CN113344314A - MCI-based configuration management system - Google Patents

Abstract

The application relates to the technical field of airplane digital configuration management, and discloses a configuration management system based on MCI (Multi-media organization), which overturns the management mode of the traditional MBOM, does not manage the consumption and effectiveness of materials by components and AO (access management organization), but performs consumption and effectiveness management by a configuration layer MCI + MSI (Multi-media organization information System), and can support the differentiated management of AO and consumed materials under different configuration items.

Description

MCI-based configuration management system

Technical Field

The application belongs to the technical field of product technology management and information, particularly relates to the technical field of airplane digital configuration management, and more particularly relates to a configuration management system based on MCI.

Background

MCI, a manufacturing configuration item, that is, a manufacturing CI item used to identify a set of deliverable, condition-determining components or parts formed during the assembly process, during the structural assembly and system assembly processes; corresponding to the station nodes in the past, the method shows how many stations need to be set for assembly under a certain section, and the station nodes are not defined as configurable nodes in the future. In order to better clean the manufacturing state and match the management mode of simplified configuration at the design end, in the future, a configuration node facing the manufacturing is defined during manufacturing planning, and research shows that the configuration layer is reasonably defined at the station level.

Disclosure of Invention

In order to solve the problem that the traditional MBOM manages the process difference by design configuration and realize decoupling of manufacturing and design configuration, the application provides a configuration management system based on MCI.

In order to achieve the above object, the technical solution of the present application is as follows:

a configuration management system based on MCI comprises an MCI/MSI node creating module, an MCI node importing module, an MCI time sequence design module, an AO node creating module, an AO node importing module, an AO time sequence design module, an MCI span displacement moving module and an AO span MCI moving module; wherein:

the MCI/MSI node creating module is used for the MCI node and the MSI node;

the MCI node import module is used for importing MCI nodes in batches;

the MCI time sequence design module is used for carrying out time sequence design on canvas of MCI on the right side of the segment position, to which the segment position node belongs;

the AO node creation module is used for creating an AO node;

the AO node import module is used for importing AO nodes in batches;

the AO time sequence design module is used for carrying out time sequence design on a canvas of the MCI on the right side of the segment position node;

the MCI span displacement module is used for moving the same MCI in different segment positions to construct a new segment position

The AO strides the MCI and moves the module to be used for in different MCI, moves the same AO node and constructs new MCI.

Preferably, when the MCI node is created, a default MSI node is created under the MCI node.

Preferably, when the MCI node is imported, the MCI node is created by using EXCEL batch import under the segment node, and when the MCI node is imported, whether the node number is consistent with the current model is checked, and whether the last three bits are numbers is checked.

Preferably, when creating an AO node, if multiple MSIs exist under the affiliated MCI, the created AO node is applied to other MSIs.

Preferably, when the AO node is imported, the AO node is created by adopting EXCEL batch import under the MSI node, and whether the node number is consistent with the current model is checked during the import.

The beneficial effect of this application:

the management mode of the traditional MBOM is overturned, the consumption and effectiveness of materials are not managed by components and AO, but the consumption and effectiveness management is carried out by the structural layer MCI + MSI, the differential management of AO and consumed materials under different structural items can be supported, and the MBOM structural material management is realized. An MBOM technical state management mode taking MCI as a core is constructed, the mapping relation between ECI and MCI is tracked, the MCI can be used as a material to flow in the manufacturing process, and the quick analysis of the change influence is realized by designing the relation between CI and manufacturing CI.

Drawings

The foregoing and following detailed description of the present application will become more apparent when read in conjunction with the following drawings, wherein:

FIG. 1 is a schematic timing diagram of MCI;

fig. 2 is a schematic diagram of a system for creating MCI nodes;

FIG. 3 is a system diagram of batch import;

FIG. 4 is a schematic diagram of a system for uploading local files;

FIG. 5 is a schematic diagram of maintaining MCI timing validity;

FIG. 6 is a schematic illustration of AO timing relationship maintenance;

FIG. 7 is a system diagram of AO node creation;

FIG. 8 is a system diagram of bulk import AO nodes;

FIG. 9 is a system diagram of AO timing design.

Detailed Description

The technical solutions for achieving the objects of the present invention are further described below by specific examples, and it should be noted that the technical solutions claimed in the present application include, but are not limited to, the following examples.

Example 1

The embodiment discloses a configuration management system based on MCI, which specifically comprises an MCI/MSI node creating module, an MCI node importing module, an MCI time sequence design module, an AO node creating module, an AO node importing module, an AO time sequence design module, an MCI span displacement moving module and an AO span MCI moving module; wherein:

the MCI/MSI node creating module is used for the MCI node and the MSI node;

the MCI node import module is used for importing MCI nodes in batches;

the MCI time sequence design module is used for carrying out time sequence design on canvas of MCI on the right side of the segment position, to which the segment position node belongs;

the AO node creation module is used for creating an AO node;

the AO node import module is used for importing AO nodes in batches;

the AO time sequence design module is used for carrying out time sequence design on a canvas of the MCI on the right side of the segment position node;

the MCI span displacement module is used for moving the same MCI in different segment positions to construct a new segment position

The AO strides the MCI and moves the module to be used for in different MCI, moves the same AO node and constructs new MCI.

Further, when the MCI node is created, a default MSI node is created under the MCI node, and the number of the MSI node is MCI node number-001.

Further, when the MCI node is imported, the MCI node is created by adopting EXCEL batch import under the segment node, and whether the node number is consistent with the current model or not is checked during import, and whether the last three bits are numbers or not is checked.

Further, when an AO node is created, if a plurality of MSIs exist in the affiliated MCI, the created AO node is applied to other MSIs.

Further, when the AO node is imported, the AO node is created by adopting EXCEL batch import under the MSI node, and whether the node number is consistent with the current machine type is checked during the import.

Example 2

The embodiment discloses a configuration management method based on MCI, which is implemented based on the management system in embodiment 1 and specifically includes the following steps, with reference to fig. 1 to 9 in the specification:

step one, MCI/MSI node creation

When the MCI node is established, the segment node number is taken in by default, the back three-digit number is input, the MCI number is established when the MCI node is confirmed, and the system checks whether the MCI number is repeated; establishing a default MSI under an MCI node while establishing the MCI, wherein the number of the MSI node is MCI node number-001;

double clicking on the parent node (which is the parent of the node to be created) on the MBOM tree, the system locks the parent node, exposing the canvas area. And clicking the MBOM (creation) node icon, and confirming by a left mouse button in a blank area of the canvas. And popping up a node attribute filling interface. Double clicking on the segment node on my work tree, the system displays the right canvas area. Clicking the icon, and lightening the right MBOM node to create the icon;

clicking the MBOM node to create an icon, and confirming the icon by a left mouse button in a blank area of the canvas. Popping up an MCI node attribute filling interface as shown in FIG. 2, after the attributes are filled, clicking (confirming) to successfully create the MCI node, automatically creating an initial MSI node under the MCI node by the system, wherein the MSI node is numbered as MCI number +001, and the validity is defaulted to be full-frame. And after the interface attribute is filled, clicking (confirming), successfully creating the node, and creating a new node on the canvas. When the MSI node is the MCI node, the system is automatically created, the number is the MCI number + 3-bit serial number, and other attributes are integrated in the MCI attributes.

Step two, leading in MCI nodes in batches

Under the segment node, establishing an MCI node by using EXCEL batch import;

clicking the [ batch import ] function of the MBOM editor main interface, and entering a batch import main interface, as shown in FIG. 3. And clicking (acquiring a template), acquiring a data import template file, downloading the data import template file to the local, and maintaining information such as a parent file number, a serial number, node attributes and the like in local Excel. After the local Excel is edited, the historical data needing to be maintained is uploaded by clicking (browsing) and clicking (importing), as shown in fig. 4.

After the Excel template is filled in, uploading the template, and processing as follows: reading Excel content, and packaging the entry information of each line into a TPprocessPol object; performing preliminary verification on the filling content compliance; checking whether the number input is in compliance; checking whether the assembly period is greater than the segment position assembly period; checking whether the branch factory brevity codes are consistent with the branch factory brevity codes of the section; and after the verification, sending the data to a server side for node creation and relationship import processing.

Step three, MCI time sequence design

The MCI to which the segment node belongs carries out time sequence design on the canvas on the right side of the segment, the effectiveness is recorded on the MCI time sequence connecting line, the effectiveness setting times are set on the MCI time sequence connecting line by a user, and the assembling period, the effectiveness and whether the MCI node is free are checked.

Step four, AO node creation

Carrying out AO node creation work when the MSI node is not issued; AO nodes can be created under the MSI nodes, the AO nodes have no hierarchical relation, and the AO nodes are displayed in a flat layer under the same MSI; when in creation, if a plurality of MSIs exist in the MCI, the system provides a function to apply the created AO to other MSIs; the branch simplified codes are required to be consistent with the branch plants of the section positions, AO nodes have no validity, and the AO nodes can be acquired by the MSI to which the AO nodes belong if the AO validity needs to be calculated;

double-clicking MSI node on MBOM tree, the system shows right canvas area. Clicking the icon, lighting the right MBOM node, and after clicking the MBOM node icon, confirming by a left mouse button in the blank area of the canvas. And popping up an AO node attribute filling interface as shown in FIG. 7. And after the interface attribute is filled, clicking (confirming), successfully creating the node, and creating a new node on the canvas. And (3) expanding the canvas on the right side of the model or section node to which the segment bit belongs by double-clicking on the MBOM tree, then double-clicking the segment bit node to be modified on the canvas, popping up a node attribute interface, and modifying and confirming. Double-clicking on the segment canvas to modify the attribute of the MCI node; double-clicking on the MCI canvas to modify the MSI node attribute; and double-clicking on the MSI canvas to modify the attribute of the AO node, and after the attribute of the AO is modified, adjusting the attributes of the AO with the same number under the MCI.

Step five, importing the AO nodes in batches

Under the MSI node, using EXCEL batch import to create an AO node;

clicking the function of batch import of the MBOM editor main interface, and entering a batch import main interface; and clicking (acquiring a template), acquiring a data import template file, downloading the data import template file to the local, and maintaining information such as a parent file number, a serial number, node attributes and the like in local Excel. After the local Excel is edited, the historical data needing to be maintained is uploaded by clicking (browsing) and clicking (importing), as shown in fig. 8.

After the Excel template is filled in, uploading the template, and processing as follows: 1. reading Excel content, and packaging the entry information of each line into a TPprocessPolan object; 2. performing preliminary verification on the filling content compliance; 3. checking whether the number input is in compliance; 4. checking whether the assembly period is greater than the segment position assembly period; 5. checking whether the branch factory brevity codes are consistent with the branch factory brevity codes of the section; 6. and after the verification, sending the data to a server side for node creation and relationship import processing.

Step six, AO time sequence design

The method comprises the following steps that a canvas of an MCI (micro computer interface) to which a segment node belongs on the right side of a segment is subjected to time sequence design, effectiveness is recorded on an MCI time sequence connecting line, and a user sets effectiveness times on the MCI time sequence connecting line;

entering an MBOM editor, double-clicking MSI nodes on the structure tree, and displaying AO nodes on the canvas; clicking a time sequence button, and connecting time sequence lines among the nodes; clicking an AO validity configuration button to open a configuration page; the validity of the MSI is displayed by default, and can be modified; after the modification is finished, clicking a confirmation button to store the time sequence validity; double-clicking the MSI node on the MBOM tree, the canvas on the right side shows the AO timing canvas, as shown in FIG. 9.

Step seven, MCI span displacement movement

Moving the MCI node integrally across segment bits, wherein the function rule is defined as: the MCI node is not released; the types of the moved segment bits are the same; the effectiveness of moving the MCI must be the MCI moves integrally for the whole time;

and selecting an MCI node in the MBOM structure tree, clicking a right-click 'move' menu, popping up a selection segment page, finding a target segment through searching, filling a validity segment, and clicking to determine. On the left MBOM tree, select MCI node, right key "move MCI", pop up move MCI interface. Querying and selecting the target segment bit to fill in the validity of the moved MCI, as shown in fig. 9;

step eight, AO moves across MCI

Before the AO moves, a user needs to disconnect the time sequence relation of the AO first, a system checks whether the AO has the time sequence relation, and if so, the AO can move after being removed;

and selecting an AO node on the MBOM structure tree, clicking a right-click 'move' menu, popping up and selecting an MCI page, and searching to find a target MCI node. The system lists the next validity segment, the target validity segment of AO movement is selected, and clicking is determined. Before the AO moves, the time sequence relation of the AO is required to be disconnected, the system checks whether the AO has the time sequence relation, and if the AO has the time sequence relation, the AO can move after being removed.

The foregoing is directed to embodiments of the present invention, which are not limited thereto, and any simple modifications and equivalents thereof according to the technical spirit of the present invention may be made within the scope of the present invention.

Claims (5)

1. An MCI-based configuration management system, characterized by: the system comprises an MCI/MSI node creating module, an MCI node importing module, an MCI time sequence design module, an AO node creating module, an AO node importing module, an AO time sequence design module, an MCI span displacement moving module and an AO span MCI moving module; wherein:

the MCI/MSI node creating module is used for the MCI node and the MSI node;

the MCI node import module is used for importing MCI nodes in batches;

the MCI time sequence design module is used for carrying out time sequence design on canvas of MCI on the right side of the segment position, to which the segment position node belongs;

the AO node creation module is used for creating an AO node;

the AO node import module is used for importing AO nodes in batches;

the AO time sequence design module is used for carrying out time sequence design on a canvas of the MCI on the right side of the segment position node;

the MCI span displacement module is used for moving the same MCI in different segment positions to construct a new segment position

The AO strides the MCI and moves the module to be used for in different MCI, moves the same AO node and constructs new MCI.

2. An MCI-based configuration management system according to claim 1 wherein: and when the MCI node is created, a default MSI node is created under the MCI node.

3. An MCI-based configuration management system according to claim 1 wherein: when the MCI nodes are imported, the MCI nodes are created by adopting EXCEL batch import under the section nodes, whether the node numbers are consistent with the current model or not is checked during import, and whether the last three bits are numbers or not is checked.

4. An MCI-based configuration management system according to claim 1 wherein: when an AO node is created, if a plurality of MSIs exist in the MCI, the created AO node is applied to other MSIs.

5. An MCI-based configuration management system according to claim 1 wherein: when the AO node is imported, adopting EXCEL to import in batch to create the AO node under the MSI node, and checking whether the node number is consistent with the current model when importing.

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