CN111881805B

CN111881805B - Method and device for identifying reinforcement distribution range and electronic equipment

Info

Publication number: CN111881805B
Application number: CN202010712124.8A
Authority: CN
Inventors: 田思源; 王忠家; 焦成杰; 侯博超
Original assignee: Glodon Co Ltd
Current assignee: Glodon Co Ltd
Priority date: 2020-07-22
Filing date: 2020-07-22
Publication date: 2024-08-09
Anticipated expiration: 2040-07-22
Also published as: CN111881805A

Abstract

The invention relates to the technical field of engineering information retrieval of building design drawings, in particular to a method and a device for identifying a reinforcement distribution range and electronic equipment, wherein the method comprises the steps of obtaining a support line, a type of a plate reinforcement and a plate in a target plate diagram; the types of the plate ribs comprise stressed ribs and negative ribs; determining an initial reinforcement distribution range of the stressed reinforcements and an initial reinforcement distribution range of the negative reinforcements by using the support lines and the types of the plate reinforcements and the plates; for each stressed bar, based on the initial bar distribution range of the negative bar and other stressed bars which are positioned on the plate where the stressed bar is positioned and are in the same direction as the stressed bar, the initial bar distribution ranges of the stressed bars are sequentially distributed to determine the bar distribution range of the stressed bars; and determining the reinforcement distribution range of each negative reinforcement according to the reinforcement distribution range of the stressed reinforcement and the initial reinforcement distribution range of the negative reinforcement. And the initial reinforcement distribution range is adjusted through linkage analysis of the reinforcement in the target plate diagram, so that a preferable arrangement result is obtained, and overlapping of reinforcement distribution ranges among the reinforcement plates is avoided.

Description

Method and device for identifying reinforcement distribution range and electronic equipment

Technical Field

The invention relates to the technical field of engineering information retrieval of building design drawings, in particular to a method and a device for identifying a reinforcement distribution range and electronic equipment.

Background

In the field of building CAD graph intelligent recognition and digital modeling, the recognition of floor slab steel bars is used as a key ring in CAD recognition, and the recognition accuracy directly influences the accuracy of the calculation result. The floor steel bars mainly play roles in supporting, protecting and connecting the framework in the building structure, and the arrangement of the steel bars directly influences the rigidity, strength and stability of the building and the cost of products. However, the arrangement specification of the plate ribs is not clear, the design experience is referred to a great extent in the design of the building field, and different geographic environments and different building structures need to be considered, so that the CAD identification of the scene to be faced becomes complex.

In CAD identification of the tendons, the tendons of the tendons are generally identified by identifying the tendons of the CAD plate drawing on which the tendons are drawn and setting the tendon distribution ranges thereof to the areas of the plates intersecting the tendons, and this identification method can identify the tendon distribution ranges of each tendon, but since there may be a plurality of or more tendons on the same plate, plate support, or there may be a certain tendon across a plurality of plates or plate supports, even if the tendon distribution ranges of each tendon can be identified, there may be overlapping of the identified tendon distribution ranges, affecting the accuracy of the calculation.

Disclosure of Invention

In view of the above, the embodiment of the invention provides a method and a device for identifying a cloth reinforcement range and electronic equipment, so as to solve the problem that the identified cloth reinforcement ranges overlap.

According to a first aspect, an embodiment of the present invention provides a method for identifying a tendon distribution range, including:

Obtaining support lines, types of plate ribs and plates in a target plate diagram; wherein the types of the plate ribs comprise stressed ribs and negative ribs;

determining an initial tendon distribution range of the stressed tendons and an initial tendon distribution range of the negative tendons by using the support lines, the types of the plate tendons and the plates;

For each stressed tendon, based on the initial tendon distribution range of the negative tendon and other stressed tendons on the plate where the stressed tendon is positioned, which are in the same direction as the stressed tendon, sequentially distributing the initial tendon distribution ranges of the stressed tendons so as to determine the tendon distribution range of the stressed tendons;

And determining the reinforcement distribution range of each negative reinforcement according to the reinforcement distribution range of the stressed reinforcement and the initial reinforcement distribution range of the negative reinforcement.

According to the method for identifying the reinforcement distribution range, firstly, the reinforcement distribution range of the reinforcement under stress in a target board diagram is identified based on the initial reinforcement distribution range of the negative reinforcement and other reinforcement under stress which is in the same direction as the initial reinforcement distribution range of the reinforcement under stress on the board, and then the reinforcement distribution range of the negative reinforcement is guided by utilizing the identified reinforcement distribution range of the reinforcement under stress; and the initial reinforcement distribution range is adjusted through linkage analysis of all the reinforcements in the target plate diagram, so that a preferable arrangement result is obtained, and overlapping of reinforcement distribution ranges among the reinforcements is avoided.

With reference to the first aspect, in a first implementation manner of the first aspect, for each of the stress tendons, based on an initial tendon distribution range of the negative tendon and other stress tendons on a plate where the stress tendons are located and in a same direction as the stress tendons, the sequentially distributing the initial tendon distribution ranges of the stress tendons to determine the tendon distribution range of the stress tendons includes:

For each stress rib, based on the position relation between each edge of the plate where the stress rib is positioned and the supporting line, establishing the relation between the edges of the plate where the stress rib is positioned and the stress rib, and obtaining the edge relation of the stress rib;

Sequentially judging whether each stressed tendon has a tendon distribution range line or not;

When the reinforcement distribution range line does not exist in the reinforcement, the initial reinforcement distribution ranges of the reinforcement are sequentially distributed based on the initial reinforcement distribution range of the negative reinforcement and other reinforcement which are in the same direction as the reinforcement on the plate where the reinforcement is located, so that the reinforcement distribution range of the reinforcement is determined;

and when the reinforcement distribution range line exists in the reinforcement, arranging the reinforcement on the basis of the reinforcement distribution range line and the plate edge relation so as to determine the reinforcement distribution range of the reinforcement.

According to the identification method of the reinforcement distribution range, the reinforcement which does not exist in the reinforcement distribution range line is arranged based on the initial reinforcement distribution range of the negative reinforcement and all other reinforcement which are in the same direction on the plate where the reinforcement is located, and the reinforcement distribution range of the negative reinforcement and other reinforcement which possibly exist reinforcement distribution conflicts are combined in the reinforcement distribution process of the reinforcement distribution, so that overlapping of the reinforcement distribution ranges is avoided through linkage analysis among the plate reinforcements; and the stress tendons with the reinforcement distribution range lines are arranged preferentially, and because the reinforcement distribution range lines are directly regulated in the target board diagram, the reinforcement distribution efficiency of the stress tendons can be improved by directly arranging the stress tendons with the reinforcement distribution range lines.

With reference to the first embodiment of the first aspect, in a second embodiment of the first aspect, for each of the stress tendons, based on an initial tendon distribution range of the negative tendon and other stress tendons on a plate where the stress tendons are located and all in the same direction as the stress tendons, sequentially distributing the initial tendon distribution ranges of the stress tendons, so as to determine a tendon distribution range of the stress tendons, including:

Extracting initial reinforcement distribution ranges of all the negative reinforcements on the plate where the stress reinforcements are positioned and initial reinforcement distribution ranges of the other stress reinforcements for each stress reinforcement so as to obtain conflict areas corresponding to the stress reinforcements;

and recursively arranging the stress tendons on the plates related to the stress tendons by utilizing the plate edge relation based on whether the collision exists between the stress tendons and the corresponding collision areas.

According to the identification method of the reinforcement distribution range, the conflict area corresponding to the reinforcement is determined before reinforcement distribution, the conflict area is avoided when the reinforcement is distributed, overlapping of reinforcement distribution ranges is avoided, the reinforcement distribution is arranged in a recursion mode, and on the premise that the whole plate is fully distributed, overlapping among the reinforcement plates is avoided.

With reference to the second implementation manner of the first aspect, in a third implementation manner of the first aspect, the recursively arranging, based on whether there is a conflict between each of the stress tendons and the conflict area corresponding to the stress tendons, each of the stress tendons on a board related to each of the stress tendons by using the board edge relationship includes:

Determining gluten parts and/or protruding parts, which do not have conflict between corresponding conflict areas, in each stressed gluten;

And arranging the gluten parts and/or the protruding parts by utilizing the plate edge relation based on the determined initial gluten distribution range of the gluten parts and/or the protruding parts.

According to the method for identifying the cloth reinforcement range, which is provided by the embodiment of the invention, the stressed reinforcement is split into the gluten part and the extension part to be respectively arranged, and the arrangement results are combined subsequently, so that the overlapping of the cloth reinforcement range can be avoided.

With reference to the second or third implementation manner of the first aspect, in a fourth implementation manner of the first aspect, the recursively arranging each of the stress tendons on a board related to each of the stress tendons by using the board edge relationship based on whether there is a conflict between each of the stress tendons and the corresponding conflict area includes:

determining gluten parts and/or protruding parts, which have conflict with corresponding conflict areas, in each stressed gluten;

breaking an initial gluten distribution range of the gluten portions and/or protruding portions having the conflict based on the support line;

arranging the broken gluten parts and/or the protruding parts based on the plate edge relation to obtain a recursion arrangement result of the gluten parts and/or the protruding parts;

Combining the recursive arrangement results of the gluten parts and/or the extending parts to obtain the arrangement results of the stressed tendons so as to form a linear gluten distribution range;

and arranging the linear reinforcement distribution range of the stressed reinforcements on the plate according to the relation between the linear reinforcement distribution range and the plate to obtain the surface reinforcement distribution range of each stressed reinforcement on the plate.

With reference to the second implementation manner of the first aspect, in a fifth implementation manner of the first aspect, the recursively arranging, based on whether there is a conflict between each of the stress tendons and the conflict area corresponding to the stress tendons, each of the stress tendons on a board related to each of the stress tendons by using the board edge relationship includes:

Obtaining the plate hole positions of the plates where the stress ribs are positioned;

determining a reinforcement-distributing forbidden zone of the plate where the stress reinforcement is located by utilizing the relation between the plate hole and the plate edge of the plate where the stress reinforcement is located;

And recursively arranging the stress tendons on the plates related to the stress tendons by utilizing the plate edge relation based on whether the collision exists between the stress tendons and the corresponding collision areas and the reinforcement distribution forbidden areas.

According to the method for identifying the cloth reinforcement range, the positions of the plate holes on the plate are considered in the cloth reinforcement range, and the plate holes are defined as the cloth reinforcement forbidden zone, so that the negative reinforcement, the plate holes and the gluten arrangement of the stressed tendons are pulled through, overlapping of the cloth reinforcement range is avoided, and an accurate data basis is provided for subsequent calculation.

With reference to the first aspect, or any one of the first to fifth embodiments of the first aspect, in a sixth implementation of the first aspect, the stress tendon includes a cross-plate tendon, and identifying the tendon placement range of the negative tendon according to the tendon placement range of the stress tendon and the initial tendon placement range of the negative tendon includes:

determining a support line which is not occupied by the initial range of the negative reinforcement and the extension part of the cross plate reinforcement by utilizing the reinforcement distribution range of the stressed reinforcement and the initial reinforcement distribution range of the negative reinforcement;

and combining the support line which is not occupied by the initial range of the negative reinforcement and the extending part of the cross reinforcement with the initial reinforcement distribution range of the negative reinforcement to obtain the reinforcement distribution range of the negative reinforcement.

According to the method for identifying the reinforcement distribution range, provided by the embodiment of the invention, the initial reinforcement distribution range of the negative reinforcement is adjusted by utilizing the reinforcement distribution range of the stressed reinforcement, so that linkage analysis between the stressed reinforcement and the negative reinforcement in the target plate diagram is realized, overlapping of the reinforcement distribution ranges is avoided, and the accuracy of subsequent calculation is improved.

With reference to the sixth implementation manner of the first aspect, in a seventh implementation manner of the first aspect, the merging the support line that is not occupied by the initial range of the negative reinforcement and the extension portion of the cross-plate reinforcement with the initial reinforcement distribution range of the negative reinforcement to obtain the reinforcement distribution range of the negative reinforcement includes:

Collecting a single-side support line occupied by a single-side extended negative rib and a double-side support line occupied by a double-side extended negative rib;

Collecting the support lines which are in the same direction and are not occupied by the extending parts of the cross plate ribs and other negative ribs on the same side of the single-side support lines and the double-side support lines respectively to obtain a first support line and a second support line;

respectively carrying out through treatment on the first support line and the second support line to obtain a first support line and a second support line which are connected end to end;

Judging whether each negative rib marks the number of spans;

And when the number of spans of the negative reinforcement is not marked, determining the reinforcement distribution range of the negative reinforcement based on the initial reinforcement distribution range of the first support line connected end to end and the negative reinforcement, the initial reinforcement distribution range of the negative reinforcement and the second support line connected end to end.

With reference to the seventh implementation manner of the first aspect, in an eighth implementation manner of the first aspect, the merging the support line that is not occupied by the initial range of the negative reinforcement and the extension portion of the cross-plate reinforcement with the initial reinforcement distribution range of the negative reinforcement to obtain the reinforcement distribution range of the negative reinforcement includes:

When the number of spans is marked on the negative ribs, the negative ribs are arranged according to the marked number of spans, and the rib distribution range of the negative ribs is obtained.

According to the identification method of the cloth reinforcement range, provided by the embodiment of the invention, for the negative reinforcement marked with the span number, the span number is directly utilized to arrange the negative reinforcement, so that the cloth reinforcement efficiency is improved.

With reference to the first aspect, in a ninth implementation manner of the first aspect, the determining an initial tendon distribution range of the tendon using the support line, the type of the tendon, and the board includes:

when the type of the plate bar is a negative bar, determining that the initial bar distribution range of the negative bar is the support line which is directly intersected by the negative bar;

and when the type of the plate rib is the stressed rib, determining the initial rib distribution range of the stressed rib as a plate which is directly intersected by the stressed rib.

According to the identification method for the reinforcement distribution range, the arrangement of the negative reinforcement depends on the support of the beam, the wall and the like, and the arrangement of the stressed reinforcement depends on the plate, so that the initial reinforcement distribution ranges of the negative reinforcement and the stressed reinforcement are respectively determined based on the support line and the plate, and the reliability of the initial reinforcement distribution range is improved.

According to a second aspect, an embodiment of the present invention further provides a device for identifying a tendon distribution range, including:

The acquisition module is used for acquiring the types of support lines and plate ribs in the target plate graph; wherein the types of the plate ribs comprise stressed ribs and negative ribs;

The determining module is used for determining an initial reinforcement distribution range of the stressed reinforcement and an initial reinforcement distribution range of the negative reinforcement by utilizing the support line and the type of the plate reinforcement;

The first recognition module is used for sequentially arranging the initial reinforcement distribution ranges of the stressed reinforcements on the basis of the initial reinforcement distribution ranges of the negative reinforcements and other stressed reinforcements which are in the same direction as the stressed reinforcements on the plate where the stressed reinforcements are positioned so as to determine the reinforcement distribution ranges of the stressed reinforcements;

the second identification module is used for determining the reinforcement distribution range of each negative reinforcement according to the reinforcement distribution range of the stressed reinforcement and the initial reinforcement distribution range of the negative reinforcement.

According to the identification device for the reinforcement distribution range, firstly, the reinforcement distribution range of the reinforcement under stress in a target board diagram is identified based on the initial reinforcement distribution range of the negative reinforcement and other reinforcement under stress which is in the same direction as the initial reinforcement distribution range of the reinforcement under stress on the board, and then the reinforcement distribution range of the negative reinforcement is guided by utilizing the identified reinforcement distribution range of the reinforcement under stress; and the initial reinforcement distribution range is adjusted through linkage analysis of all the reinforcements in the target plate diagram, so that a preferable arrangement result is obtained, and overlapping of reinforcement distribution ranges among the reinforcements is avoided.

According to a third aspect, an embodiment of the present invention provides an electronic device, including: the device comprises a memory and a processor, wherein the memory and the processor are in communication connection, the memory stores computer instructions, and the processor executes the computer instructions so as to execute the method for identifying the cloth reinforcement range in the first aspect or any implementation manner of the first aspect.

According to a fourth aspect, an embodiment of the present invention provides a computer-readable storage medium storing computer instructions for causing a computer to perform the method for identifying a tendon extension as described in the first aspect or any implementation manner of the first aspect.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings that are needed in the description of the embodiments or the prior art will be briefly described, and it is obvious that the drawings in the description below are some embodiments of the present invention, and other drawings can be obtained according to the drawings without inventive effort for a person skilled in the art.

FIG. 1 is a flow chart of a method of identifying a tendon placement range, according to an embodiment of the present invention;

FIG. 2 is a schematic view of a standoff line according to an embodiment of the invention;

FIGS. 3 a-3 b are schematic illustrations of a stiffener type according to embodiments of the present invention;

FIG. 4 is a schematic view of a plate according to an embodiment of the invention;

FIG. 5 is a flow chart of a method of identifying a tendon placement range, according to an embodiment of the present invention;

FIG. 6 is a schematic illustration of a cloth reinforcement range line in accordance with an embodiment of the present invention;

FIGS. 7 a-7 b are schematic illustrations of an arrangement of a load-bearing bar according to an embodiment of the present invention;

FIG. 8 is a schematic illustration of an arrangement of a load-bearing bar according to an embodiment of the present invention;

FIG. 9 is a schematic illustration of an arrangement of a load-bearing bar according to an embodiment of the present invention;

FIG. 10 is a flow chart of a method of identifying a tendon placement range, according to an embodiment of the present invention;

FIG. 11 is a schematic diagram of an arrangement of negative ribs according to an embodiment of the present invention;

FIG. 12 is a block diagram of a structure of a device for recognizing a cloth reinforcement range according to an embodiment of the present invention;

fig. 13 is a schematic diagram of a hardware structure of an electronic device according to an embodiment of the present invention.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present invention more apparent, the technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is apparent that the described embodiments are some embodiments of the present invention, but not all embodiments of the present 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.

It should be noted that, the method for identifying the tendon distribution range in the embodiment of the present invention may be used to identify the tendon distribution range of various gluten in the target board diagram, and may also identify the tendon distribution range of the bottom tendon. However, as the cloth of the bottom rib is simpler, in the recognition process of the cloth range, the recognition of the cloth range can be performed only by applying the recognition method of the cloth range described in the embodiment of the invention to various gluten in the target plate diagram.

For convenience of the following description, a priori knowledge involved in the embodiments of the present invention is explained as follows:

CAD recognition, namely, the original 2-dimensional CAD drawing is subjected to die turning to form a 3-dimensional engineering file which can be directly subjected to calculation. The general sequence of the turnover of the main body component is as follows: column big sample- > -column- > -beam- > -wall- > -plate- > -bar. When the plate ribs are identified, as the plate rib picture elements are attached to the support (beam, wall and plate), the negative ribs are attached to the beam or wall picture elements, and the span plate ribs and the stress ribs are attached to the plate picture elements, the support is drawn by default, and the support is inspected without errors after modification.

According to an embodiment of the present invention, there is provided an embodiment of a method for identifying a tendon scope, it being noted that the steps shown in the flowchart of the drawings may be performed in a computer system such as a set of computer-executable instructions, and that, although a logical order is shown in the flowchart, in some cases, the steps shown or described may be performed in an order different from that shown or described herein.

In this embodiment, a method for identifying a tendon distribution range is provided, which may be used in an electronic device, such as a computer, a mobile phone, a tablet computer, etc., fig. 1 is a flowchart of a method for identifying a tendon distribution range according to an embodiment of the present invention, and as shown in fig. 1, the flowchart includes the following steps:

s11, obtaining support lines, types of plate ribs and plates in a target plate diagram.

The plate rib comprises a stress rib and a negative rib, wherein the stress rib comprises a span plate rib and a stress gluten.

Modeling of the beam, the wall and the plate primitives is completed in the target plate diagram, and the support lines, the plate bar types and the plates in the target plate diagram can be obtained by CAD recognition after modeling.

For example, walls, beams, plates, holes, and negative tendons and original CAD tendons that have been identified in the target panel map. The original reinforcement wire is identified, so that an original plate reinforcement entity is obtained; breaking supports such as beams and walls according to the intersecting relation to obtain broken support lines; and then according to the position relation between the plate bar lines and the beams, the wall supports and the plate supports, the types of the plate bars (namely, the span plate bars, the negative bars, the stressed bar bottom bars or the stressed bar gluten) and the initial distribution range are identified.

The supports such as beams and walls are generally divided into horizontal supports and vertical supports, when the plate bars are identified, if the cross sections and the axes of the supports are approximately the same (namely, the supports can be visually considered to be combined into a line), the supports are combined to construct a support line concept, and the supports replace original beam supports and wall supports to participate in the identification of the plate bars. The mutually perpendicular abutments break away from each other and form a length of abutment line, called the broken abutment line. As shown in fig. 2, for convenience of description, the broken carrier line is simply referred to as a carrier line in the embodiment of the present invention.

Specifically, the input data acquired by the electronic device may be processed as follows: 1) Constructing a board support, namely constructing a single board support by using the drawn board graphic elements; constructing a combined plate according to the position relation between the original CAD reinforcing bar line drawing element and the plate; 2) Breaking supports such as beams and walls according to the intersecting relation to obtain broken support lines; 3) Clustering original CAD reinforcement line drawing elements, identifying the main reinforcement and bending type of the reinforcement line, and constructing an initial plate reinforcement entity; 4) And identifying the types of the plate bars according to the number of intersections of original steel bar lines of the plate bars and the support, the position relation between the starting points and the ending points of the steel bar lines and the support, the types of hooks and the like, and judging that the types of the plate bars are cross plate bars, negative bars, stressed bar bottom bars or stressed bar gluten.

As shown in fig. 3a and 3b, the types of individual tendons in the target plate diagram are shown. Wherein the cross-deck rib, the negative rib and the force-bearing rib bottom rib are shown in fig. 3a and the force-bearing rib gluten is shown in fig. 3 b.

The position relationship between the original CAD reinforcement line drawing element and the plate can be directly obtained, for example, the relationship is established by intersecting one reinforcement line drawing element with which plate. As shown in fig. 4, with respect to the construction of the composite board, a rebar line is drawn on multiple boards (intersecting), which multiple intersecting boards would then compose a composite board (principally Polygon). The negative ribs are in relation with the beams and the walls, so that the negative ribs do not participate in the construction of the composite board; the cross-bar is attached to the panel, but the extension is essentially the same as the negative bar, so that only the intersection of the bar portion of the cross-bar with the panel is considered when constructing the composite panel (i.e., all panels that can be completely covered by a single bar line, with the partially covered panels not being counted).

The clustering is simple line position clustering, and a cluster group is formed by intersecting a plurality of line positions. However, on the target plate diagram, there may be many perpendicularly intersecting reinforcing steel bars, so that position clustering cannot be simply performed according to the intersecting relationship. The method is characterized in that business principles are added, namely, the reinforced bar line drawing element is divided into two types, namely, a main bar part and a 3-dimensional plate bar drawing element are finally formed; one is the hooked portion, which ultimately forms the bend of a bar element, which is typically relatively short, typically within 200mm in length, and typically at both ends of the main bar portion. The result of the clustering is to identify a cluster group of a principal rib + two bends, such a group eventually becoming a plate rib primitive.

The main rib and the bending are a group, the main rib is longer, and the bending is at the two ends and shorter in the middle. The bending type is obtained according to the included angle between the main rib and the bending. The bending types are classified into: no bending, 90 degree bending, 135 degree bending, etc.; a tendon entity can be understood as each real tendon primitive to be finally generated; the tendon entity is the shape + some tendon attribute values.

It should be noted that, the above description is only an optional obtaining manner of the support line and the plate rib in the target plate diagram, but the protection scope of the present invention is not limited thereto, and no limitation is made on how the support line and the plate rib in the target plate diagram are obtained, so long as the electronic device can obtain the support line and the plate rib in the target plate diagram and the plate when recognizing the range of the plate rib.

S12, determining an initial reinforcement distribution range of the stressed reinforcement and an initial reinforcement distribution range of the negative reinforcement by using the support lines, the types of the plate reinforcements and the plates.

As mentioned above, the ribs are plate dependent when stressed, while the negative ribs are wall, beam, etc. dependent abutments. Therefore, the initial reinforcement distribution range of the stress reinforcement can be determined by utilizing the position relation of the stress reinforcement and the plate on which the stress reinforcement depends; and determining the initial reinforcement distribution range of the negative reinforcement by utilizing the position relation between the plate reinforcement and the support line on which the plate reinforcement depends. That is, the cross-plate tendons, the stressed tendons gluten and the stressed tendons bottom tendons are attached to the plate, and the distribution range of the tendons is a part of the plate polygon; the negative ribs are attached to beams and walls, and the range of the negative ribs is generally distributed along the attached support for a certain length.

The electronic equipment sequentially utilizes the types of the plate bars to determine the corresponding initial bar distribution range. Specifically, when the type of the plate bar is a negative bar, determining that the initial bar distribution range of the negative bar is the support line where the negative bar is directly intersected; when the type of the plate rib is the stressed rib, determining the initial rib distribution range of the stressed rib as the plate with the stressed rib directly intersected.

S13, for each stressed bar, the initial bar distribution range of each stressed bar is sequentially distributed based on the initial bar distribution range of the negative bar and other stressed bars which are in the same direction as the stressed bar on the plate where the stressed bar is located, so as to determine the bar distribution range of the stressed bar.

When the electronic equipment is used for identifying the reinforcement distribution range, firstly, the reinforcement distribution range of the stressed reinforcements on each plate is identified. In the following description, the plate on which the tendons are located is referred to as the current plate. When the distribution range of the stressed tendons is identified, the initial distribution range of the negative tendons on the plates and the initial distribution range of other stressed tendons in the same direction with the stressed tendons are required to be combined, the stressed tendons are subjected to conflict detection, the stressed tendons which do not conflict are firstly distributed on the current plate, and after all the stressed tendons which do not conflict on all the plates are distributed, and then the stressed tendons which do not conflict on all the plates are distributed in a recursion mode.

For example, when the reinforcement distribution range of the reinforcement on the current plate is identified, the initial reinforcement distribution range of the negative reinforcement on the current plate and the initial reinforcement distribution range of other reinforcement on the current plate can be used as non-reinforcement-distributing areas of the reinforcement, and the reinforcement distribution can be carried out on other areas except for the non-reinforcement-distributing areas on the current plate; the extent of the reinforcement of the current plate may also be identified in the manner described below. This step will be described in detail later in detail.

S14, determining the reinforcement distribution range of each negative reinforcement according to the reinforcement distribution range of the stressed reinforcement and the initial reinforcement distribution range of the negative reinforcement.

After the electronic equipment identifies the cloth bar range of each stressed bar in the target plate diagram, the electronic equipment combines the initial cloth bar range of the negative bar in the target plate diagram, adjusts the initial range of the negative bar, and covers the part which is not coated with the gluten so as to identify the cloth bar range of each negative bar.

The electronic equipment guides the recognition result of the negative gluten by utilizing the gluten distribution range of the stressed gluten, and aims to adjust the initial gluten distribution range of the negative gluten so as to cover the part which is not coated with gluten. This step will be described in detail later in detail.

In this embodiment, a method for identifying a tendon distribution range is provided, which may be used in an electronic device, such as a computer, a mobile phone, a tablet computer, etc., and fig. 5 is a flowchart of a method for identifying a tendon distribution range according to an embodiment of the present invention, as shown in fig. 5, where the flowchart includes the following steps:

S21, obtaining support lines, types of plate ribs and plates in a target plate diagram.

Please refer to S11 in the embodiment shown in fig. 1 in detail, which is not described herein.

S22, determining an initial reinforcement distribution range of the stressed reinforcement and an initial reinforcement distribution range of the negative reinforcement by using the support lines, the types of the plate reinforcements and the plates.

Please refer to the embodiment S12 shown in fig. 1 in detail, which is not described herein.

S23, for each stress reinforcement, the initial reinforcement distribution range of each stress reinforcement is sequentially distributed based on the initial reinforcement distribution range of the negative reinforcement and other stress reinforcements which are in the same direction as the stress reinforcement on the plate where the stress reinforcement is located, so that the reinforcement distribution range of the stress reinforcement is identified.

Specifically, the step S23 includes the following steps:

S231, for each stress bar, based on the position relation between each edge of the plate where the stress bar is located and the supporting line, establishing the relation between the edges of the plate where the stress bar is located and the stress bar, and obtaining the edge relation of the stress bar.

Wherein the plate edge relationship primarily refers to the positional relationship of each edge of the plate polygon and the intended standoff line, one plate edge may contain a plurality of broken standoff lines. The relation between the plate edges is mainly that the relation between broken support lines and the plate edges is considered firstly, and then the relation between the reinforcement distribution range of the plate reinforcement and the plate edges is established.

Because the direction of the plate bar line is the inserting direction of the plate bar and the inserting method is vertical to the extending direction of the plate bar, the arrangement of the range of the plate bar mainly considers how much the plate bar can be arranged in the extending direction of the plate bar, and therefore, when the plate edge relationship is established, the plate bar only needs to be in relationship with the plate edge vertical to the plate bar line.

S232, judging whether each stressed tendon has a tendon distribution range line or not in sequence.

The cloth rib range line in the target plate diagram is identified, and the cloth rib range line is a CAD graphic element which is truly existed on the target plate diagram and is used as a guide for adjusting the cloth rib range. Most of the plate bars are not provided with the bar-distribution range lines, but are provided with the stress bars with the bar-distribution range lines, the priority is highest, the final result is what is the range of the bar-distribution range lines, and the plate bars do not need to participate in the arrangement of the bar-distribution range. Wherein fig. 6 shows a schematic view of a stressed tendon with a tendon-spread line.

When the stress reinforcement has a reinforcement range line, executing S233; otherwise, S234 is performed.

It should be noted that, the electronic device first determines whether all the stress tendons have the tendon distribution range line, and executes S233 after identifying that all the stress tendons have the tendon distribution range line; for the tendons that do not have the line of the tendon range, S234 is executed to identify the tendon range.

S233, arranging the stress tendons based on the tendon distribution range lines and the plate edge relations so as to identify the tendon distribution range of the stress tendons.

After the electronic equipment recognizes the stressed tendons with the reinforcement distribution range lines, the stressed tendons are directly distributed by utilizing the reinforcement distribution range lines, and the reinforcement distribution range of the stressed tendons is obtained. After obtaining the reinforcement distribution range with the reinforcement distribution range line stress reinforcement, the electronic equipment executes S24; the reinforcement distribution range of the negative reinforcement is determined in combination with the reinforcement distribution range of the stress reinforcement obtained in S234 described below.

S234, based on the initial reinforcement distribution range of the negative reinforcement and other reinforcement bars which are in the same direction as the reinforcement bars on the plate where the reinforcement bars are located, the initial reinforcement distribution ranges of all reinforcement bars are sequentially distributed to determine the reinforcement distribution range of the reinforcement bars.

When the electronic equipment identifies the gluten distribution range of the gluten which does not have the gluten distribution range line, respectively considering whether gluten parts and extension parts of the gluten are in conflict with the initial gluten distribution range of the negative gluten and other gluten, if so, breaking the gluten distribution range, and carrying out recursion arrangement on all the gluten on all the plates to obtain arrangement results of all the gluten parts and extension parts; combining the face reinforcement part and the extension part to obtain a linear reinforcement distribution range; and finally, according to the relation between the cloth and the plate, arranging the arrangement result on the plate to obtain the face-type cloth rib range.

Specifically, the step S234 includes the following steps:

and (a) extracting the initial reinforcement distribution range of all negative reinforcements on the plate where the stressed reinforcements are positioned and the initial reinforcement distribution range of other stressed reinforcements to obtain a conflict area corresponding to the stressed reinforcements.

And for each stressed bar on the current plate, the electronic equipment obtains a conflict area corresponding to the stressed bar by extracting the initial bar distribution range of all negative bars on the current plate and the initial bar distribution range of other stressed bars. Wherein, the other stress bars represent stress bars which are positioned on the current plate and are in the same direction with the stress bars.

For example, there are two equally oriented tendons, whose initial tendons are on the same plate, and there is a conflict in the arrangement.

And (b) recursively arranging the stress tendons on the plates related to the stress tendons by utilizing a plate edge relation based on whether the collision exists between the stress tendons and the corresponding collision areas.

The recursive arrangement is that when a plurality of stress bars are arranged at the same time, an arrangement result is not directly given to a place with conflict, other places are arranged first, and after other non-conflict arrangements are completed, the place with conflict is adjusted and arranged, so that a reasonable result is finally obtained.

Therefore, in the processing of this step, the electronic device performs processing in two ways based on whether or not there is a collision between each of the stress bars and its corresponding collision region:

(1) For gluten parts and/or extensions in the stressed gluten which do not have a conflict

1.1 A gluten portion and/or an extension portion of each of the stress gluten in which there is no conflict between the conflict areas corresponding thereto is determined.

When the electronic equipment arranges the stress bars, the stress bars are divided into gluten parts and extending parts to be respectively arranged, and the gluten parts and/or the extending parts which do not have conflict with the corresponding conflict areas in the stress bars are determined at first. That is, when there is no collision between one of the gluten portions and the corresponding collision region, the gluten portion of the gluten may be a protruding portion, or the gluten portion and the protruding portion.

1.2 Based on the determined initial gluten distribution range of the gluten portions and/or the extensions, the gluten portions and/or the extensions are arranged by using the plate edge relation.

After the electronic device obtains gluten parts and/or protruding parts which do not have conflict between each stressed gluten and the corresponding conflict area, the electronic device can directly arrange the parts which do not have conflict.

(2) For gluten parts and/or extensions in which there is conflict in the stressed gluten

For the portions with conflicts, the respective ranges are determined according to the traffic to obtain a non-conflicting result (e.g. both gluten want to be directly arranged from a to B, but the end result may be to go a point X in the middle of AB, break AB, one gluten cloth AX, the other gluten cloth XB), and directly spread over the whole board without conflicts.

Specifically, the method may include the steps of:

2.1 A gluten portion and/or an extension portion of each of the stress gluten in which there is a conflict between its corresponding conflict region is determined.

When the electronic equipment arranges the stress bars, the stress bars are divided into gluten parts and extension parts to be respectively arranged, and firstly, the gluten parts and/or extension parts with conflicts between corresponding conflict areas in the stress bars are determined.

2.2 Based on the abutment line, breaking the initial gluten distribution range of the gluten portions and/or the extensions where there is a conflict.

After determining that conflicting gluten portions and/or extensions exist, the electronic device interrupts an initial gluten range of the conflicting portions based on the support wire.

For example, when there are a plurality of cross-web bars on the same plate in the same direction, the bar distribution range is as follows: the ABC three Y-direction cross-plate ribs divide the whole plate according to the support. As shown in FIG. 7a, the arrow encloses a plate, the vertical frame encloses a Y-direction cross bar, and the horizontal frame encloses an X-direction cross bar.

As shown in fig. 7b, the vertical frame selects the support for breaking the support where ABC three Y-direction ribs are located. The upper part is two sections of support lines after breaking, and the lower part is two sections. ABC can divide the entire panel range according to the relationship between the respective upper and lower ends and the broken support line.

2.3 And (3) arranging the broken gluten parts and/or the protruding parts based on the plate edge relation to obtain a recursion arrangement result of the gluten parts and/or the protruding parts.

As shown in fig. 7B, the range in which a is obtained is the range of the left oblique line, the bead-laying range of B is the range covered by the middle oblique line, and the range of C is the range of the right oblique line.

For another example, when both the cross-web gluten and the stress gluten are present on the same plate in the same direction, the gluten distribution range is as follows: the whole plate is divided by the X-direction stress gluten A and the cross plate gluten B according to the support, and the arrangement result is shown in figure 8.

2.4 Combining the recursion arrangement results of the face reinforcement parts and/or the extension parts to obtain the arrangement results of the stressed tendons so as to form a linear reinforcement distribution range.

Wherein, linear cloth muscle scope: the tendon region itself is a polygon that can be first notionally expressed as an extension in a direction perpendicular to the direction of tendon line insertion (typically the panel edge), becoming such a linear region. The linear rib distribution range is equivalent to the length range of the plate rib on the plate edge.

And the electronic equipment combines the gluten parts and/or the extending parts after obtaining the arrangement results of the gluten parts and/or the extending parts, so that the arrangement results of the stressed gluten can be obtained to form a linear gluten distribution range.

2.5 According to the relation between the linear reinforcement distribution range and the current plate, arranging the linear reinforcement distribution range of the stressed reinforcements on the plate to obtain the surface reinforcement distribution range of each stressed reinforcement on the plate.

Since the linear rib arrangement range and the plate edges are in relation, the plate edges belong to the plate, and the relation is established. And the electronic equipment arranges the arrangement result of the stress tendons on the plate to obtain the surface type reinforcement distribution range of the stress tendons on the plate.

As an alternative implementation of this embodiment, the step (b) further includes the following steps:

(1) And obtaining the plate hole positions of the plates where the stress ribs are positioned.

The plate holes can be identified in advance, and the plate edges occupied by the plate holes cannot be arranged. Therefore, the electronic device obtains the hole position on the current board for determining the reinforcement-forbidden zone.

(2) And determining a reinforcement-distributing forbidden zone of the plate where the stress reinforcement is positioned by utilizing the relation between the plate hole and the plate edge of the plate where the stress reinforcement is positioned.

The line type cloth bar range of the negative bar, the stressed bar and the line type cloth bar range of the span plate bar are all arranged on the plate edge, and the plate edge occupied by the plate hole is reserved, so that the arrangement cannot be carried out. Firstly, the parts occupied by the negative gluten and the plate holes are buckled from the plate edges, the rest parts are used as the maximum intervals of all the stressed gluten on the plate and the distribution range of the cross-plate gluten, and the range of each gluten is comprehensively considered.

Because in the scheme in the prior art, the arrangement of the cross-plate gluten and the stress gluten can not consider the areas with negative gluten and plate holes, and the connection between different cross-plate gluten and stress gluten is not established, and the range is directly set to be the whole plate as long as the plate is drawn, so that the gluten distribution range between the gluten is overlapped. According to the scheme, the negative reinforcement, the stressed reinforcement and the plate hole are comprehensively considered in a pulling-through mode, so that overlapping of reinforcement distribution ranges is avoided.

(3) And recursively arranging the stress tendons on the plates related to the stress tendons by utilizing a plate edge relation based on whether the collision exists between the stress tendons and the corresponding collision areas and the reinforcement distribution forbidden areas.

When the electronic equipment arranges the stress bars, not only the conflict area corresponding to each stress bar is considered, but also the bar arrangement forbidden area on the plate is considered so as to recursively arrange each stress bar.

The arrangement here results in that the ranges of the gluten between the different stressed gluten and the cross-web gluten do not overlap, but together they range to be able to fill the panel, which is the part of the panel that is occupied by the deducted holes and negative gluten.

For example, when both the cross-plate gluten and the stress gluten are present on the same plate in the same direction, and the arrangement range of the cross-plate gluten is in the plate hole area, as shown in fig. 9, the arrangement range is as follows: the Y-direction stress gluten B and the cross-plate gluten A divide the whole plate according to the support, but because the cross-plate gluten A meets the plate hole area when being arranged, the cross-plate gluten A can be normally arranged in the area 2 and becomes non-protruding stress gluten in the area 1.

S24, identifying the reinforcement distribution range of each negative reinforcement according to the reinforcement distribution range of the stressed reinforcement and the initial reinforcement distribution range of the negative reinforcement.

Please refer to the embodiment S14 in fig. 1 in detail, which is not described herein.

In this embodiment, a method for identifying a tendon distribution range is provided, which may be used in an electronic device, such as a computer, a mobile phone, a tablet computer, etc., fig. 10 is a flowchart of a method for identifying a tendon distribution range according to an embodiment of the present invention, and as shown in fig. 10, the flowchart includes the following steps:

S31, obtaining support lines, types of plate ribs and plates in a target plate diagram.

Please refer to the embodiment S21 shown in fig. 5 in detail, which is not described herein.

S32, determining an initial reinforcement distribution range of the stressed reinforcement and an initial reinforcement distribution range of the negative reinforcement by using the support lines, the types of the plate reinforcements and the plates.

Please refer to the embodiment S22 shown in fig. 5 in detail, which is not described herein.

S33, for each stress reinforcement, the initial reinforcement distribution range of each stress reinforcement is sequentially distributed based on the initial reinforcement distribution range of the negative reinforcement and other stress reinforcements which are in the same direction as the stress reinforcement on the plate where the stress reinforcement is located, so as to determine the reinforcement distribution range of the stress reinforcement.

Please refer to the embodiment S26 shown in fig. 5 in detail, which is not described herein.

S34, determining the reinforcement distribution range of each negative reinforcement according to the reinforcement distribution range of the stressed reinforcement and the initial reinforcement distribution range of the negative reinforcement.

Specifically, the step S34 includes:

S341, determining the support line which is not occupied by the initial range of the negative reinforcement and the extension part of the cross plate reinforcement by utilizing the reinforcement distribution range of the stressed reinforcement and the initial reinforcement distribution range of the negative reinforcement.

The electronic device can determine the support line not occupied by the initial range of the negative reinforcement and the extension part of the cross plate reinforcement by using the reinforcement distribution range of the stressed reinforcement and the initial reinforcement distribution range of the negative reinforcement obtained in the step S33.

And S342, combining the support line which is not occupied by the initial range of the negative reinforcement and the extending part of the cross-plate reinforcement with the initial reinforcement distribution range of the negative reinforcement to obtain the reinforcement distribution range of the negative reinforcement.

The electronic equipment performs head-to-tail through combination operation on the support line which is not occupied by the initial range of the negative gluten and the extending part of the cross-plate gluten and the initial gluten distribution range of the negative gluten, and calculates the combined support line to be used as the final gluten distribution range of the negative gluten, so that the part which is not coated with gluten can be covered. Wherein the non-gluten refers to the portion not occupied by any gluten range of gluten.

As an alternative implementation manner of this embodiment, S342 includes the following steps:

(1) And collecting the unilateral support line occupied by the unilaterally extended negative rib and the bilateral support line occupied by the bilateral extended negative rib.

The electronic equipment can traverse all the negative ribs, and collect the unilateral support lines occupied by the unilaterally extended negative ribs and the bilateral support lines occupied by the bilateral extended negative ribs by utilizing the relationship between the negative ribs and the unilateral support lines and the bilateral support lines.

(2) And collecting the support lines which are in the same direction and are not occupied by the extending parts of the cross plate ribs and other negative ribs on the same side of each single-side support line and each double-side support line respectively to obtain a first support line and a second support line.

The electronic equipment collects support lines which are in the same direction and are not occupied by the cross-plate ribs and other negative ribs on the same side based on each single-side support line and each double-side support line, and obtains a first support line corresponding to the single-side support line and a second support line corresponding to the double-side support line.

(3) And respectively carrying out through treatment on the first support line and the second support line to obtain the first support line and the second support line which are connected end to end.

After the electrons are arranged on the first support line and the second support line obtained in the step (2), carrying out through treatment on the first support line to obtain a first support line connected end to end; and carrying out through treatment on the second support line to obtain the end-to-end second support line.

(4) Judging whether each negative rib marks the number of spans.

Executing (5) when the negative ribs do not mark the spans; otherwise, the negative bars are arranged according to the marked span number, and the bar distribution range of the negative bars is obtained.

(5) And determining the reinforcement distribution range of the negative reinforcement based on the initial reinforcement distribution range of the first support line connected end to end and the negative reinforcement and the initial reinforcement distribution range of the second support line connected end to end and the negative reinforcement.

After the electronic equipment obtains the first support line connected end to end and the second support line connected end to end, respectively combining the first support line connected end to end with the initial reinforcement distribution range of the negative reinforcement, combining the second support line connected end to end with the initial reinforcement distribution range of the negative reinforcement, and finally taking the combined support line as the reinforcement distribution range of the negative reinforcement.

For example, as shown in fig. 11, the arrangement result of the cross-web bars a is the lower right LB1 panel, and the initial web distribution range of the negative web bars B is the broken region 1. After the cross-plate gluten A is distributed, the area 2 is found to be not covered by gluten, and the range of the negative gluten B can be extended by adjusting the negative gluten range module, wherein the final gluten distribution range of the negative gluten B is the combined part of the area 1 and the area 2.

According to the identification method of the reinforcement distribution range, the initial reinforcement distribution range of the negative reinforcement is adjusted by utilizing the reinforcement distribution range of the stressed reinforcement, so that linkage analysis between the stressed reinforcement and the negative reinforcement in the target plate diagram is realized, overlapping of the reinforcement distribution ranges is avoided, and the accuracy of subsequent calculation is improved. According to the method, the negative tendons can participate in the distribution range distribution of the cross-plate tendons and the stress tendons, the distribution conversion of the plate tendons in the distribution forbidden regions such as plate holes can be processed, the recognition of the respective distribution ranges when a plurality of and various types of tendons exist in the same direction on the same plate is solved, and after the stress tendons are distributed, the distribution of the negative tendons can be guided by the stress tendons distribution results, so that the direct overlapping of the distribution ranges of the tendons is avoided.

The embodiment also provides a device for identifying the tendon distribution range, which is used for implementing the foregoing embodiments and preferred embodiments, and is not described in detail. As used below, the term "module" may be a combination of software and/or hardware that implements a predetermined function. While the means described in the following embodiments are preferably implemented in software, implementation in hardware, or a combination of software and hardware, is also possible and contemplated.

The present embodiment provides a device for identifying a tendon distribution range, as shown in fig. 12, including:

An obtaining module 41, configured to obtain types of support lines and ribs in a target plate graph; wherein the types of the plate ribs comprise stressed ribs and negative ribs;

a determining module 42, configured to determine an initial tendon distribution range of the stressed tendon and an initial tendon distribution range of the negative tendon using the support line and the type of the tendon;

the first identifying module 43 is configured to, for each of the tendons, sequentially arrange the initial tendon arrangement ranges of the tendons based on the initial tendon arrangement ranges of the negative tendons and other tendons on the plate where the tendons are located and in the same direction as the tendons, so as to determine the tendon arrangement ranges of the tendons;

The second identifying module 44 is configured to determine a tendon distribution range of each negative tendon according to the tendon distribution range of the stressed tendon and the initial tendon distribution range of the negative tendon.

The device for identifying the reinforcement distribution range provided by the embodiment is used for identifying the reinforcement distribution range of the reinforcement under the action of the load on the target board based on the initial reinforcement distribution range of the negative reinforcement and other reinforcement under the action of the load on the board in the same direction as the initial reinforcement distribution range of the negative reinforcement, and guiding the reinforcement distribution range of the negative reinforcement by utilizing the identified reinforcement distribution range of the reinforcement under the action of the load; and the initial reinforcement distribution range is adjusted through linkage analysis of all the reinforcements in the target plate diagram, so that a preferable arrangement result is obtained, and overlapping of reinforcement distribution ranges among the reinforcements is avoided.

The identification means of the extent of the bead in this embodiment are presented in the form of functional units, where a unit refers to an ASIC circuit, a processor and a memory executing one or more software or firmware programs, and/or other devices that can provide the above-described functionality.

Further functional descriptions of the above respective modules are the same as those of the above corresponding embodiments, and are not repeated here.

The embodiment of the invention also provides electronic equipment, which is provided with the identification device of the cloth reinforcement range shown in the figure 12.

Referring to fig. 13, fig. 13 is a schematic structural diagram of an electronic device according to an alternative embodiment of the present invention, as shown in fig. 13, the electronic device may include: at least one processor 51, such as a CPU (Central Processing Unit ), at least one communication interface 53, a memory 54, at least one communication bus 52. Wherein the communication bus 52 is used to enable connected communication between these components. The communication interface 53 may include a Display screen (Display) and a Keyboard (Keyboard), and the selectable communication interface 53 may further include a standard wired interface and a wireless interface. The memory 54 may be a high-speed RAM memory (Random Access Memory, volatile random access memory) or a non-volatile memory (non-volatile memory), such as at least one disk memory. The memory 54 may alternatively be at least one memory device located remotely from the aforementioned processor 51. Wherein the processor 51 may be in conjunction with the apparatus described in fig. 12, the memory 54 stores an application program, and the processor 51 invokes the program code stored in the memory 54 for performing any of the method steps described above.

The communication bus 52 may be a peripheral component interconnect standard (PERIPHERAL COMPONENT INTERCONNECT, PCI) bus, an extended industry standard architecture (extended industry standard architecture, EISA) bus, or the like. The communication bus 52 may be classified as an address bus, a data bus, a control bus, or the like. For ease of illustration, only one thick line is shown in fig. 13, but not only one bus or one type of bus.

Wherein the memory 54 may include volatile memory (english) such as random-access memory (RAM); the memory may also include a nonvolatile memory (English: non-volatile memory), such as a flash memory (English: flash memory), a hard disk (English: HARD DISK DRIVE, abbreviation: HDD) or a solid state disk (English: solid-STATE DRIVE, abbreviation: SSD); memory 54 may also include a combination of the types of memory described above.

The processor 51 may be a central processor (English: central processing unit, abbreviated: CPU), a network processor (English: network processor, abbreviated: NP) or a combination of CPU and NP.

The processor 51 may further include a hardware chip, among others. The hardware chip may be an application-specific integrated circuit (ASIC), a Programmable Logic Device (PLD), or a combination thereof (English: programmable logic device). The PLD may be a complex programmable logic device (English: complex programmable logic device, abbreviated: CPLD), a field-programmable gate array (English: field-programmable GATE ARRAY, abbreviated: FPGA), a general-purpose array logic (English: GENERIC ARRAY logic, abbreviated: GAL), or any combination thereof.

Optionally, the memory 54 is also used for storing program instructions. The processor 51 may invoke program instructions to implement the method of identifying the tendon ranges as shown in the embodiments of fig. 1,5 and 10 of the present application.

The embodiment of the invention also provides a non-transitory computer storage medium, which stores computer executable instructions, and the computer executable instructions can execute the method for identifying the reinforcement distribution range in any of the method embodiments. Wherein the storage medium may be a magnetic disk, an optical disk, a Read-Only Memory (ROM), a random access Memory (Random Access Memory, RAM), a Flash Memory (Flash Memory), a hard disk (HARD DISK DRIVE, abbreviated as HDD), a Solid state disk (Solid-state-STATE DRIVE, SSD), or the like; the storage medium may also comprise a combination of memories of the kind described above.

Although embodiments of the present invention have been described in connection with the accompanying drawings, various modifications and variations may be made by those skilled in the art without departing from the spirit and scope of the invention, and such modifications and variations fall within the scope of the invention as defined by the appended claims.

Claims

1. The method for identifying the cloth reinforcement range is characterized by comprising the following steps:

Determining the reinforcement distribution range of each negative reinforcement according to the reinforcement distribution range of the stressed reinforcement and the initial reinforcement distribution range of the negative reinforcement;

Wherein, to each the atress muscle, based on the initial cloth muscle scope of burden muscle and the atress muscle place on the board with other atress muscle of atress muscle syntropy, each in proper order the initial cloth muscle scope of atress muscle is arranged to confirm the cloth muscle scope of atress muscle includes:

2. The method according to claim 1, wherein the arranging the initial tendon arrangement ranges of the respective tendons in order based on the initial tendon arrangement ranges of the negative tendons and other tendons on the plate where the tendons are located and all the same direction as the tendons to determine the tendon arrangement ranges of the tendons includes:

extracting initial reinforcement distribution ranges of all the negative reinforcements and initial reinforcement distribution ranges of the other reinforcements on the plate where the reinforcements are positioned so as to obtain conflict areas corresponding to the reinforcements;

3. The method of claim 2, wherein said recursively arranging each of said tendons on a plate associated with each of said tendons using said plate edge relationship based on whether there is a conflict between each of said tendons and its corresponding conflict region, comprises:

4. A method according to claim 2 or 3, wherein said recursively arranging each of said tendons on a plate associated with each of said tendons using said plate edge relationship based on whether there is a conflict between each of said tendons and its corresponding conflict region, comprises:

5. The method of claim 2, wherein said recursively arranging each of said tendons on a plate associated with each of said tendons using said plate edge relationship based on whether there is a conflict between each of said tendons and its corresponding conflict region, comprises:

acquiring the position of a plate hole on the plate where each stressed rib is positioned;

6. The method of claim 1, wherein the load-bearing tendons comprise cross-deck tendons, and wherein determining the tendon placement of the negative tendons based on the tendon placement of the load-bearing tendons and the initial tendon placement of the negative tendons comprises:

7. The method of claim 6, wherein the merging the support line not occupied by the initial range of the negative reinforcement and the extension of the cross-web reinforcement with the initial reinforcement range of the negative reinforcement to obtain the reinforcement range of the negative reinforcement comprises:

Respectively carrying out through treatment on the first support line and the second support line to obtain a first support line connected end to end and a second support line connected end to end;

Judging whether each negative rib marks the number of spans;

and when the number of spans of the negative reinforcement is not marked, determining the reinforcement distribution range of the negative reinforcement based on the initial reinforcement distribution range of the first support line connected end to end and the negative reinforcement and the initial reinforcement distribution range of the second support line connected end to end and the negative reinforcement.

8. The method of claim 7, wherein the merging the support line not occupied by the initial range of the negative reinforcement and the extension of the cross-web reinforcement with the initial reinforcement range of the negative reinforcement to obtain the reinforcement range of the negative reinforcement comprises:

9. The method of claim 1, wherein said determining an initial tendon placement range for said tendons using said standoff lines, types of tendons and said panels comprises:

10. A tendon placement range identification device, comprising:

the second identification module is used for determining the reinforcement distribution range of each negative reinforcement according to the reinforcement distribution range of the stressed reinforcement and the initial reinforcement distribution range of the negative reinforcement;

The first identification module is specifically configured to:

11. An electronic device, comprising:

The device comprises a memory and a processor, wherein the memory and the processor are in communication connection, the memory stores computer instructions, and the processor executes the computer instructions, so that the method for identifying the cloth reinforcement range according to any one of claims 1-9 is executed.

12. A computer-readable storage medium storing computer instructions for causing a computer to perform the method of identifying a cloth reinforcement range according to any one of claims 1 to 9.