CN116541547A - Industrial drawing element full-link deduction method and system - Google Patents

Abstract

The invention discloses an industrial drawing element full-link deduction method and system, wherein the method comprises the following steps: s10, identifying element information on a plurality of industrial drawing pages in a drawing database; the element information comprises a plurality of elements, a plurality of element contents corresponding to each element and connection information among the elements; s20, taking each element as a node, and constructing a corresponding directed/undirected graph according to the element information of each industrial drawing; s30, establishing a full-link connection diagram of each node according to the directed/undirected diagrams respectively corresponding to the plurality of industrial drawings; s40, outputting a full-link connection diagram of each node; by implementing the invention, the user can quickly find out the connection relation of the related nodes, the workload and time required by the user to find out the drawing are obviously reduced, and the retrieval error rate is improved, thereby being beneficial to improving the efficiency of fault analysis work.

Description

Industrial drawing element full-link deduction method and system

Technical Field

The invention relates to the technical field of nuclear power plant drawing management, in particular to an industrial drawing element full-link deduction method and system.

Background

Because the industrial drawings of the nuclear power plant are numerous, and the legends in part of the drawings are also connected with the legends of other drawings, some connecting channels can be cut and arranged in different drawings, so that the drawings become extremely complex.

At present, the conventional drawing query method of the nuclear power plant is to search drawings required by actual work in a large number of drawings by manpower, and then repeatedly search and skip the drawings in a complex manner to sort out signal link diagrams required by the work so as to meet the work requirement. Therefore, when a fault or abnormality occurs in the operation site, an operator is required to spend a great deal of time to find the reason in the drawing, which is time-consuming and labor-consuming and has the defect of high error rate.

Disclosure of Invention

The invention aims to solve the technical problem of providing an industrial drawing element full-link deduction method and system.

The technical scheme adopted for solving the technical problems is as follows: an industrial drawing element full-link deduction method is constructed, which comprises the following steps:

s10, identifying element information on a plurality of industrial drawing pages in a drawing database; the element information comprises a plurality of elements, a plurality of element contents corresponding to each element and connection information among the elements;

s20, taking each element as a node, and constructing a corresponding directed/undirected graph according to the element information of each industrial drawing;

s30, establishing a full-link connection diagram of each node according to the directed/undirected diagrams respectively corresponding to the plurality of industrial drawings;

and S40, outputting a full-link connection diagram of each node.

In an alternative embodiment, the industrial drawing element full-link deduction method further includes:

s50, receiving a node operation instruction input by a user, and executing setting display work according to the operation instruction; wherein the setting display operation includes: displaying at least one of a prompt and display operation frame of each industrial drawing associated with the corresponding node, custom arranging the corresponding node, displaying a link between the selected nodes and displaying element content of the corresponding node.

In an alternative embodiment, after step S50, further comprising:

rearranging the nodes in the full-link connection graph to be displayed according to a set arrangement rule by a topology ordering algorithm; the arrangement rule comprises arrangement from left to right or from top to bottom according to the signal flow direction of each node.

In an optional embodiment, the prompt and display operation box is used for displaying the figure number of the corresponding industrial drawing and/or the setting description content corresponding to the corresponding industrial drawing;

the industrial drawing element full-link deduction method further comprises the following steps:

and S60, displaying the corresponding industrial drawing according to the operation instruction of the prompt and display operation frame.

In an alternative embodiment, in step S10, the identifying element information on each industrial drawing page in the drawing database includes:

element information on each industrial drawing page in the drawing database is obtained through OCR text recognition technology or NLP technology.

In an alternative embodiment, after step S20, further comprising:

s21, storing drawing information of the plurality of industrial drawings in a mode of an adjacent matrix or an adjacent table; the drawing information comprises at least one of node number, node position and connection information.

In an alternative embodiment, the S30 includes: and acquiring the link connection relations among the directed graphs and the undirected graphs corresponding to the industrial drawings respectively through depth-first search, and establishing a full-link connection graph of each node according to the link connection relations.

In an alternative embodiment, before the step of obtaining the link connection relationship of each of the nodes through depth-first search, the method further includes: setting a search stopping symbol according to the acquired search instruction; the pause search symbol is used for setting a pause position when the depth-first search executes search work.

The invention also constructs an industrial drawing element full-link deduction system, which comprises:

the acquisition unit is used for identifying element information on a plurality of industrial drawing pages in the drawing database; the element information comprises a plurality of elements, a plurality of element contents corresponding to each element and connection information among the elements;

the first composition unit is used for taking each element as a node and constructing a corresponding directed/undirected graph according to the element information of each industrial drawing;

the second composition unit is used for establishing a full-link connection diagram of each node according to the directed/undirected diagrams respectively corresponding to the plurality of industrial drawings;

and the chain diagram output unit is used for outputting the full-chain connection diagram of each node.

In an alternative embodiment, the industrial drawing element full link deduction system further includes: the man-machine interaction unit is used for receiving a node operation instruction input by a user so as to execute setting display work according to the operation instruction; wherein the setting display operation includes: displaying at least one of a prompt and display operation frame of each industrial drawing associated with the corresponding node, custom arranging the corresponding node, displaying a link between the selected nodes and displaying element content of the corresponding node.

By implementing the technical scheme of the invention, the element information on a plurality of industrial drawing pages in the drawing database is identified; then, each element is used as a node, and a corresponding directed/undirected graph is constructed according to the element information of each industrial drawing; then, establishing a full-link connection diagram of each node according to the directed/undirected diagrams respectively corresponding to the plurality of industrial drawings; and finally, outputting the full-link connection diagram of each node, so that a user can pointedly and quickly find out the connection relation of the related nodes through the full-link connection diagram, search work in massive drawings is not needed by relying on manpower, the workload and time required by the user to find out the drawings are obviously reduced, and the search error rate is favorable for improving the efficiency of fault analysis work.

Drawings

The invention will be further described with reference to the accompanying drawings and examples, in which:

FIG. 1 is a flow chart of an industrial drawing element full link deduction method according to some embodiments of the invention;

fig. 2 is a schematic diagram of an industrial drawing element full-link deduction system according to some embodiments of the present invention.

Detailed Description

For a clearer understanding of technical features, objects and effects of the present invention, a detailed description of embodiments of the present invention will be made with reference to the accompanying drawings.

It should be noted that the flow diagrams depicted in the figures are merely exemplary and do not necessarily include all of the elements and operations/steps, nor are they necessarily performed in the order described. For example, some operations/steps may be decomposed, and some operations/steps may be combined or partially combined, so that the order of actual execution may be changed according to actual situations.

The block diagrams depicted in the figures are merely functional entities and do not necessarily correspond to physically separate entities. That is, the functional entities may be implemented in software, or in one or more hardware modules or integrated circuits, or in different networks and/or processor devices and/or microcontroller devices.

Referring to fig. 1, a flow chart of an industrial drawing element full-link deduction method in some embodiments of the present invention is shown, and the deduction method in this embodiment is applied to a control module of an industrial drawing management system, so that a user can quickly query a connection relationship between corresponding industrial drawings according to requirements, and work efficiency is improved. The industrial drawing element full-link deduction method comprises the steps of S10, S20, S30 and S40.

The step S10 includes: identifying element information on a plurality of industrial drawing pages in a drawing database; the element information comprises a plurality of elements, a plurality of element contents corresponding to each element and connection information among the elements.

By implementing the step, the element information on each industrial drawing page can be converted into data which can be identified by a computer, so that preparation is made for the intelligent processing of the subsequent step.

In some embodiments, the industrial drawing may include at least one of an electrical wiring diagram, an electrical schematic diagram, a logic diagram, and a simulation diagram. The elements may include at least one of legends, text, and signal retrieval labels. The legend can be a component in an industrial drawing, such as an electronic component in an electrical wiring diagram or an electrical schematic diagram, a logic symbol in a logic diagram, and the like. The text comprises the element annotation description and the element name on the page, so that the element content corresponding to the corresponding element can be acquired through the text, wherein the element content comprises the function description, the setting value data and the like of the corresponding element. The signal retrieval label is used to indicate the connection relationship between legends in each industrial drawing, so that the connection information between each element can be identified by the signal retrieval label.

In some embodiments, the connection information between elements includes reachability relationships between elements. Wherein the reachability relationship includes non-reachability and reachability. If the two elements are not reachable, it is indicated that the transmission direction between the two elements is unidirectional, that is, in the two elements, if the element a can transmit a signal to the element B, the element B cannot transmit a signal to the element a; if two elements are reachable, it is indicated that the transmission direction between the two elements is bi-directional, i.e. the two elements can transmit signals to each other.

In some embodiments, the element information on each industrial drawing page in the drawing database may be identified by: element information on each industrial drawing page in the drawing database is obtained through OCR text recognition technology or NLP technology.

Step S20 includes: and taking each element as a node, and constructing a corresponding directed/undirected graph according to the element information of each industrial drawing.

In the step, each element is used as a node without physical meaning, and a mapping relation is established between each node and a corresponding element and between each node and the content of the element corresponding to the element, so that each node and the corresponding element form a corresponding relation, a computer can take the node as a processing object of the corresponding element, and further a directed/undirected graph of each industrial drawing can be formed according to the node and the element information, so that preparation is made for constructing a full-link connection graph in the subsequent step. In addition, when the directed/undirected graph is constructed, the directional attribute of the directed graph may be determined according to the reachability relationship among the elements.

In some embodiments, after step S20, further comprising: s21, storing drawing information of a plurality of industrial drawings in a mode of an adjacent matrix or an adjacent table; the drawing information comprises at least one of node number, node position and connection information.

In the step, the drawing information is stored in a mode of an adjacency matrix or an adjacency list, so that the storage structure of the drawing information can be simplified, the computer can conveniently read, and the positive effect of improving the operation efficiency is achieved. For the selection of the adjacency matrix and the adjacency table, the adjacency matrix and the adjacency table can be determined according to the structural complexity degree of the drawing information, for example, the adjacency matrix is suitable for storing the situation that the number of the interconnection lines between the nodes in the directed/undirected graph is large, and the adjacency table is suitable for storing the situation that the number of the interconnection lines between the nodes in the directed/undirected graph is small.

Step S30 includes: and establishing a full-link connection diagram of each node according to the directed/undirected diagrams respectively corresponding to the plurality of industrial drawings.

Further, in a specific embodiment, step S30 includes: and acquiring the link connection relation between the directed graphs and the undirected graphs corresponding to the industrial drawings respectively through depth-first search, and establishing a full-link connection diagram of each node according to the link connection relation.

In this embodiment, the depth-first search may search for other nodes of each node on all branches (not limited to the same industrial drawing) with each node as a starting point and according to connection attributes contained in the directed/undirected graph of each industrial drawing, thereby determining connection relations of each node with all other nodes directly and indirectly connected thereto in a plurality of industrial drawings, and thus establishing a full-link connection graph of each node. It should be noted that although some nodes are distributed on different industrial drawings, direct or indirect connection exists between the nodes, and some nodes may not have direct or indirect connection even on the same industrial drawing, so that a user cannot quickly find out an association relationship existing between the nodes in a traditional industrial drawing, and the full-link connection diagram uses each node as an object, so that direct or indirect connection relationships and signal transmission directions between the corresponding nodes and other nodes are listed one by one.

In some embodiments, before the step of obtaining the link connection relationship of each node by the depth-first search, further comprising: and setting a search stopping symbol according to the acquired search instruction. Wherein the pause search symbol is used for setting a pause position when the depth-first search performs a search job. That is, when the search suspending symbol on a certain branch is searched, the next node continuing the search suspending symbol is stopped and returns to the last branch to continue searching for other branches, so that the user can purposefully set the search range of the depth-first search by inputting the search instruction to reduce the workload of the depth-first search, thereby more rapidly searching the relevant node information required by the work.

Step S40 includes: and outputting a full-link connection diagram of each node.

In a specific embodiment, step S40 includes: and receiving an element operation instruction input by a user, and outputting a full-link connection diagram of the corresponding node. The element operation instruction can be issued in the following way: inputting a specified code, setting a shortcut key, clicking an element with a mouse, and the like.

Compared with the traditional paper query mode, the user can pointedly and quickly find out the connection relation of the related nodes through the full-link connection graph, does not need to rely on manpower to search in massive drawings, obviously reduces the workload and time required by the user to search the drawings and the retrieval error rate, and is beneficial to improving the efficiency of fault analysis work.

In some embodiments, the user may input a setup display instruction to display the full link connection graph of the corresponding node. Wherein, the setting display instruction can be issued by the following modes: inputting a specified code, setting a shortcut key, clicking a node with a mouse, and the like.

In some embodiments, the industrial drawing element full link deduction method further comprises: s50, receiving a node operation instruction input by a user, and executing setting display work according to the operation instruction; wherein, the setting display work includes: displaying at least one of prompts and operation frames of each industrial drawing associated with the corresponding node, custom arranging the corresponding node, displaying links among the selected nodes and displaying element contents of the corresponding node.

In some embodiments, the operating instructions may be entered through a keyboard, mouse, keys, or other form of touch screen. In one embodiment, when the user moves the mouse to the position of the relevant node or element, the prompt of the node or element is displayed and the operation frame is displayed; a certain node can be selected and pulled through a mouse so as to customize the arrangement position of the node; a set-up key-in combination (e.g., ctrl/shift/alt + mouse selection, etc.) can be entered while multiple nodes are selected, so that links between the selected nodes can be highlighted for convenient viewing by the user.

In some embodiments, after step S50, further comprising: rearranging all nodes in the full-link connection diagram to be displayed according to a set arrangement rule by a topology ordering algorithm; wherein, setting the arrangement rule includes arranging from left to right or from top to bottom according to the signal flow direction of each node. In the embodiment, the arrangement of the full-link connection diagrams can be more orderly and reasonable, and a user can conveniently watch the related connection relation of the nodes.

In some embodiments, the prompt and display operation box is used for displaying the drawing number of the corresponding industrial drawing and/or the setting description content corresponding to the corresponding industrial drawing. The setting description content comprises a function brief description, a history fault record and the like corresponding to the corresponding industrial drawing. Further, the industrial drawing element full-link deduction method further comprises the following steps: s60, displaying corresponding industrial drawings according to the operation instructions for prompting and displaying the operation frames.

In the embodiment, the operation instruction for prompting and displaying the operation frame can be issued in a mode of clicking a mouse or inputting a setting instruction and the like, and the display prompting and displaying the operation frame can help a user to quickly understand basic information corresponding to related industrial drawings where the node is located, so that the user can conveniently and quickly push out the industrial drawings related to the fault according to the fault type, the user can quickly open the corresponding industrial drawings, the time required by the user to search the drawings is further reduced, and the fault analysis efficiency is improved.

As shown in fig. 2, the present invention further provides an industrial drawing element full-link deduction system, which includes:

an acquisition unit 1 for identifying element information on a plurality of industrial drawing pages in a drawing database; the element information comprises a plurality of elements, a plurality of element contents corresponding to each element and connection information among the elements;

the first composition unit 2 is used for taking each element as a node and constructing a corresponding directed/undirected graph according to the element information of each industrial drawing;

a second composition unit 3, configured to establish a full-link connection graph of each node according to the directed/undirected graphs respectively corresponding to the multiple industrial drawings;

and a composition output unit 4 for outputting the full link connection graph of each node.

In some embodiments, the industrial drawing element full link deduction system further comprises: the man-machine interaction unit 5 is used for receiving a node operation instruction input by a user so as to execute setting display work according to the operation instruction; wherein, the setting display work includes: displaying at least one of prompts and operation frames of each industrial drawing associated with the corresponding node, custom arranging the corresponding node, displaying links among the selected nodes and displaying element contents of the corresponding node.

In some embodiments, the man-machine interaction unit 5 is further configured to input an operation instruction for prompting and displaying an operation frame, a node operation instruction, a setting display instruction, and a search instruction.

In the present specification, each embodiment is described in a progressive manner, and each embodiment is mainly described in a different point from other embodiments, and identical and similar parts between the embodiments are all enough to refer to each other. For the device disclosed in the embodiment, since it corresponds to the method disclosed in the embodiment, the description is relatively simple, and the relevant points refer to the description of the method section.

Those of skill would further appreciate that the various illustrative elements and algorithm steps described in connection with the embodiments disclosed herein may be implemented as electronic hardware, computer software, or combinations of both, and that the various illustrative elements and steps are described above generally in terms of functionality in order to clearly illustrate the interchangeability of hardware and software. Whether such functionality is implemented as hardware or software depends upon the particular application and design constraints imposed on the solution. Skilled artisans may implement the described functionality in varying ways for each particular application, but such implementation decisions should not be interpreted as causing a departure from the scope of the present invention.

The steps of a method or algorithm described in connection with the embodiments disclosed herein may be embodied directly in hardware, in a software module executed by a processor, or in a combination of the two. The software modules may be disposed in Random Access Memory (RAM), memory, read Only Memory (ROM), electrically programmable ROM, electrically erasable programmable ROM, registers, hard disk, a removable disk, a CD-ROM, or any other form of storage medium known in the art.

It is to be understood that the above examples only represent preferred embodiments of the present invention, which are described in more detail and are not to be construed as limiting the scope of the invention; it should be noted that, for a person skilled in the art, the above technical features can be freely combined, and several variations and modifications can be made without departing from the scope of the invention; therefore, all changes and modifications that come within the meaning and range of equivalency of the claims are to be embraced within their scope.

Claims (10)

1. The industrial drawing element full-link deduction method is characterized by comprising the following steps of:

s10, identifying element information on a plurality of industrial drawing pages in a drawing database; the element information comprises a plurality of elements, a plurality of element contents corresponding to each element and connection information among the elements;

s20, taking each element as a node, and constructing a corresponding directed/undirected graph according to the element information of each industrial drawing;

s30, establishing a full-link connection diagram of each node according to the directed/undirected diagrams respectively corresponding to the plurality of industrial drawings;

and S40, outputting a full-link connection diagram of each node.

2. The industrial drawing element full link deduction method according to claim 1, further comprising:

s50, receiving a node operation instruction input by a user, and executing setting display work according to the operation instruction; wherein the setting display operation includes: displaying at least one of a prompt and display operation frame of each industrial drawing associated with the corresponding node, custom arranging the corresponding node, displaying a link between the selected nodes and displaying element content of the corresponding node.

3. The method for full link deduction of an industrial drawing element according to claim 2, further comprising, after step S50:

rearranging the nodes in the full-link connection graph to be displayed according to a set arrangement rule by a topology ordering algorithm; the arrangement rule comprises arrangement from left to right or from top to bottom according to the signal flow direction of each node.

4. The method for deducing the full link of the elements of the industrial drawing according to claim 2, wherein the prompt and display operation box is used for displaying the figure number of the corresponding industrial drawing and/or the setting description content corresponding to the corresponding industrial drawing;

the industrial drawing element full-link deduction method further comprises the following steps:

and S60, displaying the corresponding industrial drawing according to the operation instruction of the prompt and display operation frame.

5. The method according to claim 1, wherein in step S10, the identifying element information on each industrial drawing page in the drawing database includes:

element information on each industrial drawing page in the drawing database is obtained through OCR text recognition technology or NLP technology.

6. The method for full link deduction of an industrial drawing element according to claim 1, further comprising, after step S20:

s21, storing drawing information of the plurality of industrial drawings in a mode of an adjacent matrix or an adjacent table; the drawing information comprises at least one of node number, node position and connection information.

7. The industrial drawing element full link deduction method according to claim 1, wherein the step S30 includes: and acquiring the link connection relations among the directed graphs and the undirected graphs corresponding to the industrial drawings respectively through depth-first search, and establishing a full-link connection graph of each node according to the link connection relations.

8. The method for performing full link deduction on industrial drawing elements according to claim 7, further comprising, before the step of obtaining the link connection relationship of each of the nodes by depth-first search: setting a search stopping symbol according to the acquired search instruction; the pause search symbol is used for setting a pause position when the depth-first search executes search work.

9. An industrial drawing element full-link deduction system, comprising:

the acquisition unit is used for identifying element information on a plurality of industrial drawing pages in the drawing database; the element information comprises a plurality of elements, a plurality of element contents corresponding to each element and connection information among the elements;

the first composition unit is used for taking each element as a node and constructing a corresponding directed/undirected graph according to the element information of each industrial drawing;

the second composition unit is used for establishing a full-link connection diagram of each node according to the directed/undirected diagrams respectively corresponding to the plurality of industrial drawings;

and the chain diagram output unit is used for outputting the full-chain connection diagram of each node.

10. The industrial drawing element full link deduction system according to claim 9, further comprising: the man-machine interaction unit is used for receiving a node operation instruction input by a user so as to execute setting display work according to the operation instruction; wherein the setting display operation includes: displaying at least one of a prompt and display operation frame of each industrial drawing associated with the corresponding node, custom arranging the corresponding node, displaying a link between the selected nodes and displaying element content of the corresponding node.