CN111241644B - Reinforcing bar information generation method and device based on board drawing and computer storage medium - Google Patents

Reinforcing bar information generation method and device based on board drawing and computer storage medium Download PDF

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CN111241644B
CN111241644B CN201911415464.8A CN201911415464A CN111241644B CN 111241644 B CN111241644 B CN 111241644B CN 201911415464 A CN201911415464 A CN 201911415464A CN 111241644 B CN111241644 B CN 111241644B
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information
plate
negative
bar
graph
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CN111241644A (en
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龙飞宇
唐伟超
范高杰
陈琪宏
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Shenzhen Huayang International Engineering Design Co ltd
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Shenzhen Huayang International Engineering Design Co ltd
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Abstract

The invention discloses a method and a device for generating reinforcement information based on a board drawing and a computer storage medium, wherein the method comprises the following steps: diameter information and interval information of plate ribs of a small plate graph are obtained; determining the arrangement direction of the plate ribs in the small plate graph according to the side information of the small plate graph; acquiring diameter information and interval information of negative ribs of a platelet pattern; determining the extension information of the negative ribs according to the short span information of the small plate graph and the adjacent small plate graph; generating plate rib information on the small plate graph according to the diameter information, the interval information and the arrangement direction of the plate ribs; and generating negative rib information on the small plate graph and the adjacent small plate graph according to the diameter information, the interval information and the extension information of the negative ribs. By the method, the plate bar information and the negative bar information can be quickly generated on the small plate graph, and the rapid bar arrangement of the plate drawing is realized.

Description

Reinforcing bar information generation method and device based on board drawing and computer storage medium
Technical Field
The invention relates to the field of automatic reinforcement, in particular to a method and a device for generating reinforcement information based on a board drawing and a computer storage medium.
Background
After the structural drawings of the panels are completed, it is necessary to create reinforcing bar members on each panel of the structural drawings by a designer and to guide the drawings into a construction drawing. On the one hand, the large number of plates of the structural drawing leads to large workload of the whole designer, and on the other hand, the large number of the reinforcing steel bar members leads to paper jam or even running of the whole structural drawing, so that the whole reinforcing steel bar arrangement efficiency is extremely low.
Disclosure of Invention
The invention provides a method and a device for generating reinforcement information based on a board drawing and a computer storage medium, which are used for solving the problem of low reinforcement efficiency of a board drawing structure drawing in the prior art.
In order to solve the technical problems, the invention adopts a technical scheme that: the automatic reinforcement method based on the board drawing comprises the following steps: diameter information and interval information of plate ribs of a small plate graph are obtained; determining the arrangement direction of the plate ribs in the small plate graph according to the side information of the small plate graph; acquiring diameter information and interval information of the negative ribs of the platelet pattern; determining the extension information of the negative ribs according to the short span information of the small plate graph and the short span information of the adjacent small plate graph; generating plate rib information on the small plate graph according to the diameter information, the interval information and the arrangement direction of the plate ribs; and generating negative rib information on the small plate graph and the adjacent small plate graph according to the diameter information, the interval information and the extension information of the negative ribs.
In order to solve the technical problems, the invention adopts another technical scheme that: the device for generating the reinforcing bar information based on the board drawing comprises a processor and a memory; the memory has stored therein a computer program for execution by the processor to perform the steps of the method of any of the above.
In order to solve the above technical problem, another technical solution adopted by the present invention is to provide a computer storage medium, in which a computer program is stored, and the computer program is executed to implement the steps of the reinforcement information generating method based on the board drawing.
Compared with the prior art, the method and the device have the advantages that the diameter information and the interval information of the plate ribs of the small plate patterns are obtained, the arrangement direction of the plate ribs is determined according to the side information of the small plate patterns, and the plate rib information is generated on the small plate patterns according to the diameter information, the interval information and the arrangement direction of the plate ribs; the method comprises the steps of obtaining diameter information and interval information of reinforcing bars of a small plate pattern, determining extension information of negative bars according to short span information of the small plate pattern and adjacent small plate patterns, and generating negative bar information on the small plate pattern and the adjacent small plate patterns according to the diameter information and the interval information of the negative bars and the extension information. Therefore, reinforcement information such as reinforcement information, negative reinforcement information and the like can be rapidly generated on the small plate graph, and automatic reinforcement of the small plate graph is realized. And the automatic reinforcement is carried out through each small plate graph in the large plate graph, so that the automatic reinforcement of the large plate graph is realized.
Drawings
In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings required for the description of the embodiments will be briefly described below, and it is apparent that the drawings in the following description are only some embodiments of the present invention, and other drawings may be obtained according to these drawings without inventive effort to those of ordinary skill in the art.
FIG. 1 is a schematic flow chart of a first embodiment of a reinforcement information generation method based on a board drawing;
FIG. 2 is a schematic flow chart of a second embodiment of the reinforcement information generation method based on a board drawing;
FIG. 3 is a schematic flow chart of the substeps of step S11 in FIG. 1;
FIG. 4 is a schematic flow chart of the substeps of step S12 in FIG. 1;
FIG. 5 is a schematic flow chart of the substeps of step S13 in FIG. 1;
FIG. 6 is a schematic flow chart of the substeps of step S14 in FIG. 1;
FIG. 7 is a schematic flow chart of a third embodiment of a reinforcement information generation method based on a board drawing;
FIG. 8 is a schematic diagram of a specific scene of a large panel graphic provided by the present invention;
FIG. 9 is a schematic diagram of a specific scene of a small and medium panel graphic F in the large panel graphic of FIG. 8;
FIG. 10 is a schematic diagram showing the arrangement of negative bar information of the small and medium plate patterns H and G in the large plate pattern shown in FIG. 8;
fig. 11 is a schematic structural view of a first embodiment of the reinforcing bar information generating apparatus based on a board drawing of the present invention;
FIG. 12 is a schematic diagram of a computer storage medium according to an embodiment of the present invention.
Detailed Description
The following description of the embodiments of the present invention will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.
For a building model, the main structural members generally include beam members, wall members, column members, and plate members, where the plate members include large plates and small plates, where the small plates can be considered to cover only a minimum closed area surrounded by the beam members, wall members, and column members, and the large plates can cover multiple closed areas surrounded by the beam members, wall members, and column members. And the large plate can be split into a plurality of small plates with the same elevation, the plate members are connected with the beam members and/or the wall members and/or the column members, so that when the building model is mapped on a two-dimensional drawing sheet to form a small plate pattern or a large plate pattern, the beam members and the wall members form lines, the column members form points, the plate members form surfaces, and the surfaces formed by the small plates or the large plates are enclosed by the lines formed by the beam members and the wall members and the points formed by the column members.
Referring specifically to fig. 1, fig. 1 is a flowchart of a first embodiment of a method for generating reinforcing bar information based on a board drawing according to the present invention, where the method for generating reinforcing bar information based on a board drawing includes the following steps:
s11, diameter information and interval information of the plate ribs of the small plate pattern are obtained.
Diameter information and interval information of the plate ribs of the platelet pattern are acquired, and in particular, the platelet pattern may be a two-dimensional plane-based pattern surrounded by boundary lines and/or boundary points formed by beam members and/or column members and/or wall members.
In a specific scenario, the plate ribs are arranged in the small plate for strengthening the strength of the whole small plate, and a plurality of plate ribs are arranged in the small plate along the arrangement direction, optionally, the diameter information is the diameter value of the arranged plate ribs, and the interval information is the interval value between adjacent plate ribs arranged along the same direction.
Specifically, referring to fig. 2, fig. 2 is a flowchart of a second embodiment of the method for generating reinforcing bar information based on a board drawing of the present invention, which is a step before step S11, specifically includes the following steps:
s21, acquiring a large plate graph.
In the process of designing a building model, particularly in the process of designing a BIM (Building Information Modeling, information building model) model, the building model can be built through software such as revit, and then a construction drawing can be obtained based on the building model.
Taking building models of buildings as examples, main structural members of the buildings comprise wall members, beam members and column members, then plate members are further arranged between floors, the plate members comprise large plates and small plates, in a specific scene, the building models form plate drawings on two-dimensional planes, large plate patterns are included in the plate drawings, and reinforcement information is added to the small plate patterns in the large plate patterns so as to generate construction drawings.
In a specific embodiment, when drawing a panel member, a large panel is generally drawn directly at the same elevation position, so that when drawing the large panel member, a whole large panel pattern is first derived, the large panel pattern is also based on two dimensions, and the large panel pattern is surrounded by boundary lines and/or boundary points formed by beam members and/or column members and/or wall members, optionally, the beam members and the wall members form boundary lines when forming the large panel pattern, and the column members form boundary points when forming the large panel pattern. And for a large panel graphic, a plurality of or a plurality of regular or irregular boundary lines and/or boundary points are included.
S22, taking the boundary line formed by the beam member and/or the column member and/or the wall member as a split boundary line.
In a specific embodiment, the reinforcement of the panel is based on each small panel, so that the large panel pattern needs to be split first, and in particular, the boundary line and/or the boundary point formed by the beam member and/or the column member and/or the wall member can be used as the split boundary line.
S23, splitting the large plate pattern into a plurality of small plate patterns according to the minimum closed pattern formed by encircling the splitting boundary line.
And then splitting the large plate pattern into a plurality of small plate patterns according to the minimum closed pattern formed by encircling the splitting boundary line. I.e. as a platelet pattern for each minimum closed pattern surrounded by split boundary lines.
As shown in fig. 8, the large plate pattern is surrounded by boundary lines formed by the plurality of beam members and the plurality of column members and the plurality of wall members. After the large plate pattern is split by the minimum closed pattern formed by encircling the bisection boundary line, a plurality of small plate patterns such as a small plate pattern A, a small plate pattern B, a small plate pattern C, a small plate pattern D, a small plate pattern E, a small plate pattern F, a small plate pattern G, a small plate pattern H and the like can be obtained. And each small plate graph is a minimum closed graph formed by encircling split boundary lines. And the platelet pattern may be any regular or irregular polygon, and the sides may be straight lines or arcs, which are not limited herein.
In fig. 8, only boundary points formed by boundary lines formed by beam members and wall members and column members are schematically indicated, and other boundary lines in fig. 8 correspond to corresponding beam members or wall members, and accordingly, other boundary points may correspond to corresponding column members or connection positions of beam members and wall members, which are not limited herein.
In other embodiments, the beam members, column members, and wall members may be represented in other forms, such as solid lines, double solid lines, dashed lines, double dashed lines, etc., in either a large panel pattern or a small panel pattern, without limitation.
Referring to fig. 3, fig. 3 is a schematic flow chart of the substeps of step S11 in fig. 1, which specifically includes the following steps:
s111, obtaining the reinforcement area of the plate reinforcement of the small plate graph.
Specifically, the reinforcement area of the plate reinforcement of the small plate graph can be obtained, the reinforcement area of the plate reinforcement is specifically obtained by performing simulation data processing on the building model, and the reinforcement area of the plate reinforcement of each small plate needs to meet the requirements of supporting strength and the like.
S112, diameter information and interval information meeting the reinforcement area of the plate reinforcement are obtained from a preset reinforcement database according to the reinforcement area of the plate reinforcement.
And acquiring diameter information and interval information meeting the reinforcement area of the plate reinforcement from a preset reinforcement database, wherein the preset reinforcement database comprises a plurality of groups of combinations consisting of the diameter information, the interval information and the reinforcement area of the plate reinforcement, namely, each combination comprises one piece of the diameter information, the interval information and the reinforcement area, acquiring the combination with the reinforcement area larger than the reinforcement area of the plate reinforcement from the preset reinforcement database, and acquiring the diameter information and the interval information of the combination to be used as the diameter information and the interval information of the plate reinforcement.
In a specific scenario, there may be multiple groups of combinations meeting the requirements, and then the multiple groups of combinations may be displayed so as to be convenient for selection by a user, and the final combination is determined according to selection information of the user.
In another embodiment, the diameter information and the interval information of the input plate bars can also be directly received. The diameter information and the interval information of the plate bar directly input by the user are obtained.
S12, determining the arrangement direction of the plate ribs in the small plate patterns according to the side information of the small plate patterns.
Subsequently, the arrangement direction of the panel ribs in the panel pattern is determined based on the side information of the panel pattern. Specifically, the edges of the platelet pattern are boundary lines formed by the beam members and/or the column members and/or the wall members, and the vertices of the platelet pattern are intersection points of boundary lines formed by the beam members and/or the wall members or boundary points formed by the column members.
Referring specifically to fig. 4, fig. 4 is a schematic flow chart of the substeps of step S12 in fig. 1, which specifically includes the following steps:
s121, obtaining the side length of each side of the small plate graph.
The edge length of each side in the platelet pattern is obtained, in particular, the drawing edge length can be determined by directly measuring each side in the platelet pattern, or the length information can be directly derived from the information in the beam member and/or the column member and/or the wall member.
As shown in fig. 9, the panel pattern F includes four sides, which are a side ab, a side bc, a side cd, and a side ad, respectively. The edge lengths of the edge ab, the edge bc, the edge cd, and the edge ad are then obtained.
S122, taking the side with the largest side length as a long side, taking the length of the long side as long span information, taking the distance between the vertex farthest from the long side in the platelet graph and the long side as a short side, and taking the length of the short side as short span information.
And then taking the side with the largest side length as a long side, taking the length of the long side as long span information, taking the distance between the vertex farthest from the long side in the small plate graph and the long side as a short side, and taking the length of the short side as short span information.
That is, referring to fig. 9, for example, if the side length of the side ab is maximum, the side ab is taken as a long side, the length of the side ab is taken as long span information, the vertex farthest from the side ab in the platelet pattern F, that is, the distance between the vertex d and the side ab is taken as a short side, and the length of the short side is taken as short span information.
Specifically, the short side and the long side are perpendicular to each other.
S123, the direction parallel to the long side and the direction parallel to the short side are taken as the arrangement direction of the panel ribs.
The direction parallel to the long side and the direction parallel to the short side are taken as the arrangement direction of the panel bars. Specifically, the arrangement direction includes two directions perpendicular to each other, and the two directions are parallel to the long side and the short side, respectively.
S13, acquiring diameter information and interval information of negative ribs of the platelet pattern.
And acquiring diameter information and interval information of the negative ribs of the platelet pattern.
In a specific scene, the negative ribs are arranged on the small plates and the adjacent small plates, and as the connection strength between the adjacent small plates is enhanced, the negative ribs are particularly arranged along the connecting line direction of the adjacent small plates, the diameter information is the diameter value of the arranged negative ribs, and the interval information is the interval value between the adjacent negative ribs arranged on the same side.
In a specific scenario, the platelets are separated from the adjacent platelets by wall members or beam members, and the negative ribs can be actually considered to be led out from the wall members or beam members common to the platelets and the adjacent platelets, and embedded in the two platelets, so as to strengthen the connection strength of the adjacent platelets and the wall members or beam members. If a certain wall member or beam member of a panel is not connected to other panels, the negative ribs are led out from the wall member or beam member and embedded in the panel to strengthen the connection strength of the wall member or beam member to the panel.
Referring specifically to fig. 5, fig. 5 is a schematic flow chart of the substeps of step S13 in fig. 1, which specifically includes the following steps:
s131, obtaining the negative reinforcement area of the small plate graph.
Similar to step S111, the negative reinforcement area of the platelet pattern may be obtained, which is specifically obtained by performing simulation data processing on the building model, where the negative reinforcement area of each platelet pattern needs to meet the requirements of connection strength with an adjacent platelet pattern, and the like.
S132, acquiring diameter information and interval information meeting the reinforcement area of the negative reinforcement from a preset reinforcement database according to the reinforcement area of the negative reinforcement.
Similar to step S112, diameter information and interval information satisfying the reinforcement area of the negative reinforcement are then obtained from a preset reinforcement database, and optionally, the preset reinforcement database includes a plurality of sets of combinations of the diameter information, the interval information and the reinforcement area of the negative reinforcement, that is, each combination includes one piece of the diameter information, the interval information and the reinforcement area, a combination of the reinforcement area larger than the reinforcement area of the negative reinforcement is obtained from the preset reinforcement database, and the diameter information and the interval information of the combination are obtained as the diameter information and the interval information of the negative reinforcement.
In a specific scenario, there may be multiple groups of combinations meeting the requirement, and then the multiple groups of combinations may be displayed so as to be convenient for selection by a user, and the combinations are determined according to selection information of the user.
In another embodiment, the diameter information and the interval information of the negative rib can also be directly received. The diameter information and the interval information of the negative ribs which are directly input by the user are obtained.
S14, determining the extension information of the negative ribs according to the short span information of the small plate patterns and the short span information of the adjacent small plate patterns.
And then determining the extension information of the negative ribs according to the short span information of the small plate patterns and the adjacent small plate patterns. In particular, the negative ribs are arranged on the common side of the adjacent platelet patterns, and the protruding lengths of the negative ribs on the adjacent two platelet patterns respectively need to be determined.
Referring specifically to fig. 6, fig. 6 is a schematic flow chart of the substeps of step S14 in fig. 1, which specifically includes the following steps:
s141, short span information of the platelet graph is obtained.
The short span information of the small panel graph is obtained, specifically, the short span information may be obtained by receiving the short span information input by the user, or may be obtained by calculating in step S122, or may be directly measured from the small panel graph, which is not limited herein.
S142, acquiring short span information of the small plate graph adjacent to the small plate graph.
Similarly, the short span information of the platelet pattern adjacent to the platelet pattern may be obtained by receiving the short span information input by the user, or may be obtained by calculation in step S122, or may be directly measured from the platelet pattern, similar to step S141, which is not limited herein.
S143, determining the extension information of the negative ribs according to the short span information of the small plate pattern and the short span information of the small plate pattern adjacent to the small plate pattern.
And then determining the extension information of the negative ribs according to the short span information of the small plate pattern and the short span information of the small plate pattern adjacent to the small plate pattern. Specifically, the protrusion information of the negative rib includes the protrusion lengths of the negative ribs on the adjacent two of the platelet patterns, respectively, and with continued reference to fig. 8, the protrusion information of the negative ribs disposed on the common side of the platelet pattern F and the platelet pattern E should include the protrusion lengths on the platelet pattern F and the protrusion lengths on the platelet pattern E.
Specifically, if one edge of a platelet pattern is not connected to other platelet patterns, the protrusion information of the negative rib disposed on that edge includes only the protrusion length on that platelet pattern. As shown in fig. 8 and 9, the edge ad of the platelet pattern F is not adjacent to other platelet patterns, and thus the protrusion information of the negative rib disposed on the edge ad includes only the protrusion length on the platelet pattern F. For the side bc, although disposed adjacent to the platelet pattern C, there is no direct connection, i.e., the side bc does not belong to the common side of the platelet pattern F and the platelet pattern C, and therefore the protruding information of the negative rib disposed at the side bc also includes only the protruding length on the platelet pattern F.
Optionally, the determining the extension information of the negative rib on the platelet graph according to the obtained short span information of the platelet graph may specifically multiply the short span information with a preset proportion parameter, and optionally, for example, 1/3 or 1/4, etc., which is not limited herein, and specifically refers to an actual construction rule. In a specific scenario, the extension length corresponding to the extension information should be an integer multiple of 50, so that rounding operation is also required for the extension information.
S15, generating plate rib information on the small plate graph according to the diameter information, the interval information and the arrangement direction of the plate ribs.
Optionally, the plate bar information includes a plate bar icon and a plate bar label. And the plate ribs comprise a top plate rib and a bottom plate rib. The plate bar icons of the top plate bar and the bottom plate bar are different and can be in a line form, and the icons commonly used in the field can be adopted specifically, and are not limited specifically.
Alternatively, the panel bar icons may be arranged on the panel graphic along the arrangement direction first, specifically, the panel bar icons of the top panel bar and the panel bar icons of the bottom panel bar are arranged along the directions of the long side and the short side. And arranging the plate bar labels on the plate bar icons according to the diameter information and the interval information of the plate bars, and then arranging the plate bar labels on the corresponding plate bar icons, wherein the plate bar labels specifically comprise the diameter information and the interval information.
In another alternative embodiment, the plate bar labels can also be generated according to the diameter information and the interval information, the plate bar labels and the plate bar icons are mutually bound, then the plate bar icons are arranged on the small plate graph along the arrangement direction, and the plate bar labels bound with the plate bar icons are also arranged.
And correspondingly, the length of the plate bar icon parallel to the long side is equal to or similar to that of the long side, and the length of the plate bar icon parallel to the short side is equal to or similar to that of the short side.
Optionally, for the top plate rib of the plate ribs, only two plate rib icons, namely, the plate rib icon parallel to the long side and the plate rib icon parallel to the short side, are arranged on the small plate graph, and correspondingly, only two plate rib icons are required to be arranged on the bottom plate rib of the plate ribs.
And optionally, the plate bar label is positioned in the middle area of the corresponding plate bar icon.
S16, generating negative rib information on the small plate graph and the adjacent small plate graph according to the diameter information, the interval information and the extension information of the negative ribs;
optionally, the negative tendon information includes a negative tendon icon and a negative tendon label.
And arranging a negative rib icon on the common edge of the small plate graph and the adjacent small plate graph, wherein the negative rib icon is positioned on the midvertical line of the common edge. Specifically, the negative rib icon may be a line display and located on a midpoint vertical line of the common side. And then arranging negative rib marks on the negative rib icons according to the diameter information and the interval information of the negative ribs and the extension information. Alternatively, the diameter information and the interval information of the negative bars may be arranged in the middle area of the corresponding negative bar icon. The extension length in the small plate graph in the extension information is arranged in the area of the negative rib icon in the small plate graph.
As shown in fig. 8 and 10, the negative rib icon between the platelet pattern G and the platelet pattern H is perpendicular to the common side of the platelet pattern G and the platelet pattern H, the diameter information and the interval information are arranged on the side of the negative rib icon located in the middle area, the protruding length G of the negative rib on the platelet pattern G is arranged on the side of the negative rib icon located in the platelet pattern G, and the protruding length H of the negative rib on the platelet pattern H is arranged on the side of the negative rib icon located in the platelet pattern H.
In an alternative embodiment, reinforcement information such as reinforcement information, negative reinforcement information and the like is generated for each small plate graph in the whole plate drawing in the above mode, and then automatic reinforcement is performed on the whole plate drawing, so that a construction drawing based on the plate drawing is obtained.
In the above embodiment, the arrangement direction of the plate ribs is determined according to the side information of the plate graphics by acquiring the diameter information and the interval information of the plate ribs of the plate graphics, and the plate rib information is generated on the plate graphics according to the diameter information and the interval information of the plate ribs and the arrangement direction; the method comprises the steps of obtaining diameter information and interval information of reinforcing bars of a small plate pattern, determining extension information of negative bars according to short span information of the small plate pattern and adjacent small plate patterns, and generating negative bar information on the small plate pattern and the adjacent small plate patterns according to the diameter information and the interval information of the negative bars and the extension information. Therefore, reinforcement information such as reinforcement information, negative reinforcement information and the like can be rapidly generated on the small plate graph, and automatic reinforcement of the small plate graph is realized. And the automatic reinforcement is carried out through each small plate graph in the large plate graph, so that the automatic reinforcement of the large plate graph is realized.
Referring specifically to fig. 7, fig. 7 is a flowchart of a third embodiment of the method for generating reinforcing bar information based on a board drawing according to the present invention, where the method for generating reinforcing bar information based on a board drawing includes the following steps:
s31, if the plate bar marks of the small plate graph are overlapped with the negative bar marks.
In a specific scene, as the plate bar labels are arranged along the length direction of the plate bar icons, the negative bar labels are arranged along the length direction of the negative bar icons, and as the plate bar labels are multiple, the negative bar labels are also multiple, overlapping is likely to occur among the plate bar labels, between the plate bar labels and the negative bar labels and among the negative bar labels.
S32, the plate bar labels are moved along the length direction of the plate bar icons corresponding to the plate bar labels and/or the negative bar labels are moved along the length direction of the negative bar icons corresponding to the negative bar labels, so that the plate bar labels and the negative bar labels are arranged at intervals.
The plate bar labels can be moved along the length direction of the plate bar icons corresponding to the plate bar labels and/or the negative bar labels can be moved along the length direction of the negative bar icons corresponding to the negative bar labels, so that the plate bar labels and the negative bar labels are arranged at intervals, and the plate bar labels, the plate bar labels and the negative bar labels are arranged at intervals, and the problem of poor readability caused by label overlapping is solved.
The reinforcement information generation method based on the board drawing also comprises the step of associating the board reinforcement information and the negative reinforcement information of the small board graph with the small board graph. The association may be specifically performed by an ID.
Optionally, subsequent data statistics may be facilitated by correlating the platelet information of the platelet pattern with the negative tendon information.
The method comprises the steps of creating a data table corresponding to a whole board drawing, carrying out data display on reinforcement information of each small board graph according to the reinforcement information and the negative reinforcement information of the small board graph, and calculating information such as engineering quantity and manufacturing cost of the reinforcement and the negative reinforcement in each small board and information such as engineering quantity and manufacturing cost of the reinforcement and the negative reinforcement of the whole large board through the reinforcement information and the negative reinforcement information.
The reinforcement information generating method based on the board drawing is generally realized by a reinforcement information generating device based on the board drawing, so the invention also provides a reinforcement information generating device based on the board drawing. Referring to fig. 11, fig. 11 is a schematic structural diagram of an embodiment of a reinforcing bar information generating device based on a board drawing according to the present invention. The reinforcing bar information generating device 100 based on the board drawing of the embodiment comprises a processor 12 and a memory 11; the memory 11 stores a computer program, and the processor 12 is configured to execute the computer program to implement the steps of the reinforcement information generating method based on the board drawing as described above.
The logic process of the reinforcement information generating method based on the board drawing is presented as a computer program, and in terms of the computer program, if the logic process is sold or used as an independent software product, the logic process can be stored in a computer storage medium, so the invention provides a computer storage medium. Referring to fig. 12, fig. 12 is a schematic structural diagram of an embodiment of a computer storage medium of the present invention, in which a computer program 21 is stored in the computer storage medium 200, and when the computer program is executed by a processor, the above-mentioned network allocation method or control method is implemented.
The computer storage medium 200 may be a medium that may store a computer program, such as a usb disk, a removable hard disk, a Read-Only Memory (ROM), a random access Memory (RAM, random Access Memory), a magnetic disk, or an optical disk, or may be a server that stores the computer program, and the server may send the stored computer program to another device for running, or may also run the stored computer program itself. The computer storage medium 200 may be physically combined with a plurality of entities, for example, a plurality of servers, a server plus a memory, or a memory plus a removable hard disk.
In summary, the method and the device have the advantages that the diameter information and the interval information of the plate ribs of the small plate patterns are obtained, the arrangement direction of the plate ribs is determined according to the side information of the small plate patterns, and the plate rib information is generated on the small plate patterns according to the diameter information, the interval information and the arrangement direction of the plate ribs; the method comprises the steps of obtaining diameter information and interval information of reinforcing bars of a small plate pattern, determining extension information of negative bars according to short span information of the small plate pattern and adjacent small plate patterns, and generating negative bar information on the small plate pattern and the adjacent small plate patterns according to the diameter information and the interval information of the negative bars and the extension information. Therefore, reinforcement information such as reinforcement information, negative reinforcement information and the like can be rapidly generated on the small plate graph, and automatic reinforcement of the small plate graph is realized. And the automatic reinforcement is carried out through each small plate graph in the large plate graph, so that the automatic reinforcement of the large plate graph is realized. And the plate bar label and the negative bar label of the small plate graph are moved, so that the plate bar label and the negative bar label can be prevented from being overlapped, and further, the plate bar information and the negative bar information of each small plate are bound with the small plate, so that the automatic calculation and statistics of subsequent data are facilitated.
The foregoing description is only of embodiments of the present invention, and is not intended to limit the scope of the invention, and all equivalent structures or equivalent processes using the descriptions and the drawings of the present invention or directly or indirectly applied to other related technical fields are included in the scope of the present invention.

Claims (11)

1. An automatic reinforcement method based on a board drawing is characterized by comprising the following steps:
diameter information and interval information of plate bars of a small plate graph are obtained, wherein the diameter information and the interval information meeting the plate bar arrangement area are obtained from a preset bar arrangement database according to the plate bar arrangement area of the small plate graph;
determining the arrangement direction of the plate ribs in the small plate graph according to the side information of the small plate graph;
acquiring diameter information and interval information of the negative reinforcement of the small plate graph, wherein the diameter information and the interval information meeting the negative reinforcement area are acquired from the preset reinforcement database according to the negative reinforcement area of the small plate graph;
determining the extension information of the negative ribs according to the short span information of the small plate graph and the short span information of the adjacent small plate graph;
generating plate rib information on the small plate graph according to the diameter information, the interval information and the arrangement direction of the plate ribs;
and generating negative rib information on the small plate graph and the adjacent small plate graph according to the diameter information, the interval information and the extension information of the negative ribs.
2. The method of claim 1, wherein the step of obtaining diameter information and spacing information of the ribs of the platelet pattern is preceded by the step of obtaining the diameter information and the spacing information of the ribs of the platelet pattern; comprising the following steps:
acquiring a large plate pattern, wherein the large plate pattern is formed by enclosing boundary lines and/or boundary points formed by beam members and/or column members and/or wall members;
taking boundary lines and/or boundary points formed by the beam members and/or the column members and/or the wall members as split boundary lines;
and splitting the large plate pattern into a plurality of small plate patterns according to the minimum closed pattern formed by encircling the splitting boundary line.
3. The method according to claim 1, wherein the step of determining the arrangement direction of the ribs in the platelet pattern from the side information of the platelet pattern includes:
acquiring the side length of each side of the small plate graph;
taking the side with the largest side length as a long side, taking the length of the long side as long span information, taking the distance between the vertex farthest from the long side in the small plate graph and the long side as a short side, and taking the length of the short side as short span information;
the direction parallel to the long side and the direction parallel to the short side are taken as the arrangement direction of the plate ribs.
4. The method of claim 1, wherein the step of determining the protrusion information of the negative tendon from the short span information of the platelet pattern and the adjacent platelet pattern comprises:
acquiring short span information of the platelet graph;
acquiring short span information of the small plate graph adjacent to the small plate graph;
and determining the negative rib extension information according to the obtained short span information of the small plate graph and the short span information of the small plate graph adjacent to the small plate graph.
5. The method of claim 1, wherein the panel bar information includes a panel bar icon and a panel bar label, and wherein the step of generating panel bar information on the panel graphic based on the diameter information and the interval information of the panel bar and the arrangement direction includes:
and arranging the plate bar icons on the small plate graph along the arrangement direction, and arranging the plate bar marks on the plate bar icons according to the diameter information and the interval information of the plate bars.
6. The method of claim 5, wherein the negative bar information comprises a negative bar icon and a negative bar label, and wherein the step of generating negative bar information on the platelet pattern and the adjacent platelet pattern based on the diameter information and the interval information and the extension information of the negative bar comprises:
and arranging the negative rib icons on the public sides of the small plate graph and the adjacent small plate graph, wherein the negative rib icons are positioned on the midvertical line of the public sides, and arranging the negative rib marks on the negative rib icons according to the diameter information, the interval information and the extension information of the negative ribs.
7. The method of claim 6, wherein the method further comprises:
if the plate bar label of the small plate graph is overlapped with the negative bar label;
and moving the plate bar label along the length direction of the plate bar icon corresponding to the plate bar label and/or moving the negative bar label along the length direction of the negative bar icon corresponding to the negative bar label, so that the plate bar label and the negative bar label are arranged at intervals.
8. The method according to claim 1, wherein the method further comprises:
and correlating all the plate tendon information and the negative tendon information of the small plate graph with the small plate graph.
9. The method of claim 1, wherein the panel ribs comprise a top panel rib and a bottom panel rib.
10. The automatic reinforcement device based on the board drawing is characterized by comprising a processor and a memory; the memory having stored therein a computer program, the processor being adapted to execute the computer program to carry out the steps of the method according to any of claims 1-9.
11. A computer storage medium, characterized in that the computer storage medium stores a computer program which, when executed, implements the steps of the method according to any of claims 1-9.
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