CN113763541A

CN113763541A - Method and device for calculating longitudinal bar in column and readable storage medium

Info

Publication number: CN113763541A
Application number: CN202111074016.3A
Authority: CN
Inventors: 李玲; 白琳伟
Original assignee: Glodon Co Ltd
Current assignee: Glodon Co Ltd
Priority date: 2021-09-14
Filing date: 2021-09-14
Publication date: 2021-12-07

Abstract

The invention discloses a method, equipment and a readable storage medium for calculating longitudinal bars in a column, wherein the method comprises the following steps: acquiring a building three-dimensional model, and determining a target column primitive and a longitudinal bar primitive positioned in the target column primitive from the building three-dimensional model; respectively setting corresponding high-low pile states for each longitudinal bar primitive according to a preset high-low pile setting rule and the position relation of each longitudinal bar primitive in the target column primitives; respectively setting a corresponding communication state for each longitudinal bar primitive according to the floor where the target column primitive is located and the position relation of each longitudinal bar primitive in the target column primitive; respectively calculating the size of each longitudinal bar primitive according to the high-low pile state and the communication state of each longitudinal bar primitive; the invention solves the technical problem that the state information and the size information of the longitudinal ribs in the column cannot be automatically and accurately calculated in the prior art.

Description

Method and device for calculating longitudinal bar in column and readable storage medium

Technical Field

The invention relates to the technical field of computer aided design, in particular to a method, a device and equipment for calculating longitudinal bars in a column and a readable storage medium.

Background

In the construction stage of a building engineering project, longitudinal bar information in a column needs to be calculated according to a building drawing so as to meet the requirement of on-site longitudinal bar blanking. In the existing construction drawing sample-turning process, construction personnel are required to manually calculate the high-low pile state, the communication state and the size information of longitudinal bars in a column according to national specifications and drawing set requirements, the process is complicated, and a large amount of human resources are required to be consumed. In addition, although existing building software on the market can automatically calculate the state information and the size information of the longitudinal bars in the column according to the building three-dimensional model, the accuracy of the calculation result is low, personnel are required to manually modify error information, the operation is complicated, and the efficiency is low.

Disclosure of Invention

The invention aims to provide a method, a device and equipment for calculating longitudinal ribs in a column and a readable storage medium, which solve the technical problem that the state information and the size information of the longitudinal ribs in the column cannot be automatically and accurately calculated in the prior art.

According to one aspect of the present invention, there is provided a method of calculating a longitudinal bar in a column, the method comprising:

acquiring a building three-dimensional model, and determining a target column primitive and a longitudinal bar primitive positioned in the target column primitive from the building three-dimensional model;

respectively setting corresponding high-low pile states for each longitudinal bar primitive according to a preset high-low pile setting rule and the position relation of each longitudinal bar primitive in the target column primitives;

respectively setting a corresponding communication state for each longitudinal bar primitive according to the floor where the target column primitive is located and the position relation of each longitudinal bar primitive in the target column primitive;

and respectively calculating the size of each longitudinal bar primitive according to the high-low pile state and the communication state of each longitudinal bar primitive.

Optionally, the setting of the corresponding high-low pile state for each longitudinal bar primitive according to the preset high-low pile setting rule and the position relationship of each longitudinal bar primitive in the target column primitive includes:

acquiring the setting rule of the high-low piles; wherein, the high-low pile setting rule comprises: the position of the initial longitudinal bar and the high-low pile state of the initial longitudinal bar;

determining a longitudinal bar primitive representing the initial longitudinal bar from the column cross-section diagram corresponding to the target column primitive according to the position of the initial longitudinal bar;

numbering all longitudinal bar primitives in the column cross-section diagram according to a preset numbering rule from the longitudinal bar primitive representing the initial longitudinal bar;

on the basis of the high-low pile state of the initial longitudinal bar, sequentially setting the high-low pile state of each longitudinal bar primitive from the longitudinal bar primitive representing the initial longitudinal bar according to the numbering sequence; and the high pile state and the low pile state of two longitudinal bar primitives which are adjacent in serial number are different.

Optionally, the setting, according to the floor where the target column primitive is located and the position relationship between each longitudinal bar primitive in the target column primitive, a corresponding communication state for each longitudinal bar primitive respectively includes:

when the target column graphic elements are positioned on the lowest floor, the lower communicated states of all longitudinal bar graphic elements positioned at the bottom in the target column graphic elements are set as the inserting bars;

acquiring a column cross-section diagram corresponding to the target column primitive, sequentially traversing each longitudinal rib primitive in the column cross-section diagram, and judging whether other longitudinal rib primitives exist within a range taking the target longitudinal rib primitive as a circle center and a set length as a radius;

if so, setting the upper communication state of the target longitudinal bar primitive to be communicated when the target longitudinal bar primitive is provided with the lower communication state, or setting the lower communication state of the target longitudinal bar primitive to be communicated when the target longitudinal bar primitive is not provided with the lower communication state; and if not, setting the upper communication state of the target longitudinal bar primitive as a capping state.

Optionally, the setting, according to the floor where the target column primitive is located and the position relationship between each longitudinal bar primitive in the target column primitive, a corresponding communication state for each longitudinal bar primitive, further includes:

when the target column primitive is not located at the lowest floor, acquiring a connecting column primitive connected with the bottom of the target column primitive;

setting the lower communication state of the longitudinal bar primitives which have a connection relation with the longitudinal bar primitives in the connecting column primitives in the target column primitives according to the upper communication state of each longitudinal bar primitive in the connecting column primitives;

if so, setting the upper communication state of the target longitudinal bar primitive to be communicated when the target longitudinal bar primitive is provided with the lower communication state, or setting the lower communication state of the target longitudinal bar primitive to be communicated when the target longitudinal bar primitive is not provided with the lower communication state; if not, setting the upper communication state of the target longitudinal bar primitive as a capping state when the target longitudinal bar primitive is provided with the lower communication state, or setting the lower communication state of the target longitudinal bar primitive as a dowel bar when the target longitudinal bar primitive is not provided with the lower communication state.

Optionally, after the corresponding communication state is respectively set for each longitudinal rib primitive according to the floor where the target column primitive is located and the position relationship between each longitudinal rib primitive in the target column primitive, the method further includes:

acquiring a first upper layer column primitive connected with the top of the target column primitive and a first lower layer column primitive connected with the bottom of the target column primitive from the building three-dimensional model;

acquiring a target column primitive with the same column name as that of the target column primitive from the floor where the target column primitive is located;

acquiring a second upper layer column graphic element connected with the top of the target column graphic element and a second lower layer column graphic element connected with the bottom of the target column graphic element from the building three-dimensional model;

when the column names of the first upper-layer column primitive and the second upper-layer column primitive are the same and the column names of the first lower-layer column primitive and the second lower-layer column primitive are the same, judging whether a first combined primitive composed of the first upper-layer column primitive, a target column primitive and a first lower-layer column primitive is consistent with a second combined primitive composed of the second upper-layer column primitive, the target column primitive and the second lower-layer column primitive in style;

and if so, setting the high-low pile state and the communication state of the corresponding longitudinal bar primitive in the target column primitive according to the high-low pile state and the communication state of each longitudinal bar primitive in the target column primitive.

Optionally, the calculating, according to the high-low pile state and the communication state of each longitudinal bar primitive, the size of each longitudinal bar primitive respectively includes:

when the lower communication state of the target longitudinal bar graphic primitive is a plug-in, calculating the length of an anchoring area of the target longitudinal bar graphic primitive according to a preset calculation rule;

calculating the exposure length of the target longitudinal bar graphic element in the target column graphic element according to preset high-low pile exposure sizes and high-low pile states of the target longitudinal bar graphic element;

and taking the sum of the length of the anchoring area and the exposed length as the total length of the target longitudinal bar primitive.

when the upper communication state and the lower communication state of the target longitudinal bar graphic element are both communicated, calculating the lower length M of the target longitudinal bar graphic element in the first floor according to the following formula:

M＝P-T+L；

wherein P is the floor height of the first floor;

t is the exposure length of a first longitudinal bar primitive connected with the bottom of the target longitudinal bar primitive in the first floor;

l is the connection length of the target longitudinal bar graphic element and the first longitudinal bar graphic element;

calculating the exposure length of the target longitudinal bar graphic element in the second floor according to the preset high-low pile exposure size and the high-low pile state of the target longitudinal bar graphic element; wherein the second floor is above the first floor;

and taking the sum of the lower length and the exposed length as the total length of the target longitudinal bar graphic element.

when the upper communication state of the target longitudinal bar primitive is capping, calculating the lower length N of the target longitudinal bar primitive in the target column primitive according to the following formula:

N＝Q-B+K；

q is the floor height of a target floor where the target column graphic primitive is located;

b is the exposure length of a second longitudinal bar primitive connected with the bottom of the target longitudinal bar primitive in the target floor;

k is the connection length of the target longitudinal bar graphic element and the second longitudinal bar graphic element;

calculating the length of an anchoring area of the longitudinal bar graphic primitive according to a preset calculation rule;

and taking the sum of the lower length and the length of the anchoring area as the total length of the target longitudinal bar primitive.

Optionally, after the size of each longitudinal bar primitive is respectively calculated according to the high-low pile state and the connected state of each longitudinal bar primitive, the method further includes:

in a column cross section diagram corresponding to the target column graphic element, modifying the line thickness of a longitudinal bar graphic element according to the high-low pile state of the longitudinal bar graphic element, and adding a communication state identifier in the longitudinal bar graphic element according to the communication state of the longitudinal bar graphic element to obtain a column cross section detailed diagram;

adding the column cross-section detail drawing to a column stub board of the target column primitive, and adding the size of each longitudinal bar primitive to the column stub board.

In order to achieve the above object, the present invention further provides a computer device, which specifically includes: a memory, a processor and a computer program stored on the memory and executable on the processor, the processor implementing the above-described steps of the method for calculating a longitudinal bar in a column when executing the computer program.

In order to achieve the above object, the present invention further provides a computer-readable storage medium, on which a computer program is stored, which, when being executed by a processor, carries out the above-described steps of the method of calculating a longitudinal bar in a column.

The method, the device, the equipment and the readable storage medium for calculating the longitudinal bars in the column can determine the high-low pile state and the communication state of the longitudinal bars in the column based on the building three-dimensional model, and accurately calculate the size of the longitudinal bars according to the high-low pile state and the communication state of each longitudinal bar and the preset calculation rule; in addition, still can show the positional information, height stake state, UNICOM's state, reducing state and the size information of every vertical muscle in the post through post cross section picture to guide constructor to carry out on-the-spot reinforcement in the construction stage in the later stage, thereby reach the purpose that processing is reasonable, the ligature is convenient, save the reinforcing bar.

Drawings

Various other advantages and benefits will become apparent to those of ordinary skill in the art upon reading the following detailed description of the preferred embodiments. The drawings are only for purposes of illustrating the preferred embodiments and are not to be construed as limiting the invention. Also, like reference numerals are used to refer to like parts throughout the drawings. In the drawings:

FIG. 1 is a schematic flow chart illustrating an alternative method for calculating longitudinal ribs in a column according to an embodiment;

FIG. 2 is a schematic diagram of a column cross-section corresponding to a target column primitive according to one embodiment;

fig. 3(a), (b), (c), and (d) are schematic diagrams of the communication status identifier provided in the first embodiment;

fig. 4 is a schematic diagram of a longitudinal bar primitive provided in the first embodiment when the pile states of two connected longitudinal bars are not the same;

FIG. 5(a), (b), (c), and (d) are schematic diagrams of diameter-varying status marks provided in the first embodiment;

FIG. 6 is a schematic illustration of a column material brand provided in the first embodiment;

FIG. 7 is a schematic diagram of an alternative structure of the device for calculating longitudinal ribs in a column according to the second embodiment;

fig. 8 is a schematic diagram of an alternative hardware architecture of the computer device according to the third embodiment.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example one

The embodiment of the invention provides a method for calculating longitudinal bars in a column, which specifically comprises the following steps of:

step S101: and acquiring a building three-dimensional model, and determining a target column primitive and a longitudinal bar primitive positioned in the target column primitive from the building three-dimensional model.

The building three-dimensional model is a calculated quantity three-dimensional model in a bidding stage or a building Information BIM (building Information modeling) model in a construction stage, and the building three-dimensional model comprises parameter Information of various members (such as beams, columns, walls and the like). In addition, the target column primitive may be a column primitive of a certain floor in the building three-dimensional model, or a primitive formed by combining columns of multiple floors having a communication relationship.

Step S102: and respectively setting corresponding high-low pile states for each longitudinal bar primitive according to a preset high-low pile setting rule and the position relation of each longitudinal bar primitive in the target column primitives.

Wherein, the height stake attitude is used for the reinforcing bar length that target longitudinal bar primitive exposes at the target floor, the height stake attitude specifically includes: high piles and low piles; the length of the steel bar exposed on the target floor by the high pile state longitudinal bar in the target floor is larger than that of the steel bar exposed on the target floor by the low pile state longitudinal bar.

Specifically, step S102 includes:

step A1: acquiring the setting rule of the high-low piles; wherein, the high-low pile setting rule comprises: the position of the initial longitudinal bar and the high-low pile state of the initial longitudinal bar;

preferably, the position of the initial longitudinal bar is located at the lower left corner of the column cross-sectional view corresponding to the target column primitive, and the high-low pile state of the initial longitudinal bar is as follows: high piles;

it should be noted that before a user creates a column primitive through building modeling software, the position of an initial longitudinal bar and the height state of the initial longitudinal bar in the column primitive can be manually set according to actual requirements, so as to form a high-low pile setting rule.

Step A2: determining a longitudinal bar primitive representing the initial longitudinal bar from the column cross-section diagram corresponding to the target column primitive according to the position of the initial longitudinal bar;

in this embodiment, the primitive of the longitudinal rib located at the lower left corner of the pillar cross-sectional view is set as the starting longitudinal rib.

Step A3: numbering all longitudinal bar primitives in the column cross-section diagram according to a preset numbering rule from the longitudinal bar primitive representing the initial longitudinal bar;

preferably, the numbering rule is as follows: the edge ribs are numbered in an increasing mode along the column side line direction anticlockwise from the initial longitudinal ribs, and after the edge ribs are numbered, the edge ribs are numbered in an increasing mode from the non-edge rib positioned on the leftmost side of the first row to the leftmost side of the first row based on the positions of other longitudinal ribs in the column cross section;

in this embodiment, the number of the initial longitudinal bar is 0, the edge bars are numbered first, and then the non-edge bars are numbered; the edge rib is a longitudinal rib primitive intersected or tangent with a column edge line in the column cross-sectional diagram. As shown in fig. 2, which is a schematic diagram of a cross section of a column, a longitudinal bar primitive numbered 0 in the cross section of the column is a starting longitudinal bar.

Step A4: on the basis of the high-low pile state of the initial longitudinal bar, sequentially setting the high-low pile state of each longitudinal bar primitive from the longitudinal bar primitive representing the initial longitudinal bar according to the numbering sequence; and the high pile state and the low pile state of two longitudinal bar primitives which are adjacent in serial number are different.

In this embodiment, two longitudinal bar primitives adjacent to each other are numbered, one is a high pile and the other is a low pile.

It should be further noted that, when a longitudinal bar primitive is newly added or deleted from the target pillar primitives, the modified longitudinal bar primitives need to be numbered again and the high-low pile states need to be reset in the manner from step a1 to step a 4.

In addition, whether the high pile state and the low pile state of the longitudinal bar of the floor and the longitudinal bar of the previous floor connected with the longitudinal bar of the floor are the same or not is conveniently and quickly checked in the embodiment, the function of classifying and inquiring the high pile state and the low pile state is added, and after the classifying and inquiring of the high pile state and the low pile state, a user can modify the high pile state and the low pile state of the longitudinal bar primitive according to actual requirements.

Step S103: and respectively setting corresponding communication states for each longitudinal bar primitive according to the floor where the target column primitive is located and the position relation of each longitudinal bar primitive in the target column primitive.

Wherein the connected state comprises: the upper communication state of the target longitudinal bar graphic primitive is used for representing whether an upper longitudinal bar graphic primitive connected with the top of the target longitudinal bar graphic primitive exists or not, and the lower communication state of the target longitudinal bar graphic primitive is used for representing whether a lower longitudinal bar graphic primitive connected with the bottom of the target graphic primitive exists or not; the upper communication state comprises: communicating and capping; the lower communication state comprises: and communicating and inserting the ribs.

Specifically, step S103 includes:

In this embodiment, the lower communication states of all the longitudinal bars located at the bottommost part in the lowest floor are set as the joint bars, if the lower communication state is that no other longitudinal bar exists around the target longitudinal bar of the joint bar, the upper communication state of the target longitudinal bar is capping, and if the lower communication state is that other longitudinal bars exist around the target longitudinal bar of the joint bar, the upper communication state of the target longitudinal bar is communication; and not indulge the muscle for the target of dowel to lower part UNICOM's state, indulge the lower part UNICOM state of muscle with this target and set up to the UNICOM, in addition, if this target indulges no other muscle of indulging around the muscle, then the upper portion UNICOM state that the muscle was indulged to this target is the capping, if the target indulges there are other muscle of indulging around the muscle, then the upper portion UNICOM state that the muscle was indulged to this target is the UNICOM.

Further, step S103 further includes:

In this embodiment, the set length is 50 mm; and traversing each longitudinal bar primitive in sequence according to the serial number sequence of the longitudinal bar primitives, and when a plurality of other longitudinal bar primitives exist in the range taking the target longitudinal bar primitive as the circle center and the set length as the radius, setting the communication state of other longitudinal bars which are closest to the target longitudinal bar primitive (have small serial numbers when the distances are the same) to the target longitudinal bar primitive.

It should be further noted that, after the communication state of the longitudinal bar primitive is set according to the above manner, the user may modify the communication state of the longitudinal bar primitive according to actual requirements.

Further, after step S103, the method further includes:

setting the column communication type of the target column graphic element according to the upper communication states of all longitudinal bar graphic elements in the target column graphic element; wherein the column communication types include: a complete communication column, a complete top sealing column and a partial communication column;

setting the column communication type of the target column graphic element according to the lower communication states of all longitudinal bar graphic elements in the target column graphic element; wherein the column communication type further comprises: local tendon inserting columns and new rooting columns.

When the upper communication states of all longitudinal bar primitives in the target column primitive are communicated, the target column primitive is a complete communication column; when the communication states of the upper parts of all the longitudinal bar primitives in the target column primitive are capping, the target column primitive is a complete capping column; when the upper communication state of a part of longitudinal bar primitives in the target column primitives is communication, the target column primitives are part of communication columns; when the communication state of the lower parts of partial longitudinal rib primitives in the target column primitives is communication, the target column primitives are local rib-inserted columns; and when the communication states of the lower parts of all the longitudinal bar primitives in the target column primitive are the inserting bars, the target column primitive is a new root column.

In order to detect whether the communication state of the column longitudinal bars is normal or not in the embodiment, a function of classified inquiry of the communication state is added, and column primitives can be classified according to column communication types, so that a user can efficiently inquire the correctness of the communication state of the column primitives, wherein the upper communication state and the lower communication state of each longitudinal bar in the column primitives are separately counted. After the communication state is classified and inquired, the user can also be modified to the communication state according to the actual requirement, and meanwhile, the quick application to the column with the same name is supported.

Further, after step S103, the method further includes:

step B1: acquiring a first upper layer column primitive connected with the top of the target column primitive and a first lower layer column primitive connected with the bottom of the target column primitive from the building three-dimensional model;

step B2: acquiring a target column primitive with the same column name as that of the target column primitive from the floor where the target column primitive is located;

step B3: acquiring a second upper layer column graphic element connected with the top of the target column graphic element and a second lower layer column graphic element connected with the bottom of the target column graphic element from the building three-dimensional model;

step B4: when the column names of the first upper-layer column primitive and the second upper-layer column primitive are the same and the column names of the first lower-layer column primitive and the second lower-layer column primitive are the same, judging whether a first combined primitive composed of the first upper-layer column primitive, a target column primitive and a first lower-layer column primitive is consistent with a second combined primitive composed of the second upper-layer column primitive, the target column primitive and the second lower-layer column primitive in style;

in step B4, it is determined whether the shape of the first combined primitive coincides with the shape of the second combined primitive;

step B5: if yes, setting the high-low pile state and the communication state of the corresponding longitudinal bar primitive in the target column primitive according to the high-low pile state and the communication state of each longitudinal bar primitive in the target column primitive;

in step B5, a one-to-one correspondence relationship may be established according to the number of each longitudinal rib primitive in the target column primitive and the number of each longitudinal rib primitive in the target column primitive.

In this embodiment, after the high-low pile state and the connected state of one target column primitive are set, the high-low pile state and the connected state of the target column primitive can be synchronized to the target column primitive in a one-key synchronization manner, so that the calculation amount is reduced, and the calculation efficiency is improved.

Step S104: and respectively calculating the size of each longitudinal bar primitive according to the high-low pile state and the communication state of each longitudinal bar primitive.

Specifically, step S104 includes:

It should be noted that the preset calculation rule sets a calculation formula for calculating the length of the anchoring area, and the preset high-low pile exposure size sets the length of the longitudinal bar exposed in the target floor in the high pile state and the length of the longitudinal bar exposed in the target floor in the low pile state.

Further, step S104 further includes:

M＝P-T+L；

wherein P is the floor height of the first floor;

It should be noted that the floor where the target column primitive is located may be a first floor or a second floor.

Further, step S104 further includes:

N＝Q-B+K；

In this embodiment, the length of the longitudinal bar primitive is calculated according to the preset calculation rule for calculating the length of the anchoring area, the exposed size of the high-low pile and the connection length of the longitudinal bar according to the high-low pile state and the communication state of each longitudinal bar primitive in the target column primitives. Wherein the length of the anchoring area is the length of the longitudinal bar in the foundation (wall or beam).

Further, after step S104, the method further includes:

step C1: in a column cross section diagram corresponding to the target column graphic element, modifying the line thickness of a longitudinal bar graphic element according to the high-low pile state of the longitudinal bar graphic element, and adding a communication state identifier in the longitudinal bar graphic element according to the communication state of the longitudinal bar graphic element to obtain a column cross section detailed diagram;

preferably, the longitudinal bar graphic elements in the high pile state are represented by thick circles, and the longitudinal bar graphic elements in the low pile state are represented by thin circles; fig. 3(a) shows a communication state identification schematic diagram when the upper communication state is communication, fig. 3(b) shows a communication state identification schematic diagram when the upper communication state is capping, fig. 3(c) shows a communication state identification schematic diagram when the lower communication state is capping, and fig. 3(d) shows a communication state identification schematic diagram when the lower communication state is dowel; in addition, after the UNICOM state sign has been set up, if this layer is indulged muscle and upper strata and is indulged the muscle UNICOM, nevertheless this layer is indulged the muscle and is indulged the high low stake state of muscle different with the upper strata, then as shown in figure 4, indulge the top mark "commentaries on classics" word of muscle primitive in order to remind the user that high low stake state is different.

In addition, in the embodiment, the diameter size can be marked in each longitudinal bar graphic element in the column cross-sectional diagram; if the diameters of the upper layer longitudinal bars are different from the diameter of the present layer longitudinal bars, marking the diameter of the upper layer longitudinal bars above the diameter number of the longitudinal bars of the present layer longitudinal bar graphic primitive as shown in fig. 5 (a); if the diameter of the upper-layer longitudinal bar is large and the diameter of the upper-layer longitudinal bar is taken as the diameter of the upper-layer longitudinal bar, marking the diameter of the upper-layer longitudinal bar on the left side of the number of the diameters of the longitudinal bars of the graphics primitive of the upper-layer longitudinal bar as shown in fig. 5 (b); if the diameters of the lower layer longitudinal bars are different from the diameter of the present layer longitudinal bars, marking the diameter of the lower layer longitudinal bars below the diameter number of the longitudinal bars of the present layer longitudinal bar graphic primitive as shown in fig. 5 (c); if the diameter of the lower layer longitudinal rib is small and the diameter of the lower layer longitudinal rib is the diameter of the longitudinal rib of the layer, the diameter of the longitudinal rib of the layer and the diameter of the lower layer longitudinal rib are marked below the diameter number of the longitudinal rib of the graphics primitive of the layer as shown in fig. 5 (d).

In this embodiment for the convenience of indulging the muscle and the reducing of muscle is indulged to the upload and handle, increased the function of the categorised inquiry of reducing state, and provide the selection of getting the diameter to the big muscle of indulging of upper diameter, provide the selection that sets up the overlap joint and change the UNICOM state to indulging the muscle different at this layer and upper diameter.

Step C2: adding the column cross-section detail drawing to a column stub board of the target column primitive, and adding the size of each longitudinal bar primitive to the column stub board.

Because the calculation result of the longitudinal bars needs to guide the reinforcement binding of a construction site, the embodiment provides the function of automatically generating the column material plate, and the column cross section detailed drawing, the longitudinal bar position, the longitudinal bar number, the high-low pile state, the communication state and the longitudinal bar size are displayed in the column material plate, so that a constructor can conveniently combine the column material plate to carry out rapid construction.

Specifically, as shown in fig. 6, the column material brand indicating purpose is that, in the process of editing the column material brand, the steel bar results are displayed in the column material brand according to the sequence of longitudinal bar first and hoop bar later, insertion bar first and connection bar second, small diameter first and large diameter second, and longitudinal bar numbering; the longitudinal bars which are combined and displayed in the column big sample drawing respectively display corresponding bar numbers in the circles; the stirrup shows the muscle number that the stirrup corresponds on the stirrup line, and outer stirrup number mark is in the stirrup line one side that is close to the post sideline, and interior hoop, lacing wire number mark are in the stirrup line one side that is not close to the post sideline. The longitudinal bars and the stirrups mark bar numbers, so that a user can conveniently tie the column reinforcing bars in the column material plate in an up-down comparison mode. In addition, in order to make the reinforcing steel bar information display of the column material plate compact, the reinforcing steel bar information needs to be divided into two large columns for display, the left column is arranged first, then the right column is arranged, the row number of the required reinforcing steel bar is determined, then the row number is divided by 2, even distribution can be achieved, and when the row number cannot be evenly distributed, more rows are displayed in the left column. The steel bar information needs self-adaptation line height in order to guarantee the rationality of special-shaped stirrup display, and the adaptation is the line height of two rows, and after the line height changes, the size of the steel bar graph of another row adapts again. When editing column material cards, a plurality of column material cards need to be output, the fixed width of each column material card is 4000mm, the height of each column material card is not fixed, and if the column width is larger than 4000mm, the column material cards are zoomed. The tops of the column material cards in the first row are parallel and level, the space between every two column material card tables is 500mm, the columns are changed after 20 column material cards are filled, the tops of the column material cards in the second row are the lowest positions of the column material cards in the previous row and then are 1000mm downward, and the purpose of neatly and well dividing is achieved.

In addition, in the embodiment, classification query can be provided for the communication state, so that the communication state of the column longitudinal bars can be modified in batch; high and low pile classification query can be provided according to the high and low pile states, and the communication state of the column longitudinal reinforcement body layer and the upper layer can be modified in batches; the variable diameter classified query can be provided aiming at the variable diameter state, and the communication state, the variable diameter and the lap joint state of the column longitudinal ribs can be modified in batches.

According to the embodiment, the high-low pile state and the communication state of the longitudinal bars in the column can be determined based on the building three-dimensional model, and the size of the longitudinal bars can be accurately calculated according to the high-low pile state and the communication state of each longitudinal bar and a preset calculation rule; in addition, still can show the positional information, height stake state, UNICOM's state, reducing state and the size information of every vertical muscle in the post through post cross section picture to guide constructor to carry out on-the-spot reinforcement in the construction stage in the later stage, thereby reach the purpose that processing is reasonable, the ligature is convenient, save the reinforcing bar.

Example two

The embodiment of the invention provides a device for calculating longitudinal bars in a column, which comprises the following components in part by weight as shown in fig. 7:

the obtaining module 701 is configured to obtain a building three-dimensional model, and determine a target column primitive and a longitudinal bar primitive located in the target column primitive from the building three-dimensional model;

a first setting module 702, configured to set, according to a preset high-low pile setting rule and a position relationship of each longitudinal bar primitive in the target column primitive, a corresponding high-low pile state for each longitudinal bar primitive;

a second setting module 703, configured to set, according to the floor where the target column primitive is located and a position relationship between each longitudinal bar primitive in the target column primitive, a corresponding communication state for each longitudinal bar primitive;

and the calculating module 704 is configured to calculate the size of each longitudinal bar primitive according to the high-low pile state and the communication state of each longitudinal bar primitive.

Specifically, the first setting module 702 is configured to:

acquiring the setting rule of the high-low piles; wherein, the high-low pile setting rule comprises: the position of the initial longitudinal bar and the high-low pile state of the initial longitudinal bar; determining a longitudinal bar primitive representing the initial longitudinal bar from the column cross-section diagram corresponding to the target column primitive according to the position of the initial longitudinal bar; numbering all longitudinal bar primitives in the column cross-section diagram according to a preset numbering rule from the longitudinal bar primitive representing the initial longitudinal bar; on the basis of the high-low pile state of the initial longitudinal bar, sequentially setting the high-low pile state of each longitudinal bar primitive from the longitudinal bar primitive representing the initial longitudinal bar according to the numbering sequence; and the high pile state and the low pile state of two longitudinal bar primitives which are adjacent in serial number are different.

Further, the second setting module 703 is specifically configured to:

when the target column graphic elements are positioned on the lowest floor, the lower communicated states of all longitudinal bar graphic elements positioned at the bottom in the target column graphic elements are set as the inserting bars; acquiring a column cross-section diagram corresponding to the target column primitive, sequentially traversing each longitudinal rib primitive in the column cross-section diagram, and judging whether other longitudinal rib primitives exist within a range taking the target longitudinal rib primitive as a circle center and a set length as a radius; if so, setting the upper communication state of the target longitudinal bar primitive to be communicated when the target longitudinal bar primitive is provided with the lower communication state, or setting the lower communication state of the target longitudinal bar primitive to be communicated when the target longitudinal bar primitive is not provided with the lower communication state; and if not, setting the upper communication state of the target longitudinal bar primitive as a capping state.

Further, the second setting module 703 is further configured to:

when the target column primitive is not located at the lowest floor, acquiring a connecting column primitive connected with the bottom of the target column primitive; setting the lower communication state of the longitudinal bar primitives which have a connection relation with the longitudinal bar primitives in the connecting column primitives in the target column primitives according to the upper communication state of each longitudinal bar primitive in the connecting column primitives; acquiring a column cross-section diagram corresponding to the target column primitive, sequentially traversing each longitudinal rib primitive in the column cross-section diagram, and judging whether other longitudinal rib primitives exist within a range taking the target longitudinal rib primitive as a circle center and a set length as a radius; if so, setting the upper communication state of the target longitudinal bar primitive to be communicated when the target longitudinal bar primitive is provided with the lower communication state, or setting the lower communication state of the target longitudinal bar primitive to be communicated when the target longitudinal bar primitive is not provided with the lower communication state; if not, setting the upper communication state of the target longitudinal bar primitive as a capping state when the target longitudinal bar primitive is provided with the lower communication state, or setting the lower communication state of the target longitudinal bar primitive as a dowel bar when the target longitudinal bar primitive is not provided with the lower communication state.

Further, the calculating module 704 is specifically configured to:

when the lower communication state of the target longitudinal bar graphic primitive is a plug-in, calculating the length of an anchoring area of the target longitudinal bar graphic primitive according to a preset calculation rule; calculating the exposure length of the target longitudinal bar graphic element in the target column graphic element according to preset high-low pile exposure sizes and high-low pile states of the target longitudinal bar graphic element; taking the sum of the length of the anchoring area and the exposed length as the total length of the target longitudinal bar graphic element;

when the upper communication state and the lower communication state of the target longitudinal bar graphic element are both communicated, calculating the lower length M of the target longitudinal bar graphic element in the first floor according to the following formula: m ═ P-T + L; wherein P is the floor height of the first floor; t is the exposure length of a first longitudinal bar primitive connected with the bottom of the target longitudinal bar primitive in the first floor; l is the connection length of the target longitudinal bar graphic element and the first longitudinal bar graphic element; calculating the exposure length of the target longitudinal bar graphic element in the second floor according to the preset high-low pile exposure size and the high-low pile state of the target longitudinal bar graphic element; wherein the second floor is above the first floor; taking the sum of the lower length and the exposed length as the total length of the target longitudinal bar graphic element;

when the upper communication state of the target longitudinal bar primitive is capping, calculating the lower length N of the target longitudinal bar primitive in the target column primitive according to the following formula: N-Q-B + K; q is the floor height of a target floor where the target column graphic primitive is located; b is the exposure length of a second longitudinal bar primitive connected with the bottom of the target longitudinal bar primitive in the target floor; k is the connection length of the target longitudinal bar graphic element and the second longitudinal bar graphic element; calculating the length of an anchoring area of the longitudinal bar graphic primitive according to a preset calculation rule; and taking the sum of the lower length and the length of the anchoring area as the total length of the target longitudinal bar primitive.

Further, the apparatus further comprises:

the synchronization module is used for acquiring a first upper layer column graphic primitive connected with the top of the target column graphic primitive and acquiring a first lower layer column graphic primitive connected with the bottom of the target column graphic primitive from the building three-dimensional model; acquiring a target column primitive with the same column name as that of the target column primitive from the floor where the target column primitive is located; acquiring a second upper layer column graphic element connected with the top of the target column graphic element and a second lower layer column graphic element connected with the bottom of the target column graphic element from the building three-dimensional model; when the column names of the first upper-layer column primitive and the second upper-layer column primitive are the same and the column names of the first lower-layer column primitive and the second lower-layer column primitive are the same, judging whether a first combined primitive composed of the first upper-layer column primitive, a target column primitive and a first lower-layer column primitive is consistent with a second combined primitive composed of the second upper-layer column primitive, the target column primitive and the second lower-layer column primitive in style; and if so, setting the high-low pile state and the communication state of the corresponding longitudinal bar primitive in the target column primitive according to the high-low pile state and the communication state of each longitudinal bar primitive in the target column primitive.

Still further, the apparatus further comprises:

the material plate module is used for modifying the line thickness of the longitudinal bar graphic primitive according to the high-low pile state of the longitudinal bar graphic primitive in the column cross section diagram corresponding to the target column graphic primitive, and adding a communication state identifier in the longitudinal bar graphic primitive according to the communication state of the longitudinal bar graphic primitive to obtain a column cross section detailed diagram; adding the column cross-section detail drawing to a column stub board of the target column primitive, and adding the size of each longitudinal bar primitive to the column stub board.

EXAMPLE III

The embodiment also provides a computer device, such as a smart phone, a tablet computer, a notebook computer, a desktop computer, a rack server, a blade server, a tower server or a rack server (including an independent server or a server cluster composed of a plurality of servers) capable of executing programs, and the like. As shown in fig. 8, the computer device 80 of the present embodiment at least includes but is not limited to: a memory 801, a processor 802, which may be communicatively coupled to each other via a system bus. It is noted that FIG. 8 only shows the computer device 80 having the components 801 and 802, but it is understood that not all of the shown components are required to be implemented, and that more or fewer components can be implemented instead.

In this embodiment, the memory 801 (i.e., a readable storage medium) includes a flash memory, a hard disk, a multimedia card, a card-type memory (e.g., SD or DX memory, etc.), a Random Access Memory (RAM), a Static Random Access Memory (SRAM), a read-only memory (ROM), an electrically erasable programmable read-only memory (EEPROM), a programmable read-only memory (PROM), a magnetic memory, a magnetic disk, an optical disk, and the like. In some embodiments, the storage 801 may be an internal storage unit of the computer device 80, such as a hard disk or a memory of the computer device 80. In other embodiments, the memory 801 may be an external storage device of the computer device 80, such as a plug-in hard disk, a Smart Media Card (SMC), a Secure Digital (SD) Card, a flash Card (FlashCard), or the like, provided on the computer device 80. Of course, the memory 801 may also include both internal and external memory units of the computer device 80. In the present embodiment, the memory 801 is generally used for storing an operating system and various types of application software installed in the computer device 80. In addition, the memory 801 can also be used to temporarily store various types of data that have been output or are to be output.

Processor 802 may be a Central Processing Unit (CPU), controller, microcontroller, microprocessor, or other data Processing chip in some embodiments. The processor 802 generally operates to control the overall operation of the computer device 80.

Specifically, in the present embodiment, the processor 802 is configured to execute a program of a method for calculating longitudinal bars in a column, which is stored in the memory 801, and when executed, the program of the method for calculating longitudinal bars in a column implements the following steps:

The specific embodiment process of the above method steps can be referred to in the first embodiment, and the detailed description of this embodiment is not repeated here.

Example four

The present embodiments also provide a computer readable storage medium, such as a flash memory, a hard disk, a multimedia card, a card type memory (e.g., SD or DX memory, etc.), a Random Access Memory (RAM), a Static Random Access Memory (SRAM), a Read Only Memory (ROM), an Electrically Erasable Programmable Read Only Memory (EEPROM), a Programmable Read Only Memory (PROM), a magnetic memory, a magnetic disk, an optical disk, a server, an App application mall, etc., having stored thereon a computer program that when executed by a processor implements the method steps of:

It should be noted that, in this document, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other like elements in a process, method, article, or apparatus that comprises the element.

The above-mentioned serial numbers of the embodiments of the present invention are merely for description and do not represent the merits of the embodiments.

Through the above description of the embodiments, those skilled in the art will clearly understand that the method of the above embodiments can be implemented by software plus a necessary general hardware platform, and certainly can also be implemented by hardware, but in many cases, the former is a better implementation manner.

The above description is only a preferred embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims

1. A method of calculating a longitudinal bar in a column, the method comprising:

2. The method for calculating the longitudinal bars in the column according to claim 1, wherein the setting of the corresponding high-low pile state for each longitudinal bar primitive according to the preset high-low pile setting rule and the position relationship of each longitudinal bar primitive in the target column primitive respectively comprises:

3. The method for calculating the longitudinal bar in the column according to claim 1, wherein the step of respectively setting a corresponding communication state for each longitudinal bar primitive according to the floor where the target column primitive is located and the position relationship of each longitudinal bar primitive in the target column primitive comprises:

4. The method according to claim 3, wherein a corresponding communication state is set for each longitudinal rib primitive according to the floor where the target column primitive is located and the position relationship between each longitudinal rib primitive in the target column primitive, and further comprising:

5. The method for calculating the longitudinal bar in the column according to claim 1, wherein after the corresponding communication state is respectively set for each longitudinal bar primitive according to the floor where the target column primitive is located and the position relationship of each longitudinal bar primitive in the target column primitive, the method further comprises:

6. The method for calculating the longitudinal bar in the column according to claim 4, wherein the step of calculating the size of each longitudinal bar primitive according to the high-low pile state and the connected state of each longitudinal bar primitive comprises:

7. The method for calculating the longitudinal bar in the column according to claim 4, wherein the step of calculating the size of each longitudinal bar primitive according to the high-low pile state and the connected state of each longitudinal bar primitive comprises:

M＝P-T+L；

wherein P is the floor height of the first floor;

8. The method for calculating the longitudinal bar in the column according to claim 4, wherein the step of calculating the size of each longitudinal bar primitive according to the high-low pile state and the connected state of each longitudinal bar primitive comprises:

N＝Q-B+K；

9. The method of claim 1, wherein after the step of calculating the size of each longitudinal bar element according to the high-low pile state and the connected state of each longitudinal bar element, the method further comprises:

10. A computer device, the computer device comprising: memory, processor and computer program stored on the memory and executable on the processor, characterized in that the processor implements the steps of the method of any of claims 1 to 9 when executing the computer program.

11. A computer-readable storage medium, on which a computer program is stored, which, when being executed by a processor, carries out the steps of the method of any one of claims 1 to 9.