groups are divided into sub-groups according to individual components.

10. The power swapping station fault information pushing method according to claim 1, characterized in that: and (4) sending potential safety hazard faults to all personnel simultaneously, and continuously sending fault information for multiple times in a time-sharing manner until the faults are solved.

11. The power swapping station fault information pushing method as claimed in claim 1, wherein: the content of the fault information push comprises the following steps: time, place, name of sending fault component, fault grade, fault content description and prompt.

12. The power swapping station fault information pushing method as claimed in claim 1, wherein: the pushing mode of the fault information is that even if the fault information is pushed, the fault information is pushed in a mode of short messages, apps and applets.

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