CN111160670A - Deep sea detection equipment disassembly, maintenance, assembly and debugging engineering execution method - Google Patents

Abstract

The invention relates to a deep sea detection equipment disassembly, maintenance, assembly and debugging engineering execution method, which comprises the following steps: managing a task pool: attributing tasks in the operation and maintenance process of the submersible, and summarizing the tasks to form a set, namely a task pool; planning disassembly, maintenance, assembly and debugging engineering: selecting tasks from a task pool, generating a primary engineering plan, and forming a plan Gantt bar in a Gantt chart mode for displaying the plan; the disassembly, maintenance, assembly and debugging engineering is implemented: executing tasks according to a plan, wherein one task corresponds to one operation and maintenance information card, and one operation and maintenance information card corresponds to one actual task Gantt bar; and comparing the planned Gantt bar with the actual Gantt bar for monitoring the project progress.

Description

Deep sea detection equipment disassembly, maintenance, assembly and debugging engineering execution method

Technical Field

The invention relates to an informatization management method for disassembly, inspection, maintenance, assembly and debugging projects in the operation and maintenance process of deep sea detection equipment.

Background

With the development of the technology level, the requirements on indexes such as reliability, stability and accuracy of the submersible are more and more strict. The requirements of increased task quantity, increased task diversity, more complex submarine operation terrain, increased service time and the like are more and more emphasized, the operation and maintenance work of the submersible is very important, and the submersible can work better after maintenance is well done. However, the traditional operation and maintenance mode of the submersible cannot meet the requirements of high-speed, high-efficiency and high-quality work, so that the operation and maintenance work of the submersible is necessary to be assisted in an information mode.

Disclosure of Invention

Aiming at the technical defects, the invention aims to provide an execution method of deep sea detection equipment disassembly, inspection, maintenance, assembly and debugging engineering. The method realizes the informatization management of the operation and maintenance process of the deep sea detection equipment.

The technical scheme adopted by the invention for solving the technical problems is as follows: a deep sea detection equipment disassembly, maintenance, assembly and debugging engineering execution method comprises the following steps:

managing a task pool: attributing tasks in the operation and maintenance process of the submersible, and summarizing the tasks to form a set, namely a task pool;

planning disassembly, maintenance, assembly and debugging engineering: selecting tasks from a task pool, generating a primary engineering plan, and forming a plan Gantt bar in a Gantt chart mode for displaying the plan;

the disassembly, maintenance, assembly and debugging engineering is implemented: executing tasks according to a plan, wherein one task corresponds to one operation and maintenance information card, and one operation and maintenance information card corresponds to one actual task Gantt bar; and comparing the planned Gantt bar with the actual Gantt bar for monitoring the project progress.

The attributes comprise task names, subsystem to which the task belongs, start time and process time consumption.

The planning of the disassembly, inspection, assembly and debugging project is specifically as follows:

and for a primary operation and maintenance plan, selecting a task from the task pool, automatically generating a primary plan according to the starting time and the process time consumption of the task, displaying the primary plan in a Gantt chart mode, and finally forming an assembly debugging project plan for disassembly, maintenance and assembly through mouse operation and modification by a user.

The operation and maintenance comprises the following steps of installation and uninstallation:

and (3) installation operation: recursively comparing the tree structure of the child equipment with the tree structure of the parent equipment, supplementing the in-service list of the child equipment into the in-service list of the parent equipment if the tree structures of the child equipment and the parent equipment are completely consistent, and not installing the child equipment and the parent equipment if the tree structures of the child equipment and the parent equipment are inconsistent;

unloading operation: the in-service list belonging to the sub-equipment is directly deleted from the operation information of the parent equipment, and meanwhile, the sub-equipment exists as an independent equipment and also has an in-service list.

Before the installation and the uninstallation, the following steps are executed:

1) searching in-service list of parent equipment

Under the condition of in-service operation and maintenance, directly using the tree structure and the operation information of the submersible to form an in-service list of the submersible body;

under the condition of manual operation and maintenance, judging whether the mother equipment has operation information; when the equipment is not operated, no operation information exists; if the parent equipment has operation information, generating an in-service list according to the tree structure of the parent equipment and the operation information; if the parent equipment has no operation information, acquiring a tree structure taking the equipment as a root node in a submersible tree model structure, and directly initializing an in-service list of the equipment;

2) searching in-service lists of sub-devices

Searching the in-service list of the sub-equipment under the in-service operation and maintenance condition and the manual operation and maintenance condition; if the sub-equipment has the operation information, generating an in-service list according to the tree structure and the operation information of the sub-equipment; if the sub-equipment has no operation information, the tree structure taking the equipment as a root node is obtained in the submersible tree structure, and the in-service list of the equipment is directly initialized.

The operation and maintenance information card comprises: the method comprises the following steps of task name, subsystem to which the task belongs, starting time, process time consumption, location, process file for recording and executing the task, and task execution picture.

After the disassembly, inspection, assembly and debugging project is implemented, task rechecking is carried out, and the method specifically comprises the following steps: and according to the 'whether to recheck' attribute of the task information card, for the tasks needing to be rechecked, referring to the project plan and the operation and maintenance information card, and rechecking the actual work.

After the disassembly, inspection, assembly and debugging project is implemented, the statistical analysis is specifically as follows:

generating a report of disassembly, inspection, maintenance, assembly and debugging engineering, and summarizing and analyzing and optimizing a task pool by a worker according to the report; and according to the conditions of the participators in the operation and maintenance task information card, the workload of the personnel is counted, wherein the workload comprises the working days and the overtime days, and the workload is used for performing performance assessment on the personnel.

The invention has the following beneficial effects and advantages:

1. the method realizes dynamic configuration and adjustment of the deep sea detection equipment disassembly, maintenance, assembly and debugging project plan, avoids repeated addition of the same task and improves the working efficiency.

2. The method shows the comparison between the plan of the submersible disassembly, maintenance, assembly and debugging project and the actual work in a Gantt chart mode, so that a user can master the implementation progress of the current project at any time.

3. The method realizes the correspondence between the operation and maintenance tasks and the spare parts, records the installation and the uninstallation of the spare parts, and forms a mapping of the actual submersible in the system from the integral view; from the perspective of the spare parts, the historical operation and maintenance records of any spare part can be checked.

4. The method optimizes the operation and maintenance process by using PDCA (Plan, Do execution, Check processing Act) circulation in the quality management. The deep sea detection equipment is disassembled, maintained, assembled and debugged, an integral report is generated, the problems are summarized, the task pool is perfected, the problems are avoided appearing again, the whole disassembling, maintaining, assembling and debugging engineering is optimized, and the working quality and the working efficiency are improved.

5. The method provides an effective basis for performance assessment of workers. And according to the participants in the operation and maintenance task information card and the working time of the participants, the workload of the workers, including the overtime condition of the holidays, is counted so as to perform performance assessment on the workers.

Drawings

FIG. 1 is a system flow diagram of the present invention;

FIG. 2 is a diagram of the spare part operation of the present invention;

FIG. 3 is a mapping of spare parts to spare parts in an actual vehicle;

fig. 4 is a schematic diagram of the design concept of the present invention.

Detailed Description

The present invention will be described in further detail with reference to examples.

As shown in fig. 1, a deep sea detection device disassembly, maintenance, assembly and debugging project execution method includes the following steps:

managing a task pool: and 4 key attributes are given to the tasks involved in the operation and maintenance process of the submersible, namely the task name, the subsystem to which the submersible belongs, the approximate starting time and the approximate process time consumption. The tasks are collected to form a set, namely a task pool;

the working plan of the disassembly, maintenance, assembly and debugging project is flexibly and conveniently configured. The tasks involved in the operation and maintenance of the submersible have certain repeatability, namely, the multiple operation and maintenance tasks of one submersible have repeatability, and the operation and maintenance tasks of the same type of different submersible are approximately the same. In order to avoid repeatedly adding one task for multiple times, the method provides the concept of the task pool, puts all tasks into one set, and selects the tasks from the task pool in a targeted manner for one operation and maintenance plan. Aiming at the one-time disassembly, inspection, assembly and debugging project, after a task is selected from a task pool, a system automatically generates a primary plan according to the approximate starting time and the approximate process time consumption of the task, and the primary plan is visually displayed in a Gantt chart form. A user can conveniently and flexibly modify tasks needing to be adjusted through mouse operation to form a final disassembly, inspection, maintenance, assembly and debugging project plan.

And the execution of the disassembly, inspection, assembly and debugging project is visually displayed, and the comparison between the plan and the actual work is visually displayed, so that a user can master the execution progress of the operation and maintenance project at any time. After the plan of the disassembly, inspection, assembly and debugging project is issued, working personnel check the plan in a Gantt chart mode, execute tasks according to the plan, record task execution processes and upload relevant process data to form an operation and maintenance information card, wherein the type of the information card comprises: disassembling, checking, maintaining, repairing, assembling and debugging. Shown in a gantt bar format. This forms a comparison of the planned vs. actual gantt bars, one planned gantt bar may correspond to multiple actual gantt bars, since planning is relatively coarse. By the comparison mode, the execution progress of the current disassembly, inspection, maintenance, assembly and debugging project can be clear at a glance.

The corresponding and combination of the disassembly, inspection, maintenance, assembly and debugging engineering task and the spare parts is realized. The operation of the spare parts redesigned by the task is recorded through the operation and maintenance information card, including installation and unloading, so that the spare parts in the system correspond to the spare parts in the actual submersible one by one, the virtual and real mapping is realized, meanwhile, the historical operation and maintenance conditions of the spare parts can be checked in the system, and the whole life cycle of the spare parts is traced.

In this embodiment, the deep sea detection device is a submersible. In order to realize the mapping between spare parts in the system and spare parts in the actual submersible vehicle, the following steps are executed:

modeling a submersible tree structure: establishing a submersible tree structure model according to the subordination relation of all subsystem equipment of the submersible;

and (3) mapping the tree structures of the parts and spare parts: based on the submersible tree structure model, a tree structure subset is taken and mapped to obtain the tree structures of parts and spare parts;

mapping the active list: constructing an in-service list of the submersible, the parts and the spare parts based on the tree structures of the submersible, the parts and the spare parts and the equipment with the unique codes;

operation and maintenance service mapping: the modification of the actual operation and maintenance service to structures of submersible, parts and spare parts is mapped into the record of the operation and maintenance service and the modification to the in-service list;

in-service inventory query: and inquiring the in-service list of the submersible, the parts and the spare parts, and forming the equipment history according to the history change record of the in-service list.

The submersible tree structure modeling comprises the following steps:

establishing each node in a tree structure according to the subordination relation of each subsystem device of the submersible; and configuring the attribute of the tree structure node of the submersible.

The submersible tree node attributes include:

whether the node belongs to an in-service list, whether the node belongs to a spare part list, whether the node is installable, whether the node is a low-value node, and whether the node is only counted.

The tree structure mapping of the parts and spare parts comprises the following steps:

the tree structures of the parts and the spare parts are the tree structure subsets of the submersible vehicle tree structure, so the tree structures of the parts and the spare parts are obtained through mapping based on the submersible vehicle tree structure model.

The in-service inventory is the combination of in-service structures and operation information of submersible, parts and spare parts;

the operation information is installation or unloading information aiming at a tree node of a submersible, a part and a spare part, and comprises operator information, operation time information and equipment information;

the device has a unique identification code.

The unique identification code is a three-level code and is divided into an equipment tree code, a manufacturer type number and a running code;

equipment tree code: the equipment tree code is a code consistent with the tree structure model code and identifies the position of the equipment on the submersible;

manufacturer type number: uniquely identifying the manufacturer model corresponding to the equipment tree code;

flow code: and on the basis of the same equipment tree code and the same manufacturer type number, the flow code is uniquely identified.

The operation and maintenance service is directed at the operation and maintenance contents of the submersible, the parts and the spare parts, and comprises operation information, operation and maintenance places and operation and maintenance image data.

The one-to-one mapping relation between spare parts in the system and spare parts on an actual submersible is realized, and the operation steps comprise:

1. in-service spare part for searching parent equipment

Under the condition of in-service operation and maintenance, the installation condition of the in-service spare parts on the current parent equipment and the codes of the installed spare parts can be checked according to the historical operation and maintenance records.

In the case of manual operation and maintenance, when the parent device is not operated, it is necessary to determine whether the device has operation information, such as new purchase and new borrowing. If the parent equipment has operation information, generating an in-service list according to the tree structure model and the operation information; if the parent equipment has no operation information, acquiring a tree structure subset taking the equipment as a root node in a submersible hierarchical tree model structure, and directly initializing an in-service list of the equipment.

2. Finding out in-service spare parts of sub-equipment

In both the in-service operation and maintenance situation and the manual operation and maintenance situation, spare parts currently installed on the sub-equipment need to be searched.

If the sub-equipment has the operation information, generating an in-service list according to the in-service structure model and the installation information; if the sub-equipment has no installation information, acquiring a tree structure subset taking the equipment as a root node in a submersible tree model structure, and directly initializing an in-service list of the equipment.

3. Installing or uninstalling:

and (3) installation operation: recursively comparing the tree structure of the child equipment with the tree structure of the parent equipment, supplementing the in-service list of the child equipment into the in-service list of the parent equipment if the tree structures of the child equipment and the parent equipment are completely consistent, and not installing the child equipment and the parent equipment if the tree structures of the child equipment and the parent equipment are inconsistent;

unloading operation: the in-service list belonging to the sub-equipment is directly deleted from the operation information of the parent equipment, and meanwhile, the sub-equipment exists as an independent equipment and also has an in-service list.

The parent equipment and the child equipment are objects related to operation and maintenance services, namely the parent equipment is an installed or uninstalled carrier, and the child equipment is an uninstalled or installed part or spare part; the unloading process is to unload a plurality of sub-devices from the parent device, and the installation process is to install a plurality of sub-devices on the parent device.

The operation and maintenance service refers to operation and maintenance contents for submersibles, parts and spare parts, and comprises operation information, operation and maintenance places, operation and maintenance image data and other information; the operation and maintenance service is divided into operation in active service and operation and maintenance in hand. The mother equipment for in-service operation and maintenance is a submersible body, and the mother equipment for manual operation and maintenance is parts and spare parts. The in-service operation and maintenance means that the parts and spare parts are installed on or directly unloaded from the submersible, and the manual operation and maintenance means that the parts and spare parts are installed on or unloaded from the target parts and spare parts.

And (4) task rechecking: and according to the 'whether to recheck' attribute of the task information card, for the tasks needing to be rechecked, referring to the work plan and the operation and maintenance information card, and rechecking the actual work.

And (4) performing statistical analysis, perfecting the work flow and providing a performance assessment basis for the staff. After one project is finished, the system gives a project report by taking the project as a unit, and workers can summarize the problems existing in the project and the workflow needing to be optimized according to the report, so that the tasks in the task pool are perfected, similar problems are avoided, and the disassembly, maintenance, assembly and debugging project in the operation and maintenance of the submersible vehicle can be optimized to the maximum extent. The statistical analysis also provides a certain basis for performance assessment of the workers, and according to the conditions of the participants in the operation and maintenance task information card, the workload of the workers including working days, overtime days and the like is counted so as to perform performance assessment on the workers.

In the system, the states of spare parts are divided into 3 types: in stock, in hand, in service. The spare parts in the warehouse are the spare parts for purchasing and warehousing or returning, and the warehouse manager is responsible for the spare parts; the spare parts of the hands are spare parts after the warehouse-out operation is executed, and the personnel applying for warehouse-out are responsible for the spare parts; the spare parts in service are spare parts already installed on the submersible. The system encodes the spare parts, the codes are the unique identifiers of the spare parts, and the codes are used for tracing and tracking the historical operation and maintenance records of the spare parts. As shown in fig. 2, the operation and maintenance tasks can be divided into an operation in active service and an operation and maintenance in hand. The in-service operation and maintenance refers to the operation and maintenance service directly carried out on the submersible. Hand-in-hand maintenance refers to the maintenance of a component when it comes off the submersible to the hand, or when it is not yet installed on the submersible. For example, the collision-prevention sonar "SN 001 × 002" is installed on the submersible, and is in service when the collision-prevention sonar is directly operated and maintained, and is in hand when the collision-prevention sonar is not installed on the submersible and is required to be operated and maintained.

As shown in fig. 3, the real world is mapped into the virtualized world, and the things in the real world are abstracted and simulated by using an algorithm, wherein the things comprise operation and maintenance services, and the things comprise a submersible body and parts.

In the real world, the operation and maintenance service is a concrete representation of driving the state change of the submersible body and parts. In the virtualized world, the operation and maintenance service is mapped into installation, uninstallation and the like, the tree structure model of the submersible body is communicated with the tree structure models of the parts and spare parts, and communication records are recorded and saved to form a snapshot-type in-service list of the submersible body and the parts and a video-type electronic calendar of the submersible body and the parts.

As shown in fig. 4, the method not only tracks the operation and maintenance process, but also provides statistical analysis after the operation and maintenance task is completed, counts the workload of the workers, and provides an effective basis for performance assessment of the workers; and summarizing the existing problems according to the statistical analysis result, and optimizing the operation and maintenance process. The method optimizes the operation and maintenance process of the submersible by utilizing PDCA circulation in the quality management. The method comprises the steps of executing tasks from a task pool, summarizing problems, perfecting the task pool to form a closed loop, realizing optimization of work planning, execution, problem finding, problem correcting and planning by utilizing the closed loop, avoiding repeated occurrence of problems and improving working efficiency.

Claims (8)

1. A deep sea detection equipment disassembly, maintenance, assembly and debugging engineering execution method is characterized by comprising the following steps:

managing a task pool: attributing tasks in the operation and maintenance process of the submersible, and summarizing the tasks to form a set, namely a task pool;

planning disassembly, maintenance, assembly and debugging engineering: selecting tasks from a task pool, generating a primary engineering plan, and forming a plan Gantt bar in a Gantt chart mode for displaying the plan;

the disassembly, maintenance, assembly and debugging engineering is implemented: executing tasks according to a plan, wherein one task corresponds to one operation and maintenance information card, and one operation and maintenance information card corresponds to one actual task Gantt bar; and comparing the planned Gantt bar with the actual Gantt bar for monitoring the project progress.

2. The method as claimed in claim 1, wherein the attributes include task name, subsystem to which the deep sea probe belongs, start time, and process time.

3. The method for executing the deep sea exploration equipment disassembly, maintenance, assembly and debugging project according to claim 1, wherein the planning of the disassembly, maintenance, assembly and debugging project specifically comprises:

and for a primary operation and maintenance plan, selecting a task from the task pool, automatically generating a primary plan according to the starting time and the process time consumption of the task, displaying the primary plan in a Gantt chart mode, and finally forming an assembly debugging project plan for disassembly, maintenance and assembly through mouse operation and modification by a user.

4. The deep sea exploration equipment overhauling, maintaining, assembling and debugging project execution method according to claim 3, wherein the operation and maintenance comprises the following steps of installing and uninstalling:

and (3) installation operation: recursively comparing the tree structure of the child equipment with the tree structure of the parent equipment, supplementing the in-service list of the child equipment into the in-service list of the parent equipment if the tree structures of the child equipment and the parent equipment are completely consistent, and not installing the child equipment and the parent equipment if the tree structures of the child equipment and the parent equipment are inconsistent;

unloading operation: the in-service list belonging to the sub-equipment is directly deleted from the operation information of the parent equipment, and meanwhile, the sub-equipment exists as an independent equipment and also has an in-service list.

5. The deep sea detection equipment overhauling, maintaining, assembling and debugging project execution method according to claim 4, wherein before the installation and the uninstallation, the following steps are executed:

1) searching in-service list of parent equipment

Under the condition of in-service operation and maintenance, directly using the tree structure and the operation information of the submersible to form an in-service list of the submersible body;

under the condition of manual operation and maintenance, judging whether the mother equipment has operation information; when the equipment is not operated, no operation information exists; if the parent equipment has operation information, generating an in-service list according to the tree structure of the parent equipment and the operation information; if the parent equipment has no operation information, acquiring a tree structure taking the equipment as a root node in a submersible tree model structure, and directly initializing an in-service list of the equipment;

2) searching in-service lists of sub-devices

Searching the in-service list of the sub-equipment under the in-service operation and maintenance condition and the manual operation and maintenance condition; if the sub-equipment has the operation information, generating an in-service list according to the tree structure and the operation information of the sub-equipment; if the sub-equipment has no operation information, the tree structure taking the equipment as a root node is obtained in the submersible tree structure, and the in-service list of the equipment is directly initialized.

6. The deep sea exploration equipment disassembly, maintenance, assembly, debugging project execution method according to claim 1, wherein the operation and maintenance information card comprises: task name, subsystem to which it belongs, start time, process consumption

Time, place, record the process file of executing the task, and execute the task picture.

7. The method for executing the deep sea exploration equipment disassembly, maintenance, assembly and debugging project according to claim 1, wherein after the disassembly, maintenance, assembly and debugging project is implemented, a task is rechecked, specifically: and according to the 'whether to recheck' attribute of the task information card, for the tasks needing to be rechecked, referring to the project plan and the operation and maintenance information card, and rechecking the actual work.

8. The method for executing the deep sea exploration equipment disassembly, maintenance, assembly and debugging project according to claim 1, wherein after the deep sea exploration equipment disassembly, maintenance, assembly and debugging project is implemented, the statistical analysis specifically comprises:

generating a report of disassembly, inspection, maintenance, assembly and debugging engineering, and summarizing and analyzing and optimizing a task pool by a worker according to the report; and according to the conditions of the participators in the operation and maintenance task information card, the workload of the personnel is counted, wherein the workload comprises the working days and the overtime days, and the workload is used for performing performance assessment on the personnel.

Images